13124426 - (D) (P.T.A.B. Jun. 18, 2019)

Ex Parte Evers et al

Patent Trials and Appeals BoardJun 18, 2019

13124426 - (D) (P.T.A.B. Jun. 18, 2019)

UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE FIRST NAMED INVENTOR 13/124,426 06/28/2011 Toon Hendrik Evers 145572 7590 06/20/2019 MCCOY RUSSELL LLP 806 SW BROADWAY SUITE 600 PORTLAND, OR 97205-3335 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. DTS l 83 l 6PCTUS 6340 EXAMINER BROWN, MELANIE YU ART UNIT PAPER NUMBER 1641 NOTIFICATION DATE DELIVERY MODE 06/20/2019 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): usptomail@mccrus.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte TOON HENDRIK EVERS and MIKHAIL MIKHAYLOVICH OVSYANK0 1 Appeal2017-008280 Application 13/124,426 Technology Center 1600 Before JOHN G. NEW, TA WEN CHANG, and DAVID COTTA, Administrative Patent Judges. NEW, Administrative Patent Judge. DECISION ON APPEAL 1 Appellants identify Koninklijke Philips Electronics, N.V. as the real party- in-interest. App. Br. 1. Appeal2017-008280 Application 13/124,428 SUMMARY Appellants file this appeal under 35 U.S.C. Â§ I34(a) from the Examiner's Final Rejection of claims 2-7, 9-11, 13-20 as unpatentable under 35 U.S.C. Â§ I03(a) as being obvious over the combination of Nieuwenhuis et al. (WO 2007/129284 Al, November 15, 2007) ("Nieuwenhuis") and Marioni (US 2005/0237139 Al, October 27, 2005) ("Marioni"). Claim 14 also stands rejected as unpatentable under 35 U.S.C. Â§ I03(a) as being obvious over the combination ofNieuwenhuis, Marioni, and Immink et al. (US 2010/0289483 Al, November 18, 2010) ("Immink"). We have jurisdiction under 35 U.S.C. Â§ 6(b). We AFFIRM. NATURE OF THE CLAIMED INVENTION Appellants' invention is directed to a method for controlling the movement of magnetic or magnetizable objects in a biosensor cartridge. Abstract. REPRESENTATIVE CLAIM Claim 2 is representative of the claims on appeal and recites: 2. A biosensor comprising: (a) a biosensor cartridge with a laterally extending sensor surface, (b) at least two electromagnets arranged above and below the sensor surface, each of the at least two electromagnets configured to generate magnetic 2 Appeal2017-008280 Application 13/124,428 fields with a field gradient substantially perpendicular to the sensor surface, ( c) a driving circuit configured to: apply alternating actuation pulses to the at least two electromagnets to generate magnetic fields which urge alternatingly a plurality of magnetic objects substantially perpendicular to the sensor surface alternately away and toward the sensor surface, wherein pulse lengths of the alternating actuation pulses are adjusted such that a lateral movement of the plurality of magnetic objects along the laterally extending sensor surface is substantially avoided, and deliver a detection pulse to the at least two electromagnets which generate magnetic fields that avoid movement of the plurality of magnetic objects in a direction of gravity. App. Br. 21. ISSUES AND ANALYSES We adopt the Examiner's findings, reasoning, and conclusion that the claims are prima facie obvious over the combined cited prior art. We address the arguments raised by Appellants below. A. Issue Appellants Assert that Nieuwenhuis and Marioni are not Analogous Art Appellants argue that the Examiner erred in combining the references because Nieuwenhuis and Marioni are not analogous art. App. Br. 11. 3 Appeal2017-008280 Application 13/124,428 Analysis The Examine finds that Nieuwenhuis teaches magnetoresistive sensors designed such that magnetic fields can be generated by magnetic field generators such as coils, electromagnets, etc. Ans. 12 (citing, e.g., Nieuwenhuis 3). The Examiner finds that Marioni relates to magnetic actuators for actuating magnetic fields using an actuator drive circuit. Id. The Examiner finds that the magnetic actuator taught by Marioni includes a magnetic field-actuated material and a plurality of interconnected electrically conducting coils, configured to produce a magnetic field that is substantially oriented in one of a plurality of selectable discrete directions. Id. The Examiner finds that Marioni teaches that the actuator drive circuit is connected to the coils in a circuit configuration that reverses the direction of electrical current flow through at least one of the coils, to reorient the magnetic field from a first selected direction to a second selected direction of a plurality of selectable discrete directions. Id. The Examiner concludes that it would have been obvious to a person of ordinary skill in the art to have included the drive circuit of Marioni to the magnetic field-generating coils of the biosensor taught by Nieuwenhuis, as a known means of controlling the orientation of the magnetic field-generating coils. Ans. 12. The Examiner also reasons that Nieuwenhuis and Marioni are analogous art because they are both reasonably pertinent to Appellants' field of endeavor: the Examiner finds that both references relate to actuation of magnetic