Abstract: Certain embodiments of the present disclosure are directed toward devices, methods and systems for controlling depolarization in cardiac cells. One such device includes one or more circuits that are configured and arranged to generate an electrical stimulus at a high frequency. The circuit is configured to provide electrical stimulus over a period of time sufficient to depolarize the cardiac cells. An electrode arrangement is configured and arranged to deliver the high frequency electrical stimulus to cardiac cells and depolarize the cardiac cells.

Abstract: Techniques for enhanced microfluidic impedance spectroscopy include causing a core fluid to flow into a channel between two sheath flows of one or more sheath fluids different from the core fluid. Flow in the channel is laminar. A dielectric constant of a fluid constituting either sheath flow is much less than a dielectric constant of the core fluid. Electrical impedance is measured in the channel between at least a first pair of electrodes. In some embodiments, enhanced optical measurements include causing a core fluid to flow into a channel between two sheath flows of one or more sheath fluids different from the core fluid. An optical index of refraction of a fluid constituting either sheath flow is much less than an optical index of refraction of the core fluid. An optical property is measured in the channel.

Abstract: Techniques for enhanced microfluidic impedance spectroscopy include causing a core fluid to flow into a channel between two sheath flows of one or more sheath fluids different from the core fluid. Flow in the channel is laminar. A dielectric constant of a fluid constituting either sheath flow is much less than a dielectric constant of the core fluid. Electrical impedance is measured in the channel between at least a first pair of electrodes. In some embodiments, enhanced optical measurements include causing a core fluid to flow into a channel between two sheath flows of one or more sheath fluids different from the core fluid. An optical index of refraction of a fluid constituting either sheath flow is much less than an optical index of refraction of the core fluid. An optical property is measured in the channel.

Abstract: Certain embodiments of the present disclosure are directed toward devices, methods and systems for controlling depolarization in cardiac cells. One such device includes one or more circuits that are configured and arranged to generate an electrical stimulus at a high frequency. The circuit is configured to provide electrical stimulus over a period of time sufficient to depolarize the cardiac cells. An electrode arrangement is configured and arranged to deliver the high frequency electrical stimulus to cardiac cells and depolarize the cardiac cells.

Abstract: Techniques for enhanced microfluidic impedance spectroscopy include causing a core fluid to flow into a channel between two sheath flows of one or more sheath fluids different from the core fluid. Flow in the channel is laminar. A dielectric constant of a fluid constituting either sheath flow is much less than a dielectric constant of the core fluid. Electrical impedance is measured in the channel between at least a first pair of electrodes. In some embodiments, enhanced optical measurements include causing a core fluid to flow into a channel between two sheath flows of one or more sheath fluids different from the core fluid. An optical index of refraction of a fluid constituting either sheath flow is much less than an optical index of refraction of the core fluid. An optical property is measured in the channel.

Abstract: Embodiments of the present invention provide noninvasive methods and systems of determining and monitoring an individual's respiration pattern, respiration rate, other cardio-respiratory parameters or variations thereof.

Abstract: A method for making a plurality of low-cost microelectrode arrays (MEAs) on one substrate utilizing certain unmodified printed circuit board (PCB) fabrication processes and selected materials. In some embodiments, a MEA device is composed of a thin polymer substrate containing patterned conductive traces. Coverlays on both sides of the substrate insulate the conductive traces and defines the electrodes. Preferably, flexible PCB technology is utilized to simultaneously define the microelectrode arrays. In an embodiment, the sensor is an integrated temperature sensor/heater in which the MEA device operates to record extracellular electrical signals from electrically active cell cultures. The present invention enables economical and efficient mass production of MEA devices, making them particularly suitable for disposable applications such as drug discovery, biosensors, etc.

Abstract: A method for making a plurality of low-cost microelectrode arrays (MEAs) on one substrate utilizing certain unmodified printed circuit board (PCB) fabrication processes and selected materials. In some embodiments, a MEA device is composed of a thin polymer substrate containing patterned conductive traces. Coverlays on both sides of the substrate insulate the conductive traces and defines the electrodes. Preferably, flexible PCB technology is utilized to simultaneously define the microelectrode arrays. In an embodiment, the sensor is an integrated temperature sensor/heater in which the MEA device operates to record extracellular electrical signals from electrically active cell cultures. The present invention enables economical and efficient mass production of MEA devices, making them particularly suitable for disposable applications such as drug discovery, biosensors, etc.