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Federal Court
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Cour fédérale
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Date: 20090708
Docket: T-1712-07
Citation: 2009 FC 711
BETWEEN:
RATIOPHARM
INC.
Plaintiff
and
PFIZER
LIMITED
Defendant
REASONS FOR
JUDGMENT
(Public version of the Confidential Reasons
for Judgment issued July 8, 2009)
HUGHES J.
[1]
This
action deals with the validity of Canadian Patent 1,321,393 (the ’393 Patent).
The Plaintiff Ratiopharm Inc. seeks a declaration under section 60(1) of the Patent
Act, R.S.C. 1985, c.P.4, that the ’393 Patent is invalid and a direction
under section 62 of the Patent Act that an entry in the records of the
Canada Patent Office be made to that effect. For the Reasons that follow, I
find that the ’393 Patent is invalid and that such a declaration will be given.
Ratiopharm is entitled to its costs.
INDEX
[2]
To
assist the reader, the following is a Table of Contents for these Reasons giving
paragraph numbers for each heading:
THE
PARTIES........................................................................................... [3]
to [4]
THE
’393 PATENT.................................................................................. [5]
to [10]
AGREED
FACTS AND DOCUMENTS ............................................. [11]
to [12]
PREVIOUS
LITIGATION.................................................................... [13]
to [18]
THE
WITNESSES.................................................................................. [19]
to [26]
ISSUES.................................................................................................... [27]
to [28]
PERSON
SKILLED IN THE ART....................................................... [29]
to [31]
DATE
OF INVENTION........................................................................ [32]
to [34]
CONSTRUCTION
OF THE PATENT – CLAIM 11........................... [35]
to [44]
DEVELOPMENT
OF A PHARMACEUTICAL IN THE
MID
1980S............................................................................................. [45]
to [51]
DEVELOPMENT
AND PATENTING OF AMLODIPINE
BESYLATE........................................................................................... [52]
to [107]
THE
“INVENTION” AS PROMISED BY THE ’393 PATENT..... [108] to [112]
COMPARING WHAT THE ’393 PATENT SAYS AND
WHAT
ACTUALLY HAPPENED..................................................... [113]
to [152]
CONCLUSIONS AS TO WHAT THE INVENTORS DID
AND
WHAT THE PATENT SAYS................................................................. [153]
ADDRESSING
THE LEGAL ISSUES............................................. [154]
to [204]
A.
General ...................................................................................... [154]
B.
Obviousness............................................................................... [158]
C.
Selection
Patent.......................................................................... [174]
D.
Utility.......................................................................................... [181]
E.
Sufficiency.................................................................................. [187]
F.
Section 53.................................................................................. [195]
CONCLUSION................................................................................... [205]
to [207]
COSTS................................................................................................ [208]
to [209]
THE PARTIES
[3]
The
Plaintiff Ratiopharm Inc. (sometimes spelled ratiopharm inc.) is a Canadian
corporation located in Montréal. It previously was engaged in proceedings in
this Court under the provisions of the Patented Medicines (Notice of
Compliance) Regulations, SOR/93-133, as amended (NOC Regulations),
as a generic pharmaceutical supplier or “second person” as defined in the NOC
Regulations, respecting the ’393 Patent. There is no dispute that
Ratiopharm is an “interested person” within the meaning of section 60(1) of the
Patent Act in seeking the relief requested herein.
[4]
The
Defendant Pfizer Limited is a United Kingdom corporation located in England. The ’393
Patent on its face states that it was issued and granted to Pfizer Limited. No
contest has been made as to the continued ownership of the patent by Pfizer
Limited. The Patent Act refers to a patent owner such as Pfizer Limited
as the patentee.
THE ’393 PATENT
[5]
The
patent at issue is Canadian Patent No. 1,321,393. It was issued and granted to
Pfizer Limited on August 17, 1993. The application for this patent was filed
with the Canadian Patent Office on April 2, 1987 thus the provisions of
the “old” Patent Act, applicable to patents maturing from applications
filed before October 1, 1989, apply to the ’393 Patent. Thus, unless a
challenge to the validity of this patent is successful, it will expire 17 years
from the date it was granted, that is on August 17, 2010.
[6]
The
’393 Patent claims priority from an application for a patent filed with the
United Kingdom Patent Office, Application No. 8608335, on April 4, 1986. A copy of
that application has been filed as Exhibit 1 Document 126.
[7]
Edward
Davison and James I. Wells are named in the patent as inventors. Both of these
persons testified at the trial of this action.
[8]
The
’393 Patent is entitled “Besylate Salt of Amlodipine” and states
in the opening paragraph of the specification at page 1:
“The present invention relates to the
improved pharmaceutical salts of amlodipine and pharmaceutical compositions
thereof”
[9]
The
parties have agreed that the validity of the patent as a whole will be
determined on the basis of the validity of Claim 11. That claim reads as
follows:
“11. The besylate salt of
amlodipine.”
[10]
I
will consider this patent further.
AGREED FACTS AND
DOCUMENTS
[11]
I
have been greatly assisted by counsel for the parties who have come to an
agreement on some facts for the purposes of this action and, more particularly,
to an agreement as to some 168 documents which may be relevant and have been entered
as Exhibit 1 at trial. The individual documents in Exhibit 1 are referred to by
Tab numbers. It has been agreed that those documents do not have to be proved
in evidence, that they are true copies of the originals sent and received by
the parties as indicated on the face on or about the dates as indicated on
their face and that the published documents were published on the date
indicated on their face. After discussion with Counsel for the parties during
argument it was also agreed that the Court should on be required to have regard
to those documents in Exhibit 1 that had been specifically referred to by a
witness in giving direct evidence or in cross-examination or had been referred
to as part of an expert report or in those portions of discovery as put in
evidence at trial.
[12]
For
convenience, I repeat the Agreed Facts which were entered as Exhibit 2:
1.
The
plaintiff, ratiopharm inc. is a corporation organized and existing under the
laws of Canada and having a registered head office at 17800 Rue Lapointe, Mirabel, Quebec, J7J 1P3.
2.
The
defendant, Pfizer Limited, is a corporation organized and existing under the
laws of the United Kingdom and has a principal office or place of business at
Ramsgate Road, Sandwich, Kent, CT13 9NJ, England.
3.
The
defendant is the named owner of Canada Patent 1,321,393 (the “393 Patent”).
4.
The
393 Patent is based on an application filed in Canada on April 2, 1987.
5.
The
393 Patent claims priority from U.K. patent application 8608335 filed on
April 4, 1986.
6.
The
393 Patent was issued on August 17, 1993.
7.
The
393 Patent expires on August 17, 2010.
PREVIOUS LITIGATION
[13]
The
’393 Patent has been the subject of previous litigation in this Court and in
the Federal Court of Appeal in the context of the Patented Medicines
(Notice of Compliance) Regulations, SOR/93-134,as periodically amended- (NOC)
Regulations.
[14]
In
Pfizer Canada Inc. and Pfizer Limited v. Canada (Minister of Health) and
Ratiopharm Inc., February 17, 2006, 2006 FC 220, 46 CPR (4th)
281, Justice von Finckenstein of this Court (as he then was) dismissed an
application for prohibition holding that Pfizer had failed to prove that the
allegations as to invalidity of the ‘393 Patent were not justified. He held, at
paragraph 58 of his reasons that he did not need to deal with the issue of
obviousness. The Federal Court of Appeal in a decision delivered on June 9,
2006, 2006 FCA 214, 52 CPR (4th) 241, allowed the appeal and issued
a prohibition Order holding that the allegations as to invalidity of the ’393
Patent were not justified. In a related decision based on what the Federal
Court of Appeal held to be speculative new matters, Ratiopharm’s application to
set aside that Federal Court of Appeal decision was dismissed on December 18,
2007, 2007 FCA 407.
[15]
The
’393 Patent came before me in Pfizer Canada Inc., Pfizer Inc. and Pfizer
Limited v. Canada (Minister of Health) and Pharmascience
Inc.
I delivered a decision on April 17, 2008, 2008 FC 500, 326 FTR 88, allowing
the application for prohibition. I concluded at paragraph 117:
[117]
In conclusion, I have found that Pharmascience is precluded by the
earlier “Ratiopharm” litigation from asserting obviousness challenges to the
’393 patent. Given the recent decision of the Federal Court of Appeal,
2008 FCA 108 in Pfizer v. Canada (Minister of Health), the challenge to
validity on the basis of sufficiency fails. On the balance of probabilities the
challenge to validity bases on lack of utility fails. As a result,
Pharmascience’s allegation that the ’393 patent is invalid is not
justified. Pfizer is entitled to an Order prohibiting the Minister from
issuing a Notice of Compliance to Pharmascience in respect of its application
respecting 5 and 10 mg tablets containing amlodipine besylate at issue in these
proceedings.
[16]
A
related patent, United States Patent 4,879,303 (the ’303 Patent), put in
evidence as Exhibit 60, has been the subject of litigation in that country.
The United States District Court for the Middle District of North Carolina in Pfizer
Inc. v. Synthon Holdings BV et al in proceedings identified as 1:05CV39,
held the ‘303 Patent to be valid and infringed. The United States Court of
Appeals for the Federal Circuit (US CAFC) reversed that decision holding the
’303 Patent to be invalid for obviousness in a decision reported at 480 F.3d
1348, U.S. App. Lexis 6623, 82 U.S.P.Q. 2D (BNA) 1321.
[17]
The
United
States Court
decisions are not binding upon this Court and are based on law that may in some
respects be different from ours. Nonetheless, the decisions may be instructive.
[18]
The
decisions of this Court and the Federal Court of Appeal were dealt with in the
context of NOC Regulations and do not constitute res judicata in
the present action. Again, however, they are instructive.
THE WITNESSES
[19]
The
Plaintiff Ratiopharm Inc. called 5 witnesses at trial, all as expert witnesses.
The Defendant Pfizer Limited called 8 witnesses of which 5 were fact witnesses
and 3 were expert witnesses. Each party also entered portions of the transcripts
of the discovery of the opposite party. Exhibit 4 is portions of the
transcripts and exhibits to the discovery of the Defendant Pfizer Limited. Exhibit
5 is portions of the transcripts of the discovery of the Plaintiff Ratiopharm
Inc.
[20]
By
agreement between counsel, the Defendant Pfizer Limited called some of its
factual witnesses first. They were examined in chief and cross-examined. They
are, in the order that they were called:
(1)
Dr.
James I. Wells, one of the two named inventors of the ’393 Patent. He
worked with Pfizer Limited in the period from 1981 to 1989. He subsequently
has worked with other pharmaceutical organizations and was a university
lecturer and author of a text in that area. He testified as to his role in
developing what became the subject matter of the ’393 Patent. I believe that he
endeavoured to give honest and direct testimony even if he was at times
somewhat brusque. He clearly stated in his replies when he did not know or
could not remember and when his answers were based on speculation and
conjecture. However, where his answers, were directed to obviousness or worth a
try or empirical research, they seemed to be rehearsed. It became clear in
Cross-Examination that a declaration that he swore in United States Patent
Office contained a number of inconsistencies and misstatements. In general, I
accept his evidence except where it is contradicted by documents such as, in
particular, Exhibit 1, Document 111.
(2)
Mr.
Edward Davison, the other of the two named inventors of the ’393 Patent.
He graduated with a B.Sc. in chemistry and joined Pfizer Limited in 1969 where
he continued to work until his retirement in 2000. In the period from the mid
1970’s to 1989, he worked in pharmaceutical research and development. In that
context, he worked on what became the subject of the ’393 Patent. He testified
as to his role in that regard. I believe that Mr. Davison largely endeavoured
to testify honestly, however, his answers were quite often prolix and filled
with unnecessary detail which tended to obfuscate his answers. He would often
not address the real questions. Therefore I am cautious when dealing with his
testimony.
(3)
Mr.
Alan Pettman, a senior research fellow employed by Pfizer Limited. He
was the person representing Pfizer Limited on discovery. Mr. Pettman joined
Pfizer limited in 1977 and earned his Bachelor’s degree in chemistry while on
the job. He remains with that company to this day. During the period in the early
1980s, he was engaged in the process research and development department and
made most of the amlodipine salts which were the subject of the studies made
by and on behalf of Wells and Davison. He gave his testimony in an honest and
straightforward manner. I accept the evidence that he has given.
(4)
Dr.
Robin Platt, a PhD chemist in organic chemistry currently employed by
an independent pharmaceutical formulation development company. He was employed
by Pfizer Limited in the period from 1978 to 1993 where, in a variety of roles
having increasing responsibility, he dealt with analytical chemistry including
assessments of purity and quality. He testified as to his involvement in
assessing amlodipine and amlodipine salts samples particularly as to stability.
In general, he testified in a direct and honest manner, however, as Cross-Examination
continued, he became somewhat unreasonable and awkward, answering many
questions with a “not necessarily” then proceeding to make imperceptible points
of difference such as whether a sample had melted as stated in a particular
report or only gave an appearance of melting. For this reason, I will treat his
evidence cautiously.
[21]
At
this point, the factual evidence of the Defendant was interrupted due to
witness availability. The Plaintiff Ratiopharm Inc. next led the evidence of
the following expert witnesses who were examined in chief and cross-examined.
By agreement between counsel, the expertise of such witnesses put forward as
experts by either side was not challenged but left to be determined, if
necessary, in final argument. Further, by agreement between counsel, all
expert reports of both parties were deemed to have been read in evidence
subject to any corrections noted at the time that the reports were submitted in
evidence. The Plaintiff’s experts were called in the following order:
(1)
Dr.
Ian M. Cunningham of the Orkney Islands, Scotland, an
independent consultant to the pharmaceutical industry. He was trained as a
medicinal chemist, awarded a Ph.D. and engaged in post-doctoral studies. He
held several posts in major pharmaceutical innovator companies in the United
Kingdom
from 1977 onward, including working for ICI, a major pharmaceutical innovator
company in the United Kingdom, in the 1980’s. He provided an initial report,
exhibits to that report, and a rebuttal report marked as Exhibit 17, 18 and 19
respectively. I accept his evidence, he was not shaken nor did he retreat from
his evidence on Cross-Examination. He spoke in a low voice and, on occasion,
was difficult to hear, a problem that was rectified by microphones. He was
forthright and honest. I am particularly impressed with his depth of actual
experience in the pharmaceutical industry during the relevant period.
(2)
Dr.
Jerry L. Atwood of Columbia, Missouri. He is a professor and
Department Chair of the Department of Chemistry at the University of Missouri
– Columbia. He has
since 1968 taught, and written many articles, edited journals and been granted
patents in the area of solid state chemistry, crystallization and organic
chemistry. He has consulted widely in the field of pharmaceutical chemistry. His
first report is Exhibit 22 and the documents referred to in that report are
Exhibits 23 and 24. His rebuttal report is Exhibit 25. He gave his evidence in
a careful, clear and convincing manner. He answered the questions as put carefully
and convincingly. I accept his evidence.
(3)
Dr.
Gilbert S. Banker of Carmel, Indiana. He is Dean
Emeritus and Distinguished Professor of Drug Delivery Emeritus at the
University of Iowa, College of
Pharmacy.
He obtained a Ph.D. in Industrial Pharmacy and Pharmaceutical Chemistry. He has
since the early 1960’s taught many courses, written many books and articles and
received many awards for work in the chemical and physical design for food,
drug and cosmetic applications. He is listed in various “Who’s Who”
publications. He has consulted to both innovator and generic pharmaceutical
companies. He is very knowledgeable and experienced in the area of
pharmaceutical preparation and apparatus for that purpose. His report is
Exhibit 27 and the documents referred to in that report are Exhibits 28, 29,
and 30. He gave his evidence in an honest and forthright manner. I accept his
evidence.
(4)
Dr.
Gordon Amidon of Ann Arbor, Michigan. He is a professor
of Pharmacy and Pharmaceutical Sciences at the College of Pharmacy at the University
of Michigan.
He received his Ph.D. in Pharmaceutical Chemistry from that University. He has
taught, written and held leadership positions in pharmaceutical related areas
for over 30 years. His report is Exhibit 35 and the documents referred to in
that report is Exhibit 36. He gave his evidence in an honest and
straightforward manner. I accept his evidence.
(5)
Dr.
Nicholas F. Cappucino of Lambertville, New Jersey. He is the
Chief Scientific Officer of Eagle Pharmaceutical, a specialty pharmaceutical
company involved in the preparation of dosage forms and difficult generic
products. He received his Ph.D. in Organic Chemistry from the Stevens Institute
of Technology, Hoboken, New Jersey. He has over30 years
experience in the pharmaceutical industry. His report is Exhibit 40 and the
documents referred to in that report are Exhibit 41. Although Dr. Cappucino
gave his evidence in a clear and straightforward manner it is evident that he
is closely associated with the generic pharmaceutical industry in many ways
including representing that industry in various capacities in trade and
government relations associations. I treat his evidence cautiously for that
reason.
[22]
The
Defendant Pfizer Limited next called its expert witnesses who were examined and
cross-examined in the following order:
1.
Dr.
Trevor Laird of East Sussex, England. He received a Ph. D.
in organic chemistry and engaged in post-doctoral work in that area. He was engaged
as a research pharmaceutical chemist at increasing levels of responsibility at
Smith-Kline-French in the 1980’s period with which we are concerned. Presently he
is engaged as a principal in Scientific Update, an organization that publishes
literature and trains scientists and others in the chemical and pharmaceutical
industries. His report is Exhibit 44 and the documents referred to in that
report are Exhibit 45. He gave his evidence candidly except in the area of the
use of benzene hydrochloric acid where when confronted with evidence to the
contrary as to what was set out in his report he became overly defensive. Thus
I will use his evidence cautiously in that area but only in that area since the
balance of his evidence did provide a useful overview.
2.
Dr.
Gerald S. Brenner of Plymouth Meeting, Pennsylvania. He is a
pharmaceutical chemist who has worked in the industry for over 40 years
including working with Merck, a major pharmaceutical company, in the 1980’s in
formulation development. He received a Ph. D. in organic chemistry from the University
of Wisconsin.
His report is Exhibit 48 and the documents referred to in that report are
Exhibit 49. Dr Brenner has appeared frequently as a witness in this Court and
elsewhere including giving testimony in other proceedings respecting the ‘393
Patent. On Cross-Examination he tended to avoid or obfuscate questions that he
found difficult. I will treat his evidence very cautiously. When he conceded
answers that were unfavourable to Pfizer those concessions must be given
weight.
3.
Dr.
James McGinity of Austin, Texas. He is a tenured
professor at the College of Pharmacy, University
of Texas,
teaching and having taught a number of courses in the pharmaceutical area. He
received his Ph. D. in physical pharmacy from the University of Iowa in 1972. He
has written and consulted widely in respect of a range of pharmaceutical
formulation issues. His report is Exhibit 57 and the four Volumes of documents
referred to in that report are collectively marked as Exhibit 58. Like Dr
Brenner, Dr. McGinity has testified previously in this Court and in the United
States Court
system in respect of the ‘393 Patent and the US ‘303 Patent.
He was confronted in Cross-Examination with several contradictions between his
evidence given in the United States litigation and his
evidence given in this case. I found his endevours to distinguish between his
evidence in this action and the United States proceedings to be
unsatisfactory. I found that initially his answers on Cross-Examination were
succinct and to the point however when difficult questions arose he tended to
avoid giving a direct answer or to obfuscate. I have difficulty in having any confidence
in his evidence. Further his evidence in chief by way of a report (Exhibit 57)
is drafted in a way that on several occasions leaves the impression that he is
giving factual first hand evidence as to what the inventors or other at Pfizer
said, did, or thought, which is not the case. He was not there and did not
participate in the development work. By way of example he says at paragraph
37: “However because of their hygroscopicity, these salts
were not progressed further” and in paragraph 38: “The inventors were
not looking for a salt that met any particular numerical threshold”. There
are other examples. His report says at paragraph 14(g) that he looked at “various
other documents which I understand from counsel to Pfizer to have been
produced in this matter”. At paragraph 45 he says “I am advised by
counsel to Pfizer that there are limited data available…” Dr. McGinity
said in Cross-Examination that he had not spoken to the inventors. Taking the
tenor of his evidence as a whole I view it as containing much that is hearsay, prepared
in conjunction with counsel for Pfizer, under the guise of giving expert
evidence, while in reality providing a narrative of a Pfizer-biased view as to
the development of the besylate product. In so doing Dr. McGinity overstepped
the role of an expert and became an advocate. I will treat his evidence with
great caution.
