A motor-deficit-therapeutic method (for treatment of a patient who has hemiparesis) includes: providing, to the patient afflicted with a hemiparesis, a neurostimulator configured to stimulate a vagus nerve of the patient using electrical, magnetic, optical, acoustic or mechanical stimulation; and initiating stimulation of the vagus nerve by the neurostimulator so that at least a portion of the stimulation occurs at least during performance by the patient of a motor therapy session which is hemiparesis-therapeutic, thereby improving the patient's hemiparesis.

Provided herein are noninvasive stimulation methods and apparatus for the treatment of injury to tissues using a novel pulsed laser system that combines the benefits of near-infrared laser light and optoacoustic waves. In certain embodiments, short, high-energy laser light pulses generate low intensity ultrasound waves that travel deep into brain tissues to stimulate neural function and treat neurological dysfunctions. In certain embodiments, a patient interface is provided wherein optoacoustic waves are produced by a plurality of optical absorbers overlying all of a plurality of optical fibers while in other embodiments optoacoustic waves are generated both inside the tissue and outside the tissue via a plurality of optical absorbers overlying some but not all of the optical fibers thus enabling an option of varying proportions of optoacoustic waves generated inside and outside of tissue.

The present invention relates to methods of restoring cognitive function in aged individuals that do not exhibit a clinically detectable neurodegenerative disease. In one aspect, the present invention provides a method of improving cognitive function in an aged individual that does not have a neurodegenerative disease characterized by aggregation of a pathological protein, the method comprising or consisting of: applying a clinically safe level of acoustic energy to sites within a region of the brain, thereby saturating or substantially saturating the region with acoustic energy, thereby improving cognitive function in the aged individual.

The present specification discloses a neuromodulation system comprising a transcranially mounted neuromodulation device and a stimulation control computing environment. The disclosed neuromodulation device comprising at least one ultrasound transducer and at least one EEG electrode and the disclosed stimulation control computing environment comprises a stimulation control unit and offline computing device, the disclosed stimulation control unit including associated systems and methods for controlling the neuromodulation device functionality using acoustic simulations performed on brain image data as well as methods and uses of such neuromodulation systems in modulating brain activity using focused ultrasound stimulation of the thalamus and thalamic sub regions during certain phases of slow wave brain oscillations in order to treat various neural-based disorders or conditions including sleep disorders.

Methods and systems for improving nerve stimulation are disclosed which relate to shaping characteristics of the stimulation field such as by using different geometries and locations of stimulation. In embodiments, systems and methods are provided to improve selective modulation of specific targeted neural substrate, while minimizing the activation of adjacent non-targeted nervous tissue. While aspects of the disclosed technologies can be applied to any part of the central and peripheral nervous systems for treatment various disorders and providing symptom relief to provide for therapy related to pelvic floor disorders such as overactive bladder

In a system for electrical stimulation of nerves of a living being a pulse generator is configured to provide a sequence of electrical and/or vibration pulses to at least one electrode and/or vibration generator that are maintained in close proximity to the nerve of interest with the use of means for securing the electrode to the skin or tissue of the living being.

The present invention is directed to a method for treating a bowel disease in a subject in need thereof, the method comprising inhibiting the activity of neurons of the insular cortex of the subject. Further provided is a system comprising a transcranial stimulation transducing coil for transcranial stimulation configured to provide a series of pulses to neurons of the insular cortex.

Disclosure are a triboelectric generator including a nano-composite life-limited via selective ultrasound application thereto, and a neurostimulation therapy device using the same. Disclosure are a life-limited nano-composite that initiates biodegradation thereof upon application of focused ultrasound thereto, and to a neurostimulation therapy device for peripheral neuropathy treatment using an ultrasound-driven triboelectric generator based on the life-limited nano-composite. The device has a power source that is harmless to a human body and performs nerve stimulation treatment using this power source, and then causes biodegradation at a desired timing after the treatment is completed.

An IV catheter insertion guide is configured to reduce the pain a patient may experience during catheter insertion. The IV catheter insertion guide may include two platforms that can be positioned on opposing sides of the insertion site. An upstream platform can include an ultrasonic transducer or another type of heating component for increasing the temperature of tissue near the insertion site. This heating of the tissue can cause the targeted vessel to relax and increase its cross-sectional area prior to insertion of the catheter. A downstream platform can also include an ultrasonic transducer for stimulating nerves downstream from the insertion site during the insertion of the catheter. The stimulation of the downstream nerves may reduce the pain signal that is transmitted to the central nervous system in response to the catheter insertion.

Described here is a deep brain stimulation (“DBS”) approach that targets several relevant nodes within brain circuitry, while monitoring multiple symptoms for efficacy. This approach to multi-symptom monitoring and stimulation therapy may be used as an extra stimulation setting in extant DBS devices, particularly those equipped for both stimulation and sensing. The therapeutic efficacy of DBS devices is extended by optimizing them for multiple symptoms (such as sleep disturbance in addition to movement disorders), thus increasing quality of life for patients.