13145759 (P.T.A.B. Jun. 27, 2018)

Ex Parte Stobrawa et al

Patent Trial and Appeal BoardJun 27, 2018

13145759 (P.T.A.B. Jun. 27, 2018)

UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 13/145,759 10/05/2011 24113 7590 06/28/2018 PATTERSON THUENTE PEDERSEN, P.A. 80 SOUTH 8TH STREET 4800 IDS CENTER MINNEAPOLIS, MN 55402-2100 FIRST NAMED INVENTOR Gregor Stobrawa 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 ATTORNEY DOCKET NO. CONFIRMATION NO. 3081.322WOUS 7782 EXAMINER JENNESS, NATHAN JAY ART UNIT PAPER NUMBER 3762 MAILDATE DELIVERY MODE 06/28/2018 PAPER 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. PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte GREGOR STOBRA WA, MARK BISCHOFF and MICHAEL BERGT Appeal 2016-004596 Application 13/145,759 Technology Center 3700 Before STEVEN D.A. McCARTHY, MICHELLE R. OSINSKI and PAUL J. KORNICZKY, Administrative Patent Judges. McCARTHY, Administrative Patent Judge. DECISION ON APPEAL 1 STATEMENT OF THE CASE 2 The Appellants 1 appeal under 35 U.S.C. Â§ 134(a) from the Examiner's 3 decision finally rejecting claims 20-50. A hearing was held in this appeal 4 on April 17, 2018. We have jurisdiction under 35 U.S.C. Â§ 6(b ). The Appellants identify the real party in interest as Carl Zeiss Meditec AG. (See "Appeal Brief under 37 C.F.R. Â§ 41.37," dated Sept. 3, 2015, at 2). Appeal 2016-004596 Application 13/145,759 1 We sustain the rejection of claims 25-50 under 35 U.S.C. Â§ 101 as 2 ineligible for patent protection. 2 3 We do not sustain the rejection of claims 20-24 under 35 U.S.C. 4 Â§ 101 as ineligible for patent protection; or the rejection of those claims 5 under pre-AIA 35 U.S.C. Â§ 103(a) as being unpatentable over Rathjen (US 6 200710173793 Al, publ. July 26, 2007); Cox (US 2004/0054358 Al, publ. 7 Mar. 18, 2004 ); and Rajan (US 5,891, 131, issued Apr. 6, 1999). 8 9 THE CLAIMED SUBJECT MATTER 10 The appealed claims are directed to the field of refractive surgery, the 11 aim of which is "to selectively alter the cornea so as to influence" the 12 refraction (that is, bending), of light entering the eye, thereby improving 13 focus. (Substitute Specification, dated July 21, 2011 ("Specification" or 14 "Spec."), at 2, 1. 23 - 3, 1. 1 ). According to the Specification: 15 In order now to carry out a correction of defective v1s10n, 16 material is removed from a region within the cornea 5 by means 17 of ... pulsed laser radiation by cutting tissue layers[,] thus 18 isolating the material[,] and then mak[ing] it possible for the 19 material to be removed. The removal of material effects a change 2 The Examiner also provisionally rejected claims 25-50 in the Final Office Action under 35 U.S.C. Â§ 101 as claiming the same invention as that of claims 24--38 and 49---60 of co-pending Application 13/145,761. (Final Office Action, mailed January 8, 2015, at 6). Application 13/145,761 has since issued as Stobrawa (US 9,050,172 B2, issued June 9, 2015). The claims of Stobrawa, as issued, are not identical to the claims of Application 13/145,761, as those claims existed as of the date of the Final Office Action. In the Answer, the Examiner "note[ d] the statutory double patenting rejection [was] no longer valid; however, there remains potential for an obviousness-type double patenting rejection." (Examiner's Answer, mailed January 28, 2016, at 6). We deem the double patenting rejection under Â§ 101 withdrawn. We will not address the rejection further in this opinion. 2 Appeal 2016-004596 Application 13/145,759 1 in the volume of the cornea which results in a change in the 2 optical imaging effect of the cornea 5, which change is calculated 3 exactly such that the previously determined defective vision thus 4 is/becomes corrected as much as possible. To isolate the volume 5 to be removed, the focus of the laser radiation 2 is directed 6 towards target points in the cornea 5, generally in an area which 7 is located beneath the epithelium and the Bowman's membrane 8 and above the De[s]cemets's membrane and the endothelium. 