[23]
The
Defendant Pfizer Limited concluded the evidence by calling one more factual
witness, who was examined and cross-examined. Counsel for Pfizer had indicated
early in the trial that Dr. Davidson, a senior person at Pfizer Limited heavily
involved in the relevant development work, would also be called as a witness
for Pfizer but he never appeared. Pfizer’s Counsel in argument made reference
to portions of Pfizer’s discovery read in at trial by Ratiopharm in which it
was stated that Dr. Davidson had no recollection as to certain matters however
this does not mean that he need not be called. Dr. Davidson could well have
remembered various matters relevant to the issues and been made available for
cross-examination. He was not. No reason has ever been given for his failure
to testify at trial particularly since in the early days of the trial the Court
was led to believe by Pfizer’s Counsel that he would appear. Pfizer concluded
its evidence by tendering an affidavit upon which there was no Cross-Examination.
The evidence therefore, as presented, was:
1.
Dr.
James W. Moore of Sandwich, Kent, England. He is a
retired Chartered Patent Agent. He worked in the Pfizer Limited patent
department from 1975 until his retirement in 2000. During that time he drafted
and prosecuted patent applications and mentored the work of others including
Jenny Bowery, a trainee who worked briefly with Pfizer in the mid 1980’s and
left, apparently finding the chemistry too challenging. He gave evidence as to
the preparation and filing of the parent UK patent
application respecting the ‘393 patent. He gave his evidence in a clear and
forthright manner but somewhat cryptically. I accept his evidence for what it
is but must take it in conjunction with the documents that were generated at
the time to derive a more complete picture.
2.
An
Affidavit of David Chametzky (Ex 56). This affidavit from the
Manager of Pfizer Inc., parent of Pfizer Limited attests as to the unsuccessful
efforts made to locate Jenny Bowery who at one time was a trainee in the Pfizer
Limited patent department. Dr. Wells spoke of her in his evidence as did Dr.
Moore. Certain documents put in evidence mention her name.
[24]
In
cases such as this, the Court must accept factual witnesses as they are,
weighing their evidence based on the Court’s findings as to credibility and,
where the evidence conflicts, weighing the evidence on the balance of
probabilities. Here there is no evidence in conflict from a factual point of
view although there are many gaps. For instance, Mr. Davison’s personal
notebooks, including data as to stickiness and slope calculations, cannot be
located. Much of the dialogue between the inventors and Pfizer’s patent
personnel has been forgotten or is missing.
[25]
As
to the experts, there are conflicting opinions. I have expressed already my
reservations concerning some of the evidence of some of these experts. I prefer
the evidence of Dr. Cunningham where it conflicts with the evidence of others.
He has a substantial background in pharmaceutical development including during
the relevant period from a practical standpoint as a person working in the United
Kingdom
with an innovator pharmaceutical company. He gave his evidence in Cross-Examination
in a direct and straightforward way. I give least weight to the evidence of Dr.
Brenner and Dr. McGinity save where they gave admissions against their evidence
as it would otherwise have been. Their evidence was seriously discredited
during cross-examination. I accept the evidence of Dr. Laird as giving a good
overview of the manner in which pharmaceuticals are developed but give less
weight to his opinions as to benzenesulphonic acid. Dr. Banker, Dr. Atwood
and Dr. Amidon are all highly qualified academics who have consulted widely in
the pharmaceutical area. Their evidence is valuable from an academic point of
view but less so from a “person in the trenches” point of view. I accept their evidence
particularly in academic matters. I regret that I will give little weight to
Dr. Cappucino’s evidence. His close ties with the generic pharmaceutical
industry makes me apprehensive in placing substantial reliance on that evidence
however well meaning his intent may have been.
[26]
I
contrast the evidence given in proceedings such as this action where witness
can be observed live in the stand as opposed to the simple reading of
affidavits and cross-examination transcripts as in NOC Proceedings. Live
witness are much more valuable in seeking out the truth of a matter and sound
opinions. I still regret however not being able to place all expert witnesses
on similar subject matter on the stand at the same time so that Counsel and the
Court can determine clearly where consensus exists and what controversies
remain and why.
ISSUES
[27]
The
parties have agreed as to the issues for determination at trial, which
agreement was entered as trial Exhibit 3. That agreement states:
1. The parties agree that the
following are the issues to be determined at trial:
(a) Is the 393 Patent invalid for
lack of novelty over EP 167?
(b) Is the 393 Patent
invalid for failure to satisfy the requirements of a valid section patent?
(c) Is the 393 Patent
invalid for obviousness in view of EP 167 and the prior art?
(d) Is the 393 Patent
invalid for insufficiency of specification?
(e) Is the 393 Patent
invalid for lack of utility?
(f) Is the 393 Patent
invalid under Section 53(1) of the Patent Act?
2. The parties further
agree that the validity of the 393 patent as a whole will be determined on the
basis of the validity of claim 11.
[28]
In
final argument, Counsel for the Plaintiff advised the Court that the issue as
to novelty (1(a)) would not be pursued. No issue as to the infringement of the
’393 Patent has been raised in this action.
PERSON SKILLED IN THE
ART
[29]
The
patent, in particular Claim 11, is directed to a particular salt form of a
pharmaceutical, amlodopine besylate. I accept the identification of the
notional person skilled in the art or person of ordinary skill in the art (some
lawyers use the acronym, POSITA) to whom the patent is addressed as set out by
Dr. Cunningham at paragraph 158 of his first report, Exhibit 17, below. This
description accords essentially with that expressed by Pfizer’s experts Dr. McGinity
at paragraph 16 of his report (Ex 57) and Dr. Brenner at paragraph 17(a) of his
report (Ex 48):
158. The Patent is addressed to salt
selection for use in pharmaceutical formulations. The person skilled in the art
would be a pharmaceutical development team comprising chemists (synthetic and
analytical) and formulation scientists. Leaders within such a team may have a
doctorate and many of the team members would have at least a Bachelor’s degree
in chemistry or pharmacy or at least five years of practical experience in
synthetic, or analytical chemistry or pharmaceutical formulation.
[30]
That
“person skilled in the art” plays a role as of different dates. For purposes of
construction of the patent, that person plays a role as of the date the patent was
granted, here August 17, 1993, since the ’393 Patent is an “old” Act
patent (Whirlpool Inc. v. Camco Inc., [2002] 2 S.C.R. 1067 at
para. 55).
[31]
For
the purposes of considering a question of “obviousness,” since this is an “old”
Act patent, the relevant date is the “date of invention” (Windsurfing
International Inc. v. Bic Sports Inc. (1985), 8 C.P.R. (3d) 241 at 256
(FCA); Johnson & Johnson Inc. v. Boston Scientific Ltd., 2008 FC
552, at para. 330).
DATE OF INVENTION
[32]
The
“date of invention” for an “old” Act patent such as the ’393 Patent at
issue is initially accepted as being the date of filing the application for the
patent in the Canadian Patent Office, here April 2, 1987. However, where
priority is claimed from an application filed elsewhere, here Great
Britain,
it is presumed to be the filing date of that application, here April 4, 1986.
An even earlier date may be established if the evidence shows that the
inventors formulated orally or in writing a description which affords a means
of making that which was invented (Apotex Inc. v. Wellcome Foundation Ltd.,
2002 SCC 77, [2002] 4 S.C.R. 153 at pages 170-171; Johnson &
Johnson Inc. v. Boston Scientific Ltd., supra, at para. 339).
[33]
Usually
if a date earlier than the priority date is relevant, it should be pleaded.
There is no such pleading here. However, I have the evidence of the inventors Wells
and Davison before me, as well as that of some of their colleagues. From that
evidence, I find that it is reasonable to state that the “date of invention” is
25th November, 1985, the date of the so-called patent memorandum
written by Wells for the purpose of instructing the Pfizer patent department to
prepare a patent application (Exhibit 1, Document 111). I will refer to the
course of the development work later in these Reasons.
[34]
Amlodipine
besylate had been made and tested previously by Wells and Davison, however,
this is the first document that endeavours to pull together their work for the
purpose of describing it to others.
CONSTRUCTION OF THE
PATENT – CLAIM 11
[35]
The
jurisprudence directs that a Court, before dealing with issues as to validity
of a patent, or infringement, must first construe the claim(s) at issue. Such a
construction in the case of an “old” Patent Act patent, such as the one
at issue here, is to be made by the Court as of the date it was granted, here
August 17, 1993, through the eyes of a person skilled in the art to which the
patent pertains. The Court is to look at the claims in the context of the
entire patent specification, being neither benevolent nor harsh, to give
meaning to the claim, not by applying this or that gloss, but by reading the
document as a whole. Experts may assist as to the meaning of technical terms
and as to the state of the art at the relevant time but construction is for the
Court, not experts. [e.g. Whirlpool Inc. v. Camco Inc., supra. at paras.
43-45 & 57; Johnson & Johnson Inc. v. Boston Scientific Ltd.,
supra. at paras. 88 to 93; Janssen-Ortho Inc. v. Novopharm Inc. (2007),
59 C.P.R. (4th) 116 (FCA) at para. 4].
[36]
In
the present case, the parties have agreed that the validity of the ’393 Patent
may be determined having regard to one claim only, Claim 11, which reads:
“11. The besylate salt of
amlodipine.”
[37]
This
claim is quite straightforward. Besylate is a shortened form of the word
“benzenesulphonate” which has for many years been known as one of the salts
approved by the United States Food and Drug Agency (FDA) for pharmaceutical
use. It is listed, among several other salts, in a paper acknowledged by all parties
to be a definitive piece of prior art in the area, Berge et. al., “Pharmaceutical
Salts,” January 1977, Journal of Pharmaceutical Sciences, Vol. 66, No. 1 at
pages 1 to 19 (Berge), as being a “potentially useful salt” in dealing with
pharmaceuticals.
[38]
Amlodipine
is acknowledged to have been a previously known pharmaceutical compound. The
’393 Patent describes it at page 1:
The compound amlodipine (3-ethyl 5-methyl
2-(2-aminoethoxymethyl) - 4 - (2-chlorophenyl) -1, 4-dihydro-6-methylpridine-3,
5-dicarboxylate) is a potent and long acting calcium channel blocker have
utility as an anti-ischaemic and anti-hypertensive agent.
[39]
The
’393 Patent continues, at page 1, to acknowledge that it was already known that
several different pharmaceutically acceptable salt forms of amlodipine had been
disclosed in a prior European patent application publication no. 89167 (
sometimes referred to in evidence in this case as the ‘167 patent). In
particular, amlodipine maleate (which the evidence at trial shows is a short
form of methanesulphonate) was a known preferred salt as set out at page 1 of
the ‘393 patent:
European patent application publication
no. 89167 discloses several different pharmaceutically acceptable salt forms of amlodipine.
In particular, the pharmaceutically acceptable acid addition salts are said to
be those formed from acids which form non-toxic addition salts containing
pharmaceutically acceptable anions such as the hydrochloride, hydrobromide,
sulphate, phosphate or acid phosphate, acetate, maleate, fumarate, lactate,
tartrate, citrate and gluconate salts. Of these salts, the maleate is
disclosed as being particularly preferred.
[40]
Claim
11 can be construed as being directed to a particular salt form, besylate, of
the known pharmaceutical compound amlodipine. Thus, for purposes of this
action, the essential feature of Claim 11, and by agreement between the
parties, all claims of the ’393 Patent, is that a particular salt form,
besylate, of a known pharmaceutical compound, amlodipine, is the claimed
invention.
[41]
The
‘393 patent at page 6, the penultimate paragraph, states the rationale for
choosing the besylate salt:
“Thus the besylate salt of amlodipine
shows a unique combination of good solubility, good stability, non-hygroscopicity
and good processability which makes it outstandingly suitable for the
preparation of pharmaceutical formulations of amlodipine.”
[42]
No
particular use of the besylate salt form of amlodipine is stated in Claim 11. The
‘393 patent makes reference to three types of pharmaceutical formulations in
which that salt that would be used beginning at the last paragraph on page 1
over to the next two paragraphs on page 2. They are: a tablet formulation, a
capsule formulation and, a sterile aqueous solution for parenteral (iv or IV or
intra-venous) administration.
[43]
The
‘393 Patent does not make reference to any particular form that amlodipine
besylate is to take, that is, whether it is solid, liquid or oily or, if solid,
whether it is amorphous or crystalline or whether or not it is hydrated and, if
so, to what extent is it hydrated. Dr. Brenner opined, with reference to
Example 1 of the ‘393 patent, that the besylate salt of amlodipine, at least as
prepared by that process, was potentially crystalline ( Cross-Examination, Volume
11, pgs 99-101). Dr. McGinity opined that the besylate could be anhydrous
or a hydrate ( Cross-Examination, Volume 12, pages 48-75).
[44]
I
find that Claim 11 is to be read simply as it is, unrestricted as to any
particular use, and unrestricted as to any particular form of the compound.
DEVELOPMENT OF A
PHARMACEUTICAL IN THE MID 1980S
[45]
The
‘393 Patent arises from work done during the pre-formulation stage in
developing a commercial pharmaceutical producty and, in particular, a stage
known as salt selection or salt screening.
[46]
Dr.
Laird discussed the salt screen process in his report, Exhibit 14. I repeat
paragraphs 17, 22, 23, 24, 25 and 26:
17. A new drug
substance is often produced as a free base, but its properties in that form can make it unsuitable
for pharmaceutical formulation or administration to a patient. Free
bases can often be oils or low melting solids, or non crystalline amorphous
solids, and can be difficult to crystallise (e.g. stelazine, paroxetine and
citalopram). As I explain further below, salts tend to be more crystalline than free
bases with higher melting points and have other
properties which make them easier to manufacture and formulate.
. . .
22. There are
many other potential advantages to making a salt. The formation of a salt
usually produces a solid form which is more stable and higher melting than the
free base. The salt may, depending on the acid used to form the salt, have a
higher aqueous solubility than the free base. In addition, it is usually easier
to remove impurities from crystalline salts than from their free
base counterparts. Thus, the salt formation step often leads to
an important upgrade in quality of the drug substance. Salts are therefore
often made as a means of purification of the drug substance as well as to
provide the optimal formulated product.
F. How Salts
Were Synthesized
23. During the
1980s in the pharmaceutical industry, companies tended to conduct salt
screening (and other methodologies such as polymorph screening) in a manner
that was
not entirely systematic rather than through a strict standard operating
procedure. The individual scientist would choose which acids to use and
the conditions (such as the solvent, temperature, and concentration) under which to try
to obtain crystalline salts of the drug substance. Given the plethora
of solvents, salt forming agents and reaction conditions, there is the potential for
thousands of experiments at a time when supplies of drug
substance (free base) would be minimal. The chemist, faced with such a choice
would minimize the number of experiments performed.
24. In the
early stages of development, the drug substance (free base) will not only be in short supply but may be
of variable quality since the process to make it has not been worked
out in detail. Because the salt screen was done manually; and results were
required in a short timeline, only a limited number of experiments could be
conducted. Thus, it was not feasible to screen the whole of the range of acids
available. It was my experience
that chemists would try to screen no more than 10 to 12 salts and use a limited range of
solvents. However, there existed no standards to guide the chemist as to the
appropriate choices.
25. The scientific literature
provided little guidance in this regard. The seminal review article by S.M.
Berge et al W. (1977) J. Pharm. Sci. (Berge Article), attached as Exhibit 3,
reported on page 1 that salts were often chosen
empirically and cited over 270 scientific references that
contained discussions on various salts and their properties. However, nowhere
in this article was there a suggestion as to how the salt screen should be carried
out in practice. The later review article by P.L. Gould (1986) Int. J. Pharm. (Gould Article), attached as Exhibit
4, reported that salt selection "remains a difficult, semi-empirical
choice" and provided little more guidance to conducting a salt screen than
the Berge Article.
26. When salt screening was
conducted in the 1980s there was a tendency to do a limited amount of
experimentation to generate the salts, and in the screening to examine further
only those salts which were easily obtained and crystallised in the initial
experiments. This situation continued into the 1990s in some companies, though
eventually some automated methods became available that assisted in making the
process of conducting a salt screen more efficient.
[47]
Dr.
Cunningham said much the same thing in his report, Exhibit 17. I repeat
paragraphs 14 to 23:
14.
When compounds have been identified which have the
potential to be developed into new active ingredients process chemists and
formulation scientists will often join the project team. At this stage the
physical properties of the potential new active ingredient will be scrutinised
to ensure that, if developed:
(a)
it can be made and purified readily and routinely to very
high quality standards;
(b)
it is sufficiently stable to both heat and moisture so
that it does not change form or degrade significantly either during processing
(formulation) or storage in bulk or as formulated drug;
(c)
it is suitably soluble to be absorbed if being given as a
solid dosage form or to be formulated as an injectable dosage form; and
(d)
it is compatible with processing equipment (e.g. it flows
and does not unduly adhere to surfaces).
15.
There are of course other considerations such as cost and
toxicology to be considered.
16.
Sometimes the parent compound will be satisfactory with
respect to these criteria but if not, and if it is capable of forming salts,
then a salt screening exercise will be conducted to try to identify a suitable
salt of the new active ingredient which has a more favourable set of physical
properties.
17.
Similarly many drug molecules exhibit polymorphism i.e.
they can exist in a number of different crystalline forms, some of which will
be more stable than others. A polymorph screening exercise will be carried out
to identify if this is likely to be an issue and if so to identify a stable
polymorph for development.
Salts and Salt
Selection
18.
A salt is formed when an acid and base are reacted
together. These substances are ionic, i.e. no covalent bonds are formed.
19.
In many cases the parent compound (sometimes referred to
as the free base) cannot be used in the manufacture of a pharmaceutical product
because of its physical properties. Salts can be used to modify these
properties to improve bioavailability or to address manufacturing problems.
Physical properties that may be modified by salt formation are stability,
solubility, rate of dissolution and hygroscopicity. These and other factors,
such as crystal form, wi11 determine just how easy or difficult it will be to
manufacture and use the final dosage form.
20.
In some instances the active ingredient may not be soluble
enough to ensure good absorption and hence good bioavailability. Conversion to
a suitable salt is often investigated to address this type of problem since
different salts will have both different rates of dissolution and solubility
when compared to the free base.
21.
The properties of a salt depend on the structure of the
solid form of the salt which cannot be predicted. Hence it is not possible to
predict the various properties of a salt of a new active ingredient.
Pharmaceutical salt selection is an empirical process and salts must be made
and their properties measured to see whether they are suitable as new active
ingredients in a formulated drug product.
22.
As described above where the free base is not considered
to possess an acceptable profile of properties, a salt may be considered. The
chemist will screen candidate salts, acidic or basic as appropriate based on
his general knowledge and availability of acids/bases. In performing such a
screen, the chemist would not necessarily be looking for the "best"
salt, but one that is adequate when evaluated against the criteria given above.
The chemist would almost invariably make and assess the suitability of the
hydrochloride salt of a base or the sodium salt of an acid.
23.
In my experience it would be usual for the chemist to make
five or six salts in the first instance. In doing so, he will be guided by
lists of salts known to be pharmaceutically acceptable to the Regulatory
Authorities such as the FDA and EMEA. A list of salts approved for commercial
sale is contained in Berge, "Pharmaceutical Salts", J. Pharm. Sci., 66(1):1-19
(Exhibit "2"). The selection would normally include both inorganic and
organic counter-ions and both monobasic and dibasic species.
Typical acidic salts for consideration would include inorganic salts such as
hydrochloride and sulphate salts and organic salts with carboxylic or sulphonic
acids. There is no prescribed approach to this initial screen and the choice of
which compounds to make first will depend on the experience of the chemist in
terms of what has proved successful in general and within a particular series
of compounds.
[48]
Such
an approach has been described in an article by Gould entitled “Salt selection
for basic drugs” published in International Journal of Pharmaceuticals, 33
(1986) 201-217. I repeat the first two paragraphs of the introduction:
Introduction
Salt formation
provides a means of altering the physicochemical and resultant biological characteristics
of a drug without modifying its chemical structure. The importance of choosing
the 'correct' salt form of a drug is well outlined in a .published
review (Berge at al., 1977) but, although salt form can have a dramatic
influence on the overall properties of a drug, the selection of the salt form
that exhibits the desired combination of properties remains a difficult
semi-empirical choice.
