Patents by Inventor Michael C. Cross
Michael C. Cross has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20200354671Abstract: The invention pertains to methods and apparatuses for rapid production of organized tissue precursors with different sizes and geometry. An embodiment of the invention provides a method of producing 3D tissue structures, the method comprising: producing a plurality of patterned monolayers of cells and sequentially overlaying the plurality of patterned monolayers of cells to produce a stack of monolayers of cells. The patterns of cells in the plurality of monolayers can be designed in a manner which produces a tissue or a portion of a tissue when the plurality of monolayers is overlaid in to a stack. The invention also pertains to an apparatus for producing a 3D tissue module. The apparatus comprises: a three-dimensional positioning system, a contact stamp, a contact stamp storage container, a contact stamp holder, a contact stamp exchange unit, and a contact stamp actuator.Type: ApplicationFiled: October 6, 2016Publication date: November 12, 2020Applicant: UNIVERSITY OF SOUTH FLORIDAInventors: MICHAEL C. CROSS, OLUKEMI O. AKINTEWE, SAMUEL JAMES DUPONT, KRANTHI KUMAR ELINENI, RYAN G. TOOMEY, NATHAN D. GALLANT
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Publication number: 20180127700Abstract: The invention pertains to devices and methods for rapid release of a patterned tissue module. The invention pertains to a device comprising a substrate and a pattern of shape-memory polymer fabricated upon the substrate, wherein the shape-memory polymer is converted to a deformed state by exposure to an external stimulus, for example, a change in temperature, pH, ionic strength, solvent, salt, surfactant, or an electric or magnetic field. The invention also pertains to a method of releasing a patterned tissue module, the method comprising the steps of plating cells in the device of the invention, culturing the cells to produce the patterned tissue module on the pattern of shape-memory polymer, applying the external stimulus to the device, and collecting the patterned tissue module released from the pattern of shape-memory polymer.Type: ApplicationFiled: May 23, 2016Publication date: May 10, 2018Inventors: OLUKEMI O. AKINTEWE, MICHAEL C. CROSS, SAMUEL JAMES DUPONT, NATHAN D. GALLANT, RYAN G. TOOMEY
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Patent number: 9660654Abstract: Synchronization of oscillators based on anharmonic nanoelectromechanical resonators. Experimental implimentation allows for unprecedented observation and control of parameters governing the dynamics of synchronization. Close quantitative agreement is found between experimental data and theory describing reactively coupled Duffing resonators with fully saturated feedback gain. In the synchonized state, a significant reduction in the phase noise of the oscillators is demonstrated, which is key for applications such as sensors and clocks. Oscillator networks constructed from nanomechanical resonators form an important laboratory to commercialize and study synchronization—given their high-quality factors, small footprint, and ease of co-integration with modern electronic signal processing technologies. Networks can be made including one-, two-, and three-dimensional networks. Triangular and square lattices can be made.Type: GrantFiled: October 25, 2013Date of Patent: May 23, 2017Assignee: CALIFORNIA INSTITUTE OF TECHNOLOGYInventors: Matthew Matheny, Michael L. Roukes, Michael C. Cross, Luis Guillermo Villanueva Torrijo, Rassul Karabalin
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Patent number: 9252731Abstract: A passive electro-mechanical device that reduces phase noise in oscillators, thereby improving their frequency precision. The noise reduction device can consist of a pair of coupled nonlinear resonators that are driven parametrically—by modulating their natural frequency in time, through the output signal of a conventional oscillator at a frequency close to the sum of the linear mode frequencies. Above the threshold for parametric response, the coupled resonators can exhibit oscillation at an inherent frequency. The novel possibility for noise elimination is realized by tuning the system to operating points for which this periodic signal is immune to frequency noise in the drive signal, providing a way to clean the phase noise of the driving oscillator.Type: GrantFiled: January 14, 2014Date of Patent: February 2, 2016Assignee: CALIFORNIA INSTITUTE OF TECHNOLOGYInventors: Eyal Kenig, Michael C. Cross, Ron Lifshitz, Rassul Karabalin, Luis Guillermo Villanueva Torrijo, Matthew Matheny, Michael L. Roukes
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Publication number: 20140320219Abstract: A passive electro-mechanical device that reduces phase noise in oscillators, thereby improving their frequency precision. The noise reduction device can consist of a pair of coupled nonlinear resonators that are driven parametrically—by modulating their natural frequency in time, through the output signal of a conventional oscillator at a frequency close to the sum of the linear mode frequencies. Above the threshold for parametric response, the coupled resonators can exhibit oscillation at an inherent frequency. The novel possibility for noise elimination is realized by tuning the system to operating points for which this periodic signal is immune to frequency noise in the drive signal, providing a way to clean the phase noise of the driving oscillator.Type: ApplicationFiled: January 14, 2014Publication date: October 30, 2014Inventors: Eyal KENIG, Michael C. Cross, Ron Lifshitz, Rassul Karabalin, Luis Guillermo Villanueva Torrijo, Matthew Matheny, Michael L. Roukes
