2020000760 (P.T.A.B. Oct. 22, 2020)

BIOMET 3I, LLC

Patent Trials and Appeals BoardOct 22, 2020

2020000760 (P.T.A.B. Oct. 22, 2020)

UNITED STATES PATENT AND TRADEMARK OFFICE UNITED STATES DEPARTMENT OF COMMERCE United States Patent and Trademark Office Address: COMMISSIONER FOR PATENTS P.O. Box 1450 Alexandria, Virginia 22313-1450 www.uspto.gov APPLICATION NO. FILING DATE FIRST NAMED INVENTOR ATTORNEY DOCKET NO. CONFIRMATION NO. 15/401,740 01/09/2017 Bruce Berckmans III 5394.C64US5 3509 104326 7590 10/22/2020 Schwegman Lundberg & Woessner / Zimmer P.O. Box 2938 Minneapolis, MN 55402 EXAMINER APONTE, MIRAYDA ARLENE ART UNIT PAPER NUMBER 3772 NOTIFICATION DATE DELIVERY MODE 10/22/2020 ELECTRONIC Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address(es): SLW@blackhillsip.com USPTO@slwip.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte BRUCE BERCKMANS III, ROSS W. TOWSE, and ROBERT L. MAYFIELD Appeal 2020-000760 Application 15/401,740 Technology Center 3700 Before MICHAEL L. HOELTER, MICHAEL L. WOODS, and LEE L. STEPINA, Administrative Patent Judges. STEPINA, Administrative Patent Judge. DECISION ON APPEAL STATEMENT OF THE CASE Pursuant to 35 U.S.C. § 134(a), Appellant1 appeals from the Examiner’s decision to reject claims 36–56. We have jurisdiction under 35 U.S.C. § 6(b). We affirm in part. 1 We use the word Appellant to refer to “applicant” as defined in 37 C.F.R. § 1.42. Appellant identifies BIOMET 3I, LLC as the real party in interest. Appeal Br. 3. Appeal 2020-000760 Application 15/401,740 2 CLAIMED SUBJECT MATTER Appellant’s invention relates to dental implants having discrete monocrystalline particles deposited thereon. Spec. ¶ 2. Claim 36, 44, and 52, reproduced below with emphasis added, are the only pending independent claims. 36. A dental implant, comprising: a head portion; a lowermost end opposing the head portion; and a threaded bottom portion for engaging bone between the head portion and the lowermost end, the threaded bottom portion including: a microscale roughened surface; a first nanotopography on the microscale roughened surface; and a second nanotopography in contact with a first portion of the microscale roughened surface and a first portion of the first nanotopography. 44. A dental implant, comprising: a head portion; a lowermost end opposing the head portion; and a threaded bottom portion for engaging bone between the head portion and the lowermost end, the threaded bottom portion including: a microscale roughened surface; a nanoscale roughened surface formed on the microscale roughened surface; and a plurality of discrete nanoparticles deposited on and in contact with a first portion of the microscale roughened surface and a first portion of the nanoscale roughened surface. 52. A dental implant, comprising: Appeal 2020-000760 Application 15/401,740 3 a head portion; a lowermost end opposing the head portion; and a threaded bottom portion for engaging bone between the head portion and the lowermost end, the threaded bottom portion including: a roughened surface including an array of microscale irregularities and a plurality of permanent nanostructures formed on the microscale irregularities; and a plurality of discrete nanoparticles deposited on the roughened surface, wherein a portion of the roughened surface is exposed between at least some of the discrete nanoparticles such that the exposed roughened portion between the discrete nanoparticles is for contacting bone. Appeal Br. 19, 20, 21 (Claims App.). REFERENCES The prior art relied upon by the Examiner is: Name Reference Date Dinkelacker US 2004/0153154 A1 Aug. 5, 2004 Beaty US 2005/0263491 A1 Dec. 1, 2005 Berckmans III US 8,647,118 B2 Feb. 11, 2014 Wen2 EP1449544 A1 Aug. 25, 2004 Gintaras Gintaras Juodzbalys et. al., New Acid Etched Titanium Dental Implant Surface, Stomatologija, Baltic Dental and Maxillofacial Journal, 5:101–105 (2003) 2 The Examiner refers to this reference as “Smith.” Final Act. 12. Appeal 2020-000760 Application 15/401,740 4 REJECTIONS3 I. Claims 36–56 are rejected under 35 U.S.C. § 103(a) as unpatentable over Dinkelacker and Beaty. II. Claims 41, 42, 45, and 53 are rejected under 35 U.S.C. § 103(a) as unpatentable over Dinkelacker, Beaty, and Gintaras. III. Claims 36–39, 41, and 43 are rejected on the ground of nonstatutory double-patenting over claims 1 and 7 of Berckmans III. IV. Claims 44–46 and 49 are rejected on the ground of nonstatutory double-patenting over claims 1, 8, and 9 of Berckmans III. V. Claims 52 and 53 are rejected on the ground of nonstatutory double-patenting over claim 1 of Berckmans III. OPINION Rejection I–Dinkelacker and Beaty Claims 36–51 The Examiner finds that Dinkelacker discloses many of the elements recited in independent claims 36 and 