In making the
selection of a range of potential salts, a chemical process group considers
issues on the basis of yield, rate and quality of the crystallisation as well
as cost and availability of the conjugate acid. The formulation and analytical
groups are, on the other hand, concerned with the hygroscopicity, stability,
solubility and processability profile of the salt form, while the drug
metabolism group is concerned with the pharmacokinetic aspects and the safety
evaluation group on the toxicological effects of chronic and acute dosing of
the drug and its conjugate acid. Thus, a clear compromise of properties for the
salt form is required. but the difficulty remains of assessing which salt forms
are best to screen for a particular drug candidate.
[49]
Even
Dr. Brenner, whose evidence I treat very cautiously as placing too much
emphasis on matters that would suit Pfizer, described salt screening at
paragraphs 49 to 65 of his report, Exhibit 48, as a process that would be
carried out by the ordinary person skilled in the art in the mid 1980s in which
typically 5 to 10 salts would be selected and evaluated in a series of tests including
stability, solubility, hygroscopicity and processability. Reaction with various
excipients would be examined. As Dr. Brenner says at paragraph 136 of his
report, a person of ordinary skill in the art confronted with a stability
problem would almost certainly look for an alternate salt form. As the ’393
Patent states at the bottom of page 3, the previously known maleate tended to
break down in solution after a few weeks. In other words, it lacked stability.
[50]
As
will be seen, the procedure followed by Dr. Wells and Mr. Davison was
essentially a classic mid 1980s salt screening process for a pharmaceutical
candidate along the lines set out in the reports of Drs. Laird and Cunningham
and in the Gould article. It was somewhat rough and ready, time was an essential
constraint, certain salts only were selected, not entirely at random, for
testing. Once one or two or three sufficiently useful candidates were
identified, there was no effort to test all possible salts. The selected
candidate(s) were settled upon and passed on to the next stage, that of final
formulation for regulatory approval.
[51]
The
persons involved in the development included Dr. Wells, who headed the project,
and Mr. Davison, who had an office near Dr. Wells and carried out and
directed much of the testing. Dr. Platt was largely responsible for
stability tests. Mr. Pettman made the salts. Dr. Wells seems to have
corresponded with many people but largely reported to Dr. Davidson. At the end
of the process when a patent was being considered, Dr. Moore, a chartered
patent agent, was nominally responsible, however, much of the actual drafting
and discussions with the inventors and others appears to have been done by a
trainee, Jenny Bowery. All of these people testified at trial except Dr.
Davidson, who inexplicably did not appear, and Jenny Bowery, who apparently
cannot be found.
DEVELOPMENT AND
PATENTING OF AMLODIPINE BESYLATE
[52]
The
beginning of the development of amlodipine besylate by the two named inventors,
Wells and Davison, came when Wells was presented with a particular salt form of
amlodipine, amlodipine maleate, and told to formulate it into a medicine for
commercial use. The questions put to Dr. Wells by his Counsel, Mr. Laskin in
direct examination, and his answers at page 121 to 123 of the transcript recite
the beginning of the project:
THE WITNESS: We had studied ‑‑
for some time before the discovery of amlodipine, we had been looking at an
existing competitive product, which was called nifedipine. The problem with
nifedipine ‑‑ and which is what at Pfizer we were trying to resolve
‑‑ was we actually worked on nifedipine in the equivalence of a
photographic dark room because nifedipine completely fell apart in daylight.
So it was a very unstable compound in the presence of light and it was also
short‑acting.
The philosophy at
Pfizer was that it was better that we develop drugs which were taken once a
day, maybe twice a day, but not beyond that. So the goal was to find a new
dihydropyridine which was not sensitive to light and which had a much longer ‑‑
what we call half life. The patient would only have to take it once a day.
So I was aware ‑
this is the point I am trying to make ‑ I was aware through my involvement
with looking at nifedipine that the company were now interested in compounds of
that class.
BY MR.
LASKIN:
Q. The class being?
A. Dihydropyridines of
which amlodipine is a member. Nifedipine, amlodipine.
Q. And what was the status
or the stage of development of amlodipine at the time you became involved?
A. Discovery had
synthesised amlodipine and declared the maleate salt.
Q. Declared it --?
A. That what we were
receiving for development was amlodipine maleate.
Q. Did you have any
involvement in the process of selecting amlodipine maleate as the salt for
development?
A. No, sir.
Q. Do you know ‑‑
or did you learn the basis for the selection of the maleate?
A. No.
Q. Was your group, the
pharmaceutical R & D group, Research & Development group, to your
knowledge, involved in the selection of amlodipine for development or the
selection of the maleate salt?
A. No.
Q. Do you have any
knowledge, sir, about any other salts of amlodipine that had been tested before
you received the amlodipine maleate?
A. At the time, no.
[53]
Mr.
Davison had an office next to Dr. Wells and was assigned to the project by Dr.
Wells. In Mr. Davison’s words in response to questions put to by Mr. Laskin in
direct examination at pages 11 to 15 of Volume 3 of the transcript:
Q. Thank you.
I want to turn to
your work involving amlodipine. When did you begin working on amlodipine at
Pfizer?
A. Early in 1982.
Q. So, this was during the period
in which you had moved into pharmaceutical Research & Development?
A. That’s correct.
Q. What was your role in the
project at that point?
A. My supervisor, Dr. Jim Wells,
would assign his staff according to the state of their existing work. And at
that point I was available to take on new projects and Jim assigned me to
amlodipine.
Q. Were other members of the
department working with you on that project?
A. Well, that, of course, was the
time of pre-formulation, and so myself and my technician, Mr. David Smith were
able to personally carry out all of the pre-formulation studies.
Simultaneously to that,
because of the parallel structure of the development process, certain of the
pilot area staff within pharm R & D would also become involved in
amlodipine. Their role would be to use their default formulations to gain
experience on difficult – well, it is best to say how easy it would be to make
capsules in the first instance and tablets later on.
They wouldn’t work on tablets
until quite a while later, but capsules are the default dosage form because
they can be made with only small quantities of bulk active material. For
tablets, you require much larger quantities of bulk active material to generate
enough powder so that you can run it through machinery.
And so they would be working
simultaneously, and we would be communicating. If I found something, a problem,
I would nip around to the pilot area and tell them.
Q. At the time you began your work
had a lead amlodipine compound been identified?
A. Well, amlodipine was the lead
compound, and it was in a salt; it was a salt called amlodipine maleate.
Q. Did you take any part in
identifying amlodipine maleate?
A. No, I did not.
Q. Now, you mentioned that you got
involved in pre‑formulation work. What was the objective of the work in
which you became involved? Where were you hoping it would lead?
A. The objective is to identify
potential problems that might interfere with the achievement of our short-term
objectives, which relate to toxicology, preparing formulations suitable for
toxicology and early clinical trials.
Q. So, if those are short-term
objectives, were there also long‑term objectives?
A. There were, yes.
Q. What were those?
A. Well, when amlodipine maleate
entered development, the experts in the discovery area, the medics and the
biologists, et cetera, would have an idea of what the likely human dose is
going to be. And for amlodipine, a figure of 10 to 20 milligrams was suggested.
And that meant that we assessed amlodipine as a very potent chemical entity.
And the commercial, the
marketing people would also be interacting with this, and they would indicate
that their desire was a tablet. And so because it was a high potency compound
requiring only a few milligrams of material in the tablet, the obvious best
commercial formulation would be a direct compression blend. By that I mean
there is no granulation procedure or anything like that. A suitable blend of
direct compression-grade excipients is mixed with the bulk active, and that
powder blend is fed directly into tablet machinery.
[54]
I
will review the detail of this development but first I will jump to the end,
the selection of amlodipine besylate as the preferred compound. Dr. Wells put
the conclusion well in an answer provided in his Cross-Examination by Mr.
Aitken at Volume 2, page 165-166 of the transcript:
. . . I made a decision, along with
colleagues, that we had a salt which was suitable to take forward.
If we had tested and carried
on testing, we may still be doing it. So we took a decision to proceed with the
besylate, and I believe history shows that we got it right.
We could have looked for
other salts. We could have tested many, many more, but we found one which
worked, providing us with a suitable, sensible solution to the problem we were
faced with.
[55]
The
difficulty arises not with the commercial solution but the patent. Dr. Wells
got it right when he gave an answer in Cross-Examination at Volume 2, page 161,
of the transcript. A patent has to be clear, honest and right:
A. Well, I can’t answer that
because I am not a patent agent. My view is we disclose sufficient information
to allow a man skilled in the art to be able to repeat my experiment.
I am not aware that it has to
include every, every aspect of the work that we did. It has to be clear, it has
to be honest, and it has to be right, and that’s what we did . . .
[56]
This
accords with section 34 (1) of the “old” Patent Act, which wording is
essentially the same in section 27(3) of the “new” Act:
|
34. (1) An applicant shall in the specification of his invention
(a) correctly and fully describe the invention and its
operation or use as contemplated by the inventor;
(b) set out clearly the various steps in a process, or
the method of constructing, making, compounding or using a machine,
manufacture or composition of matter, in such full, clear, concise and exact
terms as to enable any person skilled in the art or science to which it
appertains, or with which it is most closely connected, to make, construct,
compound or use it;
|
34. (1) Dans le mémoire descriptif, le demandeur :
a) décrire
d’une façon exacte et complète l’invention et son application ou
exploitation, telles que les a conçues son inventeur
b) expose clairement les diverses phases d'un procédé, ou
le mode de construction, de confection, de composition ou d'utilisation d'une
machine, d'un objet manufacturé ou d'un composé de matières, dans des termes
complets, clairs, concis et exacts qui permettent à toute personne versée
dans l'art ou la science dont relève l'invention, ou dans l'art ou la science
qui s'en rapproche le plus, de confectionner, construire, composer ou
utiliser l'objet de l'invention;
|
[57]
The
question remains, however, as to whether Pfizer did that.
[58]
It
appears that Dr. Wells has very limited involvement with members of the
patent department and no recollection as to any dialogue that may have taken
place. I refer to his answers in direct examination, Volume 1 pages 215 to 222.
In direct examination, Volume 3, pages 132 to 135, Mr. Davison testified that
he had no communication with the Pfizer patent department, he saw drafts
presumably of the patent specification but has no knowledge as to any
discrepancies between what the patent application says and the research that he
reported. Dr. Moore, a Pfizer patent agent had some involvement in the patent
drafting essentially from the point of view of mentoring the work of Jenny
Bowery, a trainee who appears to have been the person most directly involved in
drafting the patent application. She has not been found and did not give
evidence.
[59]
It
appears that Dr. Wells’ supervisor, Dr. Davidson (who was expected to give
evidence but did not), informed Dr. Wells that an application for a patent
should be made (Wells’ Cross-Examination, Volume 2, page 259). As a result, Dr.
Wells prepared a memorandum (Agreed Document 111) dated the 25th of
November 1985, the purpose of which was to inform the patent department “. .
. with technical details to allow them to convert it into a patent with
ease” (Wells’ Direct Examination, Volume 1, pages 185-187). This
memorandum reflects what apparently was a “majority decision” including the
views of Dr. Wells and of unnamed others as well. However, once the memorandum
was turned over to the patent department, Dr. Wells’ involvement was, in his
words, “virtually none” (Wells’ Direct Examination, Volume 1, page 215).
[60]
Having
touched on the beginning and end of the process from the inventors’ point of
view, I will trace the history of the development of the amlodipine besylate
salt. It is not often that a Court is provided with an insight as to the
development of a patent, such as one relating to a drug formulation, in a
manner such that what is set out in the patent may be compared with what the
named inventors actually said and did. This is such an occasion.
[61]
Dr.
Wells received amlodipine maleate in August 1982 as a candidate pharmaceutical
developed by others as set out in a Memorandum from J.R. Davison to Dr. G.W.
McLay dated 11th August 1982, copy to Wells (Exhibit 1, Document 28).
According to an internal numbering scheme at Pfizer, amlodipine was assigned
number UK-48,340 and its salts were indentified by additional numbers such as –
11 for maleate. Thus amlodipine maleate is designated as UK-48,340-11. A more
complete inventory of salts form descriptions made by Pfizer is set out at
Exhibit 1, Document 43.
[62]
In
reviewing the evidence, it is useful to note some of the code numbers used by
Pfizer for salt forms of amlodipine. Amlodipine alone is referred to as the
“free base” or “base”, code number UK-48,304, and the salt forms are
indentified by the following numbers or letters which are placed following
UK-48,304:
– 01 hydrochloride
– 11 maleate
– 14 acetate
– 15 toluenesulfonate
(tosylate)
– 24 succinate
– 26 benzenesulphonate
(besylate)
– 27 methanesulphonate
(mesylate)
– AB or – 94 salicylate
– AN 1–naphthalenesulfonate (naphthalate) (this salt does not appear on Document 43)
[63]
A
Memorandum from Dr. Davidson to Dr. McLay, copied to Dr. Wells (Exhibit 1,
Document 28) of 11th August, 1982, informed Dr. Wells
that preliminary indications suggested that amlodipine maleate is susceptible
to photolytic, oxidation and acidic attack, degrading fairly rapidly in an
aqueous environment. The Quarterly Report also part of Document 27 stated that
analytical studies suggest that chemical incompatibilities and aqueous
instability will be the major concerns. Thus Dr. Wells and Mr. Davison were
presented with a pharmaceutical compound, amlodipine maleate, and possible
problems with respect to that compound all as developed by others and not by
them.
[64]
Dr.
Wells was told that marketing wanted to sell the product in tablet form in
which the drug, along with other ingredients called excipients, are blended as
powder and ultimately compressed into tablets by wet or dry methods. Capsules,
filled with a blended powder, and parenteral (iv liquid) forms were also
possible (Wells Direct Examination, Volume 1, pages 127 to 135).
[65]
Dr.
Wells said that (Direct Examination, Volume 1, pages 137 to 139), the first
problem encountered with amlodipine maleate was a sticking problem, when they
tried to grind it into a fine powder. Mr. Davison said that when they used a
mortar and pestle (Volume 3, page 37) the material stuck to the surface of the
equipment. The first solution proposed was to add an excipient called mannitol,
which stuck as well (Wells, Volume 1, pages 139-140). Emcompress was
substituted for mannitol. This caused the drug to react and form an unwanted
compound called a Michael Addition Reaction (MAR) compound (Wells, Volume 1,
pages 139-140). This MAR compound has been given Pfizer identification
UK-57,259.
[66]
Apparently,
the sticking and formation of unwanted compounds problems were eventually
solved not only by substituting another salt, besylate, but also by a
formulation that is described in the patent at Table III. This formulation works
equally well for both the maleate and besylate salt forms (Wells Cross-Examination,
Volume 2, pages 195-198):
Q. And that is formulation FID
0650?
A. Yes.
Q. And 0650 is essentially the
same formulation used in Norvasc today, is it not?
A. Yes.
Q. And in fact, it is essentially
the same formulation that we seen in the patent in Table III; correct?
A. This is the Canadian patent.
Q. Page eight of the Canadian
patent, Table III.
A. Sorry, page again?
Q. Page eight.
A. Thank you. Yes, that’s
correct.
Q. So, you were able to get the
maleate to work in the formulation which is called FID 0650, and when you
switched to the besylate you could take the maleate out, put the besylate in,
and it worked for the besylate; correct?
A. Yes.
Q. So, whatever inherent
stickiness there was with the maleate and whatever stickiness there is with the
besylate, the stickiness problem was solved for both by using FID 0650?
A. Yes.
[67]
Given
the problems, particularly as to stability, with the formation of unwanted
compounds, Dr. Wells in a Memorandum dated 24th April, 1984 (Exhibit
1, Document 48) made two proposals, one was to change to an anhydrous form of
one of the excipients, Emcompress, and the other proposal was to change from
the maleate salt of amlodipine to the “free base” that is, just amlodipine
alone, or change to the acetate salt. Dr. Wells proposed certain potential
salts of amlodipine as well as the “base” as set out in Table 3 of that
memorandum:
[68]
Dr.
Wells provided the following answers during his Direct Examination found at
Volume 1, pages 154 to 157, as to why he selected the various salts:
Q. Now, as you review the
various entries on the list that appears in Table III, can you just go down one
by one and explain how they made it onto the list?
A. Sure. If we go one step
back, I'd hypothesized that we should move to free base because of the reason I
gave, which is we had that bulk available to us, because it was available prior
to conversion to salt. So, the free base is on that list because it was
available. I am conscious through teaching and my own experience that drugs
are better as salts.
Q. Why are they better as
salts?
A. Because A, they are more
soluble. Drugs are notoriously insoluble until they are converted to a salt.
And secondly, and curiously and it occurs in what happens with amlodipine,
making a salt actually makes the drug purer. Converting the drug to a salt,
the actual acid cleans up the drug.
Now, later on we'll discover that, in fact, it
was the reverse with amlodipine, but we obviously looked at the base. If we
then go to the other end, I'd advocated the acetate. I had a hypothesis.
If you are familiar
with the teaching of Karl Popper, we talk about a working hypothesis. My
hypothesis was that this drug does not like acid, so I am going to try and
reduce the acidity. I hypothesized, therefore, that we should make the
acetate.
What did we discover?
That my hypothesis was completely wrong.
Q. How was it wrong?
A. Because it was
incredibly unstable. So, I have to move on and think of other possibilities in
terms of explaining and solving the problem.
So, if we then go to
the top of the list, hydrochloride is completely inconsistent with my
hypothesis, because I am saying we don't want strong acids
.
However, since the
acetate had failed to provide my original hypothesis, there was no reason not
to proceed with the hydrochloride, because of another powerful reason. It is
the most popular, populated drug salt. Sixty‑three per cent of drugs
currently on the market ‑‑ that's my memory ‑‑ 63 per
cent of drugs are hydrochlorides.
Methane sulphonate is
still a strong acid. Benzene sulphonate, as we go down this list, minus 6.1
for hydrochloride makes it a very strong acid. What I am seeking to do is to
make salts with a range of pKas. So, in consulting standard texts, we selected
a range of salts so that we would step‑wise, in decreasing their acidic
strength, that's one factor. So, if you
look, you've got minus 6.1, minus 1.2, then plus .69 and so on. And equally, I
was trying to include ‑‑ and we call them cluster groups ‑‑
the notion that we should also look at a nominal candidate from each group.
So, for example,
hydrochloride is an inorganic acid. Methane and benzene sulphonate are sulphonic
acids. Maleates, which we have already had, is a dicarboxylic acid. Lactate
is a trihydroxy acid. We couldn't make that, so here I have a list which
says potential salt forms. We were never able to make lactate.
Succinate is a
dicarboxylic acid. Acetate is a monocarboxylic acid. So, it is a combination
of choosing examples from different chemical structures and providing different
pKas, because they dictate ‑‑ the pKa dictates the pH of the
solution that sits on the surface of the crystals if there is an issue of
hygroscopicity. If water is associated on the surface of the crystal, it is
like condensation on a cold winter day on a window. That film of moisture will
be a saturated solution of the drug, and that's why pH SAT has been measured.
So, all of this is
designed to be rational in the sense that I am using a range of acidities and a
range of structures.
Q. Did you have any
expectations about how any of these salts would perform as alternatives to the
maleates?
A. I think the best word I
can use is I "hoped" that they would produce salts. And I hoped that
one of them would be okay, but ‑‑ but had we found that none of
them produced something which we could use commercially, my intention was to
say: Right, let's ‑‑ just for a
trivial example ‑‑ let us assume that the hydrochloride turned out
to be the best of this group but wasn't good enough for our purpose, because it
is an inorganic acid, I would have asked PRD to make me some other inorganic
acids like sulphuric, nitric and solvent.
[69]
Dr.
Wells had a discussion with a senior scientist at Pfizer’s Process Research and
Development department who advised Dr. Wells that the benzene sulphonic acid
that was commercially available was not of very high quality. As a result, that
person made another salt forming compound, tosylate. Ultimately, Pfizer made benzene
sulphonic acid rather than purchasing the commercial material (Wells Direct
Examination, Volume 1, pages 158 to 159).
[70]
Sometime
after Dr. Wells submitted his Memorandum of 24th
April, 1984,
senior executives of Pfizer determined that Wells should be instructed to find
an alternative salt to the maleate (Wells Direct Examination, Volume 1, pages
161 to 162).
