Optical ankle-brachial index (ABI) and blood pressure measurement systems and methods are disclosed. The blood pressure measurement system and method includes a brachial artery pressure cuff and a reflectance optical pulse detector attached to the pressure cuff. The ABI measurement system and method includes a brachial artery pressure cuff, a first reflectance optical pulse detector attached to the brachial artery pressure cuff, a dorsalis pedis artery pressure cuff or a posterior tibial artery pressure cuff; and a second reflectance optical pulse detector attached to the dorsalis pedis artery pressure cuff or the posterior tibial artery pressure cuff. A computer may also be included in the above systems and methods to detect optical pulses from the cuffs and control the inflation and deflation of the cuffs in order to determine blood pressure and/or ABI.

An electronic device includes a translucent layer that forms a portion of an exterior of the electronic device, an opaque material positioned on the translucent layer that defines micro-perforations, and a processing unit operable to determine information about a user via the translucent layer. The processing unit may be operable to determine the information by transmitting optical energy through a first set of the micro-perforations into a body part of the user, receiving a reflected portion of the optical energy from the body part of the user through a second set of the micro-perforations, and analyzing the reflected portion of the optical energy.

The present invention relates generally to systems and methods for measuring an analyte in a host. More particularly, the present invention relates to systems and methods for transcutaneous measurement of glucose in a host.

An apparatus for evaluating the tongue strength and coordination of a subject includes an intermediate device such as a lever which is pivotably attached to a coupling device and extends into a cavity of a nipple element. The lever is detached from the nipple and pivotable in response to deformation of the nipple element by a tongue force exerted on the nipple element by a subject during a suck-swallow-breathe sequence. The coupling device includes a sensing device to wirelessly transmit sensor outputs to a mobile device paired to the sensing device. The sensing device includes at least one sealed chamber defined by a membrane and a sensor. In one example, a first membrane and sensor senses pressure change in a fluid in the apparatus, and a second membrane and sensor is actuated by the intermediate device to sense deformation of the nipple element. A method using the apparatus is provided.

Disclosed are devices and methods for non-invasively measuring arterial stiffness using pulse wave analysis of photoplethysmogram data. In some implementations, wearable biometric monitoring devices provided herein for measuring arterial stiffness have the ability to automatically and intelligently obtain PPG data under suitable conditions while the user is engaged in activities or exercises. In some implementations, wearable biometric monitoring devices are provided herein with the ability to remove PPG data variance caused by factors unrelated to arterial stiffness. In some implementations, wearable biometric monitoring devices have the ability to perform PWA while accounting for the user's activities, conditions, or status.

A baby bottle device (100) is provided which comprises at least one 100 movement sensor (140, 150) for detecting a movement of the baby bottle device (100). The movement data from the movement sensor (140, 150) is analyzed in an analyzer (200) to perform a suck-swallow-breathe analysis during a drinking phase of the baby based on the movement data from the movement sensor (140, 150). Thus, a drinking behavior of a baby can be efficiently analyzed.

A sensor cable support device is described. The sensor cable support device can be used to implemented in wearable monitoring device to support a proximal portion of a sensor cable and electrically connect the proximal portion with a sensing circuitry. A distal portion of the sensor cable is insertable into a person's skin. The sensor cable support device may include a rigid body defining a pair of openings, a set legs attached to the rigid body, and a pair of electrical traces extending between the pair of openings and distal ends of a pair of legs of the set of legs. The pair of openings may be sized and configured to receive a pair of pucks that mechanically retain a sensor cable to the body and electrically connect the sensor cable with the electrical traces.

A compact handheld optical coherence tomography (OCT) spectrometer according to an embodiment of the present disclosure includes: a spectrometer optical module; a sensor board coupled to one side of the spectrometer optical module and including a sensor that converts light received from the spectrometer optical module into an electrical signal; and a connector configured to supply, to the sensor board, a control signal and a power signal received from another circuit outside the spectrometer and to transmit a signal received from the sensor board to another external circuit, and the sensor board is packaged with the spectrometer optical module, and the sensor is not indented but is formed to protrude from the surface of the sensor board, and a light receiving portion of the sensor is configured to face the inside of the packaged component and collect light from the spectrometer optical module.

Described herein are systems and methods for deploying and recording electrophysiologic signals from electrode arrays located within the dura mater of the brain. The dura matter includes layers of connective tissue, or membrane, that surround the brain and spinal cord. The present disclosure relates to an endovascular electrode system deployed within the blood vessels located between layers of the dura mater, including, for example, the middle meningeal artery and its branches.

Disclosed herein are monitoring systems and sensors for physiological measurements. The sensors can be multi-element piezo sensors capable of generating multiple electrical signals, whereby the monitoring systems can receive the multiple electrical signals to analyze the user's vital signs along multiple regions of the user's body. In some examples, the piezo sensor can include one or more corrugations, such as peaks and valleys, to create localized regions with increased mechanical response to force. The sensitivity and resolution of the piezo sensor can be enhanced by further locating electrode sections at the corrugations, where the electrode sections can be electrically isolated and independently operable from other electrode sections. Traces electrically connecting an electrode section to, e.g., an off-panel controller can be routed over and/or around other electrode sections by including an insulator to electrically insulate from the other electrode sections, or by using vias to route through one or more layers.