fields. Id. at 13. Appellants argue that Marioni is directed to ferromagnetic shape memory alloy ("FSMA")-based magnetic actuators, whereas Nieuwenhuis is 4 Appeal2017-008280 Application 13/124,428 related to biosensors and methods of operating the same. App. Br. 11. Appellants contend that the Examiner has made no prima facie showing why one would modify a biosensor based on teachings from the FMSA mechanical actuator arts, much less what one would hope to gain by such a combination. Id. We are not persuaded by Appellants' argument. Two separate tests define the scope of analogous prior art: (1) whether the art is from the same field of endeavor, regardless of the problem addressed and, (2) if the reference is not within the field of the inventor's endeavor, whether the reference still is reasonably pertinent to the particular problem with which the inventor is involved. In re Bigio, 381 F.3d 1320, 1325 (Fed. Cir. 2004). Appellants' invention is directed to: A method for controlling the movement of magnetic or magnetizable objects in a biosensor cartridge. The method comprises the step of providing a biosensor cartridge with a laterally extending sensor surface and at least a magnetic field generating means for generating a magnetic field with a field gradient substantially perpendicular to the sensor surface. The magnetic field generating means are alternatingly actuated such that the generated magnetic field directs alternatingly the magnetic or magnetizable objects substantially perpendicular to the sensor surface away and toward the sensor surface, wherein pulse lengths of the alternating actuation are adjusted such that a lateral movement of magnetizable objects along the laterally extending sensor surface is substantially avoided. Abstr. (internal references omitted). Nieuwenhuis is directed to: [S]ystems and methods for magnetic actuation of particles from and toward the surface of a sensor with a magneto-resistive element. The orientation of magnetic fields and arrangement of 5 Appeal2017-008280 Application 13/124,428 magnetic field generating means with respect to the sensor maintains or restores the sensitivity of the magneto -resistive element after actuation. Nieuwenhuis Abstr. More specifically, Nieuwenhuis teaches that: In one aspect the present invention relates to a system for measuring the presence of at least one magnetic particle at the surface of a sensor comprising a sensor with a magnetoresistive element and comprising one or more magnetic field generators arranged around the sensor at a distance arranged to generate a magnetic field at the sensor, characterized in that one or more magnetic field generators generate a field with a component in the plane of the sensor. Nieuwenhuis 2. It is thus evident to us that both Appellants' claimed invention and Nieuwenhuis are directed to the same field of endeavor, i.e., biosensor systems that use generated magnetic fields to move charged particles towards or away from the sensor surface. We therefore conclude that both Nieuwenhuis and Appellants' claimed invention are within the same field of endeavor and satisfy the first requirement of Bigio. With respect to Marioni, the reference is directed to: "magnetic actuators, and more particularly ... methods for generating actuation with magnetic field-actuated materials." Marioni ,r 3. Marioni teaches that its invention is: A magnetic actuator [ ... ] including a magnetic field-actuated material and a plurality of interconnected electrically conducting coils, each coil including a number of wire turns arranged relative to at least one other coil to produce at the magnetic field- actuated material, by superposition, a magnetic field that is substantially oriented in one of a plurality of selectable discrete directions. 6 Appeal2017-008280 Application 13/124,428 Marioni Abstr. ( emphasis added). Appellants' claim 2 recites, in relevant part: "a driving circuit configured to: apply alternating actuation pulses to the at least two electromagnets to generate magnetic fields which urge alternatingly a plurality of magnetic objects substantially perpendicular to the sensor surface alternately away and toward the sensor surface." Claim 2 thus requires generating magnetic fields of varying polarities and strengths, i.e., "in one of a plurality of selectable discrete directions." We agree with the Examiner that the teachings of Marioni relating to magnetic actuators to generate magnetic fields of various orientations is reasonably pertinent to the particular problem with which the inventor is involved, i.e., generating magnetic fields with polarities "in one of a plurality of selectable discrete directions," and therefore meets the second test of Bigio for establishing analogous art. We do not, therefore, find Appellants' argument persuasive with respect to this issue. B. The Rejection of Claims 2, 3, 5, and 6 under 35 U.S.C. Â§ 103(a) Issue Appellants argue that the references cited by the Examiner fail to teach or suggest: (1) at least two electromagnets which urge alternately a plurality of magnetic objects substantially perpendicular to the sensor surface alternately away and toward the sensor surface, in which the pulse lengths are adjusted such that lateral movement of the plurality of magnetic objects along the laterally extending sensor surface is substantially avoided; and (2) delivering a detection pulse to the at least two electromagnets which generate magnetic fields that avoid movement of the plurality of magnetic objects in a direction of gravity. App. Br. 12. 