`
`PATENT
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`IN THE UNITED STATES PATENT AND TRADEMARK OFFICE
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`Confirmation No.
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`2093
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`) ) ) )
`
`In re PATENT APPLICATION of:
`
`EVANS et 31.
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`Application No.:
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`10/872,784
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`) Group Art Unit:
`
`1617
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`Examiner: Hui, San-Ming R
`
`) ) )
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`))
`
`Filed:
`
`June 22, 2004
`
`FOR:
`
`FORMULATION
`
`DECLARATION UNDER 35 U.S.C. § 1.132
`OF PAUL RICHARD GELLERT
`
`PAUL RICHARD GELLERT of AstraZeneca, Alderley Park, Macclesfield, Cheshire, UK
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`declares:
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`l.
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`I graduated from the University of Oxford in Chemistry in 1984. I undertook postgraduate
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`research with Professor Brian Howard in the Physical Chemistry Laboratory at the
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`University of Oxford leading to the award of a D.Phil in 1988. From February 1988 until
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`the present I have been employed by AstraZeneca, (formerly Zeneca and ICI) initially as a
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`Senior Research Scientist and subsequently as a Team Leader/Manager, Principal
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`Scientist and, since 2004, a Senior Principal Scientist.
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`2.
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`I have worked in the formulation and drug delivery area throughout my career with
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`AstraZeneca, where my research and development work has covered a range of
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`formulation types including sustained released injections, including fulvestrant.
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`3. During the course of my study of the subject application (hereinafter “the Evans
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`Application”) and the underlying data, Ihave become aware of several transcription or
`
`other errors between certain disclosures of the subject application and the underlying
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`laboratory notebook data. One purpose of this Declaration is to point out the existence
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`DESI/620426061
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`InnoPharma Exhibit 1020.0001
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`and nature of these errors and to report further testing that has been carried out under my
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`guidance to obtain additional data (paragraphs 4—10 below and Attachments A—D). A
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`further purpose of this Declaration is to set out and document the manner in which an
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`experienced forrnulator would likely have approached the task of developing a sustained
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`release injectable formulation suitable for human use for a steroidal compound such as
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`fulvestrant in about early 2000, which I understand is when the priority applications
`
`supporting the Evans Application were filed (paragraphs 11 ~ 25 below and Attachment
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`E). Citations to literature and patent references in this Declaration will be in the format
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`Lead Author (Date), and the full citations are given in the Table of References at the end
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`of this Declaration. A copy of each cited reference (or cited portions of the longer
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`references) is included in Attachment F under the Tab number noted in the Table of
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`References.
`
`4.
`
`In Table 2 of the Evans Application, the solubility of fulvestrant in castor oil appears to
`
`have been transcribed incorrectly from the original source, the laboratory notebook. The
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`value in the latter is 245 mg/ml and not 20 mg/ml. In other experiments to determine the
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`solubility of fulvestrant in castor oil and also in benzyl benzoate, some variability was
`
`observed.
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`5.
`
`In Table 3 of the Evans Application, the given solubility values were generated at 4°C
`
`and not at 25°C as is stated in the title of Table 3. For fulvestrant formulations, it is
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`preferable that the fulvestrant remains completely in solution at both 4°C and 25°C. The
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`4°C temperature corresponds to the storage temperature (2°C to 80C in the FDA approved
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`label for Faslodex), and the 25°C temperature corresponds to the administration
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`temperature (ambient temperature). In addition, the specified solubility values on this
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`Table 3 are mean values calculated from analysis of replicate samples from one or more
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`trials. The individual values are shown in handwriting in the amended version of Table 3
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`in Attachment A. In addition, it appears that the mean values for the last three
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`compositions have been incorrectly calculated. The corrected mean values, together with
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`the correction of the temperature from “250C” to read “40C”, are also shown in
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`handwriting in the amended version of Table 3 in Attachment A.
