Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with a remote server for patient monitoring, prescription and/or device servicing.

Abstract: The apparatuses can comprise a controller including a RF driver configured to generate a pulsed current signal and one or more applicators coupled to the controller. Each applicator can include a coil circuit configured to receive the pulsed current signal and to emit a pulsed electromagnetic field signal comprising a magnetic field signal.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with a remote server for patient monitoring, prescription and/or device servicing.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with local computing device and a remote server for patient monitoring, prescription and/or device servicing.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with local computing device and a remote server for patient monitoring, prescription and/or device servicing.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with a remote server for patient monitoring, prescription and/or device servicing.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with a remote server for patient monitoring, prescription and/or device servicing.

Abstract: A multi-component system includes a first component housing a first conductive pad, a second conductive pad, and a first portion of a loop antenna that terminates on one side at the first conductive pad and on another side at the second conductive pad. The multi-component system further includes a second component housing a third conductive pad, a fourth conductive pad, and a second portion of the loop antenna that terminates on one side at the third conductive pad and on another side at the fourth conductive pad. The second component is distinct from, and configured to detachably couple with, the first component such that the first and third conductive pads, and the second and fourth conductive pads, respectively form first and second non-galvanic couplings that capacitively couple the first and second portions of the loop antenna while the first and second portions of the loop antenna remain galvanically separated.

Abstract: The apparatuses can comprise a controller including a RF driver configured to generate a pulsed current signal and one or more applicators coupled to the controller. Each applicator can include a coil circuit configured to receive the pulsed current signal and to emit a pulsed electromagnetic field signal comprising a magnetic field signal.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with a remote server for patient monitoring, prescription and/or device servicing.

Abstract: Described herein are high-power pulsed electromagnetic field (PEMF) applicator apparatuses. These apparatuses are configured to drive multiple applicators to concurrently deliver high-power PEMF signals to tissue. The apparatuses may be further configured to wirelessly communicate with local computing device and a remote server for patient monitoring, prescription and/or device servicing.

Abstract: A multi-component system includes a first component housing a first conductive pad, a second conductive pad, and a first portion of a loop antenna that terminates on one side at the first conductive pad and on another side at the second conductive pad. The multi-component system further includes a second component housing a third conductive pad, a fourth conductive pad, and a second portion of the loop antenna that terminates on one side at the third conductive pad and on another side at the fourth conductive pad. The second component is distinct from, and configured to detachably couple with, the first component such that the first and third conductive pads, and the second and fourth conductive pads, respectively form first and second non-galvanic couplings that capacitively couple the first and second portions of the loop antenna while the first and second portions of the loop antenna remain galvanically separated.

Abstract: A hearing assistance device including a housing, a user manipulatable control element, and a printed circuit board having a flexible substrate, sound processor circuitry on the flexible substrate, and a variable resistor that is an integral part of the printed circuit board and/or is secured to the housing.

Abstract: A hearing assistance device including a housing, a user manipulatable control element, and a printed circuit board having a flexible substrate, sound processor circuitry on the flexible substrate, and a variable resistor that is an integral part of the printed circuit board and/or is secured to the housing.

Abstract: A system for real-time sizing of fluid-borne particles is disclosed. The system further determines, in real time, whether the detected particles are biological or non-biological. As the fluid is being tested, it is exposed to a microbe collection filter which is cultured to determine the type of microbes present in the fluid being tested.

Abstract: A system for real-time sizing of fluid-borne particles is disclosed. The system further determines, in real time, whether the detected particles are biological or non-biological. As the fluid is being tested, it is exposed to a microbe collection filter which is cultured to determine the type of microbes present in the fluid being tested.

Abstract: A system for real-time sizing of fluid-borne particles is disclosed. The system further determines, in real time, whether the detected particles are biological or non-biological. As the fluid is being tested, it is exposed to a microbe collection filter which is cultured to determine the type of microbes present in the fluid being tested.

Abstract: A system for real-time sizing of fluid-borne particles is disclosed. The system further determines, in real time, whether the detected particles are biological or non-biological. As the fluid is being tested, it is exposed to a microbe collection filter which is cultured to determine the type of microbes present in the fluid being tested.

Abstract: A particle detection and classification system is disclosed. The system determines the size of measured particles by measuring light scattered by the particles. The system simultaneously determines whether measured particles are biological or non-biological by measuring fluorescent light from the particles. The system uses a parabolic reflector, and optionally, a spherical reflector to collect fluorescence light.

Abstract: A system for real-time sizing of fluid-borne particles is disclosed. The system further determines, in real time, whether the detected particles are biological or non-biological. As the fluid is being tested, it is exposed to a microbe collection filter which is cultured to determine the type of microbes present in the fluid being tested.