Abstract: A device for occlusion of blood vessels and hemorrhage control, whose design it allows to control the force of application of the blood vessel that is intended to be occluded and during its placement, applies always the same force, regardless of the diameter of the blood vessel to be occluded and/or the dimensions of the tissue that surrounds it.

Abstract: An apparatus for providing deep nerve stimulation to a patient includes a housing for supporting deep nerve stimulation coils. The housing includes a wall with an outer surface for being presented toward the patient to apply the stimulation. A primary coil is supported in a primary chamber of the housing adjacent an inner surface of the wall, opposite the outer surface. Ribs are disposed between the primary coil and the inner surface and upon which the primary coil rests. The ribs define channels through which coolant can be directed to cool a bottom surface of the primary coil during use, the bottom surface of the primary coil being closest to the patient side wall. The primary coil is adapted when energized to produce a broad and deeply penetrating magnetic field capable of hitting a target area of the patient.

Abstract: An apparatus for providing deep nerve stimulation to a patient includes a housing for supporting deep nerve stimulation coils. The housing includes a wall with an outer surface for being presented toward the patient to apply the stimulation. A primary coil is supported in a primary chamber of the housing adjacent an inner surface of the wall, opposite the outer surface. Ribs are disposed between the primary coil and the inner surface and upon which the primary coil rests. The ribs define channels through which coolant can be directed to cool a bottom surface of the primary coil during use, the bottom surface of the primary coil being closest to the patient side wall. The primary coil is adapted when energized to produce a broad and deeply penetrating magnetic field capable of hitting a target area of the patient.

Abstract: Methods of using the device for conducting business transactions are also included. An impedance spectroscopy system for monitoring ischemic mucosal damage in hollow viscous organs comprises a sensor catheter and an impedance spectrometer for electrically driving the catheter to obtain a complex tissue impedance spectrum. Once the catheter is in place in one of a patient's hollow viscous organs, the impedance spectrometer obtains the complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.

Abstract: Methods of using the device for conducting business transactions are also included. An impedance spectroscopy system for monitoring ischemic mucosal damage in hollow viscous organs comprises a sensor catheter and an impedance spectrometer for electrically driving the catheter to obtain a complex tissue impedance spectrum. Once the catheter is in place in one of a patient's hollow viscous organs, the impedance spectrometer obtains the complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.

Abstract: Impedance spectroscopy has been proposed as a method of monitoring mucosal injury due to hypoperfusion and ischemia in the critically ill. The invention includes an algorithm developed to calculate the characteristic electrical values that best describe human gastric impedance measurements and simplify the information obtained with this method. A database of gastric spectra was obtained from healthy volunteers, cardiovascular surgery and critically ill patients. The gastric spectrum forms two semi circles in the complex domain, divided into low frequency (F<10 kHz) and high frequency (F>10 kHz). A fitting algorithm was developed based on the Cole model, and central characteristic parameters were calculated. The parameters were validated using the normalized mean squared error and 0.7% of the spectra were discarded.

Abstract: Alternate embodiments of an impedance spectroscopy method are disclosed for monitoring ischemic mucosal damage in hollow viscous organs. In each embodiment, a sensor catheter is placed inside a patient's hollow viscous organ. Afterwards, the catheter is electrically driven to obtain a complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.

Abstract: A vaporizer and cartridge system are disclosed. The vaporizer may be considered a universal vaporizer in that the vaporizer may use several different liquid anesthetic materials rather than just one. The cartridges may be single-use cartridges that are disposed after use rather than refilled by an end user. The cartridges may have one or more memory devices within the cartridge so that information about the cartridge may be communicated to the vaporizer such as the type of liquid anesthetic material carried by this cartridge. The vaporizer/cartridge system may be implemented to allow the vaporizer to update information in the cartridge memory such as the amount of liquid anesthetic material that was consumed during a particular session of use of the cartridge. The vaporizer may maintain a virtual logbook with information about the operation of the vaporizer.

Abstract: A device for locating an epidural space. The device includes a connector for forming a hermetically sealed connection with a needle. An air vessel is formed by an air tank, a diaphragm, and a space in the needle when the needle is attached to the connector. The device includes a pressure sensor configured to detect the air pressure in the air vessel. An actuator is coupled to a switch and positioned adjacent to the diaphragm to compress the diaphragm when the switch is actuated by a user causing a reduction in volume in the air vessel. A circuit coupled to the pressure sensor and to an alarm detects a signal indicative of the air pressure sensed by the pressure sensor. The circuit compares the signal to a threshold and outputs a first state to the alarm when the pressure is above the threshold, and outputs a second state to the alarm when the pressure falls below the threshold.

Abstract: A pneumatic ventricular assist device (VAD) is disclosed for use in any circulatory support application including RVAD, LAVD, or BIVAD, trans-operative, short-term or long-term, tethered implantable or extracorporeal. In the preferred embodiment, the VAD consists of a soft contoured pump shell and a disposable pumping unit, which includes: a pump sac; an inlet and an outlet (a.k.a. discharge) with one-way valves; and tubing connectors. The valves comprise a cantilevered pair of closely adjacent thin ledges, nicknamed “valve leaflets,” that resemble needle-nose pliers. The valve leaflets permit a one-way flow of blood between them, as an opposite flow pinches the distal ends of leaflets together, thereby closing off the channel between them. This design is specially designed to allow continuous and fluid movement of blood (in one direction) while limiting blood-contacting surfaces.