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Publication number: 20140176203Abstract: Synchronization of oscillators based on anharmonic nanoelectromechanical resonators. Experimental implimentation allows for unprecedented observation and control of parameters governing the dynamics of synchronization. Close quantitative agreement is found between experimental data and theory describing reactively coupled Duffing resonators with fully saturated feedback gain. In the synchonized state, a significant reduction in the phase noise of the oscillators is demonstrated, which is key for applications such as sensors and clocks. Oscillator networks constructed from nanomechanical resonators form an important laboratory to commercialize and study synchronization—given their high-quality factors, small footprint, and ease of co-integration with modern electronic signal processing technologies. Networks can be made including one-, two-, and three-dimensional networks. Triangular and square lattices can be made.Type: ApplicationFiled: October 25, 2013Publication date: June 26, 2014Applicant: California Institute of TechnologyInventors: Matthew MATHENY, Michael L. Roukes, Michael C. Cross, Luis Guillermo Villanueva Torrijo, Rassul Karabalin
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Patent number: 8378758Abstract: A parametric feedback oscillator includes a resonator which has at least one transduction element and at least one electromechanical resonating element. The resonator is configured to accept as input a parametric excitation signal at a frequency 2?0 and to provide a resonating output signal at a frequency ?0. A cascaded feedback path in any electrically coupled cascade order includes at least one non-linear element, at least one phase shifter electrically, and at least one amplifier. The cascade feedback path is configured to receive as input the resonating output signal at a frequency ?0 and configured to provide as output a feedback path signal as the parametric excitation signal at a frequency 2?0 to the resonator. A parametric feedback oscillator output terminal is configured to provide the resonating output signal at the frequency ?0 as an output signal. A method of causing a parametric feedback oscillation is also described.Type: GrantFiled: April 27, 2011Date of Patent: February 19, 2013Assignee: California Institute of TechnologyInventors: Luis Guillermo Villanueva Torrijo, Rassul Karabalin, Matthew Matheny, Philip X.-L. Feng, Michael C. Cross, Michael L. Roukes
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Patent number: 8329452Abstract: A biofunctionalized nanoelectromechanical device (BioNEMS) for sensing single-molecules in solution by measuring the variation in the mechanical displacement of the BioNEMS device during a binding event is provided. The biofunctionalized nanoelectromechanical device according to the invention generally comprises a nanomechanical mechanical resonator, a detector integral with the mechanical resonator for measuring the mechanical displacement of the resonator, and electronics connected to the detector for communicating the results to a user. A system of biofunctionalized nanoelectromechanical devices and a method for utilizing the biofunctionalized nanoelectromechanical device of the present invention are also provided.Type: GrantFiled: July 14, 2011Date of Patent: December 11, 2012Assignee: California Institute of TechnologyInventors: Michael L. Roukes, Scott E. Fraser, Jerry E. Solomon, Michael C. Cross
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Publication number: 20110269649Abstract: A biofunctionalized nanoelectromechanical device (BioNEMS) for sensing single-molecules in solution by measuring the variation in the mechanical displacement of the BioNEMS device during a binding event is provided. The biofunctionalized nanoelectromechanical device according to the invention generally comprises a nanomechanical mechanical resonator, a detector integral with the mechanical resonator for measuring the mechanical displacement of the resonator, and electronics connected to the detector for communicating the results to a user. A system of biofunctionalized nanoelectromechanical devices and a method for utilizing the biofunctionalized nanoelectromechanical device of the present invention are also provided.Type: ApplicationFiled: July 14, 2011Publication date: November 3, 2011Inventors: Michael L. ROUKES, Scott E. FRASER, Jerry E. SOLOMON, Michael C. CROSS
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Publication number: 20110260802Abstract: A parametric feedback oscillator includes a resonator which has at least one transduction element and at least one electromechanical resonating element. The resonator is configured to accept as input a parametric excitation signal at a frequency 2?0 and to provide a resonating output signal at a frequency ?0. A cascaded feedback path in any electrically coupled cascade order includes at least one non-linear element, at least one phase shifter electrically, and at least one amplifier. The cascade feedback path is configured to receive as input the resonating output signal at a frequency ?0 and configured to provide as output a feedback path signal as the parametric excitation signal at a frequency 2?0 to the resonator. A parametric feedback oscillator output terminal is configured to provide the resonating output signal at the frequency ?0 as an output signal. A method of causing a parametric feedback oscillation is also described.Type: ApplicationFiled: April 27, 2011Publication date: October 27, 2011Applicant: California Institute of TechnologyInventors: Luis Guillermo Villanueva Torrijo, Rassul Karabalin, Matthew Matheny, Philip X.L Feng, Michael C. Cross, Michael L. Roukes