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`DB 13620426061
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`InnoPharma Exhibit 1020.0002
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`6‘
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`l have evaluated the transcription and other errors against the original application
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`disclosures and conclude that these do not change the ultimate conclusions made from the
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`data as originally reported. The addition of 15% wfv benzyl benzoate to compositions
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`having total alcohol concentrations in castor oil of 10%, 15%, 20% and 30% w/v
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`unexpectedly provides a positive effect on fulvestrant solubility, significantly increasing
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`the solubility of fulvestrant in the compositions despite fulvestrant having a lower
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`solubility in benzyl benzoate than in either alcohol or castor oil.
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`7. An additional set of experiments has been conducted at 25 C’C under my guidance to
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`obtain consistent data with reduced variability from a single set of rigorously controlled
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`solubility experiments and to demonstrate that the unexpected increase of solubility of
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`fulvestrant by adding benzyl benzoate into compositions containing ethanol, benzyl
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`alcohol and castor oil, is present across the broader range of composition encompassed by
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`the claims being presented with this Declaration. The solubility of fulvestrant in benzyl
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`benzoate and in castor oil was also measured in the same set of experiments using the
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`same batch ofbenzyl benzoate and the same batch of castor oil as were used to make up
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`the compositions. The Experimental Test Procedure is described in Attachment B.
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`8. The results from these solubility experiments are shown in the table in Attachment C.
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`These results Show that the solubility of fulvestrant in castor oil alone (21.4 mg/ml) is
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`significantly greater than the solubility of fulvestrant in benzyl benzoate alone (3.8
`
`mg/ml) and demonstrate the unexpected increase in fulvestrant solubility on the addition
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`of 10, .15 and 25% w/V benzyl benzoate, in place of an equivalent amount of castor oil, to
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`compositions having total alcohol concentrations in castor oil of 10%, 15%, 20%, 25%
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`and 30% w/v.
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`9. Thus, the results that were obtained from experiments conducted under rigorously
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`controlled conditions and with an expanded range of compositions, as shown in
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`Attachment C; confirm the ultimate conclusions drawn from the results shown in Table 3
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`of the original application disclosure, namely that the addition of 10% to 25% wfv benzyl
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`13331562042606. 1
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`3
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`InnoPharma Exhibit 1020.0003
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`benzoate to compositions having total alcohol concentrations in castor oil of between
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`10% to 30% wx’v unexpectedly provides a positive effect on fulvestrant solubility,
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`significantly increasing the solubility of fulvestrant in the compositions despite
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`fulvestrant having a lower solubility in benzyl benzoate than in either alcohol or castor
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`oil.
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`10. During the course of my study of the Evans Application and the underlying source
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`materials it was drawn to my attention that some of the composition data given for
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`Delestrogen and Delalutin somehow had been shifted one column to the right. Thus, for
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`Delestrogen, the 78% and 58% figures shown under the Bsz column should have been
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`under the OIL column; the 20% and 40% figures shown under the BZOH column should
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`have been under the Bsz column; and the 2% figures shown under EtOH should have
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`been under the BZOH column. Similarly for Delalutin, the “up to 2%” shown under the
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`EtOH column should have been under the BzOH column. This table reports that the
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`source of this data was J .Phann.Sci (1964) 53(8) 891, which is Riftkin (1964) elsewhere
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`referred to in this Declaration, and 1 have also verified the corrected data from the entries
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`for Delalutin and Delestrogen in PDR (1973). A copy of Table 1 from the Evans
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`Application is reproduced as Attachment D, on which these corrections have been made
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`in handwriting, and I have additionally more correctly noted that Delalutin is 17-hydroxy
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`progesterone caproate, and that the “COMP” designation for Delalutin should be “BMS”
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`UBristol-Myers Squibb). Attachment D also includes a one page explanation of the
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`corrections to this Table 1.
