Electrical non-invasive brain stimulation (NIBS) delