Provided is a method for assessing a correlation degree and an influence degree between a health degree in a health domain of concern and each preventive interventional action, based on biological information acquired in a time-series manner. The method comprises: acquiring biological information of an individual in a time-series manner; performing, based on the acquired biological information, an assessment of a health degree of the individual in a time-series manner; acquiring an intervention amount of each of one or more preventive interventional actions in a time-series manner; deriving a correlation degree and an influence degree between the time-series intervention amount of each of the one or more preventive interventional actions and the time-series health degree of the individual; and determining, as a relevant preventive interventional action, a preventive interventional action whose correlation degree is a given value or more, among the one or more preventive interventional actions.

An automated EP analysis apparatus for monitoring, detecting and identifying changes (adverse or recovering) to a physiological system generating the analyzed EPs, wherein the apparatus is adapted to characterize and classify EPs and create alerts of changes (adverse or recovering) to the physiological systems generating the EPs if the acquired EP waveforms change significantly in latency, amplitude or morphology.

An automated EP analysis apparatus for monitoring, detecting and identifying changes (adverse or recovering) to a physiological system generating the analyzed EPs, wherein the apparatus is adapted to characterize and classify EPs and create alerts of changes (adverse or recovering) to the physiological systems generating the EPs if the acquired EP waveforms change significantly in latency, amplitude or morphology.

The invention provides an advanced, modular, intraoperative neurophysiological monitoring (IONM) system, referred to as a “NeuroNet-VII” System, which is the first IONM system designed with a USB hub architecture comprising serially-connected functional “pods which provides multi-modality simultaneous data acquisition which supports all data types useful in operating rooms, diagnostic laboratories, intensive care units, and epilepsy monitoring units. The unique pod architecture makes the IONM system highly modular compared to current systems which typically place components in a limited number of centralized enclosures. The modular architecture of the invention also provides for real-time collection of data so that information may be communicated with a remotely-located physician; a user needs only to purchase pods that are needed; repair of a single pod may easily be replaced without disabling the entire system; and advances in hardware designs may be implemented for a specific pod without requiring replacement of the entire system.

The invention provides an advanced, modular, intraoperative neurophysiological monitoring (IONM) system, referred to as a “NeuroNet-VII” System, which is the first IONM system designed with a USB hub architecture comprising serially-connected functional “pods which provides multi-modality simultaneous data acquisition which supports all data types useful in operating rooms, diagnostic laboratories, intensive care units, and epilepsy monitoring units. The unique pod architecture makes the IONM system highly modular compared to current systems which typically place components in a limited number of centralized enclosures. The modular architecture of the invention also provides for real-time collection of data so that information may be communicated with a remotely-located physician; a user needs only to purchase pods that are needed; repair of a single pod may easily be replaced without disabling the entire system; and advances in hardware designs may be implemented for a specific pod without requiring replacement of the entire system.

The invention herein disclosed is a dual-function system that is used to investigate the response by an individual with neural-disorder symptoms to a variety of stimuli having different intensities and durations. Once a combination of stimuli and their settings is found to produce minimal frequency and severity of neural-disorder symptoms, the invention is then used to apply those stimuli and settings that minimize frequency and severity of symptoms as a therapeutic tool.

Systems and methods for enhancing diagnostic evoked potential recordings of a nerve or nerve pathway of interest. A grid array of stimulating electrodes are placed on, over, or through skin in a location beneath which a nerve or nerve pathway is suspected to lie. A stimulator controls the grid array, where each electrode is independently controllable as active or inactive, as a cathode or anode, etc. A plurality of recording electrodes may record Somato-Sensory Evoked Potentials (SSEPs) and/or Transcranial Electrical Motor Evoked Potentials (TCeMEP) in response to activation of the stimulating electrodes. A processor controls stimulating the stimulating electrodes, and receives responses from the recording electrodes, in a general search mode and a focused search mode in order to use a minimum stimulation intensity at which a maximum response amplitude is detected to continually stimulate the nerve or the nerve pathway.

In some embodiments, a method of treating a patient with an antipsychotic agent can include identifying the patient as an antipsychotic agent responder. The method can further include obtaining an electroencephalogram (EEG) signals from the patient. The method can further include measuring one or more EEG metrics, thereby identifying the patient as an antipsychotic agent responder. If the patient is an antipsychotic agent responder, the method can further include then administering the antipsychotic agent.

A method for delivering electrical stimulation to alter a cognitive state of a user, the method comprising: monitoring a brain signal from the user via one or more intracranial electrodes implanted in the brain of the user while the user is presented with a stimulus; comparing the brain signal to a testing phase biomarker, wherein the testing phase biomarker is derived from a cognitive test performed on a contributor during a testing phase; delivering electrical stimulation to a brain of the user based on the comparing step to steer the brain of the user towards a high performance cognitive state.

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 a neuronal stimulation means relative to afferent axon(s) targeting sensory neuron(s) in the cortex of the individual and means for determining a neuronal stimulation signal to be applied to the afferent axon(s) via the neuronal stimulation means based at least in part on the obtained spatial information.

A system for communicating conceptual information to an individual, comprising means for selecting a neuronal stimulation signal to be applied to afferent axon(s) targeting sensory neuron(s) in the cortex of the individual, wherein the neuronal stimulation signal corresponds to the conceptual information to be communicated and means for transmitting the neuronal stimulation signal to the neuronal stimulation means of the individual.