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`11. In about early 2000, a person responsible for developing a sustained release inj ectable
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`formulation suitable for administration to humans for a new steroidal compound such as
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`fulvestrant, would have had specialized training and experience in developing
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`pharmaceutical formulations and methods for their administration. In developing such a
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`formulation for fulvestrant, the objective would have been to formulate an intramuscular
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`(1M) injection that would provide for the satisfactory sustained release of fulvestrant over
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`a period of at least two weeks and preferably over a period of at least four weeks to
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`reduce the frequency of administration, and would have a target fulvestrant content of at
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`DB 11620426061
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`InnoPharma Exhibit 1020.0004
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`least 45 mgme so as to provide a fulvestrant dose of at least 250 mg in a single 5-6 mL
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`injection. From my personal experience and knowledge of the literature at about that
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`time, I believe that such an experienced formulator would likely have approached the task
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`of developing a fonnulation for fulvestrant in about the following mannerr
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`12. Given the foregoing objective, the experienced formulator would have appreciated that
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`the traditional administration options to explore were intramuscular (1M) injection of a
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`sustained release aqueous or oil suspension or an oil—based solution (depot) containing at
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`least 250 mg of fulvestrant in a volume of vehicle that is tolerable for injection, i.e., no
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`more than 5 or 6 mL.
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`13. Because of the extremely low solubility of fulvestrant in water, a reasonable starting point
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`would have been to investigate intramuscular injection of an aqueous or oil suspension of
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`fulvestrant However, the formulator would have found that injection of an aqueous
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`suspension of fulvestrant resulted in extensive local tissue irritation at the injection site as
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`well as a poor release profile, such as reported in paragraph [0042] of the Evans
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`Application. Since suspensions thus were not an acceptable option for fulvestrant, the
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`experienced formulator would have moved on to further explore whether 250 mg of
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`fulvestrant could be solubilised in no more than 5—6 mL of an oil—based vehicle, i.€.,
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`to
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`achieve the target fulvestrant concentration of at least 45 mg/mL.
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`14. In the preformulation phase, the experienced formulator would have conducted a
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`literature review or otherwise would have become familiar with commercially marketed
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`inj ectable formulations, particularly injectable sustained release formulations of steroids
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`or other relatively insoluble compounds such as those listed in Table l of the Evans
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`Application, with the objective of identifying potential oil vehicles, co—solvents and other
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`excipients that already had been found to be tolerated andior to have passed through
`
`regulatory review, and which might be candidates for further consideration and testing for
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`the fulvestrant formulation. This review also would have provided guidance with respect
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`to concentration levels of such co~solvents and other excipients that generally had been
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`found acceptable in sustained release oil-based intramuscular injections administered to
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`DB 1 r’62042606.l
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`InnoPharma Exhibit 1020.0005
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`humans. This objective is confirmed, for example, in Nema (1997) at page 166:
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`Generally, a knowledge of which excipients have been deemed
`safe by the FDA or are already present in a marketed product
`provides increased assurance to the formulator that these excipients
`will probably be safe for their new drug product. Regulatory
`bodies may View an excipient previously approved in an injectable
`dosage form favorably, and will frequently require less safety data.
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`The purpose of this Nema paper was thus “to present the various excipients that have
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`been included in the formulation of injectable products marketed in the USA.”1 Similar
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`objectives were intended to be served by the compilations of commercial formulations in
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`Strickley I (1999), Strickley II (2000) and Strickley HI (2000):
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`This compilation will also be useful for those interested in
`knowing What additives are currently used in inj ectable products
`and at what concentrations they are administered in practice. This
`compilation only focuses on marketed formulations and does not
`delve into the subject of preclinical or drug discovery formulations
`associated with early-stages pharmacokinetics or proof—of~concept
`pharmacodynamics, where the formulation scientist is not bound
`by regulatory constraints.
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`(Stricklcy 1 (1999) at 324).
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`Powell (1998) similarly states at page 238 with respect to its compilation of commercially
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`used excipients:
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`Thus, the formulation scientist is often faced with a dilemma —~
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`which excipients are truly available for use (based on what has
`been used previously), and which are not? And at what
`concentrations, and by what route?
`Herein are listed the excipients found in most of the approved
`and marketed parenteral formulations, given systematically by
`excipient name. In this format it is easy to detemiine what
`concentrations were used, the route of administration, the main
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`rationale for addition of that excipient, the drug that was
`formulated, the manufacturer, brand name, etc.
