Abstract: A catheter is provided which exhibits higher resolution at its distal end. The higher resolution can be accomplished by combining and amplifying signals received at electrodes locally. These combined and amplified signals can then be digitized locally and transmitted for further processing. Optical communication channels may be used.

Abstract: An apparatus for autonomous cleaning of an electrical wire includes an inductive means to derive power from the electrical wire through inductive coupling, a drive motor for driving motion wheels in contact with the electrical wire, and at least one retractable arm having a cleaning unit comprising a brush in contact with the electrical wire for cleaning the electrical wire. The apparatus is configured to raise the at least one retractable arm when an obstruction on the wire is detected, thereby permitting the apparatus to traverse over the obstruction and continue cleaning the electrical wire. The apparatus also includes a support wheel configured to automatically compensate for any changes in diameter of the wire during the cleaning process. The apparatus may also be used to clean multiple wires at once and is further provided with a suite of electronics for collecting and sending data to an outside operator.

Abstract: A field portable diagnostic apparatus uses a rotatable disk in which a microfluidic circuit is defined. The microfluidic circuit includes a centrifugal separation chamber receiving a sample to stratify the sample. A magnetic bead holding chamber is communicated to a mixing chamber, where mass amplifying functionalized magnetic-nanoparticles, held in a buffer solution and contained in the magnetic bead holding reservoir communicated to mixing chamber, are mixed with the separated fluid delivered to mixing chamber from the separation chamber. The functionalized magnetic nanoparticles conjugate with a target analyte in the sample. A magnet in proximity to a SAW chamber including a SAW detector draws the functionalized magnetic nanoparticles toward antibodies immobilized on the SAW sensor surface A wash reservoir is communicated to the SAW sensor chamber, and a cleanup/waste reservoir is communicated to the SAW chamber for receive fluid after it has passed through the SAW chamber.

Abstract: With respect to the methodology of using the Huygens sensing array, the invention includes an improvement in a method of sensing biopotentials in tissue including the steps of: providing a Huygens sensor array; and sensing a native electrical biopotential signal using at least one electrode on a catheter with an amplifier circuit placed on the inner surface of the at least one electrode in the Huygens sensor array to generate a well-formed waveform of the biopotential showing clear electrical properties indicative of the tissue with a SFDR of at least 24.9 dB and SNR of at least ?13 dB. In one embodiment the tissue is cardiac tissue and the biopotential signal sensed by the Huygens sensing array is a native cardiac waveform. In one embodiment the sensed biopotential signal is a manifestation of underlying electrochemical activity sensed by the Huygens sensing array of a biological substrate corresponding to the tissue.

Abstract: The invention includes a ventriculo-peritoneal shunt and a method of operating it. The shunt includes: a ventricular catheter for transferring CSF from the ventricle of a brain of a patient; a pressure sensor communicated to the ventricular catheter to measure the pressure of the CSF as delivered to the pressure sensor; a temperature sensor communicated to the ventricular catheter to measure the temperature of the CSF as delivered to the temperature sensor; a wireless data transmitter to transmit the measured pressure and temperature to an attending physician; a nonprogrammable reporting valve or programmable valve communicated to the pressure sensor and temperature sensor to regulate flow of the CSF; and peritoneal tubing communicated to the programmable valve for delivering CSF to the peritoneal cavity.

Abstract: The embodiments include an apparatus used in combination with a computer for sensing biopotentials. The apparatus includes a catheter in which there is a plurality of sensing electrodes, a corresponding plurality of local amplifiers, each coupled to one of the plurality of sensing electrodes, a data, control and power circuit coupled to the plurality of local amplifiers, and a photonic device bidirectionally communicating an electrical signal with the data, control and power circuit. An optical fiber optically communicated with the photonic device. The photonic device bidirectionally communicates an optical signal with the optical fiber. An optical interface device provides optical power to the optical fiber and thence to the photonic device and receives optical signals through the optical fiber from the photonic device. The optical interface device bidirectionally communicates an electrical data, control and power signal to the computer.

Abstract: A single electron transistor conjugated to a bacteriophage form a detectable probe where an RF signal identify the location of such probe at the site of specific biological matrix and provide a unique electronic signal such as a Coulomb Staircase and where such signal act as a diagnostic beacon and where such probe and a detector form a mesoscopic detector. The detector uses: a bioprobe containing the phage with its conjugated SET and the properties of the phage specificity; phage mobility within the biological environment and the phage ability to act as a carrier for the SET; and the SET's ultimate use as a beacon for the detection.