[71]
Given
the direction to find alternative salts, Dr. Wells established four criteria
namely: solubility, stability, hygroscopicity and processing. He said in direct
examination, Volume 1, page 166:
Q. Now, after Dr. Davidson
communicated the acceptance of your recommendation to explore alternatives, did
you arrive at criteria on which you would evaluate possible alternatives to the
maleate?
A. Yes, based on my training, I
was aware that there was certain issues associated with the qualities of
pharmaceutical bulk. And it was simply a case of after ‑‑ I've
actually given a lecture several times which I call "the three Ss",
which stands for solubility, stability, salts. And that's the central tenet about what
we're trying to do.
Now, there are other
properties and they are the ones that we have reported.
Q. Which were those?
A. Well, we've looked at solubility. We've
looked at hygroscopicity. The consequence of hygroscopicity to a large extent
dictates the drug's stability. And the final
thing is being able to make the drug work in a production environment as a
dosage form, processing.
[72]
Dr.
Wells explained the importance to him of solubility in Direct Examination at Volume
1, page 167:
Q. So, why is solubility
important?
A. Because all drugs have to be
absorbed in solution, and there is a basic rule of thumb which was expounded a
long time ago by a man called Caplan, who basically, having reviewed the
literature, came up with a notion that as long as a drug had a solubility
greater than about one milligram per ml over the physiological range, pH one to
seven, then the drug would be well‑absorbed. We have come back to this
idea of bioavailability which we have talked about with the parenteral
injection.
[73]
Solubility
was measured in the Pfizer lab, and the solubility of various salts, in water,
was provided in a report of October 11, 1984, Exhibit 1, Document 64, as
follows:
Table 1: Aqueous solubility
of UK-48,340 salts at 37ºC
|
SALT
|
SOLUBILITY
mgA ml
|
pH
|
|
Maleate
|
4.5
|
4.8
|
|
Benzene
sulphonate
|
3.6
|
4.5
|
|
Toluene
sulphonate
|
|
|
|
Methane
sulphonate
|
>25
|
3.1
|
|
Succinate
|
4.4
|
4.9
|
|
Salicylate
|
1.0
|
7
|
|
Acetate
|
>50
|
6.6
|
|
Hydrochloride
|
|
|
[74]
This
table accords with Table 1 of the ’393 Patent except for lack of hydrochloride
data and, more importantly, that the figure for benzene sulphonate in the above
table, 3.6, is different from that set out in the patent of 4.6 at a pH of 6.6,
a figure more favourable to benzene sulphonate. Neither Dr. Wells nor Mr.
Davison could clearly account for this difference. At best, reference is made
to a Memorandum from Mr. Davison to Dr. Davidson dated 18th September,
1985, Exhibit 1, Document 103, which contains a graph, Figure 1, showing
solubility of amlodipine besylate in 0.9% saline, which could be read so
as to yield a figure of 4.6 at 6.6. pH. There is no clear evidence that this is
where the figure actually came from, this is simply the only place in the
evidence where it can be found. Much was made of the differences in solubility
of salts in water and in saline solution in evidence and in argument.
[75]
As
to the next of Dr. Wells’ criteria, hygroscopicity, he said in Direct
Examination, Volume 1 at pages 167-168:
Q. You mentioned
hygroscopicity; to what extent is that important?
A. Because I think I
mentioned the idea of condensation on cold glass, that film of liquid.
Hygroscopicity (sic) is the idea that depending on climate, water will either
associate or dissociate it from the surface of materials. Materials which take
on water as condensation, by analogy on glass, we would describe as
hygroscopic. That water on the surface will dissolve the drug, and its drug in
solution which is going to degrade.
Going back to some of
the evidence we have already looked at, amlodipine maleate as bulk drug was
stable. Why? Because it is non‑hygroscopic and there was no moisture to
actually act as a vector and promote degradation, but as soon as we started
adding excipients, which in themselves contain moisture, that's when the problem starts.
Q. How does the problem
start?
A. We will see degradation
because the moisture associated with the surface of the crystal will actually
allow the process to actually generate breakdown.
[76]
Much
was made in the evidence as to what “hygroscopicity” meant, or meant in the mid
1960s and whether it truly presented a problem or not. It is generally agreed
that the presence of “free” or “unbound” water can be a problem. The debate
centres around whether “bound” water, that is water that is combined within the
crystal lattice structure of a compound so that it becomes a “hydrate,” is a
problem.
[77]
In
considering what the inventors thought or did, the scientific debate doesn’t
matter. At this point in considering the evidence we are only concerned with
what the inventors thought and did. They thought water, including hydrates, was
a problem and that salts that were hydrates or could form hydrates should be
avoided. They thought, at least early on, that besylate was not a hydrate.
[78]
Thus,
mesylate was ultimately rejected by Dr. Wells because it formed a hydrate. He
said in his Memorandum to Dr. Wood dated 25th November, Exhibit 1,
Document 111:
The mesylate probably also merits
protection since its stability and processing properties are excellent. However
it is isolated in the anhydrous form and upon exposure to moisture rises
rapidly to the monohyrdate. The besylate and tosylate are however, non-hydrscropic
and anhydrates.
[79]
When
asked about this in Direct Examination, Dr. Wells said at Volume 1, pages
190-191:
A. I have an inherent
prejudice against hydrates because there is always the capacity for them to
dehydrate under the conditions of manufacture and so on so forth.
We had recently run
into problems with fluconazole which was being developed in parallel and the
capsules had real problems with the release of the drug. And that was about
variability in hydrate levels.
So, my own view was
that we would avoid hydrates and I had a perfect position to move to because
besylate did not form a hydrate in the dry state and was completely indifferent
to moisture such that it was completely non‑hygroscopic. So I took the
view that when we were looking for best balance in terms of properties, the
besylate stood out because it was immune to water.
Q. And you mentioned that ‑‑
you mentioned that water could be released under the conditions of
manufacture. What conditions are those?
A. Because you're exposing ‑‑
you're exposing your drug to other
materials. In other words, the excipients that form the dosage form itself,
and it is true, for example, that if we go back to calcium phosphate which we
have already reviewed, calcium phosphate dihydrate is a stable hydrate, but hey
ho at 37 the water comes off and causes major problems.
So, you know, we have
to recognize that that is not predictable either, but that even though we might
talk about stable monohydrates, stable dihydrates, stable hepta hydrates,
decahydrates and so on, they are capable of efflorescing and changing their
state. It seemed to me the safest way forward was to choose a form of the drug
where that was not a possibility.
[80]
As
to the next criteria, that of stability, Dr. Wells said in Direct Examination,
Volume 1, page 168:
Q. And you referred to
stability?
A. We must provide quality
medicines where over typically a three‑year period, the appearance of
degradation should not exceed five per cent.
Q. Why is that?
A. Because we want the
patient to be able to have a medicine which is of high quality throughout its
shelf life. And given the supply chain involved in distributing medicines from
manufacture all the way through to the patient, we need typically a shelf life
of three years.
[81]
Dr.
Platt, whose job at the time with Pfizer was to analyse potential drug products,
including as to stability, sent a Memorandum dated 3rd May, 1984 to
his supervisor, Mr. Wadsworth, setting out the current status of stability
studies on amlodipine maleate (UK-48,340-11) as well as the “free base” and
indicated that “alternative salts” would be investigated as they became
available (Exhibit 1, Document 50). He indicated that stability studies
conducted at a high temperature, 75ºC, for a short period of time, 11 days,
could provide some useful information, however, a more realistic study at 50ºC
and 37ºC, with checkpoints at 6 weeks and 12 weeks should be conducted before
any firm conclusions could be reached. The ultimate aim was to produce a tablet
formulation with satisfactory stability for at least 2 years at 30ºC,
preferably 37ºC (body temperature). In that Memorandum, he refers to a compound
indentified as UK-57,259, that is found in amlodipine maleate as the MAR that
is formed when breakdown occurs during stability studies.
[82]
It
was Mr. Pettman’s task to prepare a number of alternative salts of amlodipine.
These salts were described in a Memorandum from Pettman and others to a Dr.
Edinberry, found within an August 1984 Quarterly Report (Exhibit 1, Document
57). Those salts were:
UK-48,340 (Acetate)
UK-48,340-24 (Succinate)
UK-340-27 (Methanesulphonate)
UK-340-26 (Benzenesulphonate)
UK-48-340-AB (Salicylate)
UK-48-340-01 (Hydrochloride)
UK-49(sic);340-15 (p. Toluene
sulphonate tosylate)
[83]
The
preparation of these salts took place over the period from April to October
1984 and appears to have proceeded quickly and routinely except for the
hydrochloride which required further purification, he was able to make most
salts in a day or two (Pettman Direct Examination, Volume 4, pages
154-163). The benzenesulphonic acid used was found to be dark and sticky but as
it was the only batch available it was used. Subsequently, a commercial batch
of benzenesulphonic acid from a supplier, Aldrich, which was 90% pure, was used
to make a further batch of besylate salts (Pettman, direction examination,
Volume 4, pages 163-169). Pettman was unable to make a benzoate salt, only
something described as an “oil” was produced (Pettman Direct Examination,
Volume 4, pages 169-171). Pettman later wrote a Memorandum dated February 26,
1986 to Dr. Wells (Exhibit 1, Document 124) summarizing his work apparently
for patent purposes. This was Pettman’s only involvement in the patent process
(Pettman Direct Examination, Volume 4, page 176).
[84]
Some
documents later refer to a napsylate salt which was subjected to some testing.(Exhibit
1 Doc.75 pg. 8 and Exhibit 6). Mr. Davison tested four salts –besylate,
mesylate, tosylate and napsylate on Novenber 29, 1985 apparently in an effort to
validate the selection of the besylate (Cross-Examination Volume 4, pages
59-60). No mention of the napsylate is made in the’393 Patent, an omission that
would not have been recommended by Dr. Moore the patent agent had he known
about it (Cross-Examination Volume 12, page 113).
[85]
Dr.
Platt proceeded to test several of these amlodipine salts in the period from
about April to October 1984. This testing took the form of stability studies in
which the amlodipine salts were formulated with four different mixtures and
compressed into a wafer form called a compact as well in powder form such as
would be used in capsules. The compacts were formulated as follows:
1.
Mannitol /
Dried maize starch
2.
Avicel / Starch
1500
3.
Avicel / Emcompress
4.
Avicel / Anlydrous
dicalcium phosphate
[86]
Initially
five salt forms were tested for five days at 75ºC. Dr. Platt concluded in a
handwritten Memorandum to Davison dated 15th
June, 1984
(Exhibit 1, Document 53):
In all formulations, the
benzenesulphonate salt was clearly superior to the maleate salts in terms of
the absence of UK-57,265 and the reduction in the unknown degradation products
above the main band.
In contrast, the acetate salt is
significantly worse than the maleate salt with respect to the intensity of the
unknown degradation products.
The succinate and mesylate salts show
some advantages over the maleate salt in formulations A, B and D but are
inferior in formulation C.
Recommendation
The benzenesulphonate salt should be
progressed to a further comparative study against the maleate salt as compacts
in the four formulations above. The study should run for at least 12 weeks with
compacts stored at 4ºC, 37ºC and 50ºC.
The acetate salt shows clear
disadvantages and should be dropped.
. . .
[87]
Further
testing was conducted later in 1984 by Dr. Platt. In a handwritten Memorandum
dated 1st August, 1984 (Exhibit 1, Document 58) to Dr. Wells, he
wrote in part:
Conclusions
The benzenesulphonate salt is superior to
the maleate salt in all four formulations. The only significant breakdown of
benzenesulphonate occurred in formulation C.
The succinate and mesylate salts are
equivalent and superior to the maleate salt in formulations A, B and D. The
mesylate salt is still superior in formulation C but the succinate salt is
marginally worse than the maleate salt in this formulation. This is contrary to
the results obtained after 5 days at 75ºC where the mesylate salt was the most
unstable salt form in formulation C when all salts were used as compacts.
A direct comparison of the maleate salt
stored as both blends and compacts shows that, in general, a compact is a more
severe stability challenge for UK-48,340. No additional breakdown products were
formed but the intensity of those produced was increased. There is, however,
one specific breakdown product which is more intense in the blend. One possible
explanation for this is that it represents an intermediate breakdown product
which is concentrated in the blend but undergoes further reaction in the
compact. I would recommend, therefore, that if resources are available, future
compatibility studies for this compound are performed using compacts.
It is difficult to directly compare the
benzenesulphonate salt with the succinate and mesylate salts because of the
potential compact/blend differences. However, on the basis of the degradation
profiles observed at the 3 week checkpoint, I would expect them to be
broadly comparable.
Samples of the 6 week checkpoint are now
available for testing. I am giving priority to the anhydrous decalcium phosphate
tablet formal stability batches and do not expect to be able to run the
alternative salts until w/o 13th August.
[88]
In
a typewritten Memorandum to Dr. Wells dated 9th
October 1994
(Exhibit 1, Document 63), Dr. Platt wrote:
Compatibility Studies
The initial experiments compared the
stability of UK-48,340 maleate salt with UK-48,340 free base in capsule and
tablet formulations. Blends were prepared and compacted into discs to simulate
the tablet environment. Compacts stored at 50ºC were assessed over a 12 week
period where it became obvious that, although no UK‑57,269 could be
formed in the free base formulations, the level of the unknown products was
significantly increased. UK-47,340 free base is not, therefore, a suitable
replacement for maleate salt.
Small salt batches of the acetate,
benzenesulphonate, succinate and mesylate salts were manufactured and compared
with the maleate salt as described for the free base. After 5 days at 75ºC the
acetate salt was inferior to the maleate salt in all formulations and was
dropped from the study. The remaining salts were continued to the 12 week
checkpoint where the benzenesulphonate salt showed a much improved stability
profile over the maleate in all cases. The mesylate salt was only slightly
inferior to the benzenesulphonate salt while the succinate salt was superior to
the maleate salt in 3 formulations and inferior in one.
Further salt forms were investigated
using larger scale batches of bulk drug (100 – 200 g). Maleate,
benzenesulphonate, tosylate, hydrocholoride and salicylate salts were compared
in three formulation blends. After 2 weeks at 75 ºC and 3 weeks at 50ºC the
benzenesulphonate showed a clear advantage over the other salts. The tosylate
salt was superior to the maleate salt while the salicylate was no better and
the hydro-chloride salt much worse than the maleate.
The following rank order of salt forms
has been indentified by comparing the behaviour of each salt in all the
formulations.
Benzensulphonate<
mesylate/tosylate< succinate<salicylate/maleate <acetate<<
hydrochloride
Conclusions
The sulphonic acid salts of UK-48,340 are
clearly superior to all others examined in the compatibility studies carried
out to date. Of these salts, the benzenesulphonate has shown the least
breakdown in formulations and as bulk drug.
There are indications that the quality of
the bulk drug can influence the stability of the drug substance and its
formulations. However, this effect has been minimal for the benzenesulphonate
salt.
The benzenesulphonate salt demonstrates a
clear advantage over the maleate salt in that UK-57,259 cannot be formed.
[89]
Dr.
Platt conducted further studies with four salts, benzenesulphonate, tosylate,
salicylate and hydrochloride. This produced three different blends identified
as A, C and D. The tests were conducted at 50ºC and 75ºC and sampled at 6
weeks. The blends were:
|
Blend
A
|
Blend
B
|
Blend
D
|
|
Mannitol
|
Avical
PH102
|
Avical
PH102
|
|
Dried
maize starch
|
Emcompress
|
Anhy.
Dicalcium phosphate
|
|
9.1
lubricant
|
Explotab
|
Explotab
|
|
|
Mag.
stearate
|
Mag.
stearate
|
[90]
In
a handwritten Memorandum to Dr. Wells dated 20th October, 1984, Dr.
Platt reported his observations (Exhibit 1, Document 66). At 50ºC, after 6
weeks, there was for all salts only minor breakdown in formulations A and D,
formula C was the least stable. At 75ºC, after six weeks, the
degree of breakdown of all formulations
increased. He reported the relative performance of the salts as follows:
The following rank order of salts has
been derived from the performance of the salts in all formulations:
|
Benzenesulphonate
|
↓ Increasing
breakdown
|
|
Tosylate
|
|
Salicylate
|
|
Maleate
|
|
Hydrochloride
|
[91]
I
accept as accurate a chart prepared by Pfizer’s counsel as these stability
tests, noting that the salts as tested were all blended with excipients in
certain formulations:
[omitted]
[92]
The
nature of the testing by Dr. Platt is to be noted. It was done by thin layer
chromatography (TLC). A glass plate is coated with a silica material. Small
samples of the substance tested are placed in “wells” along the bottom of the
plate and an electrical current is applied. The samples are dragged through the
gel by the electricity. Different compounds travel at different rates and thus
become visually separated into different spots. After a period of time, the
current is stopped and the plates are examined visually. A Polaroid photograph
of the plate is taken. At best, such a test is, as Dr. Atwood described, only
semi-quantitative. It can give no absolute or quantitative results, at best the
results are comparative. As an example of what the person conducting the
testing sees, or “eyeballs,” is the following depiction taken from Exhibit 1,
Document 131:
[93]
In
1990 Dr. Platt was asked to review his work done in 1984 apparently for a
patent application pending in Japan. His review and conclusions are set out in
his memorandum to Dr. Davidson dated 23rd
March 1990
(Exhibit 1, Document 154). His review pointed out that his 1984 testing was
carried out on different formulations of three salts-besylate, tosylate, and
mesylate. He was able to re-examine in 1990 certain batches of the tosylate
and hydrated mesylate, while other batches of those salts were too degraded. No
significant degradation of the besylate samples was noted. Dr. Platt noted
variations from batch to batch of the various salts. He concluded that the
besylate and one formulation of the tosylate were about equal, that in one
formulation there was no significant difference between the besylate and
mesylate, and that in another formulation, depending on the checkpoints,
besylate and tosylate exchanged places as to degradation. In part he said:
I have reviewed the original (1984) TLC
photographs accumulated during the alternative salt selection work for
amlodipine. At the time, the work was focussed on showing improvements over the
maleate salt rather than direct comparisons of the sulphonic acid salts.
However, the following conclusions can be drawn from the degradation observed
by TLC.
A) Bulk Stability
The besylate, mesylate and tosylate salts
(among others) were examined after storage for 16 hours at 105ºC. The batches
examined were:
besylate: R1 and
251PD356/1
tosylate: R1 and
261PD67/1
mesylate: 251PD 357/1
There was no significant degradation for
either sample of the besylate salt. Batch R1 of the tosylate salt also showed
no degradation but the lab sample did degrade. The lab sample of the mesylate
salt showed severe degradation. The order, in increasing degradation, is:
besylates = tosylate R1 <
tosylate lab < mesylate lab
B) Formulation Screen 1
The besylate and mesylate salts (among
others) were examined as compacted formulation blends in four different
formulations. Compacts were examined by TLC after 5 days at 75ºC and 3, 6, and
12 weeks at 50ºC. At the first checkpoint, mesylate was worse than besylate in
one of the formulations but no different in the other three. In all succeeding
checkpoints there was no significant difference between the two salts in any
formulation.
C) Formulation Screen 2
The besylate and tosylate salts were
examined as compacted formulation blends in three different formulations. The
formulations were the same as those used in B) above. Compacts were examined by
TLC after 6 days, 13 days and 6 weeks at 75ºC and 3 weeks and 6 weeks at 50ºC.
After 6 days at 75ºC there was no
significant difference between the two salts in 2 out of three formulations.
The tosylate salt was more stable than the besylate salt in the third
formulation. After 13 days at 75ºC, the tosylate was still better in one
formulation, but now worse in the other two formulations. At later checkpoints
the tosylate salt showed more degradation than the besylate in all three
formulations.
. . .
We have now re-examined samples of the
alternative salts that were prepared for the above exercise. Each has been
subjected to a TLC examination against R32 of amlodipine besylate. The batches
examined were:
tosylate: R1 and
261PD67/1
mesylate: 261PD205/1,
251PD357/1 and 261PD217/M/1 (monohydrate)
Of these only batch R1 of the tosylate
salt and the hydrated mesylate salt are suitable for further work. The other
batches show significant levels of impurities which may indicate that the
samples have degraded on storage. Whilst it is encouraging, for the purpose of
our studies, to have degradation occurring, it does show that there are batch
to batch variations in stability performance for the same salt form.
