A patch for a therapeutic electrical stimulation device includes a shoe connected to the first side of the patch, the shoe including a body extending in a longitudinal direction from a first end to a second end, and having first and second surfaces, the first end of the shoe defining at least two ports, and the first surface of the shoe defining a connection member. The patch also includes at least one conductor positioned in the ports of the first end of the shoe. The shoe is configured for sliding insertion into a receptacle defined by a controller so that the conductor is connected to the controller to deliver electrical current from the controller, through the conductor, and to the electrodes, and the connection member is at least partially captured by a detent defined by the controller in the receptacle to retain the shoe within the receptacle.

Methods of providing therapy to a patient are provided. In one method, the patient has a neuron to which a sub-threshold biological electrical stimulus is applied. The method comprises applying electrical noise energy to the neuron, wherein resonance between the biological electrical stimulus and the electrical noise energy is created, such that an action potential is propagated along the axon of the neuron. In another method, the patient has a neuron to which a supra-threshold biological electrical stimulus is applied. This method comprises applying supra-threshold electrical noise energy to the neuron, thereby preventing an action potential from being propagated along the axon of the neuron. Still another method comprises applying an electrical stimulus to a neuron, and applying supra-threshold electrical noise energy to the neuron, thereby preventing or reversing any neurological accommodation of the neuron that may occur in response to the electrical stimulus.

A wearable monitoring device includes a plurality of cardiac sensing electrodes, a monitor, at least one motion sensor, and a controller. The plurality of cardiac sensing electrodes are positioned outside a body of a subject and to detect cardiac information of the subject. The monitor administers a predetermined test to the subject, and has a user interface configured to receive quality of life information from the subject. The at least one motion sensor is positioned outside the body of the subject and to detect subject motion during the predetermined test. The controller is communicatively coupled to the plurality of cardiac sensing electrodes, the monitor, and the at least one motion sensor, and receives and stores the detected cardiac information, the quality of life information, and the detected subject motion. The controller further communicates the stored detected subject motion and the quality of life information to a remote computer.

A rescue cell apparatus used for cardiac defibrillation of a patient, the apparatus comprising: a hand held device for sending and receiving communication signals and configured to be used as a remote control to administer a defibrillation pulse to the patient for cardiac defibrillation; a defibrillator unit having a sensor electronic pad positionable on the patient, the sensor electronic pad adapted to deliver the defibrillation pulse; and a second electronic pad, connectable by an electrical wire to the defibrillator unit, the second electronic pad positionable on the patient and adapted to detect ECG signals and to deliver the defibrillation pulse to the patient; and an image recognition module configured in the handheld device, and adapted to verify positioning of the sensor electronic pad and the second electronic pad on the patient before defibrillation.

A system and method to deliver a therapeutic quantity of energy to a patient. The system includes a capacitor having a rated energy storage capacity substantially equal to the therapeutic quantity of energy, a boost converter coupled with the capacitor and constructed to release energy from the capacitor at a substantially constant current for a time interval, and an H-bridge circuit coupled with the boost converter and constructed to apply the substantially constant current in a biphasic voltage waveform to the patient. The method includes storing a quantity of energy substantially equal to the therapeutic quantity of energy in a capacitor, releasing the quantity of energy at a relatively constant current during a time interval using a boost converter coupled with the capacitor, and delivering a portion of the quantity energy in a direction to the patient using an H-bridge circuit coupled with the boost converter.

A method of stimulating a patient's brain comprising delivering an electrical stimulation to at least one electrode causing stimulation of a person's anterior cingulum bundle, or especially causing stimulation of a person's dorsal portion of an anterior cingulum bundle resulting in emotional change(s) in a patient comprising one or more of the following: anxiolysis, mirth, analgesia, improved affective tone, enhanced cognitive focus, increased well-being, engagement, or optimism. Further embodiments contemplate an apparatus. Further embodiments contemplate two implanted electrodes within the dorsal portion of the anterior cingulum bundle spaced between about 5 mm and 8 mm apart, having electrical stimulation parameters of between about 1.0 mA and about 3.5 mA, between about 100 Hz to about 150 Hz, and having a pulse width of between about 100 microseconds to about 200 microseconds.

A system and method is provided for preferentially stimulating a portion of neural tissue including a first type of neurons and a second type of neurons. The method includes defining a waveform characterizing an electrical stimulus, wherein the waveform includes an amplitude-modulated wave of the electric stimulus. The method also includes applying the electrical stimulus having the defined waveform to a stimulating element located in proximity to the neural tissue to selectively activate the first type of neurons while leaving the second type of neurons one of substantially unaffected and suppressed in response to the electrical stimulus.

Various embodiments are described herein that generally relate to a low-level laser therapy (LLLT) device to aid in at least one of the prevention and treatment of hair loss, rejuvenation of hair, and stimulation of hair regrowth for a certain percentage of users. In at least one embodiment, a plurality of emitters and bristles may be arranged in rows on a concave active surface of a housing for facing a treatment surface of the user. In some embodiments, the device is a laser therapy helmet device, wherein a portion of the device rotates relative to the treatment surface during use. In at least some embodiments, the device may further comprise a plurality of modes of operation for delivering different amounts of energy to the treatment surface.

An example of a system may include an electrode arrangement, a neural modulation generator configured to use electrodes in the electrode arrangement to generate a modulation field, a communication module configured to receive commands, a memory configured to store modulation field parameter data, and a controller configured to control the neural modulation generator to generate the modulation field. The controller may be configured to implement a trolling routine to troll the modulation field through neural tissue positions, and implement a marking routine multiple times as the modulation field is trolled through the neural tissue positions to identify when the modulation field provides patient-perceived modulation. The marking procedure implemented by the controller may receive a marking command that indicates that a modulation intensity achieved the patient-perceived modulation, and store in the memory the modulation field parameter data that affects the modulation intensity in response to receiving the marking command.

A battery terminal for an implantable battery is described. The battery terminal includes a foil stack, first and second side elements, and a weld joint coupling the foil stack and the side elements. The side elements define a varying height profile and a greatest height adjacent an inner surface of the side element in contact with the foil stack. Each element may define a height profile along the width that tapers toward an outer surface, biasing mass of the element close to the foil stack.