In some examples, a system includes a memory; and one or more processors in communication with the memory. The one or more processors are configured to: receive, from a user device, a user input including a request to initiate a physiological data collection procedure; cause the user device to display a first interactive page including one or more instructions for preparing for the physiological data collection procedure; and receive, from the user device, a user input including a request to start the physiological data collection procedure. Additionally, the one or more processors are configured to cause the user device to display a second interactive page including a set of icons, wherein each icon of the set of icons corresponds to a sensor of a set of sensors on a wearable device of the patient.

A patient monitoring sensor having a communication interface, through which the patient monitoring sensor can communicate with a monitor is provided. The patient monitoring sensor includes a light-emitting diode (LED) communicatively coupled to the communication interface and a detector, communicatively coupled to the communication interface, capable of detecting light. The patient monitoring sensor includes hydrophobic materials provided around the light-emitting diode and the detector, wherein the hydrophobic materials reduce water absorption and prevent bacterial growth within the sensor.

In one embodiment of the present disclosure, an example system may receive a plurality of frames from at least one image sensor associated with a mobile device, at least one of the plurality of frames containing an image of a wound; display a real time video including at least a portion of the plurality of frames and a visual overlay indicating a desired position of the wound; detect, based on at least part of the plurality of frames, that the wound is in the desired position; display an indication to move the mobile device in a desired direction; receive motion data from at least one motion sensor associated with the mobile device; detect that the mobile device has moved in the desired direction; and display an additional indication on the mobile device.

An exercise suit with integrated weights includes a shirt portion and a pants portion that are constructed from a lightweight elastomeric material. A plurality of soft weights are disposed along the shirt and pants portions at locations adjacent to the major muscle groups of the suit wearer. Each of the weights can be permanently secured along the inside facing surface of the shirt and pants, and conform to the shape and movement of the suit wearer. The suit also includes a fitness monitor having a heartbeat sensor, timer and display.

A gas-enhanced electrosurgical generator. The gas-enhanced generator has a housing, a first gas control module in the housing and configured to control flow of a first gas, a second gas control module in the housing and configured to control flow of a second gas, a high frequency power module, and a controller, processor or CPU within the housing and configured to control the first gas control module, the second gas control module and the high frequency power module. The first gas and second gas may be any of CO.sub.2, argon and helium or another gas. The gas-enhanced electrosurgical generator may have a third gas control module in the housing and configured to control flow of a third gas and a third connector secured on an exterior of the housing.

Certain aspects and features of the present disclosure relate to systems and methods for accessing a surgical data structure that that includes a plurality of nodes, each associated with a procedural state, connected by a plurality of edges. The surgical data structure is used to determine a current node associated with a discrete procedural state and present relevant procedural metadata associated with the procedural state to the relevant system user. The current node is determined by receiving live surgical data, detecting a component from the live surgical data using feature extraction techniques, and identifying a current node based on the component extracted from the live surgical data. In some examples, the systems and methods retrieve a set of procedural metadata associated with the current node from the surgical data structure and transmit the set of procedural metadata to the appropriate user.

A patient communicator device provides the ability for non-verbal communication between a patient and medical personnel. The device includes a handgrip module that is held by the patient and a display unit for use by the medical personnel, with a communication link coupling the two components together. The handgrip module is formed of a deformable material and encases a power source (i.e., battery) and a pressure-activated switch. The patient squeezes the handgrip module to close the switch and transmit a signal to the display unit. For example, one squeeze may be used to indicate that everything is fine, two squeezes may be used to indicate that the patient is feeling an uncomfortable amount of pain and needs additional medication. These “squeeze” signals take the form of pulses that are passed to the display unit so that the medical personnel remains apprised of the patient's condition, allowing the patient to communicate regarding issues such as anxiety, pain or discomfort.

Embodiments of the present disclosure provide a small form factor ECG monitoring device that can acquire 3 standard ECG leads including a V-lead, does not require the use of adhesives for electrodes, and provides ECG data for a user on a near instantaneous basis. The ECG monitoring device can acquire leads I, II, and V2 (or any other V lead). The addition of a V-lead not only provides an additional channel of ECG data, but also adds another orthogonal cardiac field plane (the horizontal plane) thanks to the reference point formed by leads I and II. The ECG monitoring device may derive the augmented limb leads and subsequently generate a full 12-lead ECG. The ECG monitoring device may generate one or more diagnoses based on the full 12-lead set. The ECG monitoring device may provide an easy and non-invasive way for a person to take an ECG on the fly.

A monitor device for a medical visualisation system including a visualisation device having an image sensor configured to generate image data indicative of a view, the monitor device including a display; a graphical user interface; and a power unit including a rechargeable battery and a power connection to connect an external power supply, the monitor device being operable to receive the image data as the image data is being generated by the image sensor, wherein the monitor device displays within a first portion of the graphical user interface a live representation of the image data, and wherein the monitor device displays a battery indicator indicative of a remaining charge of the rechargeable battery, wherein the battery indicator indicates an expected remaining battery time if the visualisation device is not connected and a measured power consumption if the visualisation device is connected.

The current disclosure provides methods and systems for navigating among display panels and graphical elements of a user interface of a medical imaging system via controls of a handheld imaging device. In one embodiment, the current disclosure provides for a method comprising, in response to an operator of the medical imaging system adjusting one or more controls arranged on a control handle of a handheld ultrasound device of the medical imaging system, adjusting a focus of a user interface (UI) of the medical imaging system among a plurality of graphical control elements displayed in the UI; and in response to the operator selecting a graphical control element of the plurality of graphical control elements at a location of the focus of the UI via the one or more controls, executing an action of the medical imaging system associated with the selected graphical control element.