7 Appeal2017-008280 Application 13/124,428 Analysis The Examiner finds that Nieuwenhuis teaches sensor systems for actuating particles using magnetoresistive sensors, comprising a laterally extending sensor surface which is equivalent to Appellants' claimed biosensor cartridge. Final Act. 2-3 (citing Nieuwenhuis 4, 11. 1-10). The Examiner finds that Nieuwenhuis teaches the device comprises at least two electromagnets arranged above and below the sensor surface, each of which generates a magnetic field with a field gradient substantially perpendicular to the sensor surface. Id. at 3 (citing Nieuwenhuis 12, 11. 14--19, 11, 11. 22- 24 ). The Examiner further finds that Nieuwenhuis teaches that the sensor system provides magnetic field gradients orthogonal to the sensor surface, or, alternatively, generates actuation magnetic fields which are used to pull non-selectively bound magnetic particles away from the sensor surface and/or to pull magnetic particles towards the sensor surface to speed up the binding process. Id. (citing Nieuwenhuis 12, 11. 20-32; 15, 11. 14--19; pg. 13, 11. 13-28). The Examiner finds that Nieuwenhuis also teaches the sensor surface is modified with probes attached to the measurement surface. Id. (citing Nieuwenhuis 6, 11. 30-35). The Examiner finds, however, that Nieuwenhuis fails to teach or suggest a driving circuit configured to apply alternating actuation pulses to the at least two electromagnets to generate magnetic fields which can alternatingly move a plurality of magnetic objects substantially perpendicular to the sensor surface away from, and toward, the sensor surface. Final Act. 3. Nor, the Examiner finds, does Nieuwenhuis teach adjusting pulse length of the alternating actuation pulses such that lateral movement of the magnetic objects along the sensor surface is avoided, and 8 Appeal2017-008280 Application 13/124,428 delivering a detection pulse to the at least two electromagnets, which generate magnetic fields that avoid the movement of the plurality of magnetic objects in a direction of gravity. Id. The Examiner finds that Marioni teaches a driving circuit for a magnetic actuator that can be implemented as a light-weight and compact actuator, requiring only a comparatively small power source. Final Act. 3--4 ( citing Marioni ,r 11 ). The Examiner finds that Marioni teaches that the configuration of its magnetic actuator enables a method for controlling a magnetic field-actuated material in which an electrical current flow is provided to a plurality of interconnected electrically conducting coils to produce, by superposition, a magnetic field that is substantially oriented in one of a plurality of selectable discrete directions. Id. at 4. The Examiner finds that reversing the flow of electrical current through at least one of the coils reorients the magnetic field from a first selected direction to a second selected direction of the plurality of selectable discrete field directions. Id. The Examiner concludes that it would have been obvious to a person of ordinary skill in the art to modify the invention ofNieuwenhuis to incorporate a driving circuit, as taught by Marioni, for actuating the magnetic particles and delivering a detection pulse. Final Act. 5. The Examiner concludes that such a combination would be advantageous, in that Marioni's driving circuit overcomes the limitations of conventional magnetic actuation systems by providing a magnetic actuator that can be implemented as a light-weight and compact actuator, requiring only a comparatively small power source. Id. With respect to the detection pulse recited in the claims, the Examiner finds that Nieuwenhuis expressly teaches a detection step, and Marioni 9 Appeal2017-008280 Application 13/124,428 teaches that the magnetic actuator has a circuit which is configured to deliver a pulse. Final Act. 5 ( citing Marioni ,r 15). The Examiner therefore concludes that it would have been obvious to a person of ordinary skill in the art to modify the device ofNieuwenhuis with a driving circuit, as taught by Marioni, to deliver a detection pulse to the sensor surface such that the movement of the magnetic particles objects to gravitational direction is avoided, and also for directing the magnetic particles away from the sensor surface such that the lateral movement of the plurality of magnetic objects along the laterally extending sensor surface is substantially avoided. Id. at 5-6, 7. Appellants