[94]
The
last of Dr. Wells’ criteria was processability, that is, could tablets be made
without significant difficulties such as the stickiness apparent in the maleate
salt. Dr. Wells said in Direct Examination, Volume 1, pages 168-169:
Q. And I believe the final
of the criteria that you referred to was processability, or processing?
A. Sure. At some point in
the synthesis of the salt, PRD would have to mill it. There is every chance that
if it was sticky, it would have stuck to the mill. So, that is the first
problem. And we'd already encountered some problems with milling, even in
pharma R & D. The fact that we are exposing the drug to high stress ‑‑
and the tableting process exposes materials to typically two‑tons' pressure. This is a pretty
catastrophic process. We get what's called a spherity melting. It means that
even if the crystal have a fairly high melting point, under extreme pressure,
that melting point collapses. And by the process of melting, you are likely to
get sticking, because the material becomes plastic, not crystalline and
abrasive, so one has to exclude that.
[95]
Much
has been made in the evidence as to the investigation into the stickiness of
various of the salt candidates. Dr. Wells and Mr. Davison discussed a test
using a laboratory single punch press in which a number of tablets were pressed
from powder formulated by mixing the various salts together with other
excipients then punching 10, 20, 30, 40 and 50 tablets at a time on a single
punch press. The punch was disassembled and the adhering materials dissolved
and weighed. This weight is used as a measure of stickiness. The greater the
weight, the more material it is that has stuck. Dr. Wells prepared a graph illustrating
some of the salts and the weight of the adhering material which chart is
contained in his report of 11th October, 1984, Exhibit 1,
Document 64. From this graph, Dr. Wells derived a slope, that is a number
calculated from the horizontal and vertical axes position of the data point, which
number he used to compare the various salts. It is clear from Dr. Wells’ Cross-Examination,
Volume 2, pages 162 to 166, and in answer to questions from the Court at pages
186 to 191 of Volume 2, that Dr. Wells drew only a rough and ready line, through
some but not all of these points and excluded the data at the 50 tablets point.
It is unlikely that this chart formed the basis for the data presented at Table
2 of the ’393 Patent (Davison Cross-Examination Volume 4, pages 73-77).
[96]
Further,
the ’393 Patent, at page 5, speaks of tablet runs at 100, 150, 200, 250 and 300
tablets. Dr. Wells acknowledged that his data was not generated from any runs
at such levels. He said that the patent is wrong in presenting such numbers (Cross-Examination
Volume 2, pages 181-184). Dr. Wells’ graph is as follows:
[97]
Mr.
Davison did a number of experiments to determine stickiness. These are set out
in his report dated 4th February, 1985, Exhibit 1, Document 77. A
number of graphs are presented including Figure 1 intended to show whether the
tests are reliable, that is, reproducible. To generate the data for Figure 1 a
number of runs of the same salt mixed with the same excipients were done on the
same day and the results graphically presented. Dr. Banker refers to these
results in his evidence to support his opinion that the tests are unreliable.
Figure 1 shows:
[98]
At
Figure 7 of the same report, Mr. Davison plots data from runs of different
salts mixed with the same excipients. Mr. Davison says that he put this data
into a calculator and derived a number for each salt representing the slope (Direct
Examination, Volume 3, pages 116-122). Mr. Davison in Cross-Examination, (Volume
4, pages 73-77) was convinced that the slope figures in the patent were not
derived from Dr. Wells’ graph. As to whether his graph, Figure 7, represents
data used for what is shown in the ’393 Patent, Mr. Davison is equivocal. He
cannot say whether all the data was put in the computer or only some of it, and
if only some, which parts of the data (Cross-Examination, Volume 4, pages 85 to
99). It appears that no archived notebook or other record can be found
relating what was done in this regard (Davison, Direct Examination, Volume 3,
pages 22 to 26). Dr. Amidon in his evidence made calculations based on
Figure 7 and could not come up with the numbers in the ’393 Patent. Figure 7
shows:
[99]
In
October 1984, it appears that there was a request made for further work to be
done using the maleate salt UK-48,340-11. Dr. Platt in a memorandum dated 9th
October, 1984
to Dr. Wells (Exhibit 1, Document 63), summarized his work to date stating, inter
alia:
The sudden request for further work on
the homogeneity and stability of UK-48,340-11 in rodent diet plus the proximity
of the doxasozin commercial stability programme means that it is no longer
possible to schedule work on UK-48,340 alternative salts in the dosage form
group.
It is pertinent, therefore, to recap on
the information we have accumulated to date and recommend, on the basis of this
the benzenesulphonate salt of UK-48,340 for further development.
. . .
Conclusions
The sulphonic acid salts of UK-48,340 are
clearly superior to all others examined in the compatibility studies carried
out to date. Of these salts the benzenesulphonate has shown the least breakdown
in formulations and as bulk drug.
There are indications that the quality of
the bulk drug can influence the stability of the drug substance and its
formulations. However, this effect has been minimal for the benzenesulphonate
salt.
The benzenesulphonate salt demonstrates a
clear advantage over the maleate salt in that UK-57,259 cannot be formed.
[100] Dr. Wells
summarized the state of matters in his Memorandum to Dr. Davidson of 11th
October, 1984 (Exhibit 1, Document 64), saying on the first page:
In a previous memo (J.I. Wells to J.R.
Davidson, 17.7.84) the case for a change from maleate salt to other salt(s) was
addressed in order to achieve a significant improvement in the stability of the
drug and the robustness of the tablet (drug sticking in particular).
Several tablet formulations were proposed
and Teresa Cutt has optimized these systems. Ed Davison has screened all the
potential salts (01, 11, 15, 24, 26, AB) for their sticking propensity and hygroscopicity
and Robin Platt has evaluated their chemical stability in existing and
projected tablet formulations.
ON THE BASIS OF THE DATA GENERATED SO
FAR:
(i) WE SHOULD PROGESS
THE BENZENE SULPHONATE SALT (-26)1
(ii) THERE ARE FOUR
ACCEPTABLE TABLET FORMULATIONS. WE SHOULD PROGRESS ONLY TWO (ONE BY WET MASSING
AND THE OTHER BY DIRECT COMPRESSION).
[101] While reports
were made, as already referred to, in February 1985, matters appear to have
remained fairly quiet until November 1985. A Memorandum of 14th
November, 1985 from Cutt and Dunsbee to Wells (Exhibit 1, Document 106)
summarizes work done on amlodipine besylate in its latest formulation.
[102] A Memorandum
dated 25th November, 1985 from Dr. Wells to Dr. Wood (Exhibit 1,
Document 111), the so-called patent memorandum, was prepared at the request of
Dr. Davidson so that the patent department could proceed to draft a patent
application. Dr. Wells acknowledges that this Memorandum is directed to both
the besylate salt and the tosylate salt, and also says that the mesylate merits
patent protection. Dr. Wells said in evidence at trial that his personal
preference was for the besylate alone (Direct Examination, Volume 1, pages
185-188). Such a preference is not stated in the Memorandum or otherwise stated
in any document prepared at the time
[103] This
Memorandum of November 25th was described by Dr. Moore, a Pfizer patent agent
at the time, as the document that formed the basis of the patent application
(Volume 12, pages 93 to 95). He said it was unusual to get such a comprehensive
and clear description of the invention as a starting point. This Memorandum
said, in part,
SUMMARY
We recommend a patent filing to protect
the besylate and tosylate salts of UK-48,340 because there is:
(a) improved shelf life
of solid dosage forms due to improved solid state stability of the besylate and
tosylate salts.
(b) improved processing
of tablets and capsules because sticking is considerably reduced by the
besylate and tosylate salts. This allows economic tableting by direct compression
whereas although wet massing reduces stickiness it compromises stability.
The mesylate salt probably also merits
protection since its stability and processing properties are excellent.
However, it is isolated in the anhydrous form and upon exposure to moisture
rises rapidly to the monohydrate. The besylate and tosylate are however
non-hygroscopic and anhyrdates.
None of these findings are obvious or
predictable.
[104] A laboratory
notebook, Exhibit 6, shows that Mr. Davison conducted further stability tests
on four salts of amlodipine in the November 1984 to March 1985 period. The
notebook at page 11 states that the purpose of the testing was: “To clarify
the hygroscopicity behaviour of UK 48,340
mesylate(-27), besylate (-26), tosylate (-15) and napsylate.”. In
cross-examination Mr. Davison agreed that the purpose was effectively to anoint
the besylate and validate the choice of that salt (volume 4, pages 58-59).
[105] The notebook,
Exhibit 6, at page 15 summarizes the results of a test in which samples were
exposed for 13 days at 75 degrees and 75% relative humidity stating that the
test was “… insufficient to show any significant difference between
the -26, -15, Napsylate salt forms”. A further test was run at 75 degress,
75% relative humidity for 6 weeks with a conclusion at page 18 stating that the
result “… suggests Napsylate to be the most stable followed by the -26 and -15
salts”. An assay of benzene sulphonate (besylate), mesylate, tosylate,
napsylate salts of 48340 (amlodipine) exposed for 15 weeks at 30 degrees and
95% relative humidity led to the conclusion at page 22 “No significant
breakdown of any of the samples”
[106] According to
Dr. Moore, a trainee in the patent department, Jenny Bowery, and another
person, Colin Graham, prepared a patent application in draft form for review by
the inventors (Exhibit 1, Document 125). Dr. Moore made some comments on the
draft (Cross-Examination, Volume 12, pages 132-137). Following that review the
priority application upon which the Canadian application was based, was
prepared and filed April 4, 1986 (Exhibit 1, Document 126).
[107] Mr. Davison
had no recollection as to any discussions with the patent department or review
of the patent drafts. Dr. Wells said in Direct Examination at Volume 1,
pages 220-221:
Q. Now, Dr. Wells, have you
read other than in connection with this litigation, litigation of amlodipine
besylate, the patent?
A. Have I?
Q. Have you read the
Canadian patent for amlodipine besylate?
A. I've had cites(sic-sight)
of it, but I don't think I've read it from top
to bottom.
Q. Are you aware, sir, that
a point has been made that there are some differences between the contents of
your November 25 memorandum document 111 and what is set out in the patent?
A. You are referring to
solubility distinctions?
Q. Are you aware, generally,
that it has been suggested that there are differences between the information
that is set out in your November ‑‑ in document 111 and some of
what is contained in the patent?
A. Yes.
Q. Do you have any knowledge
or information about how any such differences came about?
A. That the drafting of the
patent was largely carried out by other individuals unknown to me and I was not
diligent enough to pick up some of the subtle changes that had occurred.
THE “INVENTION’ AS PROMISED
BY THE ’393 PATENT
[108] The ’393
Patent describes the claimed amlodipine besylate salt in terms of superlatives,
saying that the discovery of its advantages was “unexpected”, that it had a
“unique” combination of properties that made it “outstandingly” suitable for
pharmaceutical preparation of amlodipine.
[109] At page 1,
the ’393 Patent after acknowledging that the prior art discloses amlodipine and
at least certain of its salts, including the maleate, says (emphasis added):
It has now unexpectedly
been found that the benzene sulphonate salt (hereinafter referred to as the besylate salt) has
a number of advantages over the known salts of amlodipine and, additionally has unexpectedly
been found to have a unique combination of good formulation
properties which make it particularly suitable for the preparation of
pharmaceutical formulations of amlodipine.
Thus according to
the present invention there is provided the besylate salt of amlodipine.
[110] At page 2,
the ’393 Patent sets out four criteria which it says the previously disclosed
salts, even the maleate, could not be satisfied:
Although amlodipine is effective as the
free base, in practice it is best administered in the form of a salt of a pharmaceutically
acceptable acid. In order to be suitable for this
purpose the
pharmaceutically acceptable salt must satisfy the following four
physiochemical criteria: (1) good solubility; (2) good stability;(3) non-hygroscopicity;
(4) processability for tablet formulation, etc.
It has been found that whilst many of the
salts outlined above satisfy some of these criteria, none satisfy them all and
even the preferred maleate . . .
[111] The ’393
Patent then provides some data as to the performance of some salts in respect
of these criteria and concludes at page 6 (emphasis added):
Thus the besylate
salt of amlodipine shows a unique combination of good solubility, good
stability, non-hygroscopicity and good processability which makes it outstandingly
suitable for the preparation of pharmaceutical formulations of amlodipine.
[112] Thus, the
’393 Patent promises not only a besylate salt of amlodipine but also promises
that the besylate salt has a “unique combination” making it “particularly
suitable” and “outstandingly suitable” for preparation of pharmaceutical
formulation of amlodipine. That is the promise of the invention.
COMPARING WHAT THE ’393
PATENT SAYS AND WHAT ACTUALLY HAPPENED
[113] It is rare to
have an opportunity to look behind what is said in a patent and compare that
with what actually happened and what was actually known to the inventors and
others. This is such an opportunity. Proceedings under the NOC Regulations,
for instance, do not afford such an opportunity. Parties there are presented
only with such affidavits that the parties choose to file. There is no
opportunity to examine a party and the inventors by way of discovery before a
hearing.
[114] The drafting
of a patent requires skill, usually left to a qualified patent agent. Great
technical skill is required to get it right. There is, however, an overriding
duty as imposed by section 34(1) (now 27(3)) of the Patent Act) to correctly
and fully describe the invention and by section 53(1) not to wilfully
provide in the specifications more or less than is necessary so as to mislead.
These are statutory continuations of earlier common law obligations. As Dr. Fox
stated in his text, The Canadian Law and Practice Relating to Letters Patent
for Inventions, 4th ed. Toronto: Carswell, 1969 at page 178,
relying in part on Minerals Separation North American Corpn v. Noranda Mines
Ltd., [1947] Ex. Cr. 306 at 317, [1950] S.C.R. 36:
A patent being in the nature of a bargain
between the inventor and the public, and having the synallagmatic feature of
consideration flowing in both directions, the utmost good faith must be
observed by the applicant in disclosing his invention and in framing his
specification, which must not contain any false representation or be wilfully
misdescriptive or misleading in any material part. If any material allegation
in the petition is untrue, or if the specifications and drawings contain
omissions or additions that are wilfully made for the purpose of misleading,
the entire patent will be void. If the omissions or additions are made by
inadvertent error, the court may discriminate and hold valid that part of the
patent that is not affected by the omission or addition.
[115] Counsel for
Pfizer objected on more than one occasion during argument, to any reliance by
Ratiopharm on a lack of good faith or failure of living up to common law
disclosure obligations saying that it had not been pleaded. It is not
necessary to rely on a generalized lack of good faith or common law disclosure
argument, the issues are squarely before this Court as set out in the agreed
issues 1(b) selection 1(c) obviousness, 1(d) insufficiency, 1(e) utility and
section 1(f) validity under section 53(1) of the Patent Act.
[116] A review of
the ’393 Patent will be done essentially as they arise in the specification commencing
at page 1 where, in the third paragraph, there is a listing of many salt forms
of amlodipine disclosed in the prior European patent application publication:
European patent application publication
no. 89167 discloses several different pharmaceutically acceptable salt forms of
amlodipine. In particular the pharmaceutically acceptable acid addition salts
are said to be those formed from acids which form non-toxic acid addition salts
containing pharmaceutically
acceptable anions such as the hydrochloride, hydrobromide, sulphate, phosphate or acid phosphate,
acetate, maleate, fumarate, lactate, tartrate, citrate and gluconate salts. Of
these salts the maleate is disclosed as being particularly preferred.
[117] At the bottom
of page 2 and top of page 3 of the ’393 Patent these salts are referred to as
not satisfying all the necessary criteria for a suitable salt:
Although amlodipine is effective as the
free base, in practice it is best administered in the form of a salt of a pharmaceutically
acceptable acid. In order to be suitable for this
purpose the
pharmaceutically acceptable salt must satisfy the following four
physiochemical criteria: (1) good solubility; (2) good stability;(3) non-hygroscopicity;
(4) processability for tablet formulation, etc.
It has been found that whilst many of the
salts outlined above satisfy some of these criteria, none satisfy them all and
even the preferred maleate, whilst exhibiting excellent
solubility tends to break-down in solution after a few
weeks.
[118] There is no
evidence that any of the salts listed in respect of the European patent
application, except the hydrochloride, the acetate, the maleate or possibly the
citrate salt had ever been made or attempted to be made. Neither Dr. Wells
(Cross-Examination, Volume 2, pages 16 to 22) nor Mr. Davison
(Cross-Examination, Volume 3, pages 150 to 154) could say that the balance of
the salts had ever been made or tested. It is reasonable to conclude,
therefore, that the inclusion of the hydrobromide, sulphate, phosphate, acid
phosphate, fumarate, possibly the citrate and gluconate salts was more than
what was necessary. It is also reasonable to conclude that it was misleading in
that to state, as the ’393 Patent did at the bottom of page 3, that such salts
failed to meet certain criteria and could not have been known to the inventors.
A misleading impression is left with the reader that such salts were made,
tested and found to be inadequate.
[119] Continuing at
page 1 of the ’393 Patent, the next paragraph states (the word unexpectedly
appears twice and the word unique and the words particularly suitable once and
have been underlined):
It has now unexpectedly
been found that the benzene sulphonate salt (hereinafter referred to as the besylate salt) has
a number of advantages over the known salts of amlodipine and, additionally has unexpectedly
been found to have a unique combination of good formulation
properties which make it particularly suitable for the preparation of
pharmaceutical formulations of amlodipine.
[120] The use of
“unexpectedly” and “unique” and “particularly suitable” are self-serving. They
presume what the Patent Office and the Courts are required to find. Are the
properties of besylate amlodipine so unexpected or so unique or so suitable as
to be patentable?
[121] A Court should not
presume that since the specification has used such words that the description
is accurate .
[122] There follows
at pages 1 and 2 a recitation that the invention may be used in formulations
including tablets, capsules and in aqueous solution for perenteral
administration. The last of these is to be particularly noted since the salt
must be in solution and not as a solid.
[123] At the last
full paragraph of page 2, four criteria for a pharmaceutically acceptable salt
are set out. To repeat that paragraph:
Although amlodipine is effective as the
free base, in practice it is best administered in the form of a salt of a pharmaceutically
acceptable acid. In order to be suitable for this
purpose the
pharmaceutically acceptable salt must satisfy the following four
physiochemical criteria: (1) good solubility; (2) good stability;(3) non-hygroscopicity;
(4) processability for tablet formulation, etc.
[124] The evidence
shows, for instance, in the Cross-Examination of Dr. Banker at Volume 7, pages
117 to 121, that a new drug substance may also be tested for other
physiochemical properties including pH (acid or base), melting point,
polymorphism and vapour pressure (enthalpy). Dr. Wells testified in chief
(Volume 1, page 166) that he was aware that there are many properties that
could be considered but, from his point of view, the central tenet was the
three Ss, solubility, stability, salts.
[125] Thus the
promise that besylate is outstanding, unique or particularly suitable must be tempered
by the awareness that such superlatives are based on four of many criteria that
could be considered.
[126] At page 3 the
’393 Patent addresses the first of the four criteria solubility. It says:
1. Generally,
it is known in the art that a good aqueous solubility is
necessary for good bioavailability. Usually a solubility
of greater than 1 mg ml-1 at pH 1-7.5 is sought although higher
solubilities are required to formulate injections. In addition salts which
provide solutions having a pH close to that of blood (7.4) are preferred
because they are readily biocompatible and can easily be buffered to the
required pH range without altering their solubility.
As can be
seen from the following comparative data the besylate salt of
amlodipine exhibits good solubility characteristics, compared with other salts.
TABLE 1
|
Salt
|
|
solubility
mg ml-1
|
pH at
saturation
|
|
Benzene sulphonate
|
(besylate)
|
4.6
|
6.6
|
|
Toluene sulphonate
|
(tosylate)
|
0.9
|
5.9
|
|
Methane sulphonate
|
(mesylate)
|
25
|
3.1
|
|
Succinate
|
|
4.4
|
4.9
|
|
Salicylate
|
|
1.0
|
7.0
|
|
Maleate
|
|
4.5
|
4.8
|
|
Acetate
|
|
50
|
6.6
|
|
Hydrochloride
|
|
50
|
3.5
|
[127] I have
already discussed the evidence respecting the data for the besylate. It comes
from a source different from all the rest. Quite possibility the besylate was
tested at a time different from all the others in a saline rather than aqueous
solution. By way of contrast the besylate that was tested in an aqueous
solution at the same time as the others and yielded a result of solubility 3.6
at a pH of 4.8. This would have put besylate in 6th place on the
chart rather than 4th place. Pfizer’s Counsel argues that this is a
harmless error in that all the tested salts have sufficient solubility. This
appears to be correct, however, it cannot then be said that besylate is in any
way “outstanding” or “unique” as far as solubility is concerned.
