A charging station for providing power to a physiological monitoring device can include a charging bay and a tray. The charging bay can include a charging port configured to receive power from a power source. The tray can be positioned within and movably mounted relative to the charging bay. The tray can be further configured to secure the physiological monitoring device and move between a first position and a second position. In the first position, the tray can be spaced away from the charging port, and, in the second position, the tray can be positioned proximate the charging port, thereby allowing the physiological monitoring device to electrically connect to the charging port.

A hat (200) for a neonate (120) comprising: a central portion (201), a first side portion (202) and second side portion (203) attached to opposite sides of the central portion (201), a first fastener (208); a top flap (204) and a second fastener (211). The hat (200) has an unfolded configuration and a worn configuration. In the unfolded configuration the first and second portions (202, 203) extend away from each other from the central portion (201) in opposite directions. In the worn configuration the hat (200) wraps a neonate's head with the central portion (201) in contact with the back of the neonate's head, the first portion (202) wrapped around a first side of the neonate's head and the second portion (203) wrapped around a second side of the neonate's head. The first and second portions (202, 203) are configured to be fastened together in the worn configuration by the first fastener (208) so that the first portion (202), central portion (201) and second portion (203) together define a hat (214) rim encircling the neonate's head. The top flap (204) is configured to cover the top of the neonate's head in the worn configuration. The top flap (204) is configured to be fastened to at least one of the first, central and second portions (202, 201, 203) by the second fastener (211). The hat (200) further comprises an optical physiological sensor that comprises: a flexible circuit board, a light emitter (310) and a light detector (311); the flexible circuit board having: a sensor portion (302) to which the light emitter (310) and light detector (311) are connected; a module portion (305) including contacts (304) for electrically connecting the light emitter (310) and light detector (311) to a removable readout module (400); and an elongate lead portion (301) between the sensor portion (302) and module portion (305).

Systems and method for monitoring patient physiological data are presented herein. In one embodiment, a physiological sensor and a mobile computing device can be connected via a cable or cables, and a processing board can be connected between the sensor and the mobile computing device to conduct advanced signal processing on the data received from the sensor before the data is transmitted for display on the mobile computing device.

Systems and method for monitoring patient physiological data are presented herein. In one embodiment, a physiological sensor and a mobile computing device can be connected via a cable or cables, and a processing board can be connected between the sensor and the mobile computing device to conduct advanced signal processing on the data received from the sensor before the data is transmitted for display on the mobile computing device.

A regional oximetry sensor can have a sensor head configured to secure to skin of a user and a stem extending from the sensor head. The sensor head can include an emitter configured to transmit optical radiation into the skin and at least one detector configured to receive the optical radiation after attenuation by blood flow within the skin. The stem can be configured to transmit electrical signals from the sensor head to a cable. A plurality of notches can extend from a perimeter of the sensor head towards an interior thereof. The plurality of notches can form a plurality of independently flexible cutouts in the sensor head configured to allow for movement of at least a portion of the skin of the user underlying the sensor head when the regional oximetry sensor is in use.

A regional oximetry sensor has a sensor head attachable to a patient skin surface so as to transmit optical radiation into the skin and receive that optical radiation after attenuation by blood flow within the skin. The sensor includes windows that press into the skin to maximize optical transmission. A stem extending from the sensor head transmits electrical signals between the sensor head and an attached cable. In a peel resistant configuration, the stem is terminated interior to the sensor head and away from a sensor head edge so as to define feet along either side of the stem distal the stem termination. The stem interior termination transforms a peel load on a sensor head adhesive to less challenging tension and shear loads on the sensor head adhesive.

A regional oximetry sensor can have a sensor head configured to secure to skin of a user and a stem extending from the sensor head. The sensor head can include an emitter configured to transmit optical radiation into the skin and at least one detector configured to receive the optical radiation after attenuation by blood flow within the skin. The stem can be configured to transmit electrical signals from the sensor head to a cable. A plurality of notches can extend from a perimeter of the sensor head towards an interior thereof. The plurality of notches can form a plurality of independently flexible cutouts in the sensor head configured to allow for movement of at least a portion of the skin of the user underlying the sensor head when the regional oximetry sensor is in use.

Implementations described herein disclose a method for direct screening and monitoring of health parameters of multiple individual subjects in a remote location with easy access and periodic visits by such multiple individual subjects, where such remote location is not a healthcare facility. Furthermore, an apparatus disclosed herein enables remote health monitoring of individual subjects including children outside the confines of a healthcare facility.

A system for a wearable circuit is described. The system includes a soft substrate. The system include a first battery assembly attached to the soft substrate. The system includes a second battery assembly attached to the soft substrate. The system includes a flexible connecting device. A flexible connecting device is configured to connect a first battery assembly to a second battery assembly and stretch along a path of a soft substrate. A flexible connecting device provides an electrical connection between a first and second battery assembly while being stretched.