44, but does not disclose a second nanotopography in contact with a first portion of a microscale roughened surface and a first portion of a first nanotopography as recited in claim 36 or a plurality of discrete nanoparticles as recited in claim 44. Final Act. 3–4. To address these deficiencies in the teachings of Dinkelacker, the Examiner turns to Beaty. Id. at 4. Specifically, the Examiner finds Beaty discloses submicron projections and cone-like topography and “discrete fine particles 3 The Examiner withdrew a rejection of claims 52–56 as unpatentable over Dinkelacker and Wen. Ans. 3. Appeal 2020-000760 Application 15/401,740 5 [of] bone-growth enhancing material . . . entrapped on and between the small cone-like structures.” Id. (citing Beaty ¶¶ 43–44). The Examiner acknowledges that Beaty does not explicitly disclose that the fine particles have a size that creates a nanotopography, but infers that these particles must be of such a size “to be able to enter and be entangle[d] in the bigger structure of the etched surface.” Id. The Examiner reasons it would have been obvious to apply fine particles as disclosed in Beaty on the surface disclosed by Dinkelacker “in order to have a uniformed surface that includes[,] in all the topographies[,] bone-growth-enhancing materials to promote the bonding of the surface to adjacent bone through all the different structures.” Id. The Examiner determines that the result of this proposed combination of the teachings of Dinkelacker and Beaty would meet all the requirements of claims 36 and 44 because the particles from Beaty would amount to the recited second nanotopography (claim 36) and plurality of nanoparticles (claim 44). See id. Nanotopography and Nanoparticles Appellant argues that the Examiner erred in finding that the fine particles disclosed by Beaty are of a size that creates a nanotopography (or nanoparticles). Appeal Br. 12. Specifically, Appellant contends that the cone-shaped elements disclosed by Beaty have base diameters of 0.3 to 1.2 microns, and, therefore, particles that may become trapped between these elements need not be small enough to create a nanotopography. Id. Appellant further contends that Beaty is silent regarding the size or shape of the disclosed fine particles. Id. at 12–13. In response, the Examiner finds that Beaty’s disclosure of the sizes and spacing of its cone-shaped elements uses the term “about” before setting Appeal 2020-000760 Application 15/401,740 6 forth any numerical ranges, thus allowing for some variation from the stated ranges. Ans. 6. The Examiner then states: It is also applicable that when Beaty describes that the surface topography is in the submicron size range, it is also included in the term “about” values of at least 0.1 micron in such range, where taking in consideration that 0.1 microns it is also read as 100 nano, therefore it is considered to represent the nanotopography. Therefore, the etched surface of Beaty is considered to be the claimed first nanotopography. Id. The Examiner further finds: it is understood that the fine particles should be in the nano size range if at least one of the material suggested is hydroxyapatite, which it is well known in the art since many years before the priority date of the present application was even submitted, this hydroxyapatite material can be obtained in the nano size particles, in the form of monocrystalline apatite. Id. at 7 (emphasis added). Thus, the Examiner points out that one of the materials used by Beaty is hydroxyapatite, and the Examiner determines this material can be used in the form of “nano size particles.” In reply, Appellant contends that there is no reason that the “about” 0.3 to 1.2 micron range of diameters for Beaty’s cone-shaped elements (spaced apart by about 0.3 to 0.75 microns) implies that particles disposed between them are nanoparticles. Reply Br. 5. In support of this argument, Appellant asserts that, based on these size/spacing ranges, the spacing between tips of cones could be 1.275 microns. Id. Appellant further states, “[a]dditionally, the only example of a preferred particle is one that is commercially available under the registered trademark ‘Bio-Oss,” and “it appears that the Bio-Oss® is available in small granules (0.25 – 1 millimeters), which is 250 microns to 1000 microns, and large granules (1-2 Appeal 2020-000760 Application 15/401,740 7 millimeters), which is 1000 microns to 2000 microns.” Id. (citing https://dental.geistlich-na.com/en-us/professionals/bone-substitutes/bio- oss/product-range/)4; see also Beaty ¶ 46. For the reasons discussed below, a preponderance of the evidence supports the Examiner’s finding that a person of ordinary skill in the art would understand the fine particles disclosed by