[128] Further, as
to solubility, the ’393 Patent in the paragraph beginning with the numeral 1 in
the passages quoted above speaks of a pH range of 1-7.5 and a preferred pH
close to 7.4. There is no evidence of testing of the 8 tested salts over that
range. The listing of besylate salt at pH 6.6 puts it closer to 7.4 and second
to salicylate in approaching 7.4 which may possibly explain a motivation for
the substitution of different besylate data. However, we are left to speculate
as to why the substitution was made. It does serve to enhance the apparent
solubility performance of the besylate.
[129] The next of
the four criteria set out in the patent is that of stability as provided at
pages 3 and 4 as follows:
2. Good stability
in the solid state is very important for tablets and capsules,
whilst good stability in solution is required for an aqueous injection.
In order
to screen for chemical stability, each of the salts was blended
in a powder vehicle and formed into tablets or capsules.
In the case of tablets the vehicle comprised microcrystalline cellulose in
50:50 combination with anhydrous dibasic calcium phosphate. In the case of
capsules the vehicle comprised mannitol in 4:1 combination with dried maize
starch. These were then stored in sealed vials at 50 and 75°C for up to three
weeks. The drug and any breakdown products were extracted with
methanol:chloroform (50:50) and separated on silica tlc plates using a variety
of solvent systems.
The
results were compared and the salts ranked according to the number and amount
of breakdown products produced.
By
comparing the results the following rank order emerges with besylate being the
most stable salt and hydrochloride the least stable.
|
 Salt
|
Stability
|
|
 Besylate
|
most
stable
|
|
Mesylate
|
↓
|
|
Tosylate
|
|
Succinate
|
|
Salicylate
|
|
Maleate
|
|
Acetate
|
|
Hydrochloride
|
unstable
|
[130] The
description states that testing was carried out in “tablets or capsules”. The
evidence shows that in fact the testing was done on what is described as a
compact which is a compressed powder but not a tablet, and on powder which was
never placed in a capsule. It appears that compacts and powder are sufficiently
similar to tablets and capsules that there is no serious error here.
[131] The
description continues by saying that the testing was carried out using a blend
of the particular salt and carbon excipients, microcrystalline
cellulose in 50:50 combination with anhydrous dibasic calcium phosphate and in
the case of capsules (powder), mannitol in 4:1 combination with dried maize
starch. It is agreed by Dr. Wells that in fact the tests were carried out using
a variety of formulations described as A, B, C and D (Exhibit 1, Document 131)
but not all blends were specified in the patent, in fact the besylate salt in
blend C broke down as Dr. Wells said at page 213 of Volume 2 in
Cross-Examination (see from page 207 to page 221, Volume 2):
In my teaching, we don't have to disclose
everything we have done. What we are disclosing are our successes.
[132] Dr. Wells
agreed as well in that passage of the Cross-Examination that the preparations
of the excipients stated in the patent were wrong and that he never checked a
draft of the patent to see if it was right.
[133] In discussing
the ranking of the salts as far as stability is concerned, Dr. Wells agreed in
Cross-Examination (Volume 2, pages 221 and 222) that while besylate is shown as
the best it is not disclosed how close the rest are behind. At page 223 in
discussing the “patent memo” (Exhibit 1, Document 111) Dr. Wells agreed that he
had written that the besylate was “marginally more stable in blends” but that
he didn’t report that in the patent. In all, as to stability, it appears that
the disclosure as to what the inventors knew was selective and not a complete
disclosure.
[134] The third of
the fourth criteria discussed in the ’393 Patent is that of the hygroscopicity
of the salt. This subject is addressed at the bottom of page 4 and to the top
of page 5:
3. In order
to provide stable formulations it is desirable
to have a non-hygroscopic salt. In the solid state where drug content is high,
absorbed films of moisture can act as a vector for hydrolysis and chemical
breakdown. It is the hygroscopic nature of a drug or its salt which contributes
to the free moisture which is normally responsible for instability.
Only the
maleate, tosylate and besylate salts do not pick up any
moisture when exposed to 75% relative humidity at 37°C for 24 hours. Even when
exposed to 95% relative humidity at 30°C for 3 days both the besylate and
maleate remain. anhydrous whilst the tosylate formed the dihydrate salt. Therefore
the besylate salt can be considered to be non-hygroscopic and
thus provides stable
formulations while minimising the risk of intrinsic chemical breakdown.
[135] There was
much debate in the evidence as to what hygroscopicity meant to the inventors
and would have meant at the relevant time to the ordinary person skilled in the
art. I accept Pfizer’s counsel’s submission at paragraph 20 of the Defendant’s
Closing Submissions that there was reasonable consensus among the experts as to
the meaning of hygroscopicity – it is the tendency of a drug substance to
attract and retain water, whether adsorbed on the surface or absorbed into the
crystal structure itself. Whether adsorbed or absorbed and released for instance
by milling, water is a potential problem if it reacts with the drug.
[136] This portion
of the ’393 Patent names the maleate, tosylate and besylate salts and suggests
by the use of the word “only” that other salts were tested as well. There is no
documentation to corroborate that such testing was done. Dr. Wells in
Cross-Examination (Volume 2, pages 108 and 109) says that, by conjecture, this
must have been done.
[137] This portion
of the ’393 Patent further says that two tests were done, one at 75% relative
humidity at 37ºC for 24 hours, the other for at least besylate, tosylate and
mesylate at 95% relative humidity at 30ºC for 3 days. There is no data for that
latter test, but there is data for such a test at 90% relative humidity. In
Cross-Examination, Dr. Wells could not be certain if any test was conducted at
95% relative humidity. Further, it appears that different salts were tested at
different times (Volume 2, pages 105 to 120). Dr. Wells further admitted on
Cross-Examination that the mesylate tested was in fact monohydrate (Volume 2,
pages 120 to 121). Thus, contrary to what the patent says, it was not
anhydrous.
[138] The point of
the volume of evidence as to hygroscopicity is to say that simply because a
salt is or becomes a hydrate is not a reason for rejecting it. The evidence is
that even the besylate forms a hydrate under certain conditions. Dr. McGinity
was cross-examined as to contradictory statements made in his report filed in
these proceedings and evidence that he gave in the United States proceedings
(Volume 12, pages 58 to 74). He eventually agreed that the besylate could exist
as a hydrate and that the mesylate, even as a hydrate, would quickly equilibrate.
Thus neither salt would be a problem from a hygroscopicity point of view.
[139] The
conclusion as to this third criteria as set out in the ’393 Patent at pages 4
and 5 is that it has not accurately reported the testing, if any, done and that
the dismissal of certain salts on the basis of hygroscopicity was ill founded.
[140] The last of
the four criteria described in the ’393 Patent is that of processability and,
in particular, whether there is an unwanted tendency towards stickiness when
making tablets. The patent says at pages 1 and 2 that the besylate salt can be
used in tablet formulations, capsules and perenteral formulations. The latter
is a liquid, capsules contain powder, thus stickiness is only important when
considering tablets. At pages 5 and 6, the ’393 Patent describes processability:
4. The final
characteristic of an acceptable salt to be considered is the processability,
i.e. the compression properties and also the ability not to stick or adhere to the tablet
making machinery.
For high
dose formulations, good compressibility is very important to make elegant tablets.
With lower dose tablets the need for good compressibility can be eliminated to
a certain extent by the use of suitable diluting excipients called compression
aids. Microcrystalline cellulose is a commonly used compression aid. However whatever the
dose the adhesion of the drug to the punches of the tablet machine must be
avoided. When drug accumulates on the punch surfaces this causes the tablet
surface to become pitted and therefore unacceptable. Also sticking of the drug
in this way results in high ejection forces when removing the tablet from the
machine. In practice it is possible to reduce sticking by
wet-massing, careful selection of excipients and the use of high levels of
anti-adherents, e.g. magnesium stearate. However selection of a salt with good
anti-adhesion properties minimises these problems.
In order to compare the
stickiness of the various salts of amlodipine the following procedure was
carried out using conventional tablet making machinery: fifty tablets
containing calcium sulphate dihydrate, microcrystalline cellulose and
amlodipine besylate were made (47.5:47.5:5), the material sticking to the
tablet punch was then extracted using methanol and the amount measured
spectrometrically. This procedure was then repeated for runs of
100, 150, 200, 250 and 300 tablets. After each run the amount of material
sticking to the tablet punch was measured after extraction with methanol. The
values are plotted and an average value calculated from the slope of the line
produced.
This same
procedure was then repeated for each of the salts of amlodipine. The amount of
amlodipine measured as sticking to the tablet punch is shown in Table 2
for each salt and relative to the maleate salt.
TABLE 2
|
Salt
|
Stickiness
|
|
|
µAmlodipine cm-2
tablet
|
Relative to maleate
|
|
|
|
|
|
Mesylate
|
1.16
|
58%
|
|
Besylate
|
1.17
|
59
|
|
Tosylate
|
1.95
|
98
|
|
Maleate
|
1.98
|
100
|
|
Free base
|
2.02
|
102
|
|
Succinate
|
2.39
|
121
|
|
Hydrochloride
|
2.51
|
127
|
|
Salicylate
|
2.85
|
144
|
Clearly
the besylate has superior anti-adhesion properties to the
maleate. Whilst the mesylate also shows good processability
it tends to be isolated as the anhydride but this equilibrates to the
monohydrate leading to variable composition after manufacture which makes it
unacceptable for use in tablets.
[141] Turning to
the third paragraph above commencing with the words “In order to compare . .
.” there is reference to tests on “conventional tablet making machinery”.
The tests conducted in Pfizer’s laboratory were conducted on a laboratory level
single punch tablet machine made by Manesty. There was a debate between
Pfizer’s counsel and Dr. Banker whether this was a “conventional” machine.
Whether it was or was not, being debatable, is not of great importance.
[142] Much more
important is the passage following where it states that the tablets tested
contained calcium sulphate dihydrate, microcrystalline cellulose and amlodipine
besylate (47.5:47.5:5) and test were repeated of 100, 150, 200, 250 and 300
tablets. Dr. Wells agreed in Cross-Examination that these statements are simply
wrong. Other important excipients were blended to make the tablets and runs of
only 10, 20, 30, 40 and 50 tablets were conducted (Volume 2 pages 182 to
186). Dr. Wells further admitted in this passage that his declaration filed in
the United States Patent office stating that the runs had been conducted as set
out in the US ’303 Patent, which is the same in this respect for the ’393
Patent, was also incorrect. He was unable to account for the error.
[143] I have
already reviewed the evidence of Dr. Wells and Mr. Davison as to stickiness
testing and the puzzling derivation of the values for lines of slope which are
said to equate stickiness. I agree with Dr. Amidon where he concludes at
paragraph 41 of his report (Exhibit 35) that the data upon which the stickiness
values set out in Table 2 of the ’393 Patent are based, do not support the
ranking of the salts in the ’393 Patent.
[144] The ’393
Patent at page 6, just after Table 2, has a paragraph stating that mesylate
equilibrates to monohydrate, making it unacceptable for use in tablets. Dr.
Wells in his “patent memorandum” (Exhibit 1, Document 111) stated that the
mesylate equilibrated to “stable” monohydrate (Footnote, page 3) and did not
say that it would be unacceptable for use in tablets. Dr. Moore, the
patent agent, was unable to account for the inclusion of such wording in the
patent (Direction Examination, Volume 12, pages 102 to 104).
[145] The ’393
Patent then continues at page 6 with the paragraph previously referred to
giving an assertion of uniqueness and outstanding suitability for the besylate.
Thus the besylate
salt of amlodipine shows a unique combination of good solubility, good
stability, non-hygroscopicity and good processability which makes it
outstandingly suitable for the preparation of pharmaceutical formulations of
amlodipine.
[146] This “uniqueness”
and exalting of “outstanding properties” of the besylate does not accord with
the opinion expressed by Dr. Wells in his “patent memorandum” (Exhibit 1,
Document 111) of 25th of November, 1985, where he recommended filing
a patent application for the “besylate and tosylate salts” of amlodipine
that the “mesylate probably merits protection”. In the summary of that
memorandum he stated that “only the besylate and tosylate salts match up to
the basic criteria”.
[147] On December 18, 1985, Ms. Bowery,
the Pfizer patent trainee, wrote a memorandum to Pfizer New York (Exhibit 1,
Document 114) stating that Pfizer Limited wanted to file a patent application
for “both the benzene sulphonate (besylate) and the toluene sulphonate
(tosylate) salts of amlodipine”.
[148] It appears
that in drafting the patent application, Dr. Moore or his colleagues restricted
the patent to the besylate salt (Direct Examination, Volume 12, pages 106 to
107). In Cross‑Examination, Dr. Moore said “We wanted to emphasize the
advantages of besylate” (Volume 12, page 129).
[149] Thus the
so-called uniqueness or outstanding properties of besylate extolled in the ’393
Patent were in fact shared with other sulphonates, tosylate and possibly
mesylate, as well as the besylate.
[150] Turning to
the examples in the ’393 Patent, there is very little reference in the evidence
to the Examples 1 to 5 of the ’393 Patent. In evidence previously referred to Dr.
Brenner opines that the product of Example 1 is crystalline and Dr. McGinity
opines that in Example 1 some besylate monohydrate may be found.
[151] The claims,
22 of them, follow. By agreement of the parties, only Claim 11 is relevant.
[152] There is an
omission in the ’393 Patent. It is the testing that was done on another of the
sulphonate group of salts, napsylate. It was tested together with the other
members of the sulphonate group as reflected in Exhibit 6. Those members were
besylate, tosylate, mesylate and napsylate. Only the tosylate results were
reported in the ’393 Patent, no mention of the tests on the other salts and no
mention at all of napsylate is made in the ’393 Patent even though, in many respects,
the napsylate was superior to the besylate (Wells Cross-Examination, Volume 2,
pages 150 to 161). I repeat part of that Cross-Examination at page 158, line 16
to page 161, line 24:
Q. Right. So having made the decision
to proceed with the besylate and knowing that you had another salt that was non‑hygroscopic
and more stable, at least in what you'd been able to see, you decided to file a
patent application saying the "besylate salt is outstandingly
suitable" among all the salts you've tested?
A. Yes.
Q. And you decided not to tell the
patent office and not to tell the Canadian public, in fact, that you had
another salt that was more stable and also non‑hygroscopic?
A. I was under a great deal of pressure
and this was a commercial decision. It probably wasn't the best salt. We have
been through these issues before. I made a decision, along with colleagues,
that we had a salt which was suitable to take forward.
If we had tested and carried on testing,
we may still be doing it. So we took a decision to proceed with the besylate,
and I believe history shows that we got it right.
We could have looked for other salts. We
could have tested many, many more, but we had found one which worked, providing
with us a suitable, sensible solution to the problem we were faced with.
Q. But when you came some months after
this, this is in November of 1985, you filed in April of '86, five months
later, in that time when you're presented with data that says a napsylate is
more stable, the napsylate is non‑hygroscopic, and you're filing a patent
to say that the besylate is the best of the ones you've tested, including
stickiness and solubility, why wouldn't you have tested stickiness and
solubility? You're not looking for a new salt now. All you've got to do is do
a solubility test? How long does that take? Overnight? Simple test,
correct? Solubility is a simple test, is it not?
A. Yes, it is. I mean, you're asking me
whether ‑‑ there comes a point in any program of work, whether it
is law or science or any that you have to say "enough is enough" and
we move on. And its my view that we had made a decision to go with besylate.
Q. I understand that's what you did from
a production, commercial product perspective. I am talking about what you
decided to tell the public and the patent office in the application.
You decided to suppress the data that
you'd already collected in relation to napsylate. You never told the patent
office that: Oh, we also tested napsylate and it was more stable than the
besylate? You never told them that, did you?
A. No.
Q. You didn't put that in your patent
application?
A. No.
Q. Why not?
A. Well, I can't answer that because I
am not a patent agent. My view is we disclose sufficient information to allow
a man skilled in the art to be able to repeat my experiment.
I am not aware that it has to include
every, every aspect of the work that we did. It has to be clear, it has to be
honest, and it has to be right, and that's what we did. We chose not to
proceed with napsylate.
Q. You chose not to proceed with the
napsylate because you had one that you thought was good enough?
A. Absolutely.
Q. You never formed a view that the
besylate was better than the napsylate, did you?
A. I didn't have to form a view.
Q. Right. You just went ahead with the
besylate because that's what you had and it was good enough?
A. Yes.
CONCLUSIONS
AS TO WHAT THE INVENTORS DID AND WHAT THE PATENT SAYS
[153] Taking all
the evidence into account including that not reviewed in these Reasons ( I
refrained, at the expense of hundreds more pages, to set it all out), I make the
following conclusions as to what inventors did both in respect of the
activities of Dr. Wells and Mr. Davison and others at Pfizer and those
drafting the application for a patent which led to the ’393 Patent at issue:
1.
Amlodipine
was a known pharmaceutical compound;
2.
Certain
salts of amlodipine were known and probably had been tested by Pfizer. These
included the hydrocholoride, the acetate, the maleate and probably the citrate
salt. Of these, the maleate salt was considered the best candidate for further
development by way of pre-formulation studies.
3.
The
’393 Patent is wrong in leaving the reader with the impression that the
hydrobromide, the sulphate, the phosphate, the acid phosphate, the fumerate,
the lactate, the tartrate or the gluconate salts had ever been tested.
4.
Dr.
Wells was given amlodipine, including amlodipine maleate and instructed by
Dr. Davidson to develop the product through pre-formulation studies. Mr.
Davison assisted Dr. Wells as did others including Mr. Pettman and Dr. Platt.
5.
Initial
investigations indicate that amlodipine maleate was sticky, a problem for
making tablets. Initially efforts were made to include different excipients to
help with this problem.
6.
The
’393 Patent does not specifically mention that stickiness is a problem with the
maleate salt.
7.
Another
problem was detected with the maleate salt, that of stability. This problem is
mentioned in the ’393 Patent.
8.
Ultimately
by choosing excipents and proportions a commercially successful maleate product
is made. That formulation, which mentions besylate but not maleate, is the
formulation as shown in Table 3 of the ’393 Patent.
9.
Dr.
Wells, having initially tried varying the excipients in a maleate formulation,
believed that a change in the salt would warrant investigation.
10.
Dr.
Wells and others in his team conducted a routine salt screen, a process where a
range of salts are selected from a group of known pharmaceutically acceptable
salts having particular regard to their activity relative to amlodipine, a
characteristic measured by pKa. That range included expected candidates such as
hydrochloride and salts selected from a group of salts known as sulphonates.
This group included mesylate, besylate, tosylate and napsylate, all of which
were tested at various times by the inventors and their collegues. There was
nothing surprising or unusual in selecting a sulphonate group of salts.
11.
The
salt screening process, as conducted by Pfizer was, in the mid 1980s, a
commonplace process in the industry. The testing of pharmaceutical salts for
solubility, stability and hygroscopicity were known techniques as applied to
salt screening. The measuring of stickiness or processability was not a known
technique.
12.
Solubility
testing was conducted on a group of salts. All the salts discussed in Table 1
of the ’393 Patent are sufficiently soluble for the intended purpose.
13.
The
’393 Patent is wrong in suggesting that solubility of the candidate salts was
tested at a pH range of 1 – 7.5. There is no evidence of that. The data in
Table 1 is misleading in that the besylate salt was tested by Pfizer along with
others in water and yielded results of 3.6 for solubility at a pH of 4.5. The
results for besylate stated in Table 1 of the ’393 Patent of 4.6 solubility at
6.6 pH were results from a different test conducted at another time in a 0.9%
saline solution. While the result reported enhances besylate’s solubility in a
meaningless way as all the salts are soluble, it puts that solubility closer to
the desirable 7.4 pH range. There is nothing in the ’393 Patent that would
alert the reader to the fact that different data had been substituted.
