10030417 (B.P.A.I. Jan. 13, 2012)

Ex Parte Muller et al

Board of Patent Appeals and InterferencesJan 13, 2012

10030417 (B.P.A.I. Jan. 13, 2012)

UNITED STATES PATENT AND TRADEMARK OFFICE __________ BEFORE THE BOARD OF PATENT APPEALS AND INTERFERENCES __________ Ex parte RAINER H. MULLER, KARSTEN KRAUSE, and KARSTEN MADER __________ Appeal 2011-007441 Application 10/030,417 Technology Center 1600 __________ Before DONALD E. ADAMS, ERIC GRIMES, and LORA M. GREEN, Administrative Patent Judges. GRIMES, Administrative Patent Judge. DECISION ON APPEAL This is an appeal under 35 U.S.C. § 134 involving claims relating to superfine micro- and nanoparticles. The Examiner has rejected the claims as obvious. We have jurisdiction under 35 U.S.C. § 6(b). We affirm-in-part. STATEMENT OF THE CASE Claims 1-17, 20, 24-29, 31-34, and 38-47 are on appeal. Claims 1 and 27 are representative and read as follows: Appeal 2011-007441 Application 10/030,417 2 1. Process for the gentle preparation of superfine micro and nanoparticles having a particle size, as average diameter of the number distribution, of 5.6 μm or less, the method comprising: subjecting a matrix material comprising solid particles to a high pressure homogenizing process in a piston-gap homogenizer in an anhydrous or water-reduced dispersion medium containing less than 50 wt.% of water in which the solid particles are suspended and at temperatures of 20°C or less, which leads to a gentle particle size reduction with minimization of the impairment of the chemical stability of the homogenized material, to form superfine micro- and nanoparticles. 27. Superfine micro- or nanoparticle dispersions having a particle size, as average diameter of the number distribution, of 5.6 μm or less, prepared according to a process comprising: subjecting a matrix material to a high-pressure homogenizing process in a piston-gap homogenizer in an anhydrous or water-reduced medium containing less than 50 wt.% of water and/or at low temperatures of 20°C or less, which leads to a gentle particle size reduction with minimization of the impairment of the chemical stability of the homogenized material and forms a dispersion comprising the superfine micro- or nanoparticles. The Examiner has rejected claims all of the claims on appeal under 35 U.S.C. § 103(a) as being obvious in view of Desai1 and Muller.2 The Examiner finds that Desai discloses the “preparation of microparticles or nanoparticles of water insoluble drugs,” where the particles are less than 200 nm in size (Answer 3). The Examiner finds that Desai discloses that the “drug is dissolved in an organic solvent…, a protein such as albumin is added to stabilize the nanoparticles … and the mixture is homogenized under high-pressure homogenization” (id.). The Examiner finds that Desai 1 Desai et al., WO 98/14174, Apr. 9 1998 2 Muller et al., US 5,858,410, Jan. 12, 1999 Appeal 2011-007441 Application 10/030,417 3 discloses a “water-reduced dispersion medium … wherein the taxol is dispersed in ethanol which is free of water” (id. at 4). The Examiner finds that Desai does not teach a piston-gap homogenizer, but Muller discloses “nanoparticles of drugs … made by dispersing solid therapeutically active drugs in a solvent and subjecting the dispersion to high-pressure homogenization in a piston-gap homogenizer … at room temperature” (id.). The Examiner concludes that “it would have been obvious to one of ordinary skill in the art to make paclitaxel nanoparticles according to the methods disclosed by Desai and homogenize it in a piston-gap homogenizer because Muller teaches that … by conversion of the microparticles into nanoparticles by means of a high-energy process … solubility increases greatly” (id. at 5). Appellants contend that the process of claim 1 requires piston-gap homogenization “in an anhydrous or water-reduced dispersion medium containing less than 50 wt.% of water” and “both Muller and Desai require the use of water in amounts greater than the claimed less than 50 wt.