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Patent number: 7989198Abstract: A biofunctionalized nanoelectromechanical device (BioNEMS) for sensing single-molecules in solution by measuring the variation in the mechanical displacement of the BioNEMS device during a binding event is provided. The biofunctionalized nanoelectromechanical device according to the invention generally comprises a nanomechanical mechanical resonator, a detector integral with the mechanical resonator for measuring the mechanical displacement of the resonator, and electronics connected to the detector for communicating the results to a user. A system of biofunctionalized nanoelectromechanical devices and a method for utilizing the biofunctionalized nanoelectromechanical device of the present invention are also provided.Type: GrantFiled: June 27, 2008Date of Patent: August 2, 2011Assignee: California Institute of TechnologyInventors: Michael L. Roukes, Scott E. Fraser, Jerry E. Solomon, Michael C. Cross
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Publication number: 20090054267Abstract: A biofunctionalized nanoelectromechanical device (BioNEMS) for sensing single-molecules in solution by measuring the variation in the mechanical displacement of the BioNEMS device during a binding event is provided. The biofunctionalized nanoelectromechanical device according to the invention generally comprises a nanomechanical mechanical resonator, a detector integral with the mechanical resonator for measuring the mechanical displacement of the resonator, and electronics connected to the detector for communicating the results to a user. A system of biofunctionalized nanoelectromechanical devices and a method for utilizing the biofunctionalized nanoelectromechanical device of the present invention are also provided.Type: ApplicationFiled: June 27, 2008Publication date: February 26, 2009Inventors: Michael L. Roukes, Scott E. Fraser, Jerry E. Solomon, Michael C. Cross
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Patent number: 7407814Abstract: A biofunctionalized nanoelectromechanical device (BioNEMS) for sensing single-molecules in solution by measuring the variation in the mechanical displacement of the BioNEMS device during a binding event is provided. The biofunctionalized nanoelectromechanical device according to the invention generally comprises a nanomechanical mechanical resonator, a detector integral with the mechanical resonator for measuring the mechanical displacement of the resonator, and electronics connected to the detector for communicating the results to a user. A system of biofunctionalized nanoelectromechanical devices and a method for utilizing the biofunctionalized nanoelectromechanical device of the present invention are also provided.Type: GrantFiled: August 9, 2001Date of Patent: August 5, 2008Assignee: California Institute of TechnologyInventors: Michael L. Roukes, Scott E. Fraser, Jerry E. Solomon, Michael C. Cross
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Patent number: 7375321Abstract: A bioNEMS device comprises a piezoresistive cantilever having flexing legs of which attach the cantilever to a support and a biofunctionalized portion at the tip. A bias current applied to the legs is limited by a maximal acceptable temperature increase at the biofunctionalized tip. The length of the cantilever has a magnitude chosen to minimize background Johnson noise. A catalyzed receptor on the device binds to a ligand whose binding rate coefficient is enhanced. The catalyst lowers the receptor-ligand binding activation energy and is designed by forced evolution to preferentially bind with the ligand. A carrier signal is injected by a magnetic film disposed on the cantilever which is electromagnetically coupled to a source of the carrier signal. A plurality of NEMS fluidicly coupled transducers generate a plurality of output signals from which a collective output signal is derived, either by averaging or thresholding.Type: GrantFiled: May 7, 2003Date of Patent: May 20, 2008Assignee: California Institute of TechnologyInventors: Michael L. Roukes, Scott E. Fraser, Jerry E. Solomon, Jessica L. Arlett, Michael C. Cross
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Publication number: 20020166962Abstract: A biofunctionalized nanoelectromechanical device (BioNEMS) for sensing single-molecules in solution by measuring the variation in the mechanical displacement of the BioNEMS device during a binding event is provided. The biofunctionalized nanoelectromechanical device according to the invention generally comprises a nanomechanical mechanical resonator, a detector integral with the mechanical resonator for measuring the mechanical displacement of the resonator, and electronics connected to the detector for communicating the results to a user. A system of biofunctionalized nanoelectromechanical devices and a method for utilizing the biofunctionalized nanoelectromechanical device of the present invention are also provided.Type: ApplicationFiled: August 9, 2001Publication date: November 14, 2002Inventors: Michael L. Roukes, Scott E. Fraser, Jerry E. Solomon, Michael C. Cross