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`15. From the literature review, the forrnulator would have noted reference to a number of
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`intramuscular injectable sustained release oil—based steroidal formulations that had been
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`“ Ncma (199?) does caution, however, that there is no guarantee that the new drug product will be safe as excipients
`are combined with other additives andfor with a new drug, creating unforeseen potentiation or synergistic toxic
`effects.
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`DB1I62042606J
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`InnoPharma Exhibit 1020.0006
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`commercially marketed:
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`o
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`Strickley I (1999), Table V II:
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`Haloperidol Dccanoates’Haldol dccanoate (50-100 mgimL in sesame oil, benzyl
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`alcohol 12%);
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`Testosterone Enanthatez’Delatestryl (200 mgme in sesame oil, chlorobutanol 5
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`mgme);
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`0 PDR (1973) at pages 1277—1278
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`Proluton/progesterone (50 mg/mL in sesame oil, 150 mg/ml benzyl benzoate, 5
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`mgf'ml benzyl alcohol, 1 mgfml propylparaben);
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`o
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`PDR (1973) at pages 1349-1354
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`DeladumonefTestosterone Enanthate & Estradiol Valerate (90 & 4 mgme in
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`sesame oil, 0.5% chlorobutanol);
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`Deladumone OB/Testosterone Enanthate & Estradiol Valerate (180 & 8 mg/mL in
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`sesame oil, 2% benzyl alcohol);
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`Delalutin/hydroxyprogesterone caproate (250 mg/mL in 52% castor oil, 46%
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`benzyl benzoate, 2% benzyl alcohol);
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`Delestrogen/estradiol valerate (20 mg/mL in 78% castor oil, 20% benzyl benzoate,
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`2% benzyl alcohol and 40 mg/mL in 58% castor oil, 40% benzyl benzoa'te, 2%
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`benzyl alcohol);
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`Delatestryl/Testosterone Enanthate (200 mg/mL in sesame oil, 0.5%
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`chlorobutanol);
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`Delaluteval 2Xr’hydroxyprogesterone caproate & estradiol valerate (250 m g/mL &
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`5 mg/mL in castor oil, 45% benzyl benzoate, 1.6% benzyl alcohol);
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`0
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`PDR (1973) at pages 1391-1392
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`Prolixin Enanthate/FluphenazineBnanthate (25 mgme in sesame oil, 1.5% benzyl
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`alcohol);
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`a Wang (1980):
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`Depo-Testosterone/testosterone cypionate (100 mgi’mL in 87.4% cottonseed oil;
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`0.1 mL benzyl benzoate, 9.45 mg benzyl alcohol as a preservative);
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`o Mackey (1995):
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`Testoviron Depotftcstosterone enanthaie (250 mgme in castor oil and henzyl
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`DB1!62()42606.1
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`InnoPharma Exhibit 1020.0007
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`benzoate);
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`as well as a number of other commercialized oil based long—acting 1M injectable
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`formulations reported on Table 1 of the Evans Application.
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`16. As a further part of the preformulation phase, the experienced formulator would have
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`conducted a preforrnulation solubility screen, separately measuring the solubility of
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`fulvestrant in a range of pure solvents, including the potential oil and co-solvent
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`candidates that had been identified in the above literature review as being suitable for
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`inclusion in intramuscular injection formulations. See, for example, Gupta (1999),
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`Chapter 17 at page 402, under the heading “Formulation Development”:
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`The activities necessary to develop a parenteral product can be
`placed into the following three broad areas: preformulation,
`formulation, and scale-up. While there are alternative development
`perspectives, all development ultimately needs to accomplish the
`same activities. Preformulation includes the characteristics of the
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`bulk drug plus initial screening for excipient compatibility with the
`drug.
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`“Preformulation studies” are said to “provide fundamental data and experience necessary
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`to develop formulations for a specific compound” including, as item 8.1 in the outline of
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`areas of specific interest, a determination of “solubility” in “selected solvents” (at 403).