Abstract: The invention includes a method of assaying an analyte in a sample in a portable, handheld microfluidic reader. The method includes the steps of: inserting the sample in the reader; capturing the analyte with a first antibody having a DNA tag attached thereto; capturing the analyte in the sample with a second antibody attached to a surface or having a magnetic nanoparticle (MNP) attached thereto; where a sandwich including the magnetic nanoparticle, first and second antibodies, the analyte and the DNA tag is formed; replicating the DNA tag using isothermal amplification to a predetermined amount of DNA tags detectable by a detector sufficient to overcome the minimal mass sensitivity limitations of the detector; and measuring the amount of replicated DNA tags using the detector. The invention also includes an apparatus or handheld portable field microfluidic reader in which the method is performed.

Abstract: A field portable diagnostic apparatus uses a rotatable disk in which a microfluidic circuit is defined. The microfluidic circuit includes a centrifugal separation chamber receiving a sample to stratify the sample. A magnetic bead holding chamber is communicated to a mixing chamber, where mass amplifying functionalized magnetic-nanoparticles, held in a buffer solution and contained in the magnetic bead holding reservoir communicated to mixing chamber, are mixed with the separated fluid delivered to mixing chamber from the separation chamber. The functionalized magnetic nanoparticles conjugate with a target analyte in the sample. A magnet in proximity to a SAW chamber including a SAW detector draws the functionalized magnetic nanoparticles toward antibodies immobilized on the SAW sensor surface A wash reservoir is communicated to the SAW sensor chamber, and a cleanup/waste reservoir is communicated to the SAW chamber for receive fluid after it has passed through the SAW chamber.

Abstract: A field portable diagnostic apparatus uses a rotatable disk in which a microfluidic circuit is defined. The microfluidic circuit includes a centrifugal separation chamber receiving a sample to stratify the sample. A magnetic bead holding chamber is communicated to a mixing chamber, where mass amplifying functionalized magnetic-nanoparticles, held in a buffer solution and contained in the magnetic bead holding reservoir communicated to mixing chamber, are mixed with the separated fluid delivered to mixing chamber from the separation chamber. The functionalized magnetic nanoparticles conjugate with a target analyte in the sample. A magnet in proximity to a SAW chamber including a SAW detector draws the functionalized magnetic nanoparticles toward antibodies immobilized on the SAW sensor surface A wash reservoir is communicated to the SAW sensor chamber, and a cleanup/waste reservoir is communicated to the SAW chamber for receive fluid after it has passed through the SAW chamber.

Abstract: An electrophysiology catheter includes: a catheter with a movable catheter tip; electrodes provided on or in an electrode region in a most distal portion of the catheter tip; sensing and amplification circuitry communicated with the electrodes, the sensing and amplification circuitry communicated with digitizing circuitry disposed in a circuitry region in a least distal portion of the catheter tip for locally sensing tissue-based electrophysiological signals and for bidirectionally communicating digital data signals to and from the circuitry; a flexible bending region of the catheter tip between the most and least distal portions of the catheter tip; a flexible sheath communicated to the sensing and amplification circuitry and digitizing circuitry for transmission of signals thereon; and a handle communicated with the sheath for bidirectionally communicating signals through the sheath between the catheter tip and external mapping station, and for controlling movement of the catheter tip.

Abstract: An automated system communicated to a remote server for diagnostically field testing a sample taken from a patient using an automated portable handheld instrument to determine the presence of Covid-19 and/or antibodies thereto includes microfluidic circuits defined in a rotatable disk for performing a bioassay using a microarray to generate an electrical signal indicative of a bioassay measurement; the microarray operationally positioned in the microfluidic circuit; one or more lasers; one or more positionable valves in the microfluidic circuit; and a backbone unit for rotating the disk according to a protocol to perform the bioassay, for controlling the lasers to selectively open the positionable valves in the microfluidic disk, for operating the microarray to generate a digital image as a bioassay measurement; for communicating the bioassay measurement to the remote server, and for associating the performed bioassay and its corresponding bioassay measurement to the patient.

Abstract: The illustrated embodiments of the invention include an automated method of assaying a viral and antibody analyte in a sample in a portable, handheld microfluidic reader having a SAW detector with a minimal mass sensitivity limitation. The automated method includes the steps of automatically performing the assay with the SAW detector with enhanced sensitivity as in Optikus I, but also includes the steps of automatically disposing a second portion of the sample on a microarray, selectively automatically probing the second portion of the sample for antibodies corresponding to the at least one selected virus using the microarray, and automatically reading the microarray using a fluorescent camera to identify antibodies in the second portion of the sample.

