Provided herein are methods and systems for monitoring a patient using a pressure-sensing device containing a pressure-sensitive region configured to selectively overlie a pressure ulcer-prone body part of the patient. In some embodiments, the pressure-sensing device includes a multilayered sensing unit containing a pressure-sensing layer to sense force and an adhesive layer configured to attach the pressure-sensing device to the body part. Also provided is a kit that includes the pressure-sensing device. The present methods, systems, and kits may fmd use in reducing the risk of pressure ulcer development in a patient.

A system for monitoring medical conditions including pressure ulcers, pressure-induced ischemia and related medical conditions comprises at least one sensor adapted to detect one or more patient characteristic including at least position, orientation, temperature, acceleration, moisture, resistance, stress, heart rate, respiration rate, and blood oxygenation, a host for processing the data received from the sensors together with historical patient data to develop an assessment of patient condition and suggested course of treatment, including either suspending or adjusting turn schedule based on various types of patient movement. The sensor can include bi-axial or tri-axial accelerometers, as well as resistive, inductive, capacitive, magnetic and other sensing devices, depending on whether the sensor is located on the patient or the support surface, and for what purpose.

Sensing devices including flexible and stretchable pressure sensors may be associated with or incorporated in garments intended to be worn against a body surface (directly or indirectly), or may be associated with other types of flexible substrates. Systems and methods for storing, communicating, processing, analyzing and displaying data collected by sensor components for remote monitoring of conditions at or near body surfaces are also disclosed. Sensors and sensor systems provide substantially real-time feedback relating to current body conditions and may provide user-specific feedback relating to gait and footwear fit and performance, facilitating improved footwear matching to individual users and improved footwear design and manufacturing, and enabling early intervention when conditions indicate intervention is appropriate.

A monitoring system and method tracks a patient's position over time and ensures that proper turning or other manipulation is done within the time prescribed. Preferably, the techniques herein continuously monitor patient position and alert medical or other personnel of the need for turning or other patient manipulation. The system may be implemented within a medical or other care facility, or within a patient's home.

A patient visualization system having a computer communicatively coupled to a pressure sensor device to periodically receive pressure sensor data experienced by a subject at locations on the pressure sensor device and having non-transitory memory for storing machine instructions that are to be executed by the computer. The machine instructions when executed by the computer implement the following functions: formatting a user interface including a body area pressure representation indicating current subject body area pressure values in response to pressure sensor data experienced by the subject at locations on the pressure sensor device and one or more body area pressure history indications configured to visualize pressure of a body area over a period of time; and displaying the user interface including the body area pressure representation and the one or more body area pressure history indications.

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 Wound Moisture and Assessment System includes a flexible coupon containing one or more electrochemical moisture sensors for measuring a moisture profile of a wound. The coupon is activated by a wireless RF scanner that provides power to the coupon for taking moisture measurements, receives the moisture measurements therefrom, and transmits the measurements to a computing device. The moisture measurements can be represented as a wound moisture map that allows a patient or caregiver to assess the health and healing progress of a wound such as an ulcer.

An all-fabric iontronic supercapacitive pressure sensing device utilizing a novel iontronic nanofabric as the sensing element is disclosed. The sensing device can be applied in several various wearable health and biomedical applications on complex body topologies. As an alternative to conventional flexible sensors, the all-fabric iontronic pressure sensor provides an ultrahigh device sensitivity with a single Pascale resolution. The device also allows rapid mechanical responses (in the milliseconds range) for high-frequency biomechanical signals, e.g., blood pressure pulses and body movements. The fabrication process for the device is low-cost highly compatible with existing industrial manufacturing processes.

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 method for detecting biometric parameters includes the steps of performing a bone graft procedure on at least one vertebra of a spine, providing at least one biometric sensor at the at least one vertebra, the sensor measuring at least one parameter selected from the group consisting of pressure, tension, shear, relative position, and vascular flow in an adjacent surrounding, and measuring the at least one biometric parameter at the vertebra with the sensor.