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`“Significant formulation activities begin with initial preformulation data and knowledge
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`of the specific route of administration” (at 405), which “formulation activities include the
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`identification and selection of a suitable vehicle (aqueous, nonaqueous or co—solvent
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`system) ...” (at 404). It is further noted that “injection volume is one of the most
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`important considerations in the formulation development of a commercial product” (at
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`405). When carrying out such a preformulation solubility screen with fulvestrant, the
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`formulator would have found that fiilvestrant had extremely low solubility in water, low
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`solubility in most oils (but highest in castor oil), low solubility in benzyl benzoate, and
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`the highest solubility in ethanol and benzyl alcohol, such as reported in Table 2 of the
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`Evans Application.
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`17. With the information on prior commercialized formulations and the fulvestrant solubility
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`data from the prefonmulation screen (such as reported in Table 2 of the Evans
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`DBL/62042606,;
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`g
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`InnoPharma Exhibit 1020.0008
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`Application), the experienced formulator would have selected castor oil as the oil vehicle
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`because of the higher solubility of fulvestrant in castor oil relative to the other oils tested.
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`Nevertheless, he would have appreciated that the target fulvestrant concentration of at
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`least 45 mgx’rnL could not be achieved with castor oil alone, and that a co—solvent would
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`be required.
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`18. A number of the commercialized fonnulations that would have been identified in the
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`literature review (including the caster oil-based formulations) have a substantial benzyl
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`benzoate component, which may be present as a co-solvent. See, for example, Delalutin
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`noted in paragraph 15 above, which is reported in PDR (1973) and noted in Table I of the
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`Evans Application, and is one of the fonnulations discussed in Riftkin (1964), “Castor
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`Oil as a Vehicle for Parenteral Administration of Steroid Hormones” (see Riffkin n. 6).
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`Deialutin is 250 mg/mL 17-hydr0xyprogesterone caproate dissolved in 52% castor oil,
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`46% benzyl benzoate and 2% benzyl alcohol. However, Riffldn Table 11 reports that the
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`solubility of 17-hyd0xyprogesterone caproate in castor oil alone is only 55.6 mg/mL, but
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`the solutility of 17—hydroxyprogesterone caproate in benzyl benzoate is substantially
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`higher, being at least 250 mg/rnL (see example 4 of Huber H] S “520) and Attachment E
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`discussed below). Even if not needed as a cosolvent, Riffkin (1964) notes that “the
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`addition ofbenzyl alcohol or benzyl benzoate to castor oil resulted in a lower and more
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`favorable viscosity, making it easier to inject” (paragraph bridging pages 893—894).
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`19. However, the skilled forrnulator would have appreciated from the fulvestrant solubility
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`data generated in the preformulation screen that fulvestrant had very different solubility
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`characteristics relative to the steroids of previous commercial formulations. Attachment E
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`is a compilation showing the chemical structures and relative solubilities in castor oil and
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`sesame oil of the compounds named in ijfkin (1964) Table 11 compared to the structure
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`and the solubility of fulvestrant in these oils. It can be seen that the solubility of
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`fulvestrant in castor oil and in sesame oil (20 mg/rnL and 0.58 mg‘mL, respectively, from
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`Table 2 of the Evans Application) is appreciably lower than the solubility of the other
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`steroids in these oils (taken from Table II of Riffldn (1964)). The second page of
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`Attachment E tabulates the concentration in benzyl benzoate of five named steroids, taken
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`DB1€62042606J
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`InnoPharma Exhibit 1020.0009
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`from Examples 1—5 of Huber (US ‘520), ranging from 200 to 400 rug/"ml.2 By
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`comparison, the solubility of fulvestrant in benzyl benzoate is reported in Table 2 of the
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`Evans Application as being only 6.15 mg/mL, and only 3.8 mgme as determined in the
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`recently conducted tests reported in Attachment C.
