94 results about "Nerve muscle" patented technology

Apparatus and methods for treating back pain are provided, in which an implantable stimulator is configured to communicate with an external control system, the implantable stimulator providing a neuromuscular electrical stimulation therapy designed to cause muscle contraction to rehabilitate the muscle, restore neural drive and restore spinal stability; the implantable stimulator further including one or more of a number of additional therapeutic modalities, including a module that provides analgesic stimulation; a module that monitors muscle performance and adjusts the muscle stimulation regime; and/or a module that provides longer term pain relief by selectively and repeatedly ablating nerve fibers. In an alternative embodiment, a standalone implantable RF ablation system is described.

A preferably non-electrical nerve communication enhancement tool that sends specific, pre-timed, controlled vibrational and/or acoustical stimulation frequencies to the body to enhance nerve communication for the purpose of assisting in proper function of skeletal muscle, smooth muscle, sympathetic and parasympathetic nervous systems, and facilitating rapid and improved cerebellar timing circuit and related cerebellar learning mechanism pathways such as the inferior olivary-Purkinje-Thalamus cell system and other similar neuronal pools, to improve muscle memory, coordinated functional neuron-musculo-skeletal performance improvement, enhance blood flow, increased range of motion, flexibility, strength and dexterity, neuromuscular re-education, muscle tone recovery, pain modulation, improved eye-hand coordination, gait improvement, balance and stability gains, kinetic chain integration, neurological performance enhancement, sensory dysfunction reduction, and improvement in mental and cognitive function.

An electromagnetic stimulation device which is comprised of a plurality of overlapping coils which are able to be independently energized in a predetermined sequence such that each coil will generate its own independent electromagnetic field and significantly increase the adjacent field. The coils are co-planar and are disposed in an ergonomic body wrap, which is properly marked to permit an unskilled patient to locate the body wrap, on a particular part of the body, of the patient so that the stimulation coils will maximize the electromagnetic stimulation on the selected nerves, muscles, and/or body tissues near the treated area. The device can be used to treat medical conditions including: muscular atrophy, neuropathic bladder and bowel, musculoskeletal pain, arthritis, as well as possible future applications in the prevention of deep vein thrombosis and weight reduction.

A novel system and method for restoring functional movement of a paralyzed limb(s) or a prosthetic device. Stimulating one or more muscles of a patient using an implanted neuromuscular implants and sensing the response of the stimulated muscle by the implants, wherein the sensing the response is not limited to data related to patient's movement intention, the posture, muscle extension, M-Wave and EMG. A communication and control protocol to operate the system safely and efficiently, use of forward and reverse telemetry channels having a limited bandwidth capacity, and minimizing the adverse consequences caused by errors in data transmission and intermittent loss of power to the implants. Adjusting stimulation rates and phases of the stimulator in order to achieve an efficient control of muscle force while minimizing fatigue and therefore providing for smooth movements and dynamic increase of the strength in patient's muscle contraction.

The invention enables a person to control the real or virtual action or movement of an output device in from one to three dimensions through the use of at least one electrical sensor which can either be implanted beneath the skin or placed on the surface of the skin as a part of a headset on either one side or if more than one sensor is used on both sides of a person's head in electrical communication with a vestigial periauricular nerve or muscle. Each sensor then communicates through a selected channel to transmit information preferably in digital form to an output device designating an action to be taken or the position of a target location for enabling the output device to perform the action or to move toward or to a target location through real or virtual space. At least one and preferably up to four sensors are located on each side of the head. The invention also provides a new method for enabling an individual to actuate or control an output device by first placing an electrical sensor on at least one side of the head in electrical communication with a vestigial periauricular nerve or muscle, then using a signal provided by the sensor for transmitting information designating an action to be performed or to move the device toward or to the target in real or virtual space.

