Methods, compositions and kits useful in the detection, assessment, diagnosis, prognosis and/or treatment of brain injuries, especially mild traumatic brain injury (mTBI) or concussion, are based upon detection of changes in levels of certain protein biomarkers in a subject undergoing testing, or upon detection of changes in levels of certain protein biomarkers in conjunction with neuroimaging analyses to detect changes in vascular or blood brain barrier (BBB) permeability in the brain, or to detect damage to fiber tracts in the brain, in which changes in biomarker levels correlate with detection of changes in BBB permeability or in brain fiber tract or white matter damage in a subject with brain injury such as mTBI or concussion.

A probe device includes an optical device including at least one of a photodetector or a first light source. A cover structure is included and is arranged in front of the optical device. The cover structure includes an electrode which contacts, in use, a body tissue.

Brain modelling includes receiving time-coded bio-signal data associated with a user; receiving time-coded stimulus event data; projecting the time-coded bio-signal data into a lower dimensioned feature space; extracting features from the lower dimensioned feature space that correspond to time codes of the time-coded stimulus event data to identify a brain response; generating a training data set for the brain response using the features; training a brain model using the training set, the brain model unique to the user; generating a brain state prediction for the user output from the trained brain model, and automatically computing similarity metrics of the brain model as compared to other user data; and inputting the brain state prediction to a feedback model to determine a feedback stimulus for the user, wherein the feedback model is associated with a target brain state.

A system and method of non-invasive diagnosis of a condition in a subject may include obtaining, from a medical scanning device, a three-dimensional (3D) scan of the subject, said scan comprising a plurality of quantitative or semi-quantitative voxel values; segmenting the scan, to obtain a segmented region of interest (ROI) of the subject; performing a singular value decomposition (SVD) of the ROI, to determine at least one axis of the ROI in the SVD space; and analyzing the voxel values along the at least one axis, to diagnose a condition of the subject. Analysis of the voxel values may include calculating a quantitative function of voxel values along the at least one axis; comparing the calculated quantitative function to a reference quantitative function; and diagnosing or predicting a condition of the subject, based on the comparison.

Catheter devices and methods are disclosed and described. A catheter device (100) can include a longitudinal lumen (104) and having a proximal end (104a) and a distal end (104b). The distal end (104b) is capable of insertion into at least the internal carotid artery. The catheter device (100) can include an occlusion balloon (120b) connected to the distal end (104b) and operable to occlude blood flow in a blood vessel (102) by inflation and deflation using a pressurization fluid. The catheter device (100) can include a pressure sensor (110b) associated with the distal end (104b) and operable to measure blood pressure data from at least one of a downstream (103b) and upstream (103a) location of the occlusion balloon (120b) and transmit the blood pressure data to a controller (150). The occlusion balloon (120b) can be operable to inflate or deflate based on inflation control information. The catheter device (100) can be used to treat cerebral thrombectomy in a subject.

Disclosed herein is a system comprising at least one probe configured for obtaining from a brain tissue at least one near infrared measurement when the at least one probe is positioned at a predetermined proximal location to brain tissue, a processor configured to receive the at least one near infrared measurement from the at least one probe, compare the at least one near infrared measurement with a predetermined threshold value for at least one predetermined compound, determine the at least one near infrared measurement is above the predetermined threshold value, generate an indication indicating the presence of a secondary brain insult in the brain tissue, and provide the indication to an output thereby notifying an operator of the at least one probe of the presence of the secondary brain insult in the brain tissue.

A processing device receives signals associated with nerve impulses that are transmitted to the visual cortex of a subject in response to one or more visual stimuli provided to at least one eye of the subject. The processing device processes the received signals and generates digital image data from the processed received signals that is representative of the visual perception, by the subject, of the one or more visual stimuli. In certain embodiments, the processing device processes digital image data that is representative of a scene to convert the digital image data to a sequence of nerve impulses, and provides the sequence of nerve impulses to the visual cortex of a subject such that the subject visually perceives the scene.

Systems, methods and devices are provided for performing diagnostic or therapeutic transcranial procedures using a patient-specific transcranial headset. The patient-specific headset may include a patient-specific frame that is fabricated, according to volumetric image data, to conform to an anatomical curvature of a portion of a patient's head. The patient-specific frame is configured to support a plurality of transducers in pre-selected positions and orientations, which may be spatially registered to the volumetric image data. This spatial registration may be employed to control at least a portion of the transducers to focus energy at a pre-selected tissue region.

The present invention relates to a system, its catheter and its method for providing electrical pulses and/or therapeutic or diagnostic liquids directly to a pituitary gland of a mammal. The catheter, containing an electrode or a microcannula or both, is moved through an endovascular route of a patient to his/her sinus cavernosus and then the distal end of the electrode or microcannula is moved through an opening in the distal end of the catheter and then through a perforation in the medial wall of the sinus cavernosus, to the pituitary gland.

This document describes systems, methods, and devices for sensing electrical activity in a brain of a mammal Some aspects include a cortical electrode assembly configured, in use, to sense electrical activity at a surface of a brain, the assembly comprising: a ring-shaped substrate; and a plurality of electrical sensors affixed to the ring-shaped substrate, wherein the plurality of electrical sensors are spaced along the ring-shaped substrate so as to form a ring of electrical sensors that substantially encircle an aperture formed by the ring-shaped substrate.