The present invention relates to a flexible pressure sensor using a multi-material 3D-printed microchannel mold, and a method for manufacturing the same, and more particularly, to a flexible pressure sensor having improved flexibility, sensitivity, and stability for use in a wearable device, and a method for manufacturing the same. Further, the present invention relates to a physical sensor for measuring a force applied from the outside, and more particularly, to a multi-directional physical sensor using a multi-layer microchannel array, which may sense all forces applied from the outside in three-dimensional directions such as a perpendicular direction and a parallel direction by applying the multi-layer microchannel array to a body having a three-dimensionally protruding shape.

Introduced here are pressure-mitigation systems able to mitigate the pressure applied to a human body by the surface of an object. A system can include a pressure-mitigation device with chambers whose pressure can be varied by a controller that regulates the flow of fluid produced by a pump. The controller may be deployed as part of a closed loop system that autonomously infers information related to the health of a patient based on data related to the pressure of these chambers. For example, the data may be examined to determine whether the values indicate the patient is properly situated. A notification may be presented responsive to determining that the patient is not situated on the pressure-mitigation device, the patient has been improperly situated on the pressure-mitigation device for a certain amount of time, etc. Thus, real-time feedback may be provided to those responsible for monitoring the patient.

Introduced here are pressure-mitigation systems able to mitigate the pressure applied to a human body by the surface of an object. A system can include a pressure-mitigation device with chambers whose pressure can be varied by a controller that regulates the flow of fluid produced by a pump. The controller may be deployed as part of a closed loop system that autonomously infers information related to the health of a patient based on data related to the pressure of these chambers. For example, the data may be examined to determine whether the values indicate the patient is properly situated. A notification may be presented responsive to determining that the patient is not situated on the pressure-mitigation device, the patient has been improperly situated on the pressure-mitigation device for a certain amount of time, etc. Thus, real-time feedback may be provided to those responsible for monitoring the patient.

A patient movement detector can receive inputs from position sensors, a thermal imaging camera, a video camera, and/or triangulation data. Based on one or more of these inputs, the patient movement detector can perform one or more of the following: fall prevention detection, bedsore prevention analysis, patient location detection, and patient walk test scoring. The patient movement detector can, for example, output a fall warning alarm, a bedsore warning alarm, patient location information, and walk test scores.

The present disclosure provides apparatuses and methods for measuring capacitance as an indication of susceptibility to the formation of a diabetic foot ulcer.

A system has a body with a base having a top surface with a receiving region to receive the bottom of a single foot. Among other things, the base may be in the form of an open or closed platform with a plurality of temperature sensors in communication with the top surface of the receiving region. The plurality of temperature sensors are within the receiving region and configured to activate after receipt of a stimulus applied to one or both the platform and the plurality of temperature sensors. A comparator is configured to form a temperature range as a function of the temperature value distribution and compare a percentage of the range size of the temperature distribution to a threshold value. An output produces ulcer information indicating the emergence of an ulcer or pre-ulcer when the percentage of the range size equals or exceeds the threshold value.

Systems and methods directed to the assessment of circulatory complications due to advancement of diabetes. Embodiments include an optical measurement device having a light source with one or more wavelengths and configured to illuminate an area of tissue, a detector configured to capture the light reflecting from one or more layers of the tissue at the one or more illumination wavelengths, a processor configured to compute, based on the detected signal of layer extracted circulatory data, one or more estimates of tissue vascular health, and a display or communication device (e.g., electronic data transfer) configured to store or report the tissue vascular health. In exemplary embodiments, the distribution of chromophores such as hemoglobin in different layers of skin is extracted using a combination of structured light in the visible and near-infrared regime.

A wound dressing for wireless communication with a transceiver includes a radio-frequency antenna circuit disposed on a flexible substrate, and an electrochemical moisture sensor circuit disposed on a surface of the flexible substrate. An adhesive is provided to attach the wound dressing skin of a user. The electrochemical moisture sensor is arranged between the adhesive and the flexible substrate.

Provided herein are medical devices, systems and platforms to monitor tissue properties such as oxygen saturation, temperature and degree of tissue edema for diagnosis and post-operative patient monitoring. The medical devices may be handheld or portable or may be removable patches. The medical devices utilize light of various visible and near-infrared wavelengths to interrogate a tissue where the intensities of reflected light correlate to one or more tissue property. Also provided are methods for measuring tissue properties, for detecting pressure ulcers and for remotely monitoring in real time a surgical flap on a post-operative subject via the medical devices.

A weight support device includes a sensor grid that measures pressure data while a user is on the weight support device. The weight support device is connected to a computer that analyzes the pressure data and generates a virtual figure to represent the user. Based on the pressure data, the computer determines how the user moves and adjusts relative positions of segments in the virtual figure that represent various body parts corresponding to the movements of the user. The relative positions of the segments may be determined based on a kinematic model. The virtual figure is presented on a display (e.g., in a video) to illustrate how the user moved.