The present invention relates to apparatuses, methods, and systems for simulating low and/or high intensity exercise. More particularly, the present invention relates to an exercise mimetic device for simulating low and/or high intensity exercise using low intensity electrical stimulation to generate low intensity muscle contractions such as a wearable garment that preferably imitates exercise by eliciting low grade muscle contractions in several of the larger skeletal muscle groups in the body. The apparatus of various embodiments of the present invention is a neuromuscular electrostimulation (NMES) device/garment with a control unit that is wirelessly connected to and controls a stimulator unit that generates and transmits a low intensity electrical stimulation within certain unique parameters. In various embodiments, the NMES device/garment is for treating conditions including but not limited to obesity, obesity related conditions such as diabetes, muscle toning, and/or other conditions benefitted by exercise. In various embodiments, the NMES device/garment is an over the counter (OTC) NMES device/garment.

The invention discloses a smart apparatus for rehabilitation training of pelvic floor muscles and a method for using the same. According to the invention, an EMG electrode slice acquires an electromyographic signal of the pelvic floor muscles, and the electromyographic signal is transmitted to an electromyographic amplifying circuit via a signal line. The electromyographic amplifying circuit is connected to an MCU via an AD sampling circuit. The MCU communicates with a mobile smart terminal via a wireless communication module. The mobile smart terminal is used for displaying a sampling result and sending a stimulation instruction. The MCU receives the instruction sent by the mobile smart terminal via the wireless communication module and controls an electrical stimulation circuit to send a stimulation pulse current. The electrical stimulation circuit is connected to an STIM electrode slice via the signal line and provides neural muscle electrical stimulation to the pelvic floor muscles. The invention also discloses the method for using the apparatus in the rehabilitation training of pelvic floor muscles. The apparatus herein is small in size and low in cost. The apparatus uses data processing function and displaying function of the mobile smart terminal in biological feedback training and neuromuscular electrical stimulation of pelvic floor muscles, which facilitates patients in the rehabilitation training of pelvic floor muscles at home.

The invention discloses a pure idea nerve muscle electrical stimulation control and nerve function evaluation system which comprises a signal collecting module, a signal processing module and an instruction control module. The signal collecting module is used for collecting input electroencephalogram signals and other physiological signals in real time; the signal processing module is used for reading the electroencephalogram signals, carrying out feature extracting through a cospace model algorithm, and carrying out mode recognition on feature data through a support vector machine to obtain a decision value; according to the decision value and the decision value threshold vale range, an idea imagination mode is judged and transmitted to the instruction control module; the instruction control module is used for converting the idea imagination mode into a trigger nerve muscle electrical stimulator switch so that nerve muscle electrical stimulation can be carried out on the limb part of a user. The system has the advantages of high stability and adaptation, and lays the foundation for the large-scale application stage of an idea control system, and it is hopeful to obtain considerable social benefits and economic benefits.

The invention discloses a neuromuscular electrical stimulation system with implantable automatic feedback adjustment, which can accurately feedback the executive condition of the implanted parameter, improve the therapeutic effects of the implantable electrode specific parameter, really realize improvement and repairing of the individual functions and improve the reliability, effectiveness and controllability of the implanted device. The invention adopts the technical proposal that an implantable electrical stimulation generator are combined with an in vitro controller which can control the stimulus wave parameters and instructions, thereby the online in vivo parameters can be effectively monitored, feedback and adjusted; the signal transmission in the in vitro controller are completed at the same time. The neuromuscular electrical stimulation system can be used in the neuromuscular electrical stimulation field.

The invention provides an interactive pelvic floor muscle rehabilitation device in the technical field of medical instruments. The rehabilitation device is composed of a power supply circuit module, a myoelectricity collection module, a stimulation circuit module, a reset module and a communication module. The interactive multi-channel medical instrument designed based on a DSP chip as a core is capable of collecting a myoelectricity signal and providing diagnosis information as well as stimulating pelvic floor muscles by currents with different intensities, frequencies, and waveforms to improve the nerve muscle function and promote conduction function rehabilitation, so that the pelvic floor nerves can work normally. Therefore, the rehabilitation device has important significance in improving the living quality of women after delivery and treating post partum urinary incontinence and pelvic organ prolapse; and the pelvic floor muscle dysfunction can be diagnosed effectively and rehabilitation can be realized.

