A surgical access assembly comprises a trocar and a surgical instrument. The trocar comprises a housing and an access tube extending distally from the housing. The housing comprises a hollow light emitter. The housing and the access tube define a lumen extending through the housing and the access tube. The hollow light emitter is configured to project light in the lumen. The surgical instrument comprises an end effector and a shaft extending proximally from the end effector. The shaft comprises an optical receiver positioned within reach of the light from the hollow light emitter. The shaft further comprises a light guide extending from the optical receiver along at least a portion of the shaft toward the end effector.

A portable system may measure and monitor physiological parameters of a human being by analysis of a body fluid. The system may include a consumable part in the form of a measuring patch to be adhered to the skin. The measuring patch may be equipped with a sensor system configured to provide measured values of physiological parameters by body fluid analysis. The system may further include a body-worn readout unit suitable for continuous use, which is configured to read out and monitor the measured values supplied by the measuring patch. The readout unit is further configured to be worn over the measuring patch adhered to the skin and to read out and monitor the measured values in this position.

A surgical robotic visualization system comprises a first robotic arm, a second robotic arm, a photoacoustic receiver coupled to the first robotic arm, an emitter assembly coupled to the second robotic arm, and a control circuit. The control circuit is configured to cause the emitter assembly to emit electromagnetic radiation toward an anatomical structure at a plurality of wavelengths capable of penetrating the anatomical structure and reaching an embedded structure located below a surface of the anatomical structure, receive an input of the photoacoustic receiver indicative of an acoustic response signal of the embedded structure, and detect the embedded structure based on the input from the photoacoustic receiver.

A CPAP device for delivering pressurized, humidified breathable gas for a patient includes a flow generator configured to pressurize a flow of breathable gas. The flow generator includes an air outlet and a removable water container configured to humidify the pressurized breathable gas received from the flow generator. The water container includes an air inlet and an air outlet. The CPAP device further includes a first elastomeric face seal configured to sealingly abut against a substantially flat portion of the water container surrounding the water container air inlet, the first elastomeric face seal being located at an intermediate position between the flow generator air outlet and the water container air inlet when the water container is placed into position to pneumatically communicate with the flow generator. In addition, the CPAP device includes a second elastomeric face seal, a portion of which is configured to sealingly abut against a substantially flat external surface portion of the water container surrounding the water container air outlet.

Disclosed herein are monitoring systems and sensors for physiological measurements. The sensors can be multi-element piezo sensors capable of generating multiple electrical signals, whereby the monitoring systems can receive the multiple electrical signals to analyze the user's vital signs along multiple regions of the user's body. In some examples, the piezo sensor can include one or more corrugations, such as peaks and valleys, to create localized regions with increased mechanical response to force. The sensitivity and resolution of the piezo sensor can be enhanced by further locating electrode sections at the corrugations, where the electrode sections can be electrically isolated and independently operable from other electrode sections. Traces electrically connecting an electrode section to, e.g., an off-panel controller can be routed over and/or around other electrode sections by including an insulator to electrically insulate from the other electrode sections, or by using vias to route through one or more layers.

The present application provides a personal hand-held monitor for the measurement of a subject's blood pressure and, optionally, one or more other vital signs, comprising a housing located on a personal hand-held computing device or a hand-held component of a computing system; a blood flow occlusion means located in the housing; a pressure sensor adapted to provide an electrical signal indicative of the pressure applied; a means for detecting the flow of blood in the body part of the subject when pressure is applied; and means for receiving electrical signals from the pressure sensor and the blood flow detecting means and for transmitting electrical signals indicative of the pressure and blood flow to the processor of the personal hand-held computing device or the computing system, wherein the processor of the personal hand-held computing device or computing system provide at least a measurement of the blood pressure of a subject. The processor is further adapted to carry out a process to measure a diastolic blood pressure value and a systolic blood pressure value.

Impedance devices with integrated circuit modules and method of using the same to obtain luminal organ information. In one embodiment, a device comprises an elongated body for at least partial insertion into a mammalian luminal organ and having a first conductor extending therethrough, a proximal electrical unit connected to the elongated body to deliver power along the first conductor, and a sensor substrate located at or near a distal end of the elongated body and comprising a circuit module operable and/or configured to direct the sizing portion to obtain sizing data and the pressure sensor to obtain pressure data, and facilitate transmission of the sizing data and/or the pressure data to the proximal electrical unit.

The invention relates to a mobile medical device, in particular a mobile C-arm X-ray device, comprising a device trolley which can be driven in at least two movement modes in a motor-supported manner, having at least one gripping element, which is provided for gripping by means of at least one human hand of an operator in order to move the device, and additionally having at least one sensor, which is arranged on the gripping element or in the direct vicinity thereof and is designed to detect measurement data that characterizes the type and/or location of the grip by means of the at least one human hand, an evaluating unit, which is designed to evaluate the measurement data with respect to the type and/or location of the grip and assign a movement mode of the device trolley, and a control unit for automatically setting the evaluated movement mode of the device trolley.

The present invention relates to systems, methods and algorithms for determination of heart pump function and their use in livings subject are described. The invention further relates to complementary parts of such systems that work best in combination. Medical catheters, sheaths and shafts are disclosed that carry an arrangement of integrated digital sensor systems-on-chip (SoC) in the portion thereof residing inside the body. These devices combine at their portion that resides inside the body, the complete chain of signal transduction, signal analog-to-digital conversion and digital signal transmission, and allow to acquire single and multiple physical entities in a single setup. In specific instances the devices integrate wireless data transfer functionality, and in specific instances they integrate wireless energy harvesting for battery-free functionality. The present invention further describes complementary monitor systems that are suited for reception, processing and analysis of data acquired by such catheters/sheaths/shafts to yield a robust assessment of cardiac performance. Moreover, the present invention relates to innovations which render such systems applicable to patients with and without cardiac assist devices.

A neuromuscular, physiological, biomechanical, or musculoskeletal activity monitoring system for a subject is provided. The system includes a wearable inertial measurement unit including at least one accelerometer and/or at least one gyroscope. The system also includes a controller in communication with an output component. The controller is configured to: receive and process information from the inertial measurement unit representative of one or more physical actions performed by the subject; generate an inertial data set for the one or more physical actions based on the received and processed information; compare the generated inertial data set to reference data stored on computer readable memory in communication with the controller; and cause the output component to provide feedback including predictive injury information. The predictive injury information is based, at least in part, on the comparison between the generated data set and the reference data.