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`20. The experienced formulator thus would have expected that benzyl benzoate would not act
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`as a co-solvent for fulvestrant in castor oil because the solubility of fulvestrant in benzyl
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`benzoate was significantly lower than its solubility in castor oil. The addition of benzyl
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`benzoate to castor oil, for whatever reason, would have been expected to decrease, rather
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`than increase, the solubility of fulvestrant in the resulting castor oil/benzyl benzoate
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`mixture. This is confirmed in Table 4 of the Evans Application, which reports a
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`fulvestrant solubility of only 12.6 mg/mL in the castor oil vehicle containing only 15%
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`benzyl benzoate, compared to the 20 mg/mL solubility of fulvestrant in castor oil alone as
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`reported in Table 2.3
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`21. Based on the solubility data determined in the preformulation screen (such as reported in
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`Table 2 of the Evans Application), ethanol and/or benzyl alcohol would have been seen as
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`the best co—solvent candidates for raising the fulvestrant solubility to the 45 mg/mL target
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`in the castor oil vehicle, and would also function to lower the viscosity of the resulting
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`formulation and make it easier to inject. Consistent with this solubility data, Dukes (US
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`‘814) added 40% w/v benzyl alcohol in order to dissolve 50 mg/mL fulvestrant in the
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`castor oil-based formulation used in the experimental rat studies of his Example 3. It thus
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`would have been apparent that 40% w/V benzyl alcohol could fimction as a co-solvent in
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`castor oil to achieve the target fulvestrant concentration. Nevertheless, the skilled
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`formulator would have been concerned with using such a high alcohol content in
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`intramuscular inj ectable formulations for administration to a human.
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`2 Data taken from the Examples of Huber (US “520); these are concentrations used in the examples and not
`necessarily the actual maximum solubility of each steroid in benzyl benzoate, which may be higher. Huber was a co-
`author on Riftkin (1964).
`1 It should be noted that in the further tests that were recently conducted under my guidance (paragraphs 7—9 above
`and Attachments B and C hereto), the solubility of fulvestrant in castor oil alone was again tested and found to be
`21.4 mgi’mL, and the solubility of fulvestrant in benzyl benzoate alone was again tested and found to be only 3.8
`mgme, which further confirms that benzyl benzoate would not be expected to act as a cosolvcnt for fulvcstrant in
`castor oil.
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`DBls'62042606J
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`InnoPharma Exhibit 1020.0010
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`22. First of all, the experienced formulator would want to minimize the amount of co-
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`solvents and excipients in any injeetable formulation. For example, as stated in Gupta
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`(1999), Chapter 17, “Formulation and Administration Techniques to Minimize Injection
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`Pain and Tissue Damage Associated with Parental Products.” at page 414:
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`Cosolvents are commonly used to enhance drug solubility and
`stability. Cosolvents may include ethanol, propylene glycol,
`polyethylene glycols, and glyeerine. These components have
`intrinsic effects on biologic tissue and can alter the properties of
`other exeipients, thus influencing the tissue damage or pain caused
`by a product. There is a dearth of literature on the pain caused by
`cosolvents, but there is also a growing body of knowledge on the
`tissue damage that they can cause. It is not certain that tissue
`damage is always directly correlated with the injection pain, but
`minimization of both pain on injection and potential for tissue
`damage should be included in the product development plan.
`
`See also Gupta (1999), Chapter I 1, titled Cosolvent Use in Injeetable Formulations, page
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`217:
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`Ideally, it is best to select and use solvents that would maximize
`the solubility of the compound. Maximizing the solubility of a
`compound in a panicular cosolvent system would result in lower
`total levels of the non-aqueous solvent(s) being administered to the
`patient, thereby lowering the chance for potential side effects.
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`This objective would have applied to aqueous and oil-based systems alike, in that the
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`precedent of commercialized formulations identified in the literature review would have
`
`confirmed that fixed oils, such as castor oil, have long been commercially used and
`
`accepted as the major component of oil—based sustained release intramuscular inj eetable
`
`steroidal formulations. On the other hand, co-solvents such as ethanol or benzyl alcohol
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`have generally been used only in far lesser concentrations, as discussed in the following
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`paragraph.