argue that, contrary to the recitations of the claims, Nieuwenhuis teaches that magnetic fields should be applied at an angle, with a component parallel to the sensor surface, which would inherently move the magnetic objects laterally along the magnetic surface. App. Br. 11. Appellants contend that the failure to apply an angled magnetic field with a component laterally along the sensor surface results in the problem illustrated in Fig. 8 of Nieuwenhuis in which a large reset component is needed. Id. Appellants argue further that Nieuwenhuis neither teaches nor suggests a detection pulse, as recited in claim 2, much less a detection pulse that generates magnetic fields that avoid movement of the magnetic objects in a direction of gravity. App. Br. 11. According to Appellants, Nieuwenhuis teaches actuation pulses and reset pulses, but does not teach the required detection process. Id. Appellants assert that Marioni does not cure the alleged shortcomings ofNieuwenhuis, but rather teaches how to apply magnetic pulses to change 10 Appeal2017-008280 Application 13/124,428 the phase or crystalline structure of a fixed FSMA or magnetorestrictive material in order to cause it to elongate and exert a force. App. Br. 12. Appellants contend that Marioni neither teaches nor suggests applying pulses which avoid lateral movement of magnetic objects, and that Marioni, like Nieuwenhuis, does not teach a detection pulse that avoids movement of the magnetic objects in a direction of gravity. Id. We are not persuaded by Appellants' arguments. Nieuwenhuis teaches: The present invention relates to the use and positioning of magnetic field generators such as permanent magnets, current carrying wires, or electromagnets in combination with magnetoresistive sensors such as GMR sensors. Herein actuation magnetic field generators such as magnets are used to manipulate particles towards and from a sensor .... A magnetic field from such a magnetic field generator can be either oriented mainly perpendicular to the sensor swface or under a first angle (alpha) and/or under a second angle (beta) (see Figs. 1 and 2). A reset magnetic field generator such as a magnet or a coil or a wire is used to restore the sensitivity of a sensor that has been distorted, by generating a well-defined magnetization profile in the sensor material. Nieuwenhuis 9 (emphasis added). Nieuwenhuis also teaches: "A second aspect of the invention relates to a sensor system with actuation fields orthogonal to the sensor surface as known from the prior art .... " Nieuwenhuis 12; see also id. at 10 (explaining that "[t]ypically actuation of particles has been performed with a force perpendicular to the surface of a sensor ( to either pull the particles towards the sensor surface or to pull them away from the sensor surface,)" even though "it is also possible to apply a lateral magnetic force"). Nieuwenhuis also adds that: "an additional magnetic field (reset field) is applied to restore the disoriented magnetization 11 Appeal2017-008280 Application 13/124,428 of the sensor." Id. at 12; see also id. at 15 (Example 2 in which actuation field is applied by coil which generates field perpendicular to sensor surface before reset pulse is applied). Furthermore, Nieuwenhuis teaches: Accordingly, another aspect of the present invention is a sensor device with two magnetic field generators such as magnets, as depicted in Fig. 5, wherein one magnetic field generator or magnet is positioned at one side of the sensor and has a field perpendicular to the surface of the sensor. This magnetic field generator or magnet is only used to actuate particles to or from the sensor surface. The other magnetic field generator or magnet is positioned at the other side of the sensor surface to generate a field with a first angle (alpha) and/ or a second angle (beta) with respect to the sensor surface. This second magnetic field generator or magnet actuates particles towards or from the sensor surface and at the same time restores the field at the sensor surface that was distorted by any applied magnetic field. Id. at 13. Nieuwenhuis further teaches that: Any of the methods of the present invention may include a step of measuring the presence of at least one magnetic particle accumulated at the surface of the sensor. The system of the present invention can be used for several applications wherein sensitive magnet detection is performed combined with magnetic actuation for enhancing the movement of magnetic particles towards and from a sensor surface. Id. at 14 ( emphasis added). Nieuwenhuis thus expressly teaches using two magnets to create fields that are orthogonal to the sensor surface, and that such an arrangement was well known in the prior art. With respect to the "detection step" recited in the claims, Appellants' Specification discloses: 12 Appeal2017-008280 Application 13/124,428 Figures 6A to 6C show different steps of a typical assay in a biosensor. In particular, Figure 6A shows the magnetic particles