A patient monitoring system for use in either a patch mode or a holster mode for monitoring physiological data of a patient includes a multi-mode sensor configured to continuously and/or intermittently acquire the physiological data from the patient in the least two modes and to transmit the acquired physiological data to a remote location and/or record the acquired physiological data in an internal memory, the physiological data including one or more of patient electrocardiogram (ECG) data, patient posture, patient movement, radio-frequency (RF) based physiological data, body temperature, and/or patient respiration; an attachment mechanism disposed on the multi-mode sensor, the attachment mechanism configured to removably connect the multi-mode sensor to either a holster and associated monitoring cables worn by the patient or a patch worn by the patient; at least one electrical contact disposed on the multi-mode sensor, the at least one electrical contact configured to engage a counterpart electrical contact of the holster and/or a counterpart electrical contact of the patch; and configuration circuitry disposed in the multi-mode sensor. The configuration circuitry is configured to determine when the multi-mode sensor is removably connected to the holster and cause the multi-mode sensor to acquire the physiological data in the holster mode when connected to the holster, and to determine when the multi-mode sensor is removably connected to the patch and cause the multi-mode sensor to acquire the physiological data in the patch mode when connected to the patch.

An eco-system for tracking a user's physiological parameters comprises a central sensor and at least one remote sensor in wireless communication with the central sensor, a portable device readily accessible to the user, and a cloud platform. Each sensor may be worn by the user and measure data indicative of one or more of the physiological parameters. The central sensor may receive and process the measured data from each remote sensor and processes its own measured data. The portable device comprises a receiver wirelessly receiving the processed data and instructions from the central sensor; a processor running a mobile application handling the processed data and instructions; and a transmitter transmitting the processed data. The cloud platform receives the processed data from the transmitter; analyzes the received processed data; and transmits the results of the analysis to at least one of the portable device and an authorized healthcare entity.

Systems and methods are provided for blood circulation evaluation by providing a measurement device collection in communication with a thermal exchange device comprising an appendage chamber having a thermal exchange member. The measurement device collection may measure patient information such as height, weight, temperature, pulse, and/or blood pressure, and transmit the patient information to the thermal exchange device to estimate patient blood volume based on the patient information. Blood flowing through the arteriovenous anastomosis (AVA) of the appendage may be heated or cooled at the thermal exchange member for therapeutic application of thermal energy to adjust blood viscosity in the human to alleviate symptoms associated with a number of autoimmune, circulatory, neurological, lymphatic, and endocrinal maladies. The thermal exchange device may calculate a patient circulation rating based on the estimated blood volume, thermal transfer energy over a specific time period or thermal transfer at various locations throughout the body, and a baseline circulation rating, and generate an alert if the patient circulation rating falls outside a predetermined threshold.

A noninvasive physiological sensor can include a first body portion and a second body portion coupled to each other and configured to at least partially enclose a user's finger. The sensor can further include a first probe coupled to one or more emitters and a second probe coupled to a detector. The first probe can direct light emitted from the one or more emitters toward tissue of the user's finger and the second probe can direct light attenuated through the tissue to the detector. The first and second probes can be coupled to the first and second body portions such that when the first and second body portions are rotated with respect to one another, ends of the first and second probes can be moved in a direction towards one another to compress the tissue of the user's finger.

A sensor attached to a living body includes a sensor body that outputs a signal corresponding to biological information, and a cable that is connected to a sensor body and transmits the signal. The cable has a first portion having a first flexibility and a second portion having a second flexibility lower than the first flexibility. The second flexibility enables the second portion to be bent, and is able to retain a shape of the second portion in a bent state.

The present disclosure generally relates to the field of blood glucose monitoring. A device for determining a blood glucose level includes a first light emitting unit configured to emit a first light; a second light emitting unit configured to emit a second light, wherein one of the first light and the second light is configured to be insensitive to glucose content in blood; a first light receiving unit configured to generate a first signal based on the first light; and a second light receiving unit configured to generate a second signal based on the second light.

An optical physiological sensor configured to perform high speed spectral sweep analysis of sample tissue being measured to non-invasively predict an analyte level of a patient. An emitter of the optical physiological sensor can be regulated to operate at different temperatures to emit radiation at different wavelengths. Variation in emitter drive current, duty cycle, and forward voltage can also be used to cause the emitter to emit a range of wavelengths. Informative spectral data can be obtained during the sweeping of specific wavelength regions of sample tissue.

Disclosed herein is an apparatus (10) for analyzing a material (12) comprising at least one analyte, said apparatus (10) comprising a measurement body (16) having a contact surface (14) suitable to be brought in thermal contact or pressure-transmitting contact with said material (12), an excitation radiation source configured for irradiating excitation radiation into the material (12) to be absorbed therein, and a detection light source for generating a detection light beam (22) travelling through at least a portion of said measurement body (16) or a component included in said measurement body, wherein said detection light beam is directed to be totally or partially reflected at said contact surface (14), wherein said contact surface (14) of the measurement body is curved in at least one principal direction in the area where the detection light beam (22) is reflected.

According to one embodiment, an apparatus comprising a portable monitoring device to be affixed to a user. The portable monitoring device including: 1) a set of one or more sensors to generate sensor data indicative of physical activity of a user when the portable monitoring device is affixed to the user; and 2) processing circuitry coupled with the set of sensors, to detect that the user has been sedentary for a period of time, and cause the portable monitoring device to alert the user responsive to the detection to encourage the user to move.

Aspects of the disclosure relate to pledget stimulation/recording electrode assemblies that are particularly useful for automatic periodic stimulation. Embodiments are compatible with nerve monitoring systems to provide continuous stimulation of a nerve during surgery. Disclosed embodiments include an electrode assembly having one or more electrodes rotatably supported by and positioned within a pledget substrate. The flexible pledget substrate conforms and fixates to bioelectric tissue to secure the electrode assembly in position, wrapped around the target tissue. In some embodiments, the pledget substrate includes two bodies, each including at least one electrode, the two bodies being selectively separable so that the bodies can be repositioned with respect to one another. The electrode assembly further includes a lead wire assembly including at least one insulating jacket positioned around a wire core. Optionally, the electrode assembly includes an insulating cup interconnecting the electrode and the insulating jacket.