Abstract: A single electron transistor conjugated to a bacteriophage form a detectable probe where an RF signal identify the location of such probe at the site of specific biological matrix and provide a unique electronic signal such as a Coulomb Staircase and where such signal act as a diagnostic beacon and where such probe and a detector form a mesoscopic detector. The detector uses: a bioprobe containing the phage with its conjugated SET and the properties of the phage specificity; phage mobility within the biological environment and the phage ability to act as a carrier for the SET; and the SET's ultimate use as a beacon for the detection.

Abstract: The illustrated embodiments of the invention include an automated method of assaying a viral and antibody analyte in a sample in a portable, handheld microfluidic reader having a SAW detector with a minimal mass sensitivity limitation. The automated method includes the steps of automatically performing the assay with the SAW detector with enhanced sensitivity as in Optikus I, but also includes the steps of automatically disposing a second portion of the sample on a microarray, selectively automatically probing the second portion of the sample for antibodies corresponding to the at least one selected virus using the microarray, and automatically reading the microarray using a fluorescent camera to identify antibodies in the second portion of the sample.

Abstract: The invention includes a method of assaying an analyte in a sample in a portable, handheld microfluidic reader. The method includes the steps of: inserting the sample in the reader; capturing the analyte with a first antibody having a DNA tag attached thereto; capturing the analyte in the sample with a second antibody attached to a surface or having a magnetic nanoparticle (MNP) attached thereto; where a sandwich including the magnetic nanoparticle, first and second antibodies, the analyte and the DNA tag is formed; replicating the DNA tag using isothermal amplification to a predetermined amount of DNA tags detectable by a detector sufficient to overcome the minimal mass sensitivity limitations of the detector; and measuring the amount of replicated DNA tags using the detector. The invention also includes an apparatus or handheld portable field microfluidic reader in which the method is performed.

Abstract: The embodiments include an apparatus used in combination with a computer for sensing biopotentials. The apparatus includes a catheter in which there is a plurality of sensing electrodes, a corresponding plurality of local amplifiers, each coupled to one of the plurality of sensing electrodes, a data, control and power circuit coupled to the plurality of local amplifiers, and a photonic device bidirectionally communicating an electrical signal with the data, control and power circuit. An optical fiber optically communicated with the photonic device. The photonic device bidirectionally communicates an optical signal with the optical fiber. An optical interface device provides optical power to the optical fiber and thence to the photonic device and receives optical signals through the optical fiber from the photonic device. The optical interface device bidirectionally communicates an electrical data, control and power signal to the computer.

Abstract: A bioFET cell for measuring a time dependent characteristic of an analyte bearing fluid includes a source, a drain, a semiconductive single wall carbon nanotube network layer extending between the source and drain electrodes and electrically coupled there between, a gate insulatively spaced from and disposed over and extending between the source and drain electrodes, a layer of at least one selected antibody disposed on and linked to the polymer layer to functionalize the semiconductive single wall carbon nanotube network layer to a selected target biomarker corresponding to the at least one selected antibody so that electron transport into the semiconductive single wall carbon nanotube network layer is facilitated, where the source, drain and gate electrodes with the carbon nanotube network layer form a defined channel through which the analyte bearing fluid may flow, and a high impedance source follower amplifier coupled to the source electrode.

Abstract: A bioFET cell for measuring a time dependent characteristic of an analyte bearing fluid includes a source, a drain, a semiconductive single wall carbon nanotube network layer extending between the source and drain electrodes and electrically coupled there between, a gate insulatively spaced from and disposed over and extending between the source and drain electrodes, a layer of at least one selected antibody disposed on and linked to the polymer layer to functionalize the semiconductive single wall carbon nanotube network layer to a selected target biomarker corresponding to the at least one selected antibody so that electron transport into the semiconductive single wall carbon nanotube network layer is facilitated, where the source, drain and gate electrodes with the carbon nanotube network layer form a defined channel through which the analyte bearing fluid may flow, and a high impedance source follower amplifier coupled to the source electrode.

Abstract: A bioFET cell for measuring a time dependent characteristic of an analyte bearing fluid includes a source, a drain, a semiconductive single wall carbon nanotube network layer extending between the source and drain electrodes and electrically coupled there between, a gate insulatively spaced from and disposed over and extending between the source and drain electrodes, a layer of at least one selected antibody disposed on and linked to the polymer layer to functionalize the semiconductive single wall carbon nanotube network layer to a selected target biomarker corresponding to the at least one selected antibody so that electron transport into the semiconductive single wall carbon nanotube network layer is facilitated, where the source, drain and gate electrodes with the carbon nanotube network layer form a defined channel through which the analyte bearing fluid may flow, and a high impedance source follower amplifier coupled to the source electrode.