E which can bind to the analyte or target molecule C in solution. In order to bind the particles E with bound target molecules C to the sensor surface A, a magnetic field is applied such that the particles E travel to the sensor surface (see Fig. 6B). The force Fl of the magnetic [field] which acts on the particles E is indicated by the double arrows in Figure 6B. The unbound particles are magnetically removed from the sensor surface in a subsequent washing step (see Fig. 6C). Again, the force F2 of the magnetic field which acts on the particles E is indicated by the double arrows in Figure 6C. In a subsequent step the bound particles are detected using a technique that is sensitive only to particles that are close to the sensor surface A. Spec. 3--4. Figures 6A---C are reproduced below. FIG. 6A FIG. 68 FIG. 6C Figures 6A---C depict: (1) an immunoassay in solution (Fig. 6A); (2) an immunoassay during an actuation step (Fig. 6B); and (3) an immunoassay during a washing step Appellants' Specification further discloses that: The inventors of the present invention discovered that the instability of the signal after the washing step (see Fig. 6B) is substantially caused by sedimentation of non-bound particles, especially when relatively large particles are used (e.g.[,] particles with a diameter of 500 nm are frequently used in these biosensors ). Spec. 4. Consequently, the Specification discloses: 13 Appeal2017-008280 Application 13/124,428 [T]he method according to the present invention preferably comprise the step of adjusting the magnetic field for a certain duration of time such that the absolute value of the force acting on the magnetic or magnetizable objects opposite to the direction of the gravitational force is equal or larger then [sic] the absolute value of the gravitational force. Still in other words, the resulting force of the magnetic field acting against the gravitational force is adjusted such that the magnetic or magnetizable objects remain substantially stationary within the solution. Spec. 6 ( emphasis added). We interpret these disclosures of Appellants' Specification to mean that the detection pulse is an adjustment of force F2 in Figure 6C, such that the magnetic objects E are pushed away from the sensor surface and prevented from moving back towards the sensor surface by opposing the downward directional force of gravity. We therefore interpret the limitation of claim 2 reciting: "deliver a detection pulse to the at least two electromagnets which generate magnetic fields that avoid movement of the plurality of magnetic objects in a direction of gravity," as meaning adjusting a force (e.g., F2 in Figure 6C of Appellants' Specification supra) that actuates the magnetic particles in a direction away from the horizontal sensor surface, i.e., in a direction against the downward force of gravity. As we have explained supra, Nieuwenhuis teaches generation of magnetic fields that are orthogonal to the sensor plate and the movement of the magnetic particles orthogonally towards and away from the sensor surface. Furthermore, Marioni expressly teaches: An actuator drive circuit is connected to the coils in a circuit configuration that reverses a direction of electrical current flow 14 Appeal2017-008280 Application 13/124,428 through at least one of the coils to reorient the magnetic field from a first selected direction to a second selected direction of the plurality of selectable discrete directions. Marioni Abstr. We agree with the Examiner that a person of ordinary skill in the art would reasonably have expected that the drive circuit of Marioni thus described could be used to reverse the direction of a force in the same way that the force is reversed in Figures 6B and 6C of the Specification (where the downward directional component of Fl in Figure 6B is reversed to an upward component F2 in Figure 6C), thus providing the recited "detection pulse" that holds the magnetic particles away from the horizontal sensor plate and the direction of the gravitational force. As the Examiner explains, the person of ordinary skill would have been motivated to use Marioni's drive circuit in such a way because "Nieuwenhuis teaches generating magnetic fields that pull the non-bound magnetic particles away from the sensor surface which is the same as avoid[ing] movement of the magnetic particles in the direction of gravity." Ans. 15. Because we find that the combined references teach or suggest the limitations of the claims, we affirm the Examiner's rejection C. The Rejection ofClaim 3 under 35 U.S.C. Â§ I03(a) Issue Appellants also argue dependent claim 3 separately. App. Br. 12. Claim 3 depends from claim 2, and recites: [W]herein during the magnetic fields that urge the magnetic objects towards the sensor surface, at least one of the plurality of magnetic objects binds to the sensor surface and the driving circuit is further configured to deliver a washing pulse and the detection pulse, wherein the washing pulse is configured to