14.
As
to stability, Pfizer conducted aggressive tests at elevated temperatures for a
relatively brief period. Such tests do not reflect actual conditions of use nor
tests required for regulatory approval. However it was not uncommon in
commercial organizations where there are time constraints to use such
aggressive tests in the hopes of eliminating weaker candidates and selecting
better ones.
15.
The
stability data as far as excipients and proportions used in stability testing
is wrong. In some formulations, using various excipients and proportions,
several of the salt candidates broke down, including the besylate. Only the
best results were selected. Dr. Wells said they don’t report their failures.
16.
The
chart for stability as set out in the ’393 Patent is simply a ranking of
stability created from selective data. Hydrochloride is said in the text to be
“least stable” and in the chart to be “unstable”. One cannot readily tell if
all salts are suitable or only some and if some, where are they divided.
17.
As
to hygroscopicity, again very aggressive tests were carried out for the same
reason as stability. The ’393 Patent is wrong in stating that test were carried
out at 95% relative humidity, the evidence shows only tests at 90%. This may be
a meaningless error. However, the tests showed that even the besylate can be a
hydrate and that other salts such as the tosylate and maleate can form stable
hydrated salts which are satisfactory. At the most charitable, the
hygroscopicity results stated are careless and incomplete. If fully and properly
reported at least the tosylate as well as the besylate and probably the maleate
would all have been satisfactory from a hygroscopicity point of view.
18.
Stickiness
or processability was not the subject of any well understood standard or test
or criteria. It is described in the evidence of Dr. Wells, as a rough and ready
measure. He derived a test whereby a few tablets would be pressed on a single
punch press and the adhering material weighed. The results were plotted for
differing runs of tablets. These results are highly variable. Much depends on
the excipients with which the tablets are blended. Even the same blend of the
same salt on the same day gave highly variable results. There is no clear
evidence as to how the figures in Table 2 were derived or whether they are
reliable or even indicative of relative stickiness. At best it can be suggested
that the sulphonates (including napsylate, which is not mentioned in the ‘393
Patent) are perhaps less sticky than some of the other salts tested.
19.
A
decision was made, probably by Dr. Davidson, who unexpectedly did not testify
at trial, that patent protection should be sought for at least two of the
sulphonate salts, besylate and tosylate. Dr. Wells prepared a memorandum for
the patent department recommending that a patent be sought for the besylate and
tosylate salts and probably also the mesylate.
20.
The
task of drafting a patent application was given to a trainee, Jenny Bowery, who
was mentored by Dr. Moore, a chartered patent agent. Dr. Moore describes her as
not being comfortable with chemical terms. It appears that she was only loosely
supervised. Dr. Wells has no clear recollection of having met her or of having reviewed
any draft patent application with her or anyone else in the patent department.
Mr. Davison is even stronger on the point that he had no communications with
the patent department.
21.
It
appears from an initial memorandum from Bowery that her first inclinations were
to draft a patent directed to the besylate and tosylate salts. This did not
happen. The patent was drafted directed to the besylate salt alone. Words such
as “unexpectedly”, “unique” and “outstandingly suitable” used in describing the
besylate do not come from Dr. Wells or Mr. Davison, the two named
inventors or anyone else in the scientific area of Pfizer. They could only have
come from the Pfizer patent department after some person, an executive or a
patent agent, had decided to apply for a patent directed to besylate alone.
ADDRESSING THE LEGAL
ISSUES
A. General
[154] As indicated
much earlier, the parties through their Counsel, have greatly simplified the
legal issues and one issue, novelty, has been dropped. Those issues can be
restated as follows:
Given that the ’393 Patent is represented
by Claim 11, “the besylate salt of amlodipine”, is that patent invalid having
regard to whether it is:
a)
obvious;
b)
a
valid select patent;
c)
shown
to have utility;
d)
sufficient;
and
e)
in
violation of Section 53.
[155] To a great
extent, these issues are intertwined. Lawyers are keen to put labels on things,
cite snippets of law and confine issues to the labels and snippets. This is not
new, two centuries ago actions would fail if not pleaded in the right way,
trover instead of replevin and so forth. The simple facts of this case are
that Pfizer developed its amlodipine drug through a routine pre-formulatopn
procedure in which a common procedure called a salt screen was conducted. As a
result of that salt screen of the seven or so salts tested besylate was
selected as the preferred salt. It was not clearly superior to three or four
others tested particularly those of the sulphonate group (besylate, mesylate,
napsylate, tosylate) but was chosen as a reasonable compromise. Some executive
made a decision to seek patent protection. The inventors recommended the
besylate , the tosylate and, possibly the mesylate for that purpose. The
patent department singled out the besylate only , mixed data from some tests
with data from other tests, put in data that cannot be found anywhere in the
evidence and left out data favourable to other salts while using words such as
unique and outstanding and particularly suitable when referring to the
besylate-words the inventors never used. This is the essence of the facts when
it comes to assessing validity on a number of legal bases.
[156] The Courts
have discussed in various decisions what is required of a person who, believing
they have made an invention, must do in order to obtain a valid patent. They
must:
1.
Have
made an invention, something that would not have been obvious to a person
skilled in the art (Obviousness and Invention);
2.
The
invention must be new. If it has been previously disclosed in such a way as to
enable a person skilled in the art to understand the invention as previously
disclosed, no valid patent can be granted (Novelty);
3.
The
invention as promised in the specification must live up to that promise.
It must have the promised utility (Utility);
4.
The
invention must be fully and correctly disclosed as contemplated by the
inventors in a way that a person skilled in the art could read the patent
and put the invention into practice (Disclosure); and
5.
The
patent specification cannot mislead a person skilled in the art (Section 53).
[157] In
considering obviousness and novelty the Court must look at the invention as
claimed. In considering utility the Court must look at the usefulness of
the invention as promised in the specification. In considering
sufficiency of the disclosure the Court must look at the entire specification
to determine if it adequately instructs a person skilled in the art, however,
in a case such as this where we have much evidence from the inventors
themselves, their colleagues and contemporaneous documents, the Court cannot
assume that the patent specification is an accurate reflection of the
understanding of the inventors. In considering whether the specification is
misleading the Court must look at the specification, the nature of the alleged
misleading material to determine if it would be likely to mislead a
person skilled in the art, and whether, taking the evidence as a whole, whether
an intention to mislead can be determined directly or by reasonable
inference.
B. Obviousness
[158] The first of
the issues raised is that of obviousness. In this regard, the Court must look
at the claim as properly construed. Here the claim in Claim 11 which has been
construed as the besylate salt of amlodipine without any particular limitation
as to use or form.
[159] The Supreme
Court of Canada in Apotex Inc. v. Sanofi-Synthelabo Canada Inc., 2008
SCC 61, [2008] 3 S.C.R. 265 per Rothstein J for the Court gave consideration to
the issue of obviousness. The Court commenced the inquiry by restating the
“Windsurfing” questions posed by the English Court of Appeal by writing at
paragraph 67:
It will be useful in an
obviousness inquiry to follow the four-step approach first outlined by Oliver
L.J. in Windsurfing International Inc. v. Tabur Marine (Great Britain) Ltd.,
[1985] R.P.C. 59 (C.A.). This approach should bring better structure to the
obviousness inquiry and more objectivity and clarity to the analysis. The
Windsurfing approach was recently updated by Jacob L.J. in Pozzoli SPA v. BDMO
SA, [2007] F.S.R. 37 (p. 872), [2007] EWCA Civ 588, at para. 23:
In the result I
would restate the Windsurfing questions thus:
(1) (a)
Identify the notional "person skilled in the art";
(b)
Identify the relevant common general knowledge of that person;
(2) Identify
the inventive concept of the claim in question or if that cannot readily be
done, construe it;
(3) Identify
what, if any, differences exist between the matter cited as forming part of the
"state of the art" and the inventive concept of the claim or the
claim as construed;
(4) Viewed
without any knowledge of the alleged invention as claimed, do those differences
constitute steps which would have been obvious to the person skilled in the art
or do they require any degree of invention? [Emphasis added.]
It will be at the fourth step of the
Windsurfing/Pozzoli approach to obviousness that the issue of "obvious to
try" will arise.
[160] If a matter
is “obvious to try”, the Supreme Court provided further considerations at
paragraph 69:
If an
"obvious to try" test is warranted, the following factors should be
taken into consideration at the fourth step of the obviousness inquiry. As with
anticipation, this list is not exhaustive. The factors will apply in accordance
with the evidence in each case.
1.
Is it more or less self-evident that what
is being tried ought to work? Are there a finite number of identified
predictable solutions known to persons skilled in the art?
2.
What is the extent, nature and amount of
effort required to achieve the invention? Are routine trials carried out or is
the experimentation prolonged and arduous, such that the trials would not be
considered routine?
3.
Is there a motive provided in the prior
art to find the solution the patent addresses?
[161] In the Sanofi
case, the Supreme Court had to determine whether it was “more or less
self-evident” what the enantiomeric properties of a racemate (a compound
containing in solid form two identical structures configured differently) would
be if separated. This is evident from what the Supreme Court wrote at paragraph
92:
[92] The methods to
obtain the invention of the '777 patent were common general knowledge. It can
be assumed that there was a motive to find a non-toxic efficacious product to
inhibit platelet aggregation in the blood. However, it was not self-evident
from the '875 patent or common general knowledge what the properties of the
dextro-rotatory isomer of this racemate would be or what the bisulfate salt's
beneficial properties would be and therefore that what was being tried ought to
work. The course of conduct and the time involved throughout demonstrate that
the advantage of the dextro-rotatory isomer was not quickly or easily
predictable. Had the dextro-rotatory isomer been "obvious to try", it
is difficult to believe that Sanofi would not have opted for it before
unnecessary time and investment were spent on the racemate. I conclude that the
prior art and common general knowledge of persons skilled in the art at the relevant
time were not sufficient for it to be more or less self-evident to try to find
the dextro-rotatory isomer.
[162] This finding
bears out the finding of the Trial Judge, Shore J., on the facts of the case.
He wrote at paragraphs 80 to 83 of his decision 2005 FC 390:
[80] It is important
to remember that the process claims (claims 6 to 9) in the '777 patent, which
explain a method to separate the racemate into its isomers, are not contested
in these proceedings. But even though process claims are not at stake, a
necessary additional step after following the teachings of the prior art (e.g.
the '875 patent) in order to obtain the compounds disclosed in claim 1
(dextro-rotatory isomer of the racemate) and in claim 3 (bisulcate salt of the
dextro-rotatory isomer of the racemate) is to separate the racemate into its
isomers (using a successful method, even if it is not the one disclosed
in the '777 patent), in order to obtain the dextro-rotatory isomer of the
racemate. Experts from both parties listed five well-known separation
techniques at the time the '777 patent was invented: forming the diastereomeric
salts of the racemate and performing a fractional crystallization; directly
resolving the enantiomers using chiral chromatography; synthesis from optically
active reagents; immunoassay techniques; and direct chromatographic resolution.
There was no evidence presented to this Court that knowledge at the relevant
time was such that a person skilled in the art would know before trying
the different separation techniques which one would work with the racemate at
issue in this case. The only evidence before this Court is that the person
skilled in the art would eventually find the right technique out of the
well-known separation techniques. Through this evidence, what the experts are
really saying from a legal perspective is that separating the racemate was
worth a try. Having to try different methods, though they be well-known, in
order to discover which one will yield the desired result cannot mean that the
desired result, in this case, the compounds in claims 1 and 3 and their
pharmaceutical compositions, was obvious.
[81] Second, not
only did the compounds in claims 1 and 3 of the '777 patent require first the
separation of their racemate, which was not obvious, but these compounds needed
to be tested in order for their respective beneficial properties to be
discovered. The Court first turns to the dextro-rotatory isomer of the racemate
(claim 1). Though methods to discover the properties of separated isomers were
well known, there is no evidence that knowledge was such at the relevant time
that a person skilled in the art would know before separating the
racemate into its isomers and then testing the separated dextro-rotatory isomer
what the dextro-rotatory isomer's properties would be. The only evidence before
this Court is that using standard techniques, a skilled person in the art would
be able to discover the properties of each separated isomer. Here again, having
to try different separation techniques with uncertainty as to whether each or
some specific techniques would actually result in a successful separation and
then having to perform tests to discover what the properties of the
dextro-rotatory isomer of the racemate were, cannot mean that this compound and
its beneficial properties were obvious. The properties that were discovered in
the case of the dextro-rotatory isomer were its high activity and its low
toxicity, as compared to the levo-rotatory isomer.
[82] The Court then
gave its attention to the bisulcate salt of the dextro-rotatory isomer of the
racemate (claim 3). Though different pharmaceutically-acceptable salts could
have been tried in combination with the dextro-rotatory isomer of the racemate
(some of these salts being, indeed, present in the examples of the '875
patent), there was no evidence that a person skilled in the art would know before
trying the different salts in combination with the dextro-rotatory isomer what
the bisulcate salt's beneficial properties would be. The only evidence before
this Court is that in using known techniques, a person skilled in the art would
have been able to discover the properties of a salt used in combination with an
isomer. Again, having to try different separation techniques with uncertainty
as to whether each or some specific techniques would actually result in a
successful separation and then having to perform tests to discover what the
properties of the bisulcate salt used in combination with the dextro-rotatory
isomer of the racemate would be, cannot mean that this compound and its
beneficial properties were obvious. The properties that were discovered in the
case of the bisulcate salt of the dextro-rotatory isomer were its easy
crystallization, its non-hygroscopic characteristic and its good water
solubility, as compared to other salts.
[83] It flows from
the finding that claims 1 and 3 were not obvious and that claims 10 and 11,
being composition claims, were not obvious either.
[163] The Federal
Court of Appeal, after the Supreme Court decision in Sanofi was
published considered the application of the test in Apotex Inc. v. Pfizer
Canada Inc., 2009 FCA 8. Noel, JA for the Court, after reviewing the Sanofi
reasons, said at paragraph 28:
[28]
I take it from this that the test
adopted by the Supreme Court is not the test loosely referred to as “worth a
try”. After having noted Apotex’ argument that the “worth a try” test should be
accepted (para. 55), Rothstein J. never again uses the expression “worth a try”
and the error which he identifies in the matter before him is the failure to
apply the “obvious to try” test (para. 82).
[164] Curiously
when the Federal Court of Appeal decision was reported in the Canadian Patent
Reports at 72 C.P.R. (4th) 141 that paragraph is misquoted. The
C.P.R. reports it as:
[28]
I take it from this that the test
adopted by the Supreme Court is a precise application of the test loosely
referred to as “worth a try”. After having noted Apotex’ argument that the
“worth a try” test should be accepted (para. 55), Rothstein J. never again uses
the expression “worth a try” and the error which he identifies in the matter
before him is the failure to apply the “obvious to try” test (para. 82).
[165] I am advised
that the Court website version 2009 FCA 8 is the accurate version and accurately
represents that Court’s view of the Sanofi decision.
[166] Thus I am to
be guided in determining obviousness by considering not whether a matter is
“worth a try” rather I am to consider, to repeat paragraph 69 of Sanofi:
If an
"obvious to try" test is warranted, the following factors should be
taken into consideration at the fourth step of the obviousness inquiry. As with
anticipation, this list is not exhaustive. The factors will apply in accordance
with the evidence in each case.
1.
Is it more or less self-evident that what
is being tried ought to work? Are there a finite number of identified
predictable solutions known to persons skilled in the art?
2.
What is the extent, nature and amount of
effort required to achieve the invention? Are routine trials carried out or is
the experimentation prolonged and arduous, such that the trials would not be
considered routine.
3.
Is there a motive provided in the prior
art to find the solution the patent addresses?
[167] In the
present case, unlike Sanofi, we are presented with a situation where the
inventors were given a task, to look at amlodipine maleate and see if they
could make it work sufficiently so as to pass it on for final formulation for
regulatory approval. They quickly determined that there were two problems,
stability and stickiness, only the first of which is mentioned in the patent.
They tried adjusting formulations, a routine task. In fact, a suitable
formulation for maleate was eventually found but not mentioned in the patent
except as a besylate formulation. They also tried other salts through a well
known process, salt screening. They tried a number of salts, including
sulphonates, of which besylate is one. While besylate would not be everyones’
first choice, it was not an unreasonable choice.
[168] In proceeding
through a salt screen, the besylate as well as other sulphonates, seems to work
well enough so as to pass them along to others for final formulation and seek
regulatory approval.
[169] All of this is
routine for a person skilled in the art at the time. In the first set of salts
screened the inventors found a few salts, particularly the sulphonic acid
salts, including besylate, good enough, so they stopped there, why bother
testing more.
[170] I agree in
particular with Dr. Cunningham in his conclusions as set out in paragraph 179
of his report, Exhibit 17, a person skilled in the art would be motivated to
test sulphonic acid salts in general and would have every reason to test the
besylate salt as this had already been shown to offer advantages over other
salts in terms of stability.
[171] I come to the
same factual conclusions that the United States Court of Appeals for the
Federal Circuit did in Pfizer Inc. v. Apotex Inc. (2006) 480 F.3d 1348
at page 10:
However, on the particularized facts of
this case, consideration of the “routine testing” performed by Pfizer is
appropriate because the prior art provided not only the means of creating acid
addition salts but also predicted the results, which Pfizer merely had to verify
through routine testing. . . . The evidence shows that, upon making a new acid
addition salt, it was routine in the art to verify the expected physicochemical
characteristics of each salt, including solubility, pH, stability,
hygroscopicity, and stickiness, and Pfizer’s scientists used standard
techniques to do so. These type of experiments used by Pfizer’s scientists to
verify the physicochemical characteristics of each salt are not equivalent to
the trial and error procedures often employed to discover a new compound where
the prior art gave no motivation or suggestion to make the new compound nor a
reasonable expectation of success
[172] I find, in
applying the Sanofi test, that the claimed invention, a besylate salt of
amlodipine, was obvious, hence the ’393 Patent is invalid.
[173] Having so
found, I will nonetheless in the event of an appeal, which is almost inevitable
in actions such as this, consider the other issues raised.
C. Selection Patent
[174] This issue
can be simply put: Given that a person skilled in the art already knows that
amlodipine exists and already knows that several pharmaceutically acceptable
salts of amlodipine exist, can a valid patent be obtained for the besylate
salt, particularly where that particular salt has not been previously
developed?
[175] In other
cases, I have already expressed the view that an attempt to create a special
category for “selection” patents is really nothing more than a way of
approaching an issue of obviousness. The question generally stated is, if a
class of compounds has been discovered, is it obvious that a particular member
or group within that class will have the same or different properties, and, if
different, how different?
[176] The Supreme
Court of Canada in Sanofi, supra, addressed the question of
selection patents at paragraphs 9 to 11 of its reasons:
9 The locus classicus describing selection patents is the decision of
Maugham J. in In re I. G. Farbenindustrie A. G.'s Patents (1930), 47 R.P.C. 289 (Ch. D.). At p. 321, he
explained that in the field of chemical patents (which would of course include
pharmaceutical compounds), there are often two "sharply divided
classes". The first class of patents, which he called originating patents,
are based on an originating invention, namely, the discovery of a new reaction
or a new compound. The second class comprises patents based on a selection of
compounds from those described in general terms and claimed in the originating
patent. Maugham J. cautioned that the selected compounds cannot have been made
before, or the selection patent "would fail for want of novelty". But
if the selected compound is "novel" and "possess[es] a special
property of an unexpected character", the required "inventive"
step would be satisfied (p. 321). At p. 322, Maugham J. stated that a selection
patent "does not in its nature differ from any other patent".
10 While not exhaustively defining a
selection patent, he set out (at pp. 322-23) three conditions that must be
satisfied for a selection patent to be valid.
1.
There must be a substantial advantage to be secured or
disadvantage to be avoided by the use of the selected members.
2.
The whole of the selected members (subject to "a few
exceptions here and there") possess the advantage in question.
3.
The selection must be in respect of a quality of a special
character peculiar to the selected group. If further research revealed a small
number of unselected compounds possessing the same advantage, that would not
invalidate the selection patent. However, if research showed that a larger
number of unselected compounds possessed the same advantage, the quality of the
compound claimed in the selection patent would not be of a special character.
