A temperature therapy system and a method for temperature control for such a temperature therapy system are disclosed. According to one embodiment, a temperature therapy system has a retention mechanism and a plurality of temperature modulation systems attached to the retention mechanism, wherein each of the plurality of temperature modulation systems comprises a thermoelectric cooler. The wearable personal temperature therapy system may have a plurality of temperature sensors and a plurality of conductive flags, wherein each of the plurality of conductive flags is adhered to a respective thermoelectric cooler and a respective temperature sensor. The wearable personal temperature therapy system may have a control module electrically coupled to each of the plurality of temperature modulation systems and each of the plurality of temperature sensors, wherein each of the temperature modulation systems is controlled based on a control voltage applied to the thermoelectric cooler of the respective temperature modulation system.

Provided is a heat generator for knees capable of effectively warming a knee joint. A heat generator for knees 1 includes a heat-generating material and a pouch that is formed from a pair of sheets and that accommodates the heat-generating material inside. The pouch includes a peripheral joint portion that is formed from the pair of sheets that are joined, and that has a heat generation area inside, and a partition portion that divides the heat generation area into sections in the left-and-right direction by the pair of sheets joined in the up-and-down direction on the inner side of the peripheral joint portion.

A system and method for providing a universal wrap that can apply a thermal pack to many different regions of a patient's body. The universal wrap is provided in a standardized form. The medical provider is provided with options to modify the standardized form in order to adapt the wrap to many different applications.

A therapy wrap for treatment of at least a portion of an animate body having improved kink resistance. The therapy wrap may be selectively reinforced for improved kink resistance in only a portion of the wrap. The reinforcement may decrease the kink radius. The wrap may include a kink reducer in all or only a selected kink-prone region. The kink reducer may be selectively configured attachment points or spot welds. The therapy wrap may include a reinforcement layer of one or more discrete reinforcement members. The wrap may be formed by pre-tensioning the material layers while forming the fluid bladder and/or gas pressure bladder. The therapy wrap may be adapted to compensate for conditions that normally cause kinking of the wrap or buckling of the fluidic channels. Also disclosed are methods of manufacturing the wrap and methods of administering a temperature-controlled treatment to an anatomical body part.

Thermal management devices and associated systems and methods are disclosed herein. In some embodiments, a representative device can comprise (i) thermoelectric components (TECs) each including a first side configured to be operated at a desired temperature and a second side opposite the first side, and (ii) a heat transfer system including an array of fluid distribution networks, an inlet passage coupled to the fluid distribution networks, and an outlet passage coupled to the fluid distribution networks. In operation, a working fluid flows through the fluid distribution networks from the inlet passage to the outlet passage, and absorbs heat from the fluid distribution networks. The inlet and outlet passages can be fluidically coupled to individual fluid distribution networks such that pressure drop and/or temperature drop of the working fluid across the individual fluid distribution networks is about the same as one another.

A heating pad assembly includes a flexible heating pad having a flexible substrate forming a plurality of deflectable tabs and one or more electrically conductive heating traces routed through the plurality of deflectable tabs and configured to radiate heat therefrom in response to electrical current flowing through the one or more heating traces.

Methods, apparatuses, systems, and implementations for inductive heating of a foreign metallic implant are disclosed. A foreign metallic implant may be heated via AMF pulses to ensure that the surface of the foreign metallic implant heats in a uniform manner. As the surface temperature of the foreign metallic implant rises, acoustic signatures may be detected by acoustic sensors that may indicate that tissue may be heating to an undesirable level approaching a boiling point. Once these acoustic signatures are detected, the AMF pulses may be shut off for a time period to allow the surface temperature of the implant to cool before applying additional AMF pulses. In this manner, the surface temperature of a foreign metallic implant may be uniformly heated to a temperature adequate to treat bacterial biofilm buildup on the surface of the foreign metallic implant without damaging surrounding tissue. The AMF pulse treatment can be combined with an antibacterial/antimicrobial treatment regimen to reduce the time and/or antibacterial dosage amount needed to remove the biofilm from the metallic implant.

A temperature controllable wrap assembly that includes a wrap portion configured to be worn around a user's body part, and at least a first temperature control module positioned on the wrap portion. The first temperature control module includes a housing, a controllable temperature element, a spreader member and at least a first finger spreader pivotably attached to the spreader member. The lower surface of the spreader member is positioned to contact the user's body part. The controllable temperature element is configured to transfer thermal energy to an upper surface of the spreader member, and the spreader member is configured to conduct thermal energy to the first finger spreader.

A heating system comprises a wearable sleeve, a first heating pad associated with a first portion of the wearable sleeve, a second heating pad associated with a second portion of the wearable sleeve, one or more temperature sensors associated with the wearable sleeve, and control circuitry communicatively coupled to the first heating pad, the second heating pad, and the one or more temperature sensors. The control circuitry is configured to receive one or more temperature signals from the one or more temperature sensors, determine a temperature associated with a patient based on the one or more temperature signals, determine that the temperature is less than a target temperature value, and at least partly in response to said determining that the temperature is less than the target temperature value, activate at least one of the first heating pad or the second heating pad.

The Pocketed Compression sheath is polyester compressive material formed into an open-ended sheath. Squares of the same type of polyester material are sewn onto the sides of the open-ended sheath to form pockets. The sheath is intended to be slid onto an extremity such as foot. Figure B illustrates a larger version intended to be utilized for the mid to upper leg. The pockets are intended to be place holders for heating packs or ice packs to help minimize swelling and pain in muscles and joints.