move 15 Appeal2017-008280 Application 13/124,428 at least one of the plurality of magnetic objects which is unbound away from the sensor surface. Id. at 21-22. Appellants argue that neither reference teaches a washing pulse and a detection pulse. Id. at 12. Analysis Appellants argue that the Examiner relies upon Marioni as teaching the dependent limitation at issue. App. Br. 12. However, Appellants assert, the driving circuit of Marioni does not deliver a washing pulse or a detecting pulse. Rather, the driving pulse of Marioni is configured to cause a FSMA material actuator to expand or elongate the FSMA material to produce a driving force. Thus, the driving circuit of Marioni operates in a different way, for a different purpose, to achieve a different end result than that of Nieuwenhuis. Id. The Examiner responds that the terms "washing" pulse and "detecting" pulse are interpreted as the intended uses of the claimed driving circuit. Ans. 16. The Examiner finds that Nieuwenhuis teaches pulses, as well as washing the magnetic particles, removing the unbound particles, and detecting the magnetic particles. Id. (citing Nieuwenhuis 14, 11. 4--18). The Examiner finds that Nieuwenhuis teaches that the electromagnets alternatively generate actuation magnetic fields which are used to pull non- selectively bound magnetic particles away from the sensor surface and/or to pull magnetic particles towards the sensor surface to speed up the binding process. Id. (citingNieuwenhuis 15, 11. 14--19; 13, 11. 13-28). The Examiner also finds that Marioni teaches a driving circuit capable of delivering pulses for generating actuation magnetic field with a coil 16 Appeal2017-008280 Application 13/124,428 configuration. Ans. 16. The Examiner concludes that it would have been obvious to a person of ordinary skill in the art modify the device of Nieuwenhuis with a driving circuit to deliver a washing pulse and a detection pulse, because the driving circuit is taught by Marioni as driving a magnetic actuator capable of controlling magnetic fields. Id. at 16-17. We agree with the Examiner. Niuwenuis expressly teaches a washing pulse, i.e., moving the magnetic objects away from the biosensor surface. Nieuwenhuis 12, 11. 14--19; 13, 11. 13-27. And as we have explained supra, based on Appellants' Specification we construe "detection pulse" as a pulse that pushes the magnetic objects in a direction opposite to the gravitational force so that there is no net movement toward the sensor surface to interfere with detection. We agree with the Examiner that a person of ordinary skill in the art would reasonably expect that the driver circuit taught by Marioni could be used successfully to deliver pulses to adjust the magnetic field to deliver washing and detection pulses, and Nieuwenhuis provides the motivation to configure Marioni' s driver circuit to do so because Nieuwenhuis teaches the desirability of keeping unbound or non-specifically or non-selectively bound particles away from the biosensor surface using a magnetic field. Id. at 1, 11. 14--16; 12, 11. 14--19; 13, 11. 13-27. We note that Niuwenhuis teaches that particles may move towards the sensor surface via gravity and sedimentation, id. at 1, 11.17-21, which further provides motivation to a skilled artisan to configure Marioni's driver circuit to deliver a "detection pulse." Furthermore: The test for obviousness is not whether the features of a secondary reference may be bodily incorporated into the structure of the primary reference; nor is it that the claimed 17 Appeal2017-008280 Application 13/124,428 invention must be expressly suggested in any one or all of the references. Rather, the test is what the combined teachings of the references would have suggested to those of ordinary skill in the art. In re Keller, 642 F.2d 413,425 (C.C.P.A. 1981). In this instance, the Examiner relies upon Marioni as teaching actuators that can be used to alter the direction and strength of magnetic fields. We have explained supra why Marioni is therefore reasonably pertinent to the particular problem with which the inventor is involved, and conclude that it would have been obvious to a person of ordinary skill to combine the references to arrive at the claimed limitation. We therefore affirm the Examiner's rejection of claim 3. D. The Rejection ofClaim 5 under 35 U.S.C. Â§ 103(a) Issue Appellants also argue dependent claim 5 independently. App. Br. 12. Claim 5 recites: "The biosensor according to claim 2, wherein a frequency of the alternating actuation pulses of the at least two electromagnets is larger than 1 Hz and lower than 10 Hz." Id. at 22. Appellants argue that the Examiner erred in concluding that, although this range is not taught or suggested by the prior art, it would have been obvious to optimize the frequency of the actuation pulses to the recited range. Id. at 12. Analysis Appellants question whether the Examiner's conclusion applies to the optimum or workable ranges for biosensors or only the ranges for