Methods, devices and systems to improve neural stimulation by applying biphasic waveforms including a positive anodal pulse followed by a negative cathodal pulse to speed conduction and improve mitochondrial function in conditions such as cerebellar dysfunction (such as gluten ataxia, spinocerebellar ataxia, and Alzheimer's disease). Improved neural stimulation of more distal brain structures may interrupt epileptic seizures. Additionally, biphasic waveforms including a positive anodal pulse followed by a negative cathodal pulse speed wound healing by lowering the cell membrane potential of the skin, and may stimulate the release of hormonal secretions or insulin by proper placement of electrodes.

Tumor treating fields (TTFields) can be delivered to a subject's body with improved safety and efficacy by determining the condition of participating electrode elements and/or the subject's skin condition under positioned electrode elements. This may be accomplished by applying an AC signal to pairs or groups of electrode elements and taking corresponding impedance measurements. In some embodiments, the impedance measurements are indicative of electrode element condition and/or skin condition. These determined conditions can be used to adjust or pause TTFields treatment, for example to permit skin recovery or to ensure that participating electrode elements will properly function.

The electrical stimulation garment includes an electrical stimulator, a flexible substrate, a plurality of electrical connectors, a plurality of electrodes and a plurality of locators. The electrical stimulation is applied to the body part by the electrical stimulator through the placement of the plurality of electrical connectors in contact with the plurality of electrodes to a prescribed area of the body part as identified by the plurality of locators.

A stimulator substrate device for stimulating nerve cells, and apparatus including same, in particular nerve cells in an extremity, includes a substrate support, in which a plurality of stimulators for emitting stimulation signals to the nerve cells are provided. The plurality of stimulators is provided in a line on the substrate support and the substrate support is tubular.

The invention described herein provides for a portable autonomic nerve system stimulation device that may operate as an “open-loop” or “closed-loop” stimulation system and includes in some embodiments a paired therapy for a disease or condition. Embodiments of the inventive device include at least one stimulation circuit for the generation and delivery of a stimulation, at least one biological signal monitoring apparatus for monitoring a biological state of a user wearing the device, at least one controller in electrical communication with the stimulation circuit and at least one power supply for providing power to the controller and stimulation circuit. Aspects of the invention provides for a portable autonomic nerve system stimulation device which may be worn in the ear, or about the head, of a subject, patient or user.

A neurostimulation system is disclosed for providing treatment to a patient during a therapy session. The neurostimulation system includes a neurostimulator for transmitting magnetic or electrical signals based upon a treatment program. A programmer is connected to the neurostimulator to set a treatment session parameter value to calculate a therapy compliance value. A compliance module is connected to the neurostimulator and the programmer to calculate and store a therapy compliance value. A control module is connected to the compliance module, the programmer and the neurostimulator and determines whether the therapy compliance value is within a range of the treatment program. The neurostimulator transmits electrical or magnetic signals to the patient in a treatment session only if the therapy compliance value meets a compliance criteria.

Devices, systems and methods are disclosed for treating or preventing an autism spectrum disorder, a pervasive developmental disorder, or a disorder of psychological development. The methods comprise transmitting impulses of energy non-invasively to selected nerve fibers, particularly those in a vagus nerve. The nerve stimulation may be used as a behavior conditioning tool, by producing euphoria in an autistic individual. Vagus nerve stimulation is also used to modulate circulating serotonin levels in a pregnant woman so as to reduce the risk of having an autistic child; modulate the levels of growth factors within a child; promote balance of neuronal excitation/inhibition; modulate the activity of abnormal resting state neuronal networks; increase respiratory sinus arrhythmia; and avert episodes of motor stereotypies with the aid of forecasting methods.

The present disclosure relates to neuromuscular stimulation and sensing cuffs. The neuromuscular stimulation cuff has at least two fingers and a plurality of electrodes disposed on each finger. More generally, the neuromuscular stimulation cuff includes an outer, reusable component and an inner, disposable component. One or more electrodes are housed within the reusable component. The neuromuscular stimulation cuff may be produced by providing an insulating substrate layer, forming a conductive circuit on the substrate layer to form a conductive circuit layer, adhering a cover layer onto the conductive circuit layer to form a flexible circuit, and cutting at least one flexible finger from the flexible circuit. The neuromuscular stimulation cuff employs a flexible multi-electrode design which allows for reanimation of complex muscle movements in a patient, including individual finger movement.

The present invention relates to an electrical nerve stimulator configured to deliver an electrical signal to a user to entrain Mu-band neural oscillations and/or Beta-band neural oscillations. The electrical nerve stimulator may be used in the treatment of neurological conditions associated with desynchronization of neural oscillations, such as Tourette's syndrome. The electrical nerve stimulator may be wearable on a wrist of a user, and may be configured to deliver rhythmic stimulation at a frequency falling within the same frequency range of Mu-band or Beta-band neural oscillations. The invention provides a convenient means of treating conditions such as Tourette's syndrome without the need for specialist medical equipment or facilities. Also disclosed is a method of delivering an electrical signal to a user to entrain Mu-band neural oscillations and/or Beta-band neural oscillations.

A system includes a collar that is worn around a neck of the user. A stimulator is coupled to the collar such that the stimulator is positioned adjacent to an airway of the user. The sensor is coupled to the collar and configured to generate data associated with the airway of the user. The memory is coupled to the collar and storing machine-readable instructions. The control system is coupled to the collar and includes one or more processors configured to execute the machine-readable instructions to determine, based at least on an analysis of the generated data, that the user is currently experiencing an apnea event. In response to the determination, the control system causes the stimulator to provide electrical stimulation, at a first intensity level, to one or more muscles of the user that are adjacent to the airway to aid in stopping the apnea event.