A method for monitoring feeding maturation in premature babies, the method including measuring an acoustic response from a baby during a selected time period to provide acoustic information; comparing the measured acoustic response against a train data set to determine an indication of a swallow event; and measuring a respiration pattern of the baby during a swallow cycle using a peak and valley model to provide respiration data, where a feeding maturity of the baby is determinable in dependence on the swallow indication and respiration data.

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 fixing indentation containing the sensor, a filler disposed in the fixing indentation to retain the sensor in the holder, and a blocking element disposed between the implantation hole and the fixing indentation to hold the sensor in the holder and restrict the filler in the fixing indentation.

An analyte detection device with intelligent identification function, includes: a transmitter; a sensor unit including a sensor base and a sensor with first parameter, and one end of the sensor inserted under the skin while the other end is installed in/on the sensor base; a bottom base; at least one physical unit with second parameter which corresponds to the first parameter arranged on the bottom base, on the sensor base or on/in the transmitter; and a detection circuit for detecting the second parameter which can be transmitted to the transmitter. Using this detection device, the transmitter can automatically identify the corresponding sensor information.

A probe includes an insertion portion insertable into a body organ, a projecting portion being exposed to an outside of a body after the insertion portion is inserted into the body organ, a device mounting area onto which an external-device coupler is removably mountable, and sensing electrodes provided on the insertion portion and the device mounting area. When the insertion portion is inserted into the body organ, the sensing electrodes detect a biosignal and become conductive with coupling electrodes of the external-device coupler mounted onto the device mounting area. The probe is an electromyograph probe that detects a biosignal measurable by an electromyograph. The insertion portion and the projecting portion of the probe may be integrated or separate from each other. Both of the insertion portion and the projecting portion or only the insertion portion may be disposable.

A water resistant biometric data logging system for an animal including a housing containing an electrophysiological data logging device and an underwater connector configured to route and waterproof at least 10 electrode cables to the electrophysiological data logging device. Further disclosed is an apparatus (e.g., headcap) for mounting electrodes onto the animal. The apparatus includes a first layer comprising a first plurality of openings or holes, the first layer comprising a foam or a sacrificial material; a second layer comprising a second plurality of openings or holes, the second layer comprising or consisting essentially of synthetic rubber; and a potted piece containing a plurality of electrode cables, wherein the electrode cables are routed from the potted piece through the first plurality of openings and the second plurality of openings or holes.

A brush electrode includes an electrode base that is connectable to an external device that is configured to generate an electrical signal or receive an electrical signal. A plurality of strand electrodes extend outward from the electrode base. A distal end of each strand electrode is configured to contact a skin surface. The strand electrodes are configured to hold an electrolyte to facilitate ionic conduction of the electrical signal to or from the skin surface.

A mounting element (8) for releasably receiving a sensor (18) for transferring and/or receiving electrical currents and/or signals relating to a body of an organism, comprising a mounting element base (9) having a receiving space (17) for receiving the sensor (18), the receiving space (17) comprising a floor (19), a wall (16) disposed on the floor (19) and disposed on at least three sides, an opening (20) formed by at least one tab (21, 22), at least one clip closure (23, 24), and further comprising a cover (10) for the mounting element base (9), an at least three-sided wall being disposed on the inner side (11) thereof, the end face (30) thereof being implemented for contacting the end face (41) of the wall (16), wherein at least one counterpart (28, 29) to the at least one clip closure (23, 24) is disposed on the wall (27), and the mounting element base (9) and the cover (10) are connected to each other by a connecting element (13) such that the cover (10) is displaceable relative to the mounting element base (9), and the mounting element base (9) and the cover (10) are therefore lockable to each other by means of the at least one clip closure (23, 24) and the at least one counterpart (28, 29) and can also be opened again.

Systems, apparatuses, and methods are described herein for a communication bus that virtualizes physiological data. Sensors and/or physiological data acquisition devices have different physical connectors which provide physiological data from a patient to a shared interface such as a display or patient monitor. A transfer interface within a mount can receive and interpret data streams associated with one or more physiological data acquisition devices. The transfer interface can prioritize the various data streams associated with the one or more physiological data acquisition devices and generate a single, combined data stream based on the assigned prioritization. The transfer interface can provide the combined data stream for transmission to a patient monitor via an interchangeable transport medium. Another transfer interface can process and/or virtualize the data streams from the physiological data acquisition devices.

In general, innovative aspects of the subject matter described in this specification can be embodied in an electrode headset and methods of using an electrode headset. An exemplary electrode headset includes a head covering, an electrode assembly, and a plurality of electrodes. The head covering has a plurality of holes and the electrode assembly includes a plurality of first connectors arranged to align with the plurality of holes of the head covering. Each electrode has a second connector configured to releasably mate with one of the first connectors of the electrode assembly through one of the plurality of holes of the head covering.

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.