FSMA actuators. App. Br. 12. Appellants contend, again, the biosensor of 18 Appeal2017-008280 Application 13/124,428 Nieuwenhuis and the FSMA actuator of Marioni work in different ways, for different purposes, and achieve different end results. Id. at 13. According to Appellants, optimizing the actuation for a biosensor has not been shown to be the same as for optimizing the duty cycle of an FSMA actuator. Id. We are not persuaded by Appellants' argument. As we have explained supra, the Examiner is not trying to directly incorporate the actuator of Marioni used for applying directional magnetic fields to FMSAs, but is incorporating the broader teaching of Marioni that states its compact and efficient actuators can be driven by circuitry to alter the orientation of a magnetic field in a given application, e.g., the biosensor ofNieuwenhuis. Specifically, Marioni teaches that: In accordance with the invention the use of pulsed current flow through the coil configuration overcomes the actuation speed limitations of DC and AC magnetic field generation and can be preferred for many applications. Pulsed magnetic field generation can be accomplished by a short-duration, high-current pulse through the coil configuration. Due to the short duration of the pulse, a high level of current can be sustained without damage to the coil wires. Marioni ,r 72; see also, id. at ,r 81 ("The magnetic pulse duration and the time to reach the peak field strength must correspond to the actuation frequency desired for a given application."); id at ,r 93 ("It is recognized in accordance with the invention that both pulsed and AC-current generated magnetic fields can be employed to incrementally actuate and/or reset a magnetic material in the magnetic actuator of the invention. Step-wise actuation and/or reset can be accomplished by control of the magnetic pulse duration and/or maximum field intensity or by control of the AC duty cycle characteristics and maximum field intensity."). 19 Appeal2017-008280 Application 13/124,428 In short, Marioni teaches that the frequency of the applied pulses is a result-effective variable in driving magnetic objects generally and, as such, would be routinely optimized by a skilled artisan in applications requiring the driving of magnetic objects, such as in the system suggested by the combination ofNieuwenhuis and Marioni. See In re Boesch, 617 F.2d 272, 276 (C.C.P.A. 1980) ("[D]iscovery of an optimum value of a result effective variable ... is ordinarily within the skill of the art"). We consequently affirm the rejection of claim 5. E. The Rejection ofClaim 6 under 35 U.S.C. Â§ 103(a) Issue Claim 6 depends from claim 2, and recites: "wherein the driving circuit is further configured to apply the alternating actuation pulses such that the plurality of magnetic objects, which are located at and unbound to the sensor surface, alternately move a predetermined distance away from the sensor surface and substantially the same predetermined distance toward the sensor surface." App. Br. 22-23. Appellants argue that the Examiner erred because neither of the cited references teaches or suggests this limitation. Id. at 13. Analysis Appellants argue that Nieuwenhuis does not teach or describe the movement of the magnetic objects recited in the claims. App. Br. 13. Appellants assert that Marioni applies magnetic pulses to change the crystalline structure or phase of a magnetic field-actuated material ( element 18) to elongate it. Id. Appellants contend that Marioni makes no suggestion 20 Appeal2017-008280 Application 13/124,428 of moving the magnetic field-actuated material, or any magnetic object, a predetermined distance towards and away from a sensor surface. Id. The Examiner responds that Nieuwenhuis teaches moving magnetic particles away and toward the sensor surface. Ans. 18. The Examiner finds that, although Nieuwenhuis fails to teach a driving circuit to control the actuation of the magnetic particles to move at the same distance with respect to the sensor surface, Marioni teaches such a driving circuit. Id. at 18-19. The Examiner concludes that it would have been obvious to one of ordinary skill in the art to modify the device ofNieuwenhuis to incorporate a driving circuit capable of moving the magnetic particles a predetermined distance away and toward the sensor surface because driving circuit was a known means of magnetic actuator and because Nieuwenhuis teaches that its magnetic particles are designed to move towards and away from the sensor surface. Id. We agree with the Examiner. "[O]ne cannot show non-obviousness by attacking references individually where ... the rejections are based on combinations of references." Keller, 642 F.2d at 426. Rather: "the test is what the combined teachings of the references would have suggested to those of ordinary skill in the art." Id. at 425. In this instance, the Examiner has concluded that it would have been obvious to combine the drive circuit of Marioni with the biosensor ofNieuwenhuis to permit the alternation of magnetic field direction in the latter to move the magnetic particles predetermined distances towards and away from the sensor surface. We agree with the Examiner's conclusion that it would have been obvious to a person of ordinary skill to combine the references, and we affirm the rejection of claim 6. 