11 Although
much has been written about selection patents since I. G. Farbenindustrie, Maugham J.'s analysis is
consistently referred to and is well accepted. I find it is a useful starting
point for the analysis to be conducted in this case.
[177] To address
these criteria in this particular case we must determine if the besylate salt
of amlodipine has a “special advantage” in respect of a “quality of special
character” unique to besylate.
[178] The use of
words like “unexpectedly” and “unique” and “outstandingly suitable” by the
person or persons drafting the application that resulted in the ’393 Patent
becomes clearly apparent.
[179] However,
adjectives and adverbs without solid foundation cannot create a “selection
patent” where none in fact exists. As reviewed in the evidence, it is difficult
from the face of the patent and unsupportable from the evidence to state that
besylate is sufficiently superior to the other salts, for instance tosylate and
mesylate so as to make it “unique” or “outstanding” or “particularly suitable”.
[180] If a category
of “selection” patent exists, besylate salt of amlodipine does not merit being
a member of that category. The ’393 Patent is invalid for this reason as well.
D. Utility
[181] Section 2 of
the Patent Act, supra, requires that a patented invention be “new
and useful”.
[182] I have
already reviewed the ’393 Patent from the point of utility based on the
patent alone in Pfizer Canada Inc. v. Canada (Minister of
Health),
2008 FC 500 at paragraphs 90 through 116. I concluded at paragraph 116:
[116]
I find that, on the balance of probabilities, Pharmascience has
failed to show on the data presented in the patent, or even beyond the patent,
that the invention disclosed in the patent lacks utility. Put another
way, I have not been satisfied on the evidence that a person skilled in the art
would have been confounded by the data presented in the patent or not have been
able to make reasonable conclusions as to the utility of the besylate
salt. The evidence beyond the patent is of no further assistance in
respect of that proposition.
[183] In the
present case through evidence presented at trial, I do have evidence beyond the
patent. The invention disclosed in the patent is that the besylate salt of
amlodipine has a “unique” combination of features which make it “outstandingly
suitable” for pharmaceutical formulations of that drug. That is, on the
evidence, not the case. Tosylate and even mesylate were, depending on the
formulations and circumstances, equally good or better. The maleate is sold as
a commercial product as well as the besylate.
[184] I repeat what
I said in Pfizer Canada Inc., supra, in quoting Strayer J, who in
turn quoted from Thorson P, at paragraphs 93 and 94:
[93]
The Patent Act, supra, in defining an “invention”
in section 2 requires that the invention be “new and useful”.
There has not been a great deal of discussion by the higher Courts in Canada as to the concept of “utility”. That concept
at times seems to be conflated with that of “sufficiency”, that is, does the
patent provide sufficient description such that a person skilled in the art can
make something that is workable. Utility also seems at times to be
conflated with the concept of “claims broader than the invention”, that is,
while the patent describes something that is useful, it has claimed something
more than that and the something more is not useful.
[94]
A good summary of the Canadian law as to
utility, which is representative as to the law even today, was given by Strayer
J. in his Reasons in Corning Glass Works v. Canada Wire & Cable Ltd.
(1984), 81 C.P.R. (2d) 39 (F.C.(T.D.)) at page 71:
The legal position asserted by the defendant is perhaps best represented
by a passage which counsel cited from Minerals Separation North American Corp.
v. Noranda Mines Ltd. (1950), 12 C.P.R. 99 at p. 111-2 [1947] Ex. C.R. 306 at
p. 317, 6 Fox Pat. C. 130, where, in speaking of the description of the
invention which must be set out in the disclosures, Thorson P. said:
The description must also give all information that is necessary for
successful operation or use of the invention, without leaving such result to
the chance of successful experiment, and if warnings are required in order to
avert failure such warnings must be given. Moreover, the inventor must
act uberrima fide and give all information known to him that will enable the invention
to be carried out to its best effect as contemplated by him.
To the same effect see also Hatmaker v. Joseph Nathan & Co. Ltd.
(1919), 36 R.P.C. 231 at 237 (H.L.). Counsel also cited Hoechst
Pharmaceuticals of Canada Ltd. et al. v. Gilbert & Co. et al. (1965), 50
C.P.R. 26 at p. 58 [1966] S.C.R. 189, at p. 194, 32 Fox Pat. C. 56. In
that case Hall J. for the court invalidated certain claims because they covered
every possible member of a class of compounds whether any given member could conceivably
be made or not. The patentee was held to have overclaimed in this
respect.
[185] Here, the
evidence beyond the patent shows that the promise of the invention as being
unique and outstanding, is not fulfilled.
[186] The ’393
Patent is invalid for lack of utility.
E. Sufficiency
[187] Section
34(1)(a) and (b) (now section 27(3)) of the “old” Patent Act requires:
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34. (1) An applicant shall in the specification of his invention
(a) correctly and fully describe the invention and its
operation or use as contemplated by the inventor;
(b) set out clearly the various steps in a process, or
the method of constructing, making, compounding or using a machine,
manufacture or composition of matter, in such full, clear, concise and exact
terms as to enable any person skilled in the art or science to which it
appertains, or with which it is most closely connected, to make, construct,
compound or use it;
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34. (1) Dans le mémoire descriptif, le demandeur :
a) décrire
d’une façon exacte et complète l’invention et son application ou
exploitation, telles que les a conçues son inventeur
b) expose clairement les diverses phases d'un procédé, ou
le mode de construction, de confection, de composition ou d'utilisation d'une
machine, d'un objet manufacturé ou d'un composé de matières, dans des termes
complets, clairs, concis et exacts qui permettent à toute personne versée
dans l'art ou la science dont relève l'invention, ou dans l'art ou la science
qui s'en rapproche le plus, de confectionner, construire, composer ou
utiliser l'objet de l'invention;
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[188] In describing
these requirements, often called “sufficiency” the Courts have focused on
whether the patent itself describes sufficient information so as to
enable a person skilled in the art to put it into practice. The Federal Court
of Appeal in Pfizer Canada Inc. v. Canada (Minister of Health), 2008 FCA
108 considered the question of sufficiency stating that the question is not
whether there is enough data in the patent to substantiate the promise of the
patent but rather whether sufficient information has been disclosed so
as to enable a person skilled in the art to make use of the invention. I repeat
paragraphs 63 of that decision:
[63]
The applications judge erred in construing the
promise of the patent and mischaracterized the disclosure requirement under
subsection 27(3) of the Act by asking whether there was sufficient data to
substantiate the promise of the patent. Such an examination exceeds the scope
of the provision. An attack on a selection patent on the basis that there is no
data to support the claimed advantage is certainly relevant for the purposes of
validity (most likely to the question of utility), but it is not relevant with
respect to disclosure under subsection 27(3) of the Act.
[64]
The patent must disclose the invention and how
it is made. The 546 patent does this. It also discloses the advantages that
underlie the selection. This, in my view, is the extent of the requirement
under subsection 27(3) of the Act, the purpose of which is to allow a person
skilled in the art to make full use of the invention without having to display
inventive ingenuity.
[189] In Pfizer
Canada Inc. v. Canada (Minister of Health), supra, I applied this
test to the ’393 Patent at paragraphs 64 to 83 of that decision and concluded
that is was sufficient at paragraph 83:
[83]
Taking the evidence as a whole into account,
and dealing only with what is set out on the face of the patent, I do not find
that what is set out in the patent is insufficient. I am satisfied that,
taking the patent at face value, a person skilled in the art would be given
sufficient information as to what the invention was and how to put it into
practice. As stated by the Supreme Court of Canada in Consolboard Inc. v.
MacMillan Bloedel (Saskatchewan) Ltd., [1981] 1 S.C.R. 504 at page 525:
“There is
no suggestion here that the invention will not give the result promised.”
and at page 526 in
speaking of section 36(1) (now 27(3)) of the Patent Act:
Although (i) s. 36(1)
requires the inventor to indicate and distinctly claim the part, improvement or
combination which he claims as his invention and (ii) to be patentable an
invention must be something new and useful (s. 2), and not known or used by any
other person before the applicant invented it (s. 28(1)(a)), I do not read the
concluding words of s. 36(1) as obligating the inventor in his disclosure or
claims to describe in what respect the invention is new or in what way it is
useful. He must say what it is he claims to have invented. He is
not obliged to extol the effect or advantage of his discovery, if he describes
his invention so as to produce it.
As Thorson
P. stated in R. v. American Optical Company et al. [(1950), 11 Fox Pat. C. 62]
at p. 85:
Nor is it
any objection to the sufficiency of the disclosures that the advantages of the
invention as enumerated by Professor Price were not set out in the
specification…If an inventor has adequately defined his invention he is
entitled to its benefit even if he does not fully appreciate or realize the
advantages that flow from it or cannot give the scientific reasons for
them. It is sufficient if the specification correctly and fully describes
the invention or its operation or use as contemplated by the inventor, so to
the public, meaning thereby persons skilled in the art, may be able, with
only the specification, to use the invention as successfully as the inventor
could himself.
[190] In so doing,
I was looking at what was presented in the patent itself, not the underlying
data. I said at paragraph 68:
[68]
Therefore, as to sufficiency a Court must look
at what is presented in the patent itself. Evidence as to the underlying
data is not to be considered for this purpose. Looking at the face of the
patent the Court must consider whether there is sufficient information given to
conclude that the invention and its use is identified and whether a person
skilled in the art could put it into practice.
[191] In the
present case, we have a different situation, we have not only the underlying
data presented much more fully but the evidence of Dr. Wells, the principal
inventor, given live in the witness box as well as the evidence of the other
named inventor, Mr. Davison, also given live and in the witness box. Previously
only Mr.Davison had provided affidavit evidence and transcript of
Cross-Examination in an earlier proceeding, 2008 FC 500.
[192] Attention
must be given, where it has not been given before in decisions of the Court, as
to the concluding words in Section 34(1)(a) of the Patent Act “as
contemplated by the inventor(s)”.
[193] We now know
what the inventors contemplated and can compare that with what the ’393 Patent
says. As discussed earlier in these Reasons, there are many serious errors,
omissions, insertions from elsewhere and departures in the ‘393 Patent in
comparison with what the inventors contemplated. Rarely has the Court had the
opportunity to look into such matters. Lacking the appropriate evidence the
Courts in the past have had to assume that the words in the specification of a
patent at issue coincided with what the inventors contemplated and, on that
basis, looked only at what the specification would tell a person skilled in the
art.
[194] Here, the
evidence shows that the specification of the ’393 Patent does not disclose what
the invention was as contemplated by the inventors. It is also invalid for that
reason.
F. Section 53
[195] Section 53 of
the Patent Act (the same in both “old” and “new”) says:
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53. (1) A patent is void if any material allegation
in the petition of the applicant in respect of the patent is untrue, or if
the specification and drawings contain more or less than is necessary for
obtaining the end for which they purport to be made, and the omission or
addition is wilfully made for the purpose of misleading.
(2)
Where it appears to a court that the omission or addition referred to in
subsection (1) was an involuntary error and it is proved that the patentee is
entitled to the remainder of his patent, the court shall render a judgment in
accordance with the facts, and shall determine the costs, and the patent
shall be held valid for that part of the invention described to which the
patentee is so found to be entitled.
(3)
Two office copies of the judgment rendered under subsection (1) shall be
furnished to the Patent Office by the patentee, one of which shall be
registered and remain of record in the Office and the other attached to the
patent and made a part of it by a reference thereto.
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53.
(1) Le brevet est nul si la pétition du demandeur, relative à ce brevet,
contient quelque allégation importante qui n’est pas conforme à la vérité, ou
si le mémoire descriptif et les dessins contiennent plus ou moins qu’il n’est
nécessaire pour démontrer ce qu’ils sont censés démontrer, et si l’omission
ou l’addition est volontairement faite pour induire en erreur.
(2)
S’il apparaît au tribunal que pareille omission ou addition est le résultat
d’une erreur involontaire, et s’il est prouvé que le breveté a droit au reste
de son brevet, le tribunal rend jugement selon les faits et statue sur les
frais. Le brevet est réputé valide quant à la partie de l’invention décrite à
laquelle le breveté est reconnu avoir droit.
(3)
Le breveté transmet au Bureau des brevets deux copies authentiques de ce
jugement. Une copie en est enregistrée et conservée dans les archives du
Bureau, et l’autre est jointe au brevet et y est incorporée au moyen d’un
renvoi
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[196] Canada,
unlike other jurisdictions such as the United States, does not
have an explicit statutory provision directed to issues of fraud. However, Section
53 comes close. In so doing, I agree with the submissions of Pfizer’s counsel
that allegations directed to this section must be pleaded with particularity
and a party alleged to have breached the provisions of that section should have
ample opportunity to know what is alleged and prepare its defences.
[197] Ratiopharm
has alleged that Pfizer has breached section 53 in three aspects having regard
to the Amended Statement of Claim, October 20, 2008, paragraphs 63 to 78:
i) omitting to
mention the stability of the mesylate monohydrate and adding that it was
unsuitable for tablet formulations;
ii) omitting the
sulphonic acid test data showing mesylate, napsylate and tosylate to be stable,
non-hygroscopic hydrates; and
iii) adding a
statement that none of the salts outlined in EP167 had been found to satisfy
the four criteria for pharmaceutically acceptable salts.
[198] In argument
at trial, nearing the end of reply argument, Ratiopharm’s Counsel argued that
one other alleged misstatement could, by implication, be found in the
pleadings. Implications are not good enough. Further, Counsel made an oral
motion, based on material he had viewed the night previous but had in his
possession for at least about two months, that another allegation be allowed to
be made. I refused the motion, it was too late.
[199] The evidence
has shown that the misstatements that are the subject of proper pleading were
made, that they were misstatements and that they served to enhance the alleged
uniqueness and outstanding characteristics of the besylate salt, which
characteristics were not true. These misstatements and the selection of words
such as unique, outstanding and particularly suitable were the work of patent
draftsmanship not of the inventors.
[200] Dr. Wells and
Mr. Davison in their evidence distanced themselves from the patent drafting,
even at the expense of admitting failure or neglect in doing so. Dr. Moore, the
only person to testify as to what went on in the patent drafting, placed the
burden of the blame on Jenny Bowery, a trainee about whom he said things like
she found it difficult to deal with complex organic chemistry so she decided to
move on (Volume 12, page 24). Dr. Moore said that he probably reviewed her work
but could not recall anything specific.
[201] This effort
in distancing oneself from the patent draft and placing blame on a trainee not
very competent in chemical matters, who now cannot be found, has left this
Court with the clear impression that Pfizer knew that there were problems with
the patent as drafted. That being the case, Pfizer has taken no steps to do
anything about it save to mount a vigorous defence to this action.
[202] Rarely, if
ever, does one admit to doing something wrong, such as intentionally putting
misstatements in a patent. Pfizer’s Counsel in direct examination put a leading
question to Dr. Moore in that regard which I disallowed. I give no weight to
the answer to the follow up question because the seed had already been planted
in Dr. Moore’s mind. (Volume 12, pages 107 and 108).
[203] As I said in G.D.
Searle & Co. v. Novopharm Ltd., 2007 FC 81, [2008] 1 F.C.R. 477
(reversed on other grounds in 2007 FCA 173, [2008] 1 F.C.R. 529 (CA), without
discussion of this issue) at paragraphs 70 to 77 that proper disclosure is
essential and that intent to mislead can be inferred. I repeat paragraphs 70 to
74.
[70]
The Supreme Court of Canada states in the FBI case, quoted at paragraphs
30 and 31 of Flexi-Coil, supra, and also in Whirlpool Inc. v. Camco Inc.,
[2000] 2 S.C.R. 1067, at paragraph 37 and in AstraZeneca Canada Inc. v. Apotex
Inc. 2006 S.C.C. 49, at paragraph 12, that disclosure by the patentee is an
essential part of the bargain for which this country grants the patent
monopoly.
[71]
Since at least sixty years ago there has been a doctrine of good faith in
respect of patents. President Thorson of the Exchequer Court in Noranda
Mines Ltd. v. Minerals Separation North American Corp., [1947] ExCR 306, at
page 317, said that the inventor must act uberrimae fide and give all
information known to him that will enable the invention to be carried out to
the best effect as contemplated by him.
[72]
A patent is a monopoly sought voluntarily by an applicant, there is no
compulsion to do so. An application for a patent is effectively an ex
parte proceeding, only the applicant and the Patent Office examiner are
involved in dialogue. The patent, when issued, is afforded a presumption
of validity by the Patent Act.
[73]
A patent is not issued simply to afford a member of the public an
opportunity to challenge its validity (see e.g. by way of analogy to revenue
legislation Kingstreet Investments Ltd. v. New Brunswick (Department of
Finance), 2007 S.C.C. at paragraph 54). An obligation arises on those
seeking to gain a patent to act in good faith when dealing with the Patent
Office. The application for the patent includes a specification and draft
claims. The specification is the disclosure for which the monopoly
defined by the claims is granted. This disclosure, as the Supreme Court
has said, should be full, frank and fair. Further disclosure made in
dialogue with the Patent Office examiner. Since at least October 1, 1996,
communications with the examiner must be made in good faith. It is to be
expected that there will be full, frank and fair disclosure. There is
afforded during the prosecution ample opportunity to make further disclosure or
to correct an earlier misstatement or shortcoming. It is not harsh or
unreasonable, if after the patent issues, and disclosure is found to lack good
faith, that the Court deems the application and thus the patent, to have been
abandoned.
[74]
I find that the representation that claims 1-16 of the European patent
applications had been allowed, (the truth being that claims 1-8 had been
allowed and the remainder had been transferred to another, divisional,
application) does not provide a basis for finding abandonment of the
application for lack of good faith. Claims 1-8 include the subject matter of
claims 4 and 8 now at issue here. The other claims 9-16 do not relate to
claim 4 or 8 at issue here. A subsequent response provided the information that
only claims 1-8 had been allowed, even though that information was not specifically
referred to or highlighted. There is nothing on the record to indicate
that the information materially influenced the examiner, nor is there any
information as to the intent of the applicant or its patent agent. The
materiality is low and evidence of intent is lacking.
[204] Here I find
that the three pleaded matters were misstatements, they were misleading and,
sufficient intent to make such statements has been made out in the evidence.
The ’393 Patent is invalid for this reason as well, it cannot be saved under
section 53(2) of the Patent Act.
CONCLUSION
[205] I have found that the ’393 Patent,
as represented by Claim 11 to be invalid on all grounds argued at trial:
·
Obviousness;
·
Selection
patent;
·
Utility;
·
Sufficiency;
and
·
Section
53
[206] A declaration will be
made that the ’393
Patent is invalid and a direction issued to the Commissioner of Patents to make
an entry in the Patent Office records to that effect.
[207] The successful party,
Ratiopharm Inc., is entitled to its costs.
COSTS
[208] The successful party,
Ratiopharm Inc., is entitled to an award of costs to be assessed at the middle
of Column IV. It is entitled to assess costs of two Counsel, one senior and one
junior at trial. It is entitled to reasonable expert witness fees and
disbursements, for all witnesses except for Dr. Cappucino for whom no fees
or disbursements are allowed. No expert witness fees or disbursements shall be
disproportionately high when compared to those of other expert witnesses retained
by any party.
[209] I have set out in other
cases how I believe costs and disbursements should be assessed and will simply
indicate that the same should apply here. I can be spoken to for directions as
to costs if needed.
"Roger
T. Hughes"
FEDERAL COURT
NAME OF COUNSEL AND SOLICITORS OF RECORD
DOCKET: T-1712-07
STYLE OF CAUSE: RATIOPHARM
INC.
PLAINTIFF
- and -
PFIZER LIMITED
DEFENDANT
PLACE OF HEARING: Toronto, Ontario
DATE OF HEARING: JUNE 1, 2, 3, 4, 8, 9, 10, 12,
JUNE 15, 16, 17, 18, 23, 25 and 26, 2009
REASONS
FOR JUDGMENT: HUGHES,
J.
DATED: JULY 8, 2009
APPEARANCES:
Mr. David W. Aitken
Mr. Marcus Klee
PLAINTIFF
Mr. John B. Laskin
Ms. Kamleh J. Nicola
Mr. W. Grant Worden
Ms. Asma Faizi DEFENDANT
SOLICITORS OF RECORD:
Osler Hoskin and Harcourt LLP
Ottawa, Ontario PLAINTIFF
Torys LLP
Toronto, Ontario DEFENDANT
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