Abstract: The present invention is a biosensor apparatus that includes a substrate, a source on one side of the substrate, a drain spaced from the source, a conducting channel between the source and the drain, an insulator region, and receptors on a gate region for receiving target material. The receptors are contacted for changing current flow between the source and the drain. The source and the drain are relatively wide compared to length between the source and the drain through the conducting channel.

Abstract: The present invention is a biosensor apparatus that includes a substrate, a source on one side of the substrate, a drain spaced from the source, a conducting channel between the source and the drain, an insulator region, and receptors on a gate region for receiving target material. The receptors are contacted for changing current flow between the source and the drain. The source and the drain are relatively wide compared to length between the source and the drain through the conducting channel.

Abstract: The present invention is a biosensor apparatus that includes a substrate, a source on one side of the substrate, a drain spaced from the source, a conducting channel between the source and the drain, an insulator region, and receptors on a gate region for receiving target material. The receptors are contacted for changing current flow between the source and the drain. The source and the drain are relatively wide compared to length between the source and the drain through the conducting channel.

Abstract: The present invention is a biosensor apparatus that includes a substrate, a source on one side of the substrate, a drain spaced from the source, a conducting channel between the source and the drain, an insulator region, and receptors on a gate region for receiving target material. The receptors are contacted for changing current flow between the source and the drain. The source and the drain are relatively wide compared to length between the source and the drain through the conducting channel.

Abstract: The present invention is a biosensor apparatus that includes a substrate, a source on one side of the substrate, a drain spaced from the source, a conducting channel between the source and the drain, an insulator region, and receptors on a gate region for receiving target material. The receptors are contacted for changing current flow between the source and the drain. The source and the drain are relatively wide compared to length between the source and the drain through the conducting channel.

Abstract: Isolation of semiconductor based biosensors is described. The present invention is directed to prevention of undesirable influences including, but not limited to, chip leakage current. Several forms of sensor isolation and other protective means affect protection from adverse chip influences. The effect of biochemical attachment outside the sensor active region may have adverse effects on sensor performance. This potential problem is averted using protective design features.

Abstract: An electronic sensor is provided for detecting the presence of one or more targets of interest in a sample. The sensor preferably comprises a special type of field effect transistor in which conductance is enhanced by target binding to recognition elements in the active region. An array of sensors may be formed to analyze a sample for multiple targets. The sensor may be used, for example, to detect the presence of pathogens, polypeptides, nucleic acids, toxins and other biochemical and chemical agents. The sensor is useful in a wide variety of applications including medical diagnostics, agriculture, public health, environmental monitoring and biomedical research.

Abstract: Chemical sensors for detecting chemicals are provided using surface and bulk selective chemical reactions. Large charge complexes are bound to the bound target and provide ultrasensitive sensing detection of the original target. In particular embodiments, the sensing device is affected by a change in the resistance of some key part of the device. In certain embodiments, the invention employs beads and other systems to provide a significantly enhanced sensor detection signal. In other embodiments, the invention employs chemical reactions with a pre-selected surface integrated with a suitable semiconductor sensor devices where material coats the top active sensing region of a sensor, and a reaction results in a new compound.

Abstract: A novel label-free sensitive detection method by employing a novel sensitive charge sensor is provided. Dissociation constant information is provided by a simple measurement of the dissociation of the target molecule form the target's receptor. The later process is affected by a novel system and its configuration as described herein. Basic objectives are to provide a drug discovery and characterization system that is an improvement over the current state of the art, low cost, highly sensitive, accurate, fast and easy to use. This invention involves both a physical system and a methodology.

Abstract: A new distributed channel bipolar device (DCBD) has a large channel of a selected shape formed in a surface of a substrate by doping or by influencing of a coating. The channel acts as a collector or emitter. Another emitter of a transistor is separated from the channel by a base of varying thickness. Drain collectors in contact with the channel provide distinct channel functions. A second transistor in the substrate has a base in contact with the channel. Electrical leads provide voltages. Current is controlled and varied by the channel and influencing chemicals.

Abstract: An electronic sensor is provided for detecting the presence of one or more analytes of interest in a sample. The sensor preferably comprises a field effect transistor in which conductance is enhanced by analyte binding to receptors in the active region. An array of sensors may be formed to analyze a sample for multiple analytes.