Abstract: An apparatus and method for detecting an analyte are described. The apparatus includes at least one microchannel adapted for an analyte to adhere to an interior surface thereof, a mixing element positioned within at least a portion of the at least one microchannel, a light source for energizing quantum dots conjugated with the analyte within the at least one microchannel, and a detection system for detecting and quantifying fluorescent energy emitted by the quantum dots in one or more predetermined wavelength ranges, wherein each wavelength range being correlated to one and only one type of analyte.

Abstract: An apparatus and method for detecting an analyte are described. The apparatus includes at least one microchannel adapted for an analyte to adhere to an interior surface thereof, a mixing element positioned within at least a portion of the at least one microchannel, a light source for energizing quantum dots conjugated with the analyte within the at least one microchannel, and a detection system for detecting and quantifying fluorescent energy emitted by the quantum dots in one or more predetermined wavelength ranges, wherein each wavelength range being correlated to one and only one type of analyte.

Abstract: A liver sinusoid model includes a generally planar substrate having first and second generally parallel microchannels formed therein. A microporous membrane is disposed between and separating the first and second generally parallel microchannels. A first layer of cells lines one side of the membrane in the first microchannel. The first layer of cells are all a first common cell type. A second layer of cells extends parallel to the first layer of cells in one of the first microchannel and the second microchannel. The second layer of cells is all of a second common cell type. A liver sinusoid bioreactor utilizing the inventive model is also disclosed.

Abstract: An implantable system for the treatment of hydrocephalus has a plurality of hollow microneedles in a fixed array. The microneedles have passages there through and are of a size to extend through dura mater with a proximal end on one side of the dura mater and a distal end communicating with the venous system in an area on a second side of the dura mater. An array of microvalves associated with a proximal end of the microneedles include segments movable by a pressure build up of cerebrospinal fluid (CSF) within the interior of the brain to provide open communication between the interior of the brain on one side of the dura mater and the venous system on the second side of the dura mater. A plurality of fluid transmitting members has distal ends communicating with the microvalves and a proximal end communicating with the ventricular space of the brain.

Abstract: An implantable system for the treatment of hydrocephalus has a plurality of hollow microneedles in a fixed array. The microneedles have passages there through and are of a size to extend through dura mater with a proximal end on one side of the dura mater and a distal end communicating with the venous system in an area on a second side of the dura mater. An array of microvalves associated with a proximal end of the microneedles include segments movable by a pressure build up of cerebrospinal fluid (CSF) within the interior of the brain to provide open communication between the interior of the brain on one side of the dura mater and the venous system on the second side of the dura mater. A plurality of fluid transmitting members has distal ends communicating with the microvalves and a proximal end communicating with the ventricular space of the brain.

Abstract: An implantable system for the treatment of hydrocephalus includes a plurality of microneedles in a fixed array relative to each other adapted to extend from the subarachnoid space containing CSF surrounding the brain, through dura mater forming the wall of the superior sagital sinus. A microvalve is associated with a proximal end of each of the microneedles and is adapted to permit the flow of cerebrospinal fluid (CSF) from the subarachnoid space through the wall of the superior sagital sinus and deposited in the venous return of the brain. The method of treating hydrocephalus with the system of this invention also constitutes a part of the invention.

Abstract: An implantable system for the treatment of hydrocephalus includes a plurality of microneedles in a fixed array relative to each other adapted to extend from the subarachnoid space containing CSF surrounding the brain, through dura mater forming the wall of the superior sagital sinus. A microvalve is associated with a proximal end of each of the microneedles and is adapted to permit the flow of cerebrospinal fluid (CSF) from the subarachnoid space through the wall of the superior sagital sinus and deposited in the venous return of the brain. The method of treating hydrocephalus with the system of this invention also constitutes a part of the invention.