Brian J Baker
Security Companies and Guards in Salt Lake City, UT

2013019, Aug 1, 2013

Jul 15, 2011

13/810402

Alonso P. Moreno - Draper UT, US
Gary S. Goldberg - Stratford NJ, US
Abhijit Mondal - Salt Lake City UT, US
Ian Harvey - Kaysville UT, US
Brian Baker - Salt Lake City UT, US

G01N 27/00

435 34, 4352871, 4352831

Electrophysiological recording systems for analysis of cultured cells include an recording device and a housing for supporting the electrophysiological recording device. The device has a porous membrane with top and bottom surfaces and a plurality of pores extending between the top and bottom surfaces. The porous membrane defines a first cell culture region disposed on the top surface and an opposed second cell culture region disposed on the bottom surface. The electrophysiological recording device has a plurality of electrodes positioned on the porous membrane in between a first insulation layer and a second insulation layer. The plurality of electrodes extend to the first cell culture region of the porous membrane. Recording ends of the electrodes measure electrical properties of cells cultured within the first and second cell culture regions, while the contact ends of the electrodes are positioned in electrical communication with data acquisition equipment.

8421305, Apr 16, 2013

Apr 17, 2008

12/596091

Ian R. Harvey - Kaysville UT, US
Taylor M. Meacham - Salt Lake City UT, US
Ronald W. Boutte - Layton UT, US
Brian Baker - Salt Lake City UT, US
Iain E. Harvey - Kaysville UT, US

The University of Utah Research Foundation - Salt Lake City UT

H02N 1/00

310309, 335 78

A microelectromechanical system (MEMS) device includes an actuator having a plurality of charge collection elements. At least one of the charge collection elements is configured to build up electrical charges by directly interacting with an energy field thereby actuating the MEMS through Coulombic interactions. An actuator for a MEMS device is configured to actuate the MEMS device through Coulombic interactions by pumping charges to the actuator when subject to an energy field. A method of actuating a MEMS device includes irradiating an actuator of the MEMS device with an energy field thereby building up electrical charges on the actuator, and actuating the MEMS device with Coulomb forces from the built up electrical charges.

2012009, Apr 19, 2012

Oct 13, 2011

13/272851

Ian Harvey - Kaysville UT, US
Brian Baker - Salt Lake City UT, US

H01J 37/20, H01L 31/02

250307, 257429, 257E3111

A microelectromechanical system (MEMS) device is configured to be actuated directly by an energy field through Coulombic interactions to have a translational motion. The MEMS device can be untethered, and actuated by irradiating an actuator with the energy field thereby building up electrical charges on the actuator. The MEMS device can thus be actuated with Coulomb forces from the built up electrical charges to suspend a movable portion over a rail. In one example, the energy field includes an electron beam from a scanning electron microscope (SEM).

2011017, Jul 21, 2011

Jun 29, 2009

13/001992

Charles Fisher - Salt Lake City UT, US
Ian Harvey - Kaysville UT, US
Brian Baker - Salt Lake City UT, US

H04N 5/232, G02B 7/09, G02B 7/02, B29D 11/00, B29C 45/14

348345, 359823, 359822, 264 26, 264 17, 348E05045

A flexible lens may be actuated to change its focal length by a deployable lens actuator. The lens actuator translates a rotational motion of an outer frame into a linear radial motion of a plurality of linear elements. The linear elements have fixed pins, which may be slidably coupled to cam pockets in the outer frame. The cam pockets have a gradually varying distance from the center of the outer frame. The rotation of the outer frame thus drives the cam pockets to slide about the pins, thereby causing radial motions of the linear elements. The linear elements stretch a flexible lens, thereby changing a curvature of the flexible lens.