This application is generally related to identifying or otherwise programming one or more cycling parameters for operation of an implantable pulse generator to provide a neurostimulation therapy to a patient using a non-paresthesia stimulation pattern. In some embodiments, the cycling parameter is selected by measuring physiological signals during trial stimulation. In other embodiments, multiple cycling parameters are identified for use by the patient using a patient controller device.

An apparatus and method for improving functioning of at least a portion of a subject's nervous pathway system includes a garment or device worn or disposed on the subject; and at least one stimulator disposed on, in or within the garment or device capable of providing at least one corrective non-weight stimulus to the subject's nervous pathway system. The kind of nonweight stimulus provided by the stimulator to the subject's nervous pathway system, the amount, degree or intensity of the stimulus provided by the stimulator to the subject's nervous pathway system, and/or the body location of non-weight stimulus provided by the stimulator to the subject's nervous pathway system is determined by a reiterative diagnostic method leading to an optimal response for the treated subject.

The present invention relates to a system for providing neuronal stimulation signals configured to elicit sensory percepts in the cortex of an individual, comprising means for obtaining spatial information relating to the actual or planned position of at least one neuronal stimulation means relative to at least one afferent axon targeting at least one sensory neuron in the cortex of the individual and means for determining at least one neuronal stimulation signal to be applied to at least one afferent axon via the at least one neuronal stimulation means based at least in part on the obtained spatial information.

The present invention further relates to a system for communicating conceptual information to an individual, comprising means for selecting at least one neuronal stimulation signal to be applied to at least one afferent axon targeting at least one sensory neuron in the cortex of the individual, wherein the at least one neuronal stimulation signal corresponds to the conceptual information to be communicated and means for transmitting the at least one neuronal stimulation signa to at least one neuronal stimulation means of the individual.

A method is described for making determinations on or classifying the pain of an estimation subject on the basis of the brainwaves of the estimation subject. This method includes: (a) stimulating the estimation subject at a plurality of levels of stimulation intensity; (b) acquiring brainwave data for the estimation subject; (c) extracting a brainwave feature quantity from the brainwave data or the analysis data; (d) for plugging the feature quantity into a Sparse model analysis, making the feature quantity approach a quantitative level and/or a qualitative level for pain, and estimating or making a determination on a pain level. Another method is described including comparing of brainwave data or analysis data from the 2,000 msec following the earliest of an induced brainwave component, an initial-event-related voltage component, and 250 msec after a target stimulus has been applied.

The clinical diagnosis and monitoring of patients with neurological conditions may be established through behavioral examinations, assessments or evaluations, or neuroimaging scans. The system and methods described herein diagnose the cognitive function of a subject by measuring the neural response of the subject to one or more naturalistic sensory stimuli. The system measures the subject's sensory evoked response to the naturalistic sensory stimuli by computing the statistical comparison between the subject's neural signal and either the raw stimulus signal or the stimulus' signal envelope. A latency value, or other signal feature, is extracted from the subject's sensory evoked response and a diagnosis of the subject's cognitive function is then made based on the identified latency value or other extracted signal feature.

Systems, methods and techniques for providing sensory input to a subject through non-invasive brain stimulation are generally described. In some examples, an input signal related to an environment may be received. In various further examples, a communication to the subject may be determined in response to the input signal. In some examples, an output signal corresponding to the determined communication may be generated. Some further examples may comprise non-invasively stimulating a portion of the subject's brain with the output signal with a stimulation subsystem positioned outside of the subject's scalp. In various examples, the stimulation of the portion of the subject's brain may be effective in producing a sensory response perceivable by the subject.

A system for electrical brain stimulation including a plurality of electrodes arranged around the patient's brain (either directly or indirectly through layers of dura, skull or skin) such that axes connecting each electrode pair intersect at a predetermined focal point, and a ground-independent switching circuit configured to selectively activate and deactivate electrodes via a plurality of ground-independent switches. Electrodes are sequentially activated and deactivated.

The objective of the present invention is to provide a technique which enables analysis to be performed in real-time without taking a control or the like, by performing wavelet transformation at the same time, without pre-processing of a signal. The present invention provides a pain estimating method and device with which pain of an estimation target can be objectively and accurately estimated, and with which the quality and quantity thereof can be classified simply. The present invention provides a method for processing a signal of a target in response to a stimulus, and includes: a) a step of obtaining from the target a signal in response to a stimulus; (b) a step of subjecting the signal to cross correlation processing using part or all of the signal; and (c) a step of calculating a feature quantity of the signal and a coefficient correlated to the stimulus from the processing results obtained in b).

The present application provides for use of a somatosensory evoked potential (SEP) during the hyperacute stroke phase as marker for predicting the outcome of endovascular treatment in a patient suffering from acute ischemic stroke, wherein when the SEP ipsilateral to the stroke site has an amplitude from 60% to 100% with respect to the corresponding SEP contralateral to the stroke site this is indicative of good outcome of the endovascular treatment, whereas when the SEP ipsilateral to the stroke site has an amplitude from 0% to 20% with respect to the corresponding SEP contralateral to the stroke site this is indicative of bad outcome of the endovascular treatment.

The system and methods described herein determine a subject's indication of attention to a first and a second sensory stimuli. The system determines a sensory evoked response of the subject by calculating the statistical relationship between the subject's neural response to the stimuli and a signal feature of the first and the second sensory stimuli. A magnitude value of the sensory evoked response is extracted to determine whether the subject attended-to or ignored the sensory stimuli. The system will select the stimuli that elicited the greater indication of attention, and then trigger further processing by a computer. Such processing can include selecting future content for improving safety warnings, educational materials, or advertisements or further processing can include controlling and navigating a brain computer user interface.