Featured are devices (e.g., peripheral devices) and systems that interact with a device having sensors (e.g., a wearable device or device configured for use with a piece of equipment, such as a vehicle) to receive and process data (e.g., physiological data) from the sensors. Also featured are computer implemented methods including software (e.g., an application) for receiving and processing data by the peripheral device. An application that communicates with the device (e.g., wearable device or equipment device) and sensor information processed by the application or a device running or accessing the application provides situational awareness for users in adverse conditions, such as during combat or wartime. The wearable device may include one or more inflatable bladders configured to apply pressure to a wound site for treatment.

A tourniquet for occluding blood flow to a limb is improved by the addition of proximal and distal strain gauges. The proximal strain gauge may be monitored under conditions of total blood flow occlusion for time-varying signals indicative of volumetric limb changes arising from the subject's blood flow in the proximal section of the limb. Upon a change in limb occlusion pressure, the signals from the proximal strain gauge can be observed to change also, and the working pressure in the tourniquet can be adjusted safely in response. Automated control systems may further use inputs from a distal strain gauge and/or from a sensor that detects induced pressure changes within the tourniquet to improve the control of the tourniquet working pressure during operation to avoid unwanted blood flow past the tourniquet.

Monitoring vital parameters of a wearer of a compression garment by analyzing a pressure signal waveform indicative of a fluid pressure in an inflatable and deflatable bladder of the compression garment. Analyzing the pressure signal waveform for an oscillating amplitude as a function of time and/or a representation of a pulse of the wearer provides an indication of blood pressure of the wearer.

Disclosed is an intelligent femoral artery hemostasis device by compression, including a main body capable of automatic compression. The main body includes a compression mechanism and a pressing plate mechanism successively provided from bottom to top; a lift regulator is provided between the support column and the compression mechanism; the compression mechanism is further provided with a detector for bleeding detection; and the main body is further integrated with a power supply module, an operation module and a central processing module. This invention realizes automatic bleeding detection and automatic pressurizing, and ensures the integration and compactness of the device. The power supply module, the operation module and the central processing module are integrated in the main body, avoiding external connecting wires and making it convenient to use the device when the tourniquet works in a twining working condition.

The present invention relates to a femoral compression system (14) for applying compression against a puncture site of a vessel in a patient, and a method for applying compression with a femoral compression system. The compression system (14) comprises an inflatable compression element (15) adapted to apply a pressure against the puncture site, a tightening unit (23) adapted to extend around a part of, or the whole of, the patients body to fixate and to tighten the compression element (15) against the puncture site, a pump (16) adapted to inflate the compression element (15), a valve (17) adapted to deflate the compression element (15), a pressure transducer (18) adapted to sense the pressure within the compression element (15). The system further comprises a blood pressure pulse detector (19) adapted to sense the patient's blood pressure pulse and to generate a pulse signal in dependence thereto that is applied to a control unit (20) that is connected to the pump (16), valve (17) and pressure transducer (19), wherein the control unit (20) is adapted to control the pressure within the compression element (15) in dependence of the pulse signal, by applying control signals to said pump (16) and valve (17).

A thigh compression device and technique to control, time, delay and/or prevent excessive early venous enhancement relative to arterial enhancement and thereby improve and/or enhance MRA images, including peripheral MRA images, is disclosed. In one embodiment, the present invention uses a curved strip of material which is longer on the superior edge and shorter along the inferior edge. When wrapped around the conical shape of the thigh of a subject, for example, a human, the thigh compression device more uniformly conforms to and/or fits around the thigh, providing more even/uniform compression as well as reducing, minimizing and/or eliminating significant movement of the thigh compression device towards the knees of the subject. A snug fit on the thighs may also enable the thigh compression device to be inflated with less fluid, which is faster and less cumbersome for the operator.

There is provided a method for controlling a flow of sperms in a uterine tube of a female patient. The method comprises electrically stimulating a uterine tube wall portion by controlling an implanted stimulation device from at least one of an external control unit and an internal control unit, wherein the electrically stimulating causes contraction of the uterine tube wall portion along a length of the portion to restrict the flow of sperms in the uterine tube.

A collar sized to be worn around the neck of a human subject has at least one member that defines an arc of less than 360° and greater than 180° having a diameter, a first compressor at a first end of the arc, a second compressor at a second end of the arc and a bend angle sensor. The collar is adapted to exert an inwardly-directed force on the first and second compressors when worn. The bend angle sensor is configured and positioned to detect a bend angle of the collar, wherein the bend angle correlates to the inwardly-directed force on the first and second compressors when worn.

A smart tourniquet includes a casing having a control unit; a contact area arranged to the casing, configured to contact a patient's skin, and connected to the control unit; a cuff arranged to the casing with an inflatable bladder; an adjustable strap arranged to the cuff for securing the cuff and casing to the patient; a pump contained in the casing, connected to the bladder, and controlled by the control unit; a thermoelectric module contained in the casing, controlled by the control unit, and connected to the contact area; and at least one sensor contained in the casing for detecting blood pulse and controlled by the control unit. The control unit is configured to inflate and deflate the bladder in response to blood pulse for changing a pressure around an arm or leg and to heat the contact area for vasodilating a vein under the patient's skin for visual detection.

Single- or dual-bladder devices for automated delivery of remote ischemic conditioning treatment via partial limb occlusion involve various methods of operating the cuff in which partial or full limb occlusion is achieved during the periods of cuff inflation. Achieving clinical benefits of remote ischemic conditioning without extended cessation of limb blood flow are advantageous due to lower required cuff pressure and reduced risk of clot formation in the limb vasculature.