Abstract: A driver for a pneumatic ventricular assist device (VAD) is powered by pressurized air, oxygen or any other gas commonly available in hospital rooms, intensive care units and operating rooms. The driver can provide both blood-ejecting pressure (systole) and blood-filling vacuum (diastole) to the VAD. The driver is controlled by a computer/digital controller by means of pressure and volume sensors, and electromechanical valves. Ventricular pumping is performed by a single spring-loaded piston or bellows. The computer can actively regulate maximum systolic ventricular pressure, maximum diastolic vacuum, cycling rate and/or ejection volume (depending on the operating mode). The driver is also capable of automatically and periodically venting the drive line to eliminate condensation and foul air. The absence of a motor or electrical pump make the device small, reliable, easy to handle, and less expensive.

Abstract: A spectrometer for measuring the complex impedance spectrum of tissue comprises: a multi-frequency excitation current generator; a demodulation signal generator; two identical amplification/demodulation circuits; an A/D converter; and a microprocessor for signal processing. In use, the current generator excites the tissue sample and a series-connected reference impedance. The voltages generated in the tissue and reference are measured, demodulated, and digitized in parallel using the demodulation signal generator, the two amplification/demodulation circuits, and the A/D converter. Demodulation is done using the same demodulation signal generated at a frequency with a preset difference from the excitation signal, which allows measurements to be made at a low frequency independent of the excitation frequency. The microprocessor then calculates the complex impedance spectrum in relation to the reference signal.

Abstract: Alternate embodiments of an impedance spectroscopy method are disclosed for monitoring ischemic mucosal damage in hollow viscous organs. In each embodiment, a sensor catheter is placed inside a patient's hollow viscous organ. Afterwards, the catheter is electrically driven to obtain a complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.

Abstract: An impedance spectroscopy system for monitoring ischemic mucosal damage in hollow viscous organs comprises a sensor catheter and an impedance spectrometer for electrically driving the catheter to obtain a complex tissue impedance spectrum. Once the catheter is in place in one of a patient's hollow viscous organs, the impedance spectrometer obtains the complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.

Abstract: A pneumatic ventricular assist device is designed for use in any circulatory support application including RVAD, LAVD, or BIVAD, trans-operative, short-term or long-term, tethered implantable or extracorporeal. It consists of a soft contoured pumping shell and a disposable pumping unit, which includes a pump sac, two one-way valves, and tubing connectors. The pumping unit is specially designed to allow continuous and fluid movement of blood and to limit blood-contacting surfaces, and is made of a supple and elastic material such as silicone. The components can be inexpensively and reliably manufactured by injection molding. Also, the pumping shell and pumping unit include complementary features that quickly and securely hold the pumping unit, and any attached cannulae, in place.

Abstract: A driver for a pneumatic ventricular assist device (VAD) is powered by pressurized air, oxygen or any other gas commonly available in hospital rooms, intensive care units and operating rooms. The driver can provide both blood-ejecting pressure (systole) and blood-filling vacuum (diastole) to the VAD. The driver is controlled by a computer/digital controller by means of pressure and volume sensors, and electromechanical valves. Ventricular pumping is performed by a single spring-loaded piston or bellows. The computer can actively regulate maximum systolic ventricular pressure, maximum diastolic vacuum, cycling rate and/or ejection volume (depending on the operating mode). The driver is also capable of automatically and periodically venting the drive line to eliminate condensation and foul air. The absence of a motor or electrical pump make the device small, reliable, easy to handle, and less expensive.

Abstract: An impedance spectroscopy system for monitoring ischemic mucosal damage in hollow viscous organs comprises a sensor catheter and an impedance spectrometer for electrically driving the catheter to obtain a complex tissue impedance spectrum. Once the catheter is in place in one of a patient's hollow viscous organs, the impedance spectrometer obtains the complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.

Abstract: A technique for measuring analyte concentration and a modulated aspiration condenser capable of performing this technique. The method for detecting the analyte comprises first collecting and ionizing a gas sample including the analyte in which the concentration of the analyte is high enough to completely saturate ionization process. The ion mobilities of ions contained in the ionized gas sample are determined. On the basis of the mobilities, a concentration of the analyte in the gas sample is determined. The modulated ion mobility detector comprises an ionizer ionizing a continuously flowing gas sample. A detection cell receives the ionized gas sample in which a reference plate and a collection electrode establish a time varying electric field in a direction transverse to the direction of flow of the gas sample in the detection cell. Ions contained in the gas sample are thereby deflected into the collection electrode.

Abstract: The pCO.sub.2 probe has a miniaturized glass bulb pH sensor concentrically arranged in a flexible, noncollapsible hollow tube. A silicone end cap is expanded in a freon solvent and placed over the end of the tube while the freon evaporates, returning the end cap to its normal contracted size where it forms a tight elastic fit. The pH sensor includes an internal electrode and an outer electrode is concentrically wrapped about the glass bulb so the electrodes are in close proximity. The glass bulb and the chamber defined by the tube walls and silicone membrane are both filled with suitable electrolytes of sufficient volume to minimize air bubbles. Without air bubbles, the electrodes remain emersed in the respective electrolytes regardless of the physical orientation of the probe.

Abstract: An impedance spectroscopy system for monitoring ischemic mucosal damage in hollow viscous organs comprises a sensor catheter and an impedance spectrometer for electrically driving the catheter to obtain a complex tissue impedance spectrum. Once the catheter is in place in one of a patient's hollow viscous organs, the impedance spectrometer obtains the complex impedance spectrum by causing two electrodes in the tip of the catheter to inject a current into the mucosal tissue at different frequencies, while two other electrodes measure the resulting voltages. A pattern recognition system is then used to analyze the complex impedance spectrum and to quantify the severity of the mucosal injury. Alternatively, the complex impedance spectrum can be appropriately plotted against the spectrum of normal tissue, allowing for a visual comparison by trained personnel.