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`23. Thus, use of such a high content of either benzyl alcohol or ethanol would have been
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`contrary to precedent as shown from the review of commercialized oil-based
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`intramuscular injectahle sustained release formulations. The literature review as of early
`
`2000 would have shown that any benzyl alcohol in such formulations was almost always
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`DBU62042606.1
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`l 1
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`InnoPharma Exhibit 1020.0011
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`present as a presewative in a concentration of about 2% or less, occasionally at a
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`concentration of up to 5%, but only rarely at higher concentrations. With respect to
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`benzyl alcohol see, for example:
`
`- Gupta (1999), Chapter 11 at page 229 stating that benzyl alcohol “is typically used in
`
`concentrations of up to 2 percent as a preservative and up to 5 present as a solvent,”
`
`and then discussing reported toxicities.
`
`- Nema (1997), Table V at page 168, reporting that benzyl alcohol was present as an
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`antimicrobial preservative in 74 injectable formulations (not limited to oil—based IM
`
`formulations) at concentrations of from 0.75-5% (note that benzyl alcohol is not
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`included at all in Nema Table I, “Solvents and Co—solvents”;
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`-
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`Powell (1998), the benzyl alcohol listing at pages 244—246, particularly those
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`indicated as being used in M formulations;
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`-
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`Strickley I (1999) at page 329 notes the inclusion of 2% benzyl alcohol in an IM
`
`lorazapam formulation in a propylene glycol vehicle, but does not include benzyl
`
`alcohol at all in Table VI listing “Cosolvents Used in Parenteral Formulations;”
`
`- Lopatin (1972) noting in Table 3 at page 727 opposite Benzyl alcohol, “Toxic. Used
`
`in concentration of not over 3%. Has irritant action in concentration of 5%,”
`
`0 Cornelius (US ‘863), col. 1, lines 30-35 stating, “It is known that the solubility of
`
`steroids in vegetable or animal oils can be increased by the addition of excipients such
`
`as benzyl alcohol and benzyl benzoate. An objection to the use of such excipients, and
`
`specifically benzyl alcohol in somewhat higher concentrations, is that these agents
`
`may imitate the tissues.”
`
`The literature review as of early 2000 also would have shown that, with few exceptions,
`
`ethanol was not included in such formulations in excess of about 10%. See, for example:
`
`- Gupta (1999), Chapter 11 at page 225 noting that ethanol has been used at levels up
`
`to 50 percent, but these levels typically are associated with pain on injection;
`
`- Strickleyl (1999), Table VI, “List of Cosolvents Used in Parenteral Fonnulations”
`
`more specifically lists the ethanol content in IM formulations for specifically
`
`identified drugs, which concentrations range only from 2.5 to 10%; an IM/IV
`
`lorazapam formulation in a propylene glycol vehicle is noted at page 329 as having
`
`13% alcohol, but is not included with the 1M formulations in Table VI;
`
`DB13620426061
`
`1 2
`
`InnoPharma Exhibit 1020.0012
`
`
`
`- Nema (1997), Table I, “Solvents and (Io-solvents” at page 167, lists ethanol as being
`
`in 24 formulations with a concentration range of 06—80% (for Prograf); note that this
`
`is misleading, however, since Prograf is a concentrate for intravenous infusion only,
`
`and is to be diluted 250 to 1000 times before administration;
`
`0 Powell (1998), lists “alcohol” at page 242 and “ethyl alcohol” at page 255, wherein
`
`the ethanol concentration for M formulations ranges from 0.61-10%,
`
`24. Thus, even though Dukes (US ‘814) had demonstrated that the target 45 mg/mL
`
`fulvestrant concentration could be achieved by adding 40% benzyl alcohol to the castor
`
`oil vehicle, the precedent of commercialized IM oil—based systems would have motivated
`
`the experienced formulator to substantially reduce the benzyl alcohol content of the
`
`formulation intended for human use, and this commercial precedent would have made
`
`him very reluctant to replace benzyl alcohol with the substantial amount of ethanol that
`
`would be needed to maintain the target fulvestrant concentration. Benzyl benzoate clearly
`
`would not be considered to solve this dilemma, but rather would be expected to have a
`
`negative effect on fulvestrant solubility since fulvestrant was even less soluble in benzyl
`
`benzoate than in castor oil, that is, one would have expected that adding benzyl benzoate
`
`would require still more alcohol to maintain the target fulvestrant concentration.4
`
`25. Under these circumstances, the discovery by Evans et (21., that the addition of benzyl
`
`benzoate to the castor oil/alcohol mixture actually increases the solubility of fulvestrant
`
`such that more fulvestrant could be dissolved in a given volume of formulation, was
`
`unexpected and truly surprising. This positive benzyl benzoate effect on fulvestrant
`
`solubility in the resulting formulation is shown in Table 3 of the specification (and is not
`
`changed by the above-noted corrections), and is confirmed and demonstrated over a
`
`broader range of formulation composition by the additional set of experiments conducted
`
`under my guidance and discussed in paragraphs 7-9 above, the results of which are
`
`reported in Attachments C.