Beaty to include particles of a size that produces a nanotopography as recited in claim 36. Appellant’s Specification describes the effect of the pH of the solution in which the fine particles are immersed during deposition, stating that, for low pH solution, “the particles deposited on the surface are generally smaller (about 20 nanometers) and more uniform[, and at] an elevated pH (i.e., greater than 9), the size of the HA nanocrystals deposited is generally greater, ranging from about 20 nanometers to about 150 nanometers.” Spec. ¶ 45. The Specification also sets the lower limit for structure that is considered to be “microscale” at 1 micron (1000 nanometers). Id. ¶ 38. The Specification also provides an example using nanocrystalline calcium phosphate (“HA”). See id. ¶¶ 8, 40. Specifically, the Specification states, “[i]n preparing a solution of HA nanocrystals, raw HA nanocrystal material may be refined to achieve a stock solution with limited agglomeration of crystals” and “[a]n appropriate particle size distribution (volume) as indicated by the Nanotrac 150 . . . has a D10 (tenth percentile distribution) of less than 150 nanometers, a D50 (fiftieth percentile distribution) of less than 300 nanometers, and a D90 (ninetieth percentile distribution)) of less than 900 nanometers.” Id. ¶ 40. Thus, the Specification considers crystals 4 Appellant does not identify where, in the record, this website has been entered as evidence. Appeal 2020-000760 Application 15/401,740 8 having a size of 900 nanometers5 to be nanostructures, namely, “nanocrystals.” Appellant’s Specification discusses another filed patent application, PCT/US2006/010281 (hereinafter “PCT ’281”), when describing nanostructures. See Spec. ¶ 89. Specifically, the Specification states: Controllable, generally permanent nanostructures are then applied to the implant surface prior to depositing the discrete nanoparticles on the implant surface. The controllable permanent nanostructures may be applied using techniques described in PCT/US2006/010281, entitled “Controllable Nanostructuring On Micro-Structured Surfaces,” which is incorporated by reference in its entirety. The nanostructures are formed by depositing a vapor of nanostructuring material on the implant surface and forming nanostructures from the nanostructuring material. Id.6 PCT ’281 relates to a process for creating nano-sphere structures on microstructured surfaces. PCT ’281, 1:10–11. In disclosing what sizes may be considered nanostructures, PCT ’281 states: The nanostructure on the substrate can be in any physical appearance. In one embodiment, the nanostructure is a nano- sphere or a plurality of nano-spheres. The nanostructure generally has a size in the range from about 1 nm to over 1000 nm, e.g., about 5 nm, about 10 nm, about 20 nm, about 50 nm, about 80 nm, about 90 nm, about 95 nm, about 100 nm, about 200 nm, about 500 nm, about 800 nm, about 900 nm, about 1000 nm or about 1500 nm. 5 The disclosed distribution has a cut-off for the ninetieth percentile at 900 nanometers, allowing for some of the particles to have a size even greater than 900 nanometers. 6 Appellant quotes this paragraph in its entirety on page 4 of the Reply Brief. Appeal 2020-000760 Application 15/401,740 9 Id. at 8:16–21. Thus, a document that is incorporated by reference in Appellant’s Specification considers “nanostructure” to have dimensions ranging from about 1 nm to about 1500 nm. Furthermore, Dinkelacker gives an indication of what sizes may be considered “nanoscale,” stating, “[t]he depth of the lacunae of the nanostructure may be in the range of 10-500 nm, e.g., 250 nm, and the distance between the elevations may be in the range of 100 to 500 nm, e.g., 250 nm.” Dinkelacker ¶ 36; see also id. at claims 8, 24. Thus, Dinkelacker gives an example of nanostructure as large as 500 nm. In light of Appellant’s Specification, the broadest reasonable interpretation of the term “nanostructure,” and, accordingly, of “nanotopography” and “nanoparticle” in the claims, includes structures having sizes from 1 nm to at least 1000 nm. It is unnecessary for us to determine the exact upper bound of broadest reasonable interpretation of these terms because Appellant’s relevant arguments can be addressed based on the understanding that the acceptable range for nanostructure extends from 1 nm to at least 1000 nm. Beaty describes its cone-shaped elements as follows: Substantial numbers of the irregularities are substantially cone- shaped elements having base-to-peak heights in the range from about 0.3 microns to about 1.5 microns. The bases of these cone- shaped elements are substantially round with diameters in the range from about 0.3 microns to about 1.2 microns, and spaced from each other by about 