Abstract: A surgical device is provided that includes a jaw portion, having a first jaw in opposed correspondence with a second jaw, the second jaw including a surgical member. The surgical device may include a shaft portion coupled to a proximal end of the jaw portion and at least one motor configured to rotate the jaw portion relative to the shaft portion, to move the jaw portion relative to the shaft portion, move the first jaw relative to the second jaw and move the surgical member within the second jaw. The surgical member may be prevented from moving within the second jaw unless the first jaw is in a closed position relative to the second jaw. Advantageously, the surgical member may be, e.g., a cutting element and/or a stapling element, disposed within one of the jaws.

Abstract: A system and method for forming a staple pocket, e.g., on the anvil portion of a surgical stapler device. A laser-machining system may include a laser-emitting device that is configured to emit a laser beam or beams for forming staple pockets on the anvil of a surgical stapler. The staple pockets of an anvil may be formed successively or simultaneously. The anvil of the surgical stapler is mounted in a mounting mechanism so as to control its movement, and the laser-emitting device is controlled by a control module, which may control any aspect of the laser-machining operation, e.g., the intensity of the laser beam, the movement of the laser-emitting device relative to the anvil, etc. The control module may be a processor that includes software that provides instructions for the operation of the control module, and may be programmable by a user for inputting parameters, e.g., shape, arrangement, etc., corresponding to the staple pockets.

Abstract: A shaft being, e.g., flexible, that includes an elongated outer sheath, at least one drive shaft disposed within the outer sheath and a ring non-rotatably mounted on the at least one rotatable drive shaft and at least one light source mounted within the shaft, such that, upon rotation of the at least one rotatable drive shaft, the ring alternately blocks and allows light from the light source to be detected. The shaft may also include a moisture sensor disposed within the outer sheath of the shaft and configured to detect moisture within the outer sheath. The shaft may include couplings that connect a distal end of the outer sheath to a surgical attachment and a proximal end of the outer sheath to a remote power console.

Abstract: A surgical imaging device includes at least one light source for illuminating an object, at least two image sensors configured to generate image data corresponding to the object in the form of an image frame, and a video processor configured to receive from each image sensor the image data corresponding to the image frames and to process the image data so as to generate a composite image. The video processor may be configured to normalize, stabilize, orient and/or stitch the image data received from each image sensor so as to generate the composite image. Preferably, the video processor stitches the image data received from each image sensor by processing a portion of image data received from one image sensor that overlaps with a portion of image data received from another image sensor. Alternatively, the surgical device may be, e.g., a circular stapler, that includes a first part, e.g., a DLU portion, having an image sensor a second part, e.g., an anvil portion, that is moveable relative to the first part.

Abstract: Uterine activity is sensed by passing light through the patient's abdominal wall and detecting the light reflected from abdominal tissues. The intensity of the reflected light varies with the state of contraction of the patient's uterus. The use of light for monitoring uterine activity avoids the problems of size, fixation, and measurement accuracy exhibited by the conventional tocodynamometer technique.

Abstract: A wireless patient monitoring apparatus uses low frequency inductive coupling to couple signals from a transducer to monitoring and analysis instrumentation. Signals indicative of physiological functions are modulated onto a low frequency carrier and output from a self-contained portable transducer assembly via a transducer coil. A corresponding receiver coil receives the signals by electromagnetic induction. The received signals are demodulated and processed by instrumentation coupled to the receiver coil. A mattress pad containing the receiver coil is also disclosed. In a fetal monitor implementation, both wireless ultrasound and tocodynamometer transducers are provided.

Abstract: Uterine activity is sensed by passing light through the patient's abdominal wall and detecting the light reflected from abdominal tissues. The intensity of the reflected light varies with the state of contraction of the patient's uterus. The use of light for monitoring uterine activity avoids the problems of size, fixation, and measurement accuracy exhibited by the conventional tocodynamometer technique.

Abstract: A wireless patient monitoring apparatus uses an optical signal to transmit information from a transducer to a photodetector of an optical receiver. The photodetector converts the optical signal to an electrical signal which is then provided to monitoring and analysis instrumentation. Signals which are indicative of physiological functions are modulated onto a carrier, and the resulting modulated signal is provided, in turn, to the optical source, which may be a light-emitting diode (LED) which emits in the infrared band. A self-contained portable transducer assembly which is strapped or otherwise secured to the patient may house the transducer, modulator and optical source, and is adapted for underwater use. Optionally, the optical source can be positioned remote from the assembly. In a fetal monitor implementation, both wireless ultrasound and tocodynamometer transducers are provided.

Abstract: A method of exposing a patient's extremity to light of two wavelengths and detecting the absorbance of the extremity at each of the wavelengths is provided comprising the steps of: (a) generating pulses of light having the first wavelength at a first pulse frequency; (b) generating pulses of light having the second wavelength at a second pulse frequency; (c) exposing the extremity to the first and second pulses; (d) producing an electrical signal corresponding to the total amount of light transmitted through the extremity; (e) separating the electrical signal produced in step (d) into a first amplitude-modulated electrical signal at the first pulse frequency and a second amplitude-modulated electrical signal at the second pulse frequency; and (f) demodulating the first and second amplitude-modulated electrical signals to produce a first signal corresponding to the amount of light transmitted through the extremity at the first wavelength and a second signal corresponding to the amount of light transmitted thro

Abstract: A blood pressure system which cycles through an inflation cycle and a deflation cycle during which systolic and diastolic blood pressure in a patient is automatically measured. The blood pressure system basically comprises an inflatable pressure cuff system for accomplishing occlusion and the subsequent opening of an artery in a patient being monitored, and an electrical system for increasing and decreasing the pressure in the cuff under servo loop control and for displaying the systolic and diastolic measurements. A pressure transducer produces an electrical signal indicative of the actual pressure in the cuff. A solenoid valve permits selective pressure decrease during the deflation cycle. A rotary vane compression pump provides pressure increase during the inflation cycle. During the inflation cycle, pressure increase in the cuff is accomplished by a servo control loop comprising the transducer, the pump, and an inflate/deflate controller.

Abstract: A blood pressure system which cycles through an inflation cycle and a deflation cycle during which systolic and diastolic pressure in a patient is automatically measured. The blood pressure system basically comprises a pressure cuff system for accomplishing occlusion and the subsequent opening of an artery in a patient being monitored, and an electrical system for controlling the pressure cuff system and for displaying the systolic and diastolic measurements. In order to automatically carry out the inflation and deflation cycle of the blood pressure system, a dedicated controller is employed. A microphone, contained within the blood pressure cuff produces an electrical signal indicative of pulsatile activity within the artery. A K-sound detector receives the signal and relays information to the dedicated controller. In the blood pressure system, K-sound detection continually takes place during both the inflation and deflation cycles of the instrument.

Abstract: A telemetry system and associated antenna for monitoring the physiological condition of hospitalized patients. The antenna consists of two separate sections. The first is the antenna pre-amp section and contains passive receiving antenna elements integrated with a transistor amplifier. The second section provides the required circuitry that allows cascading of additional active antennas. Monitoring a number of patients may be accomplished from a receiver located in a central location. The antennas are small for suitability within a hospital environment, yet offer superior signal/noise performance.