A spirometer attachment includes a housing. A securement on the housing removably secures the housing to a spirometer. A measuring device within the housing is to collect breath data from the spirometer. At least one LED is to emit light away from the housing based on the collected breath data. A circuit board or controller within the housing is to control the light emitted by the LED based on the breath data.

ECG electrode assemblies are disclosed which include an adhesive-backed patch incorporating an ECG electrode and an adhesive-backed cover configured to cover and surround a lead wire clip attached to a contact of the ECG electrode. ECG electrode assemblies comprising said adhesive-backed patch and said adhesive-backed cover secure the connection between the lead and the electrode and effectively reduce the number of telemetry disruptions due to leads failure. ECG electrode assemblies can also provide water resistance to allow for patient showering while hospitalized on telemetry monitoring.

A regional oximetry pod drives optical emitters on regional oximetry sensors and receives the corresponding detector signals in response. The sensor pod has a dual sensor connector configured to physically attach and electrically connect one or two regional oximetry sensors. The pod housing has a first housing end and a second housing end. The dual sensor connector is disposed proximate the first housing end. The housing at least partially encloses the dual sensor connector. A monitor connector is disposed proximate a second housing end. An analog board is disposed within the pod housing and is in communications with the dual sensor connector. A digital board is disposed within the pod housing in communications with the monitor connector.

The present invention discloses a holder carrying thereon a sensor to measure a physiological signal of an analyte in a biological fluid, wherein the sensor has a signal detection end and a signal output end, and the holder includes an implantation hole being a channel for implanting the sensor and containing a part of the sensor, a waterproof seal disposed above the implantation hole, and an elastic divider disposed in the implantation hole to separate the implantation hole and covering all over a cross-sectional area of the implantation hole.

A mobile device includes a connector, an audio generator, a biological signal processor, a switch element, and a controller. The switch element has a first terminal and a second terminal. The first terminal of the switch element is coupled to the connector, and the second terminal of the switch element is selectively coupled to either the audio generator or the biological signal processor according to a control signal. The controller is coupled to the audio generator and the biological signal processor, and is configured to generate the control signal.

A multiparameter lead set, method of use, and method of assembling or re-processing a multiparameter lead set. The multiparameter lead set includes a first patient lead for monitoring a first health indicator of a patient. The first patient lead further includes a first lead interconnection feature. The lead set further includes a second patient lead for monitoring a second health indicator of the patient. The second patient lead further include a second lead interconnection feature. The second lead interconnection feature and the first lead interconnection feature are interconnectable to removably connect a first portion of the first patient lead to a second portion of the second patient lead.

The present invention provides a uterus OCT catheter, comprising: a catheter body; the catheter body comprises an outer sleeve, an OCT imaging catheter and a Luer connector; the outer sleeve is provided with an exit window; the reflecting surface of the reflecting prism in the OCT imaging catheter faces the exit window. The present invention further provides a uterus OCT equipment with pull-back function, comprising a pull-back device and the catheter body, the pull-back device comprises a first housing, a driving connector, a fixing sleeve and a catheter fixing tube. The invention adopts the way that the outer sleeve wraps the OCT imaging catheter to increase the overall strength and diameter; a pull-back device is adopted, the pull-back process is stable and in uniform speed, and can effectively prevent complications during human operation and damage to human tissue during pull-back process.

The present invention relates to an adapter (100) for coupling with a medical coupling unit (1) and a medical sensor (2) that are configured for being coupled for electrical signal transmission between them. The adapter comprises an adapter coupling unit (101) configured to fit with a coupling-side connector (10) of the medical coupling unit (1) and including a plurality of coupling-side electrical contacts (111, 113) for contacting a plurality of electrical contacts (11, 13) of the coupling-side connector (10) and a sensor-side connector (120) configured to fit with a sensor-side connector (20) of the medical sensor (2) and including a plurality of sensor-side electrical contacts (121, 123) for contacting a plurality of electrical contacts (21, 23) of the sensor-side connector (20), allowing the adapter coupling unit (101) to be mechanically coupled between the medical coupling unit (1) and the medical sensor (2). Further, the adapter comprises one or more wires (102) fixedly connected to the adapter coupling unit for coupling one or more sensor elements (225) with the adapter coupling unit for electrical signal transmission from the one or more sensor elements to the adapter coupling unit, and connection circuitry (103) within the adapter coupling unit (101) for connecting said sensor-side electrical contacts (121, 123) and said one or more wires (102) with said coupling-side electrical contacts (111, 113) allowing signal transmission from the medical sensor (2) and one or more sensor elements (225) coupled to the adapter coupling unit (101) to the medical coupling unit (1).

A regional oximetry system has a display and at least one processor causing a plurality of views to be displayed on the display, each configured to occupy at least a portion of the display. The views are adapted to present data responsive to at least one physiological signal. A first sensor port is configured to receive at least a first physiological signal representative of a regional tissue oxygenation level, and a second sensor port is configured to receive at least a second physiological signal representative of an arterial oxygen saturation level. One view presents a first trend graph of the first physiological signal and a second trend graph of the second physiological signal. An area between the first trend graph and the second trend graph can include a differential analysis of regional-to-central oxygen saturation.

Various methods and systems are provided for a deployable invasive device. In one example, the deployable invasive device has a transducer including a plurality of transducer arrays spaced apart by a shape memory material. The shape memory material is configured to transition between a first configuration with a first set of dimensions and a second configuration with a second, larger set of dimensions.