Abstract: A system for treating and/or monitoring a patient includes a patient physiological parameter monitoring patch and a companion device. The patient physiological parameter monitoring patch including an energy harvesting module, an energy storage module, a sensor module and a communication module. The energy harvesting module harvesting energy from one or more ambient sources, the energy being storable in the energy storage module and usable by one or more components of the patient physiological parameter monitoring patch. The sensor module senses one or more physiological parameters of the patient and the communication module can transmit the sensed data. The companion device can receive the sensed physiological parameters and can send the same to a remote device or store the same.

Abstract: A system for treating and/or monitoring a patient includes a patient physiological parameter monitoring patch and a companion device. The patient physiological parameter monitoring patch including an energy harvesting module, an energy storage module, a sensor module and a communication module. The energy harvesting module harvesting energy from one or more ambient sources, the energy being storable in the energy storage module and usable by one or more components of the patient physiological parameter monitoring patch. The sensor module senses one or more physiological parameters of the patient and the communication module can transmit the sensed data. The companion device can receive the sensed physiological parameters and can send the same to a remote device or store the same.

Abstract: A defibrillation system that includes a first defibrillation device and a second defibrillation device. The first defibrillation device including a therapy module, a communication module, a physiological parameter module and a timing control unit. The second defibrillation device including a therapy module and a communication module. The timing control unit configured to output an instruction to cause the therapy module of the first defibrillator and the therapy module of the second defibrillator to each discharge an energy delivery according to a timing relationship.

Abstract: A method of treating lionfish envenomation; it includes administering to a subject a therapeutically effective amount of a P2X3 receptor antagonist; topical compositions for treating lionfish envenomation are also described.

Abstract: A system for treating and/or monitoring a patient includes a patient physiological parameter monitoring patch and a companion device. The patient physiological parameter monitoring patch including an energy harvesting module, an energy storage module, a sensor module and a communication module. The energy harvesting module harvesting energy from one or more ambient sources, the energy being storable in the energy storage module and usable by one or more components of the patient physiological parameter monitoring patch. The sensor module senses one or more physiological parameters of the patient and the communication module can transmit the sensed data. The companion device can receive the sensed physiological parameters and can send the same to a remote device or store the same.

Abstract: A system for treating and/or monitoring a patient includes a patient physiological parameter monitoring patch and a companion device. The patient physiological parameter monitoring patch including an energy harvesting module, an energy storage module, a sensor module and a communication module. The energy harvesting module harvesting energy from one or more ambient sources, the energy being storable in the energy storage module and usable by one or more components of the patient physiological parameter monitoring patch. The sensor module senses one or more physiological parameters of the patient and the communication module can transmit the sensed data. The companion device can receive the sensed physiological parameters and can send the same to a remote device or store the same.

Abstract: A defibrillation system that includes a first defibrillation device and a second defibrillation device. The first defibrillation device including a therapy module, a communication module, a physiological parameter module and a timing control unit. The second defibrillation device including a therapy module and a communication module. The timing control unit configured to output an instruction to cause the therapy module of the first defibrillator and the therapy module of the second defibrillator to each discharge an energy delivery according to a timing relationship.

Abstract: A defibrillation system that includes a first defibrillation device and a second defibrillation device. The first defibrillation device including a therapy module, a communication module, a physiological parameter module and a timing control unit. The second defibrillation device including a therapy module and a communication module. The timing control unit configured to output an instruction to cause the therapy module of the first defibrillator and the therapy module of the second defibrillator to each discharge an energy delivery according to a timing relationship.

Abstract: A cabinet capable of attenuating or blocking wireless signals contains, a medical device, such as an AED, an internal directional antenna mounted to an internal surface of the cabinet, an external omnidirectional antenna mounted to an external surface of the cabinet, and an electrical connection between the internal directional antenna and the external omnidirectional antenna. The internal and external antennas are configured to transmit wireless signals at particular frequencies and to receive wireless signals at the particular frequencies. The internal antenna is a high gain directional antenna, and the external antenna is a lower gain omnidirectional antenna.

Abstract: A system for treating and/or monitoring a patient includes a patient physiological parameter monitoring patch and a companion device. The patient physiological parameter monitoring patch including an energy harvesting module, an energy storage module, a sensor module and a communication module. The energy harvesting module harvesting energy from one or more ambient sources, the energy being storable in the energy storage module and usable by one or more components of the patient physiological parameter monitoring patch. The sensor module senses one or more physiological parameters of the patient and the communication module can transmit the sensed data. The companion device can receive the sensed physiological parameters and can send the same to a remote device or store the same.

Abstract: Technologies and implementations for a multifunctional healthcare monitoring apparatus are generally disclosed.

Abstract: A cabinet capable of attenuating or blocking wireless signals contains, a medical device, such as an AED, an internal directional antenna mounted to an internal surface of the cabinet, an external omnidirectional antenna mounted to an external surface of the cabinet, and an electrical connection between the internal directional antenna and the external omnidirectional antenna. The internal and external antennas are configured to transmit wireless signals at particular frequencies and to receive wireless signals at the particular frequencies. The internal antenna is a high gain directional antenna, and the external antenna is a lower gain omnidirectional antenna.

Abstract: Assays for selecting a candidate modulator of a TMEM120A ion channel and/or a candidate modulator of chronic pain, the steps comprising contacting a lipid membrane comprising contacting a lipid membrane comprising TMEM120A polypeptide with a test compound; quantitating the TMEM120A ion channel activity; comparing the ion channel activity of the TMEM120A polypeptide with a control; and selecting the test compound that modulates the ion channel activity compared to the control; and methods and compositions for treating chronic pain including osteoarthritic pain.

Abstract: Assays for selecting a candidate modulator of a TMEM120A ion channel and/or a candidate modulator of chronic pain, the steps comprising contacting a lipid membrane comprising contacting a lipid membrane comprising TMEM120A polypeptide with a test compound; quantitating the TMEM120A ion channel activity; comparing the ion channel activity of the TMEM120A polypeptide with a control; and selecting the test compound that modulates the ion channel activity compared to the control; and methods and compositions for treating chronic pain including osteoarthritic pain.

Abstract: Embodiments of the invention are directed to manufacturing a medical device in a way that minimizes the possibility of defects. Because of the general increasing desire to eliminate lead from the environment, electronic producers are removing lead from their manufacturing processes. The lead had beneficial qualities, however, in that it prevented other metals, in particular tin, from developing “whiskers,” believed to be caused from thermal and mechanical stress of the tin parts or components. Removing the lead has caused an increasing incidence of failure in electronic devices. Many vendors, believing that lead-free devices are universally desirable, routinely substitute lead-free components for components that previously contained lead. Oftentimes these substitutions are made without knowledge of the buyer. Some devices, in particular life-saving devices, may be adversely affected by such a substitution.

Abstract: The invention disclosed here is a data bus system integration tester designed specifically to be used in connection with testing digital autonomous terminal access communication (DATAC) buses. The tester is characterized in that it listens to the digital information broadcast by other terminals on the bus, and also has the capability of transmitting information to simulate transmitting terminals. The tester is a non-microprocessor based system.