21 Appeal2017-008280 Application 13/124,428 F. The Rejection ofClaim 4 under 35 U.S.C. Â§ 103(a) Issue Appellants argue that independent claim 4 requires, inter alia, "at least two electric magnets arranged below the sensor surface and a driving circuit which actuates said magnets arranged below the sensor surface with an opposite polarity to urge the magnetic objects toward the sensor surface and to actuate the electromagnets below the sensor surface with the same polarity to urge the magnetic objects away from the sensor surface." App. Br. 13. Appellants argue that the Examiner erred because neither Nieuwenhuis nor Marioni teaches these limitations. Id. Analysis Appellants argue that Nieuwenhuis does not disclose or fairly suggest operating two magnets below a sensor surface with the same and alternate polarities to move magnetic objects toward and away from a sensor surface. App. Br. 13. According to Appellants, Marioni fails to cure this alleged deficiency ofNieuwenhuis, because Marioni uses surrounding magnetic coils to change the crystalline structure or phase of a magnetic field-actuated material, causing it to elongate. Id. Appellants argue further that claim 4 calls for the actuation to be such that lateral movement of the magnetic objects is substantially avoided. App. Br. 14. Appellants assert that Nieuwenhuis advocates applying magnetic fields with a component extending laterally along the sensor surface, which would inherently urge the magnetic objects laterally along the sensor 22 Appeal2017-008280 Application 13/124,428 surface. Id. Marioni, argue Appellants, teaches applying magnetic fields to change the crystalline structure or phase of a magnetic field-actuated material, causing it to extend laterally, but does not cure the alleged deficiencies ofNieuwenhuis. Id. Furthermore, Appellants argue, if one were to use the actuator of Marioni to move an object, such as a particle, away from a surface such as a sensor surface, one end of the actuator would be affixed to the particle or object and the other would be connected to the sensor surface. Appellants contend that interposing such a mechanical structure between the magnetic objects and the sensor surface ofNieuwenhuis would interfere with the normal and intended operation ofNieuwenhuis to such an extent that it would not function for its normal and intended purpose. App. Br. 14. We are not persuaded by Appellants' arguments for the same reasons we have explained supra. As discussed above, Nieuwenhuis expressly teaches a magnet to move particles in a direction orthogonal to the plane of the biosensor: "In such a sensor system an actuation magnetic field generator generates a field gradient perpendicular to the surface of the sensor and an additional reset magnetic field generator or magnet is supplied that can be used to restore the magnetic orientation of the sensor." Nieuwenhuis 12; see also Figs. 3, 8. Again, we state that it is the combination of the references that form the basis of the Examiner's rejection. Marioni is cited with respect to the drive circuit of the actuators, but the combination of reference does not require all of the physical features of Marioni to be incorporated into the biosensor ofNieuwenhuis, as implied by Appellants. See Keller, 642 F.2d at 426. We consequently affirm the rejection of claim 4. 23 Appeal2017-008280 Application 13/124,428 G. The Rejection of Claims 7, 9, 10, 11, 13-15, and 17-20 under 35 U.S.C. Â§ 103(a) Appellants' arguments with respect to these claims are all essentially the same as, or slight variations of, those presented supra, with Appellants arguing that the references cannot be combined to teach the disputed claims and that the individual references do not teach the limitations of the claims. See App. Br. 15-20. With respect to dependent claims 10 and 17-20, we agree with the Examiner, as we have explained supra, that the details of the actuating regime employed by the driver circuit would necessarily be result- effective variables, i.e., regulating the movement of the magnetic particles with respect to the sensor surface, that would be well within the skill of a person of ordinary skill in the art to optimize, and as would be expected from the teachings ofNieuwenhuis. See Boesch, 617 F.2d at 276. Therefore, and for the reasons we have explained supra with respect to the preceding claims, we affirm the Examiner's rejection of the claims. DECISION The Examiner's rejection of claims 2-7, 9-11, 13-20 under 35 U.S.C. Â§ 103(a) is affirmed. No time period for taking any subsequent action in connection with this appeal may be extended under 37 C.F.R. Â§ 1.136(a)(l )(iv). AFFIRMED 24