0.3 microns to about 0.75 microns. Beaty ¶ 43. Beaty next describes the materials applied to the cone-shaped elements, stating “[e]xamples of such materials are bone-growth-enhancing materials such as bone minerals, bone morphogenic proteins, hydroxyapatite, whitlockite, and medicaments,” and “[t]hese materials are Appeal 2020-000760 Application 15/401,740 10 preferably applied to the etched surface in the form of fine particles which become entrapped on and between the small cone-like structures.” Id. ¶ 44 (emphasis added). Paragraphs 43 and 44 of Beaty describe the size and spacing of the “cone-like” projections in which fine particles become trapped, but these paragraphs do not explicitly describe the size or spacing of the trapped particles. As the spacing between the cone-like structures may be as small as about 300 nanometers (well within the 1–1000 nanometer range discussed above), we agree with the Examiner that a person of ordinary skill in the art would understand particles entrapped between the cone-like structures would have nano-scale dimensions, i.e., dimensions of no more than 1000 nanometers. Accordingly, we find unavailing Appellant’s argument alleging the Examiner erred in finding that the fine particles disclosed by Beaty are of a size that creates a nanotopography. Teaching Away Appellant next argues that Dinkelacker intends to avoid using sharp edges on its topography, and, therefore, “Dinkelacker teaches away from using cone-shaped projections as disclosed in Beaty.” Appeal Br. 13 (emphasis omitted). In response, the Examiner explains that Dinkelacker is relied upon to provide the first nanotopography recited in claim 36, stating: It would be obvious for a person skill in the art to combine[] the at least microscale roughened surface and the first nanotopography on the microscale roughened surface disclosed by Dinkelacker, with the nano particles that are in between of the nanotopography of Beaty, in order to promote the bonding of the implant surface to the adjacent bone through all the different structures in the surface. Appeal 2020-000760 Application 15/401,740 11 Ans. 8 (emphasis added). The Examiner rephrases this statement of the proposed combination as follows, “if Beaty’s second nanotopography can be attached in between another nanotopography, the same particles can be used in between the first nanotopography of Dinkelacker’s, in this way forming a second nanotopography including a portion contacting the first nanotopography and a portion contacting the microstructure.” Id. Thus, the Examiner proposes to include only the fine particles disclosed by Beaty in the nanostructure already disclosed by Dinkelacker.7 In other words, Appellant’s argument that Dinkelacker teaches away from incorporating Beaty’s cone-like projections is an attack on a combination of the teachings of Dinkelacker and Beaty that is not proposed by the Examiner. Accordingly, Appellant’s argument that Dinkelacker teaches away from the proposed modification does not identify Examiner error. Apparently in response to the Examiner’s reiteration that the rejection relies on Dinkelacker, not Beaty, to teach the first nanotopography recited in claim 36, Appellant argues the rounded domes of the microscale surface of Dinkelacker facilitate the cell movements into the lacunae. Reply Br. 6. According to Appellant, “one would not deposit particles onto the surface in Dinkelacker as doing so would alter the rounded domes and lacunae of the micro scale surface and the nanostructures to have projections, etc.” Id. This argument amounts to unsupported speculation as to the technical effects of the addition of the fine particles disclosed by Beaty. Appellant provides no persuasive technical reasoning and no evidence as to why the addition of these particles, which Beaty considers to be beneficial, would not 7 Appellant makes no argument that this combination is beyond the level of ordinary skill in the art. Appeal 2020-000760 Application 15/401,740 12 provide the same type of benefit when incorporated in the first nanotopography of Dinkelacker. Nor does Appellant provide such evidence that the addition of these particles would be detrimental. Requirement to be “in contact with” Appellant next argues “Appellant[’s] claims require that the nanoparticles are deposited onto both a portion of the microscale portion and the first nanotopography,” and the Examiner’s proposed combination of the teachings of Dinkelacker and Beaty fails to meet this requirement. Appeal Br. 13. In response, the Examiner states that describing that the second nanotopography is in contact with a portion of the microscale roughened surface, and another portion is in contact with the first nanotopography, indicates that not all