`
`
`4 It should be noted that even apart from this solubility issue, there would have been no motivation to add benzyl
`benzoate for Viscosity reduction since the significant quantity of alcohol would serve the dual function of acting as a
`co—solvent as well as reducing the injection viscosity and making it easier to inject, whereas the benzyl benzoate
`would be expected to have a negative effect on the fulvestrant solubility.
`
`13131362042606, 1
`
`13
`
`InnoPharma Exhibit 1020.0013
`
`
`
`The undersigned declares fuither that all statements made herein of his own knowledge are true
`
`and that all statements made on information and belief are believed to be true; and fiirther that
`
`these statements were made with the knowledge that wilful false statements and the like so made
`
`are punished by fine or imprisonment, or both, under Section 1001 of Title 18 of the United
`
`States Code and that such wilful false statements may jeopardise the validity of the application or
`
`any patent issuing thereon.
`
`H. Mi-
`
`
`
`Date:
`
`Kw MWE 1‘;ng -
`
`DB1J620426061
`
`14
`
`InnoPharma Exhibit 1020.0014
`
`
`
`TABLE OF REFERENCES
`
`Author/Inventor
`
`Reference Citation/Patent
`
`US Patent 4,212,863
`Cornelius (US “863)
`
`
`
`EP 0 346 014 A1 (corresponds to US Patent 5,183,814)
`
`US Patent 5,183,814 (corresponds to EP 0 346 013 A1)
`
`P.K. Gupta and G.A. Brazeau (eds). Injectable Drug
`Development: Techniques to Reduce Pain and Irritation. Chapters 11 &
`17 Interpharm Press, Denver, Colorado (1999)
`
`US Patent 3 ,164,520
`
`P.V. Lopatin, V. P. Safonov, T. P. Litvinova and L. M. Yakimenko. Use
`of nonaqueous solvents to prepare injection solutions. Pharm. Chem. J.
`6:724-733 (1972)
`
`Dukes (US ‘814)
`
`Gupta (1999)
`
`Huber (US ‘520)
`
`Lopatin (1972)
`
`Mackey (1995)
`
`Nema (1997)
`
`PDR (1973)
`
`Powell (1998)
`
`Riffkin (1964)
`
`
` Dukes (EP ‘014)
`
`M.A. Mackey, A.J. Conway and DJ. Handelsman. Tolerability of
`intramuscular injections of testosterone ester in oil vehicle. Hum.
`‘ Reprod. 10: 862-865 (1995)
`
`S- Nema, RJ. Washkuhn, and R.J. Brendel. Excipients and their
`; use in injectable products. PDA J. Pharm. Sci. Technol. 511166-71
`;(1997)
`:Physicians DeskReference (27th edition). 1277-1278, 1350—1354, 1391‘
`1392 Medical Economics Company, Oradell, NJ (1973)
`
`E M. F. Powell, T. Nguyen, and L. Baloian. Compendium of excipients for
`parenteral formulations. PDA J. Pharm. Sci. Technol. 52:23 8311 (1998)
`
`C. Riffkin, R. Huber and CH. Keysser. Castor oil as a vehicle for
`parenteral adminstation of steroid hormones. JPharm.Sci. 53: 891-5
`(1964)
`
`StrickleyI (1999)
`
`R. G. Strickley. Parenteral formulations of small molecule therapeutics
`marketed in the United States (1999) —Part 1. FDA J. Pharm. Sci