Systems, catheters, and methods for accessing and treating along the central nervous system are disclosed. An example method may manage inflammation of the patient to treat a condition of the patient by processing values related to one or more physiological parameters of a patent, identifying when an inflammation condition of the patient has reached a treatment condition based on the processed values, and automatically providing an indication that the inflammation condition has reached the treatment condition. An example indication may include actuation of a treatment protocol. The example method may be performed with an inflammation management system.

In embodiments, devices, methods and systems to analyze the different mediums of brain function in a mathematically uniform manner may be provided. These devices, methods and systems may manifest at several levels and ways relating to brain physiology, including neuronal activity, molecular chirality and frequency oscillations. For example, in an embodiment, a computer-implemented method for determining structure of living neural tissue may comprise receiving at least one signal from at least one read modality, the signal representing at least one physical condition of the living neural tissue, determining action potentials based on the signals received from the read modalities, determining frequency oscillations based on the signals received from the read modalities and the action potentials, and determining neuron network structures based on the signals received from the read modalities, the action potentials, and the frequency oscillations.

A disclosed biological data processing device includes a calculator configured to calculate relative position data indicating a relative position of a subject with respect to a biological sensor for measuring the subject using the biological sensor, a specifying unit configured to identify a predetermined part of the subject to specify a relative position of the identified predetermined part with respect to the biological sensor based on the relative position data, and a generator configured to reconfigure electric current sources based on biological data measured by the biological sensor, using the relative position specified by the specifying unit as a calculated position, to generate reconfigured data.

Methods and systems for providing neuromodulation therapy are disclosed. The methods and systems are configured to sense an evoked neural response and use the evoked neural response as feedback for providing neuromodulation therapy. Methods of reducing stimulation artifacts that obscure the sensed evoked neural response are disclosed. The methods of artifact reduction include recording a stimulation artifact in the absence of an evoked neural response, aligning and scaling the stimulation artifact with respect to the obscured signal, and subtracting the aligned and scaled artifact from the obscured signal.

The present invention relates to a system and methods generally aimed at surgery. More particularly, the present invention is directed at a system and related methods for performing surgical procedures and assessments involving the use of neurophysiology.

A method of visualizing spinal nerves includes receiving a 3D image volume depicting a spinal cord and a plurality of spinal nerves. For each spinal nerve, a 2D spinal nerve image is generated by defining a surface within the 3D volume comprising the spinal nerve. The surface is curved such that it passes through the spinal cord while encompassing the spinal nerve. Then, the 2D spinal nerve images are generated based on voxels on the surface included in the 3D volume. A visualization of the 2D spinal images is presented in a graphical user interface that allows each 2D spinal image to be viewed simultaneously.

A system may be configured to sense local field potentials (LFPs) from electrodes placed in epidural space near the spine of a patient. The system may be configured to analyze the sensed LFPs and determine a change in a state of the patient, such as a physiological state of the patient. The system may use such analysis to update and/or suggest parameters for delivery of electrical stimulation therapy. The system may further be configured to analyze LFPs in a frequency domain by applying a wavelet transform or other transform to sensed LFPs.

Some disclosed techniques relate to extracting one or more features based on an average evoked response and generating a result that identifies: a predicted degree of inflammation; a predicted degree of myelination; a predicted degree of demyelination; or a predicted degree to which a symptom or disease of the subject would be effectively treated by a remyelination therapy. Some disclosed techniques relate to accessing evoked compound action potentials, mapping the evoked potentials to a functional system; generating an average evoked response; extracting one or more features from the average evoked response; and generating a functional-system impairment metric associated with the functional system based on the one or more features, where the functional-system impairment metric indicates whether or an extent to which the functional system of the subject is impaired.

Provided is an intraesophageal electrostimulator configured so that other medical tools can also be easily inserted into an esophagus and misalignment in the esophagus can be reduced. An intraesophageal electrostimulator 100 includes a stimulator body 101, stimulating electrodes 111, 112, and power feed lines 113, 114. The stimulator body 101 is formed, in order to insert the stimulator body 101 into an esophagus S, in an elongated flat plate shape with flexibility in a longitudinal direction. The stimulator body 101 includes a first flat plate member 102, a second flat plate member 103, and an exterior body 104. On one plate surface of the first flat plate member 102, each of the stimulating electrodes 111, 112 is provided so as to protrude from the plate surface. The second flat plate member 103 overlaps with the other plate surface of the first flat plate member 102 such that the second flat plate member 103 and the first flat plate member 102 sandwich the power feed lines 113, 114. The exterior body 104 covers the first flat plate member 102 and the second flat plate member 103 overlapping with each other.

Embodiments of the present systems and methods may relate to a non-invasive system with diagnostic and treatment capacities that use a unified code that is intrinsic to physiological brain function. For example, in an embodiment, a computer-implemented method for affecting living neural tissue may comprise receiving at least one signal from at least one read modality, the signal representing release of photons from mitochondria of the living neural tissue, computing at least one signal to effect alterations to the living neural tissue based on the received input signal, the computed signal adapted to cause transmission of photons to the living neural tissue, and delivering the photons to the living neural tissue to effect alterations to the living tissue.