System, device and method for providing neuromuscular electrical stimulation (NMES) to muscles of foot. The device includes an electrical signal generator for producing a wave pattern of variable frequency, duration, intensity, ramp time and on-off cycle. Device further includes surface electrodes for being positioned over the foot muscles or around ankles and attached to signal generator. Signal generator is programmed to stimulate the foot muscles and nerves. Location of the electrodes and the programming are adjusted to reduce pooling of the blood in the soleal veins of the calf and enhance venous blood flow to prevent deep vein thrombosis (DVT), to enhance venous blood flow for the post-thrombotic syndrome patient, to expedite wound healing, to reduce neuropathic pain of the foot and ankle, chronic musculoskeletal pain of the ankle and foot, and acute post-operative foot and ankle pain, and to prevent muscular atrophy of the foot muscles.

A method of detecting neuromuscular pathology in an individual is disclosed comprising the steps of placing a detector on the skin surface of the individual substantially adjacent to a skeletal muscle; obtaining signals from the detector; processing the signals; and determining neuromuscular status in response to the signals. A system for detecting neuromuscular disease in an individual is disclosed, the system comprising at least one means for recording a first signal from a skeletal muscle; a filter in communication with the recording means to generate a second signal consisting substantially of spontaneous myoelectrical activity; and a processor in communication with the filter, wherein the first signal from the skeletal muscle is filtered so as to generate spontaneous myoelectrical signals, and further wherein the processor calculates the power spectral density of the filtered signals and determines the neuromuscular status in response to the power spectral density of the filtered signals.

The invention, which relates to the technical field of biomedicine, provides a piezoelectric stent composition capable of realizing self-generating electricity stimulation as well as a preparation method and application thereof. The composition is composed of a biodegradable metabolic material and a piezoelectric material. With a 3D printing, jetting, pouring, extruding, die forming or electrostatic spinning method, the co-melt of the biodegradable material and the piezoelectric material or an organic solvent is formed into various biomedical application stents, especially nerve conduit stents. According to the invention, the mechanical energy in an in-vivo environment can be into electrical stimulation to promote regeneration, proliferation and differentiation of nerves, muscles, bones, blood vessels and the like without implantation of an external power supply or an electrode. The piezoelectric stent composition has advantages of being simple to prepare, low in cost, easy to controlin quality, wide in application range and the like. Rat in-vivo experiments show that the piezoelectric catheter stent has functions of promoting nerve regeneration and angiogenesis, relieving muscleatrophy and the like and has the broad clinical application prospects.

A system and method for using video-synchronized electromyography to improve neuromuscular performance of a target muscle is disclosed. A subject may perform a series of exercises or movements that are candidates for inclusion in an exercise regimen. Video of the subject performing the candidate movements may be combined with electromyogram data from a target muscle and a facilitating muscle. The clips may be analyzed to determine the best exercises for the subject to achieve his or her fitness goals for the target muscle.

The invention provides a motor function monitoring management method based on electroencephalogram and myoelectricity cross frequency coupling. The motor function monitoring management method comprises the steps that electroencephalogram signals EEG and myoelectricity signals EMG are synchronously collected; baseline drift, overflow, eye movement and power frequency interference are correspondingly removed from the collected EEG and EMG; and cross frequency coupling analysis between EEG signals and EMG is studied, and the relation between cerebral cortex and muscles in different motion states is obtained. Four main methods in cross frequency coupling, namely phase-phase coupling PPC, phase-amplitude coupling PAC, frequency-amplitude coupling FAC and frequency-frequency coupling FFC, are selected, four different types of coupling methods are analyzed, a neuromuscular system motion function monitoring model based on multi-modal characteristic indexes is constructed, relevance research of the four methods is carried out, so that a relatively accurate analysis result is obtained, a physiological mechanism generated by the motion function is researched, and neuromuscular system motion function monitoring is effectively managed.