The present invention provides a compact, wearable and portable self driven rehabilitation device which is cost effective, light weight, portable, easy to use and customizable to fit as needed. It provides real-time mirroring effect for better visual feedback.

A system with plurality of smart wearable and non-wearable having embedded NFC (Near Field Communication) tags, vital health sensors and UV-C germicidal irradiation sources; a computer mobile/cloud implemented platform with an artificial intelligence or machine learning powered virtual assistant; and a central cloud server is provided for prevention of spread of pathogens and for monitoring and/prediction of infection and timely intervention assistance for better health outcomes to the user, taking into account the underlying conditions of the user. The system includes a plurality of body wearables including, but not limited to, a hand glove, a footwear, a vest, a full body suit, a face mask, a footwear cover or a smart portables and at least one non-wearable portable smart device, and all of them with re-programmable NFC tags and UVGI source embedded within them, to dis-infect any surface the user desire, and to avoid touching any surfaces, and the same—each device of which having a plethora of various body health and viral monitoring sensors, embedded within them to transmit and upload data to mobile/cloud platform, to predict probability of infection and take necessary actions to provide better personalized health outcomes.

An Internet of Thing (IoT) device includes a camera coupled to a processor; and a wireless transceiver coupled to the processor. Blockchain smart contracts can be used with the device to facilitate secure operation.

The smart wearable with embedded NFC (Near Field Communication) tags, vital health sensors and UV-C germicidal irradiation sources is provided for Prevention of spread of pathogens. The smart wearables is any of a hand glove, a footwear, a vest, a full body suit, a face mask, a footwear cover or a smart portables where all the smart wearables includes a plurality of re-programmable tags to facilitate touch less activities, and a plurality of body health monitoring sensors to monitor health of the wearer in real time for early warning health mechanisms, an Ultraviolet Germicidal Irradiation (UVGI) source to disinfect the surfaces coming in contact with the smart wearables with maximum efficacy and spread prevention. Further, the inner layer of the smart wearables which makes contact with the skin of the wearer is made of a Celliant synthetic polymer fabric material that traps the body's infrared energy and cycle it back to improve oxygenation and resolve minor aches and pains.

A health care management system for geospatial biosurveillance including a bioimpedance device. The health care management system provides real time data and analysis of an individual's physiological condition using bioimpedance data. The health care management system is further operable to monitor and model disease progression and remission based on physiological conditions during a pandemic event as well as modeling the treatment and remediation of long-lasting physiological symptoms and organ damage due to post-acute sequelae of SARS-CoV2 infection (PASC).

The present disclosure provides an optical palpation device for evaluating a mechanical property of a sample material. The device comprises a body having a sensing portion and a sensing layer positioned at the sensing portion of the body and having a sensing surface positioned for direct or indirect contact with a surface area of the sample material. The sensing layer is deformable and has a predetermined deformation-dependent optical property. The device further comprises a light detector positioned to detect light transmitted through at least a portion of the sensing layer. The optical palpation device is arranged such that, when the sensing surface of the sensing layer is in direct or indirect contact with the surface area of the sample material and a pressure is applied through both the sensing layer and at least a portion of the surface area of the sample material, because of the predetermined deformation or pressure-dependent optical property of the sensing layer the mechanical property of the sample material is measurable by detecting the light that transmitted through at least a portion of the sensing layer.

An article configured to warm and monitor a patient during a dialysis treatment, the article includes one or more heating elements. The article also includes one or more sensors configured to monitor a condition of the patient during the dialysis treatment. The article also includes a fabric portion configured to receive the one or more heating elements and the one or more sensors and position the one or more heating elements and the one or more sensors on the patient during treatment. The article also includes a transmitter configured to transmit information from the one or more sensors to a dialysis machine and an electrical connector configured to provide power to at least one of the one or more heating elements and the one or more sensors.

A body monitoring sensor system is described and wherein a sensor module is attachable to a thermally insulated article of warmth, such as an article of apparel, having a thermal insulation of a known clo index value and wherein the sensor system has various sensors to produce various atmospheric and body condition signals to feed a computer having a processor. The processor is programmed to perform calculations to generate a output signals indicative of the corrective action required based on the protection offered by the clo index of the thermal insulation of the article of warmth and taking into account the calculated wind chill temperature and humidity as well as the wearer person's body temperature and humidity conditions to provide warmth and comfort to the user person under the actual atmospheric conditions.

A smartphone or other mobile computer device, general purpose or specialized, wherein the smartphone device is configured to actively control the configuration of one or more bladders, compartments, chambers or internal sipes and one or more sensors located in either one or both of a sole or a removable inner sole insert of the footwear of the user and/or located in an apparatus worn or carried by the user, glued unto the user, or implanted in the user. The one or more bladders, compartments, chambers, or sipes, and one or more sensors are configured for computer control. A sole and/or a removable inner sole insert for footwear, including one or more bladders, compartments, chambers, internal sipes and sensors in the sole and/or in a removable insert; or on an insole; all being configured for control by a smartphone or other mobile computer device, general purpose or specialized.

A meridian impedance measurement device and method are provided, including: at least one set of measurement electrodes placed on the wrists or ankles, each set including six measurement electrodes in contact with six corresponding meridians; at least one reference electrode placed on the wrists or ankles, simultaneously being in contact with all the six corresponding meridians; at least one impedance measurement unit; a microprocessor; an impedance display unit; and a storage unit. During measurement, the adjustable voltage output unit delivers voltage to each pair of measurement electrode and reference electrode, the impedance measurement unit collects signals and pass the signals to the microprocessor for calculation. The whole procedure is done automatically and can be built into a wearable device.