% as the dispersion medium” (Appeal Br. 5). We agree with Appellants that the Examiner has not adequately shown that the cited references would have made obvious the process claims on appeal. Desai discloses methods for the preparation of water insoluble pharmacologically active agents which comprise subjecting a mixture comprising: an organic phase containing said pharmacologically active agent dispersed therein, and aqueous medium containing biocompatible polymer wherein said mixture contains substantially no surfactants, in a high pressure homogenizer at a pressure in the range of about 3,000 up to 30,000 psi. Appeal 2011-007441 Application 10/030,417 4 (Desai 14: 10-21.) All of Desai’s working examples include homogenization of compositions comprising greater than 50% water (id. at 33-42). Although the Examiner cites Desai’s Example 4 as disclosing a dispersion with reduced water or no water (Answer 6), that example actually states: “30 mg Taxol is dissolved in 0.55 ml chloroform and 0.05 ml ethanol. The solution is added to 29.4 ml of Tween 80 solution (1% w/v) , which is presaturated with 1% chloroform. The mixture is homogenized.” (Id. at 35: 21-24.) A 1% Tween 80 solution that includes 1% chloroform is 98% water and thus, Desai’s Example 4 describes homogenization of a composition that contains greater than 50% water. The Examiner also argues that “Muller teaches literally that ‘since the lowest possible surfactant content is desirable … surfactant-free nanosuspensions have also been prepared’ (col. 8, lines 27+)” (Answer 6). We do not agree that this disclosure describes the water-reduced medium required by the process claims on appeal. Muller discloses “a drug carrier comprising particles of at least one pure active compound which is insoluble, … sparingly soluble or moderately soluble in water, aqueous media and/or organic solvents” (Muller, abstract). Muller discloses that “[s]uspensions were prepared with a drug, which was ground in an air jet, in an aqueous surfactant solution.… The suspension was homogenized in a piston-gap homogenizer.” (Id. at col. 5, ll. 27-31.) All of Muller’s examples describe compositions for homogenization that contain greater than 50% water (id. at cols. 11-18). The Examiner cites Muller’s reference to its Example 13 as showing surfactant-free compositions, but Appeal 2011-007441 Application 10/030,417 5 that example describes a surfactant-free composition that nevertheless contains greater than 50% water. Thus, neither Desai nor Muller discloses or suggests the homogenization of compositions containing less than 50 wt.% water, and the Examiner has not adequately explained why that limitation would have been obvious to one of ordinary skill in the art. The rejection of independent claim 1, and dependent claims 2-17, 20, 24-26, 28, 29, 31-34, and 38-44 is reversed. Independent claims 46 and 47 are also directed to processes that include dispersing solid particles “in an anhydrous or water-reduced dispersion medium containing less than 50 wt.% of water form a pre- suspension; and subjecting the pre-suspension to a high-pressure homogenizing process in a piston-gap homogenizer to reduce the particle size.” Thus, the rejection of claims 46 and 47 is also reversed for the reasons discussed above. The Examiner has also rejected independent claim 27 as being obvious in view of Desai and Muller, based on the disclosures discussed above. Claim 27 is directed to a product that is defined, in part, by the method by which it is made. Appellants argue that claim 27 is not obvious over Desai and Muller for the same reasons discussed above for the process claims (Appeal Br. 12). Appellants also argue that “[s]ince the claimed particles are produced using the gentle homogenization, without the high shock waves of cavitation, less damage to the homogenized material is present compared to the particles produced using cavitation according to Muller” (id.). Appeal 2011-007441 Application 10/030,417 6 Appellants’ arguments are not persuasive. Claim 27 recites “high- pressure homogenizing process in a piston-gap homogenizer in an anhydrous or water-reduced medium containing less than 50 wt.% of water and/or at low temperatures of 20°C or less” (claim 27, emphasis added). The claim thus reads on carrying out the homogenization either in a water-reduced medium or at a temperature of 20°C or less. Since Muller discloses nanoparticle dispersions having an average particle size of 10 nm to 1,000 nm that were prepared by subjecting a powdered drug compound (i.e., a matrix material) to high-pressure homogenization in a piston-gap homogenizer at room temperature, which would reasonably include 20°C or less, we conclude that claim 27 is anticipated by Muller. Thus, we affirm the rejection of claim 27 as being obvious in view of Desai and Muller since “[i]t is well settled that ‘anticipation is the epitome of obviousness.’” In re McDaniel, 293 F.3d 1379, 1385 (Fed. Cir. 2002). Claim 45 falls with claim 27 (Appeal Br. 5, 12; 37 C.F.R. § 41.37(c)(1)(vii)). SUMMARY We reverse the rejection of claims 1-17, 20, 24-29, 31-34, and 38-47 under 35 U.S.C. § 103(a). However, we affirm the rejection of claims 27 and 45 under 35 U.S.C. § 103(a). Appeal 2011-007441 Application 10/030,417 7 TIME PERIOD FOR RESPONSE No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. § 1.136(a). AFFIRMED-IN-PART lp