9 For this purpose the treatment apparatus 1 has a mechanism for 10 shifting the position of the focus of the laser radiation 2 in the 11 cornea 5. 12 (Spec. 24, 1. 22 - 25, 1. 9 & Fig. 1 ). Because this technique requires a high 13 degree of accuracy, the cornea typically is pressed against a curved contact 14 glass to immobilize the cornea during surgery. (See Spec. 6, 11. 6-9; see also 15 id. 36, 11. 12-19). 16 A control apparatus 12, depicted schematically in Figure 4 of the 1 7 underlying application, controls, among other functions, the position and 18 movement of the focal point of the laser radiation within and across the 19 cornea. (Spec. 26, 11. 15-17). "The control apparatus 12 operates according 20 to predetermined control data which predetermine the target points for 21 shifting the focus" of the laser radiation. (Spec. 27, 11. 1 & 2). The control 22 data, in tum, derives from the geometry or, equivalently, the refractive 23 power, of the cornea before surgery; and from the desired geometry or 24 refractive power of the cornea after surgery. (See generally Spec. 27, 1. 10 - 25 33, 1. 5 & Fig. 10). The Specification also teaches that the control data must 26 be corrected or adjusted to account for the distortion of the cornea when 27 pressed against the contact surface during the surgical procedure. (See Spec. 28 36, 1. 12 - 37, 1. 8, citing Muhlhoff (US 2007 /0293851 Al, publ. Dec. 20, 29 2007)). 3 Appeal 2016-004596 Application 13/145,759 1 Claims 20, 22, 24--26, 31, 32, 38 and 39 are independent. Claims 20, 2 25 and 26 recite: 3 20. A method for generating control data that control a 4 laser for surgical correction of defective vision of an eye of a 5 patient, wherein prior to application of the laser to a cornea is 6 brought from an undeformed state to a deformed state by 7 pressing a front surface of the cornea against a contact surface; 8 the method comprising: 9 a) predetermining a correction surface by application 10 of a control unit, which correction surface relates to the cornea 11 in the undeformed state and is to be produced for correction of 12 defective vision as a cut surface of the cornea; 13 b) selecting several points lying in the correction 14 surface or in an approximation surface derived therefrom by 15 application of the control unit, the several points being a subset 16 of points lying in the correction surface or the approximation 17 surface derived therefrom; 18 c) generating transformed points by transforming by 19 application of the control unit, coordinates of the selected points 20 into coordinates of the same points for the cornea in the deformed 21 state to compensate for the deformed state of the cornea during 22 operation of the laser; 23 d) generating an interpolation surface by interpolating 24 between the transformed points by application of the control unit; 25 and 26 e) selecting target points lying on the interpolation 27 surface by application of the control unit; and 28 29 data. t) using the target points for generating the control 30 25. A device, the device including a control unit that 31 generates control data, the control data controlling a laser for 32 surgical correction of defective vision of an eye of a patient, 33 wherein: 4 Appeal 2016-004596 Application 13/145,759 1 the control data are adapted to control the laser 2 which cuts cornea tissue by irradiating laser radiation into the 3 cornea of the eye and wherein the control unit is operably 4 coupled to the laser, 5 the control unit generates the control data such that 6 the laser, during operation according to the control data, emits 7 the laser radiation such that a volume in the cornea is isolated, 8 the removal of which volume from the cornea effects a desired 9 correction of the defective vision, and 10 to determine the control data, the control unit 11 calculates a radius of curvature Rev* of the cornea reduced by 12 the volume further wherein 13 the radius of curvature Rev* is locally varying and 14 satisfies the following equation: 15 Rev*(r,cp) = 1 I ( (1/ Rev(r,cp)) + BeoR(r,cp)/ (nc-1)) + F, 16 wherein Rev(r,