Abstract: An implantable pressure sensor arrangement is disclosed. The arrangement includes a substrate, a coil positioned on the substrate, a flexible membrane positioned proximate to the coil and configured to be moveable with respect to the coil, thereby forming a fluid chamber, fluidly sealed from outside of the implantable pressure sensor arrangement, a porous membrane positioned on the flexible membrane and configured to transfer pressure from outside of the implantable pressure sensor arrangement onto the flexible membrane wherein a differential pressure is generated on the two sides of the flexible membrane thereby causing the flexible membrane to deflect towards and away from the coil, and an electrode coupled to the flexible membrane.

Abstract: The invention generally relates to a cell culture system for coculturing non-neoplastic and neoplastic cells on a planar member which more faithfully mimics the in vivo geometry of a lumen or a cavity.

Abstract: An implantable pressure sensor arrangement is disclosed. The arrangement includes a substrate, a coil positioned on the substrate, a flexible membrane positioned proximate to the coil and configured to be moveable with respect to the coil, thereby forming a fluid chamber, fluidly sealed from outside of the implantable pressure sensor arrangement, a porous membrane positioned on the flexible membrane and configured to transfer pressure from outside of the implantable pressure sensor arrangement onto the flexible membrane wherein a differential pressure is generated on the two sides of the flexible membrane thereby causing the flexible membrane to deflect towards and away from the coil, and an electrode coupled to the flexible membrane.

Abstract: A method of using a AFM/NMR probe, the method comprising the steps of injecting a sample to be analyzed with magnetic particles, introducing a probe into proximity with the sample, the probe capable of both transmitting and sensing electromagnetic radiation; generating a magnetic field via the probe, and adjusting the magnitude of the magnetic field to manipulate the magnetic particles within the sample.

Abstract: The invention generally relates to a cell culture system for coculturing non-neoplastic and neoplastic cells on a planar member which more faithfully mimics the in vivo geometry of a lumen or a cavity.

Abstract: A method of using a AFM/NMR probe, the method comprising the steps of injecting a sample to be analyzed with magnetic particles, introducing a probe into proximity with the sample, the probe capable of both transmitting and sensing electromagnetic radiation; generating a magnetic field via the probe, and adjusting the magnitude of the magnetic field to manipulate the magnetic particles within the sample.

Abstract: An implantable pressure sensor arrangement is disclosed. The arrangement includes a substrate, a coil positioned on the substrate, a flexible membrane positioned proximate to the coil and configured to be moveable with respect to the coil, thereby forming a fluid chamber, fluidly sealed from outside of the implantable pressure sensor arrangement, a porous membrane positioned on the flexible membrane and configured to transfer pressure from outside of the implantable pressure sensor arrangement onto the flexible membrane wherein a differential pressure is generated on the two sides of the flexible membrane thereby causing the flexible membrane to deflect towards and away from the coil, and an electrode coupled to the flexible membrane.

Abstract: The present disclosure is discloses the development of a new device, system, and method that combines advantages of magnetic resonance and atomic force microscopy technologies, and the utility of the new device, system, and method for a wide range of biomedical and clinical researchers. According to one aspect of the present disclosure, a device for micro-scale spectroscopy is disclosed. The micro-scale spectroscopy device includes a beam having a distal end, a proximal end, a top surface and a bottom surface, where the beam is attached to an anchor at the proximal end and further includes a tip extending substantially perpendicular from the bottom surface at or near the distal end, and a coil having at least one turn mounted to the top surface of the beam at or near the distal end opposite the tip, where the coil is capable of both transmitting and sensing electromagnetic radiation.

Abstract: The present disclosure is discloses the development of a new device, system, and method that combines advantages of magnetic resonance and atomic force microscopy technologies, and the utility of the new device, system, and method for a wide range of biomedical and clinical researchers. According to one aspect of the present disclosure, a device for micro-scale spectroscopy is disclosed. The micro-scale spectroscopy device includes a beam having a distal end, a proximal end, a top surface and a bottom surface, where the beam is attached to an anchor at the proximal end and further includes a tip extending substantially perpendicular from the bottom surface at or near the distal end, and a coil having at least one turn mounted to the top surface of the beam at or near the distal end opposite the tip, where the coil is capable of both transmitting and sensing electromagnetic radiation.

Abstract: A pressure monitoring system is disclosed. The pressure monitoring system includes a stimulation/response circuit configured to transmit a first signal during a stimulation mode and receive a second signal during a response mode, and a pressure monitoring apparatus configured to receive the first signal and transmit the second signal. The pressure monitoring apparatus includes a capacitive pressure sensor assembly, an insertion needle assembly, and a coil assembly. The insertion needle assembly, having an insertion opening, is coupled to the capacitive pressure sensor assembly, wherein fluid pressure at the insertion opening is fluidly communicated with the capacitive pressure sensor assembly.