of the threaded bottom portion includes all three layers as argued. Some portion of the threaded bottom portion have all three layers, and other portion only has two, e.g. the microscale roughened surface and the second nanotopography layers. Therefore, for purposes of analysis, the Office is concentrating on the three “layers” portion. In other words, by the second nanotopography being on the first nanotopography, and due to the first nanotopography roughness is incorporated onto the microscale roughened surface, not by adding a material layer, but by creating a second roughness on top of the initial surface, the second nanotopography is in contact with the first nanotopography, and it is also in contact with the surface having the microstructure. Ans. 5. Thus, the Examiner finds that once the second nanotopography (from Beaty) is added to the first nanotopography (from Dinkelacker), the second nanotopography will automatically be in contact with the microscale roughened surface. Appeal 2020-000760 Application 15/401,740 13 Appellant has the better argument because the broadest reasonable interpretation of claims 36 and 44 requires two distinct surfaces to contact the second nanotopography (or nanoparticles). For example, claim 36 recites, in part “a second nanotopography in contact with a first portion of the microscale roughened surface and a first portion of the first nanotopography.” Appeal Br. 19 (Claims App.) (emphasis added). By using the word “and” between reciting contact with the first portion of the microscale roughened surface and contact with the first portion of the first nanotopography, claim 36 implies that these two surfaces are not the same surface. Furthermore, the Examiner’s reading of claim 36 renders superfluous the recitation in claim 36 that the second nanotopography is “in contact with a first portion of the microscale roughened surface.” See Stumbo v. Eastman Outdoors, Inc., 508 F.3d 1358, 1362 (Fed. Cir. 2007) (denouncing claim constructions which render phrases in claims superfluous). This is so because, according to the Examiner, mere contact with the first portion of the first nanotopography also qualifies as contact with a first portion of the microscale roughened surface. The Examiner’s unreasonably broad interpretation of claim 36 led to the unsupported conclusion that adding the fine particles disclosed by Beaty to the surfaces disclosed by Dinkelacker would meet all the requirements of claim 36. Accordingly, we do not sustain the rejection of claim 36, and claims 37–43 depending therefrom, as unpatentable over Dinkelacker and Beaty. For substantially similar reasons, we do not sustain the rejection of claim 44, and claims 45–51, depending therefrom, as unpatentable over these references. Appeal 2020-000760 Application 15/401,740 14 Claims 52–56 Unlike claims 36 and 44, independent claim 52 does not recite a second nanotopography (or a plurality of discrete nanoparticles) in contact with two other distinct surfaces. See Appeal Br. 21 (Claims App.). Thus, Appellant’s argument regarding this claim limitation does not apply to claim 52. Appellant makes no argument in support of the patentability of claims 52–56 aside from the arguments discussed above. See Appeal Br. 10–18. Accordingly, as none of those arguments apprises us of Examiner error with respect to the rejection of claim 52, we sustain the rejection of claims 52–56 as unpatentable over Dinkelacker and Beaty. Rejection II–Dinkelacker, Beaty, and Gintaras In addition to rejecting claims 41, 42, 45, and 53 as unpatentable over Dinkelacker and Beaty, the Examiner rejects these claims based on a combination of Dinkelacker, Beaty, and Gintaras. See Final Act. 11–12. The Examiner’s use of the disclosure in Gintaras does not remedy the deficiency in Rejection I discussed above. Appellant makes no separate arguments for the patentability of claim 53. See Appeal Br. 10–18. We sustain Rejection II with respect to claim 53, but do not sustain this rejection with respect to claims 41, 42, and 45. Rejections III–V Obviousness Double-Patenting Appellant does not traverse Rejections III–V. See Appeal Br. 7–18. Accordingly, we summarily sustain these rejections. CONCLUSION The Examiner’s rejections are affirmed in part. Appeal 2020-000760 Application 15/401,740 15 DECISION SUMMARY Claims Rejected 35 U.S.C. § Basis Affirmed Reversed 36–56 103(a) Dinkelacker, Beaty 52–56 36–51 41, 42, 45, 53 103(a) Dinkelacker, Beaty, Gintaras 53 41, 42, 45 36–39, 41, 43 Nonstatutory Double Patenting 36–39, 41, 43 44–46, 49 Nonstatutory Double Patenting 44–46, 49 52, 53 Nonstatutory Double Patenting 52, 53 Overall Outcome 36–39, 41, 43–46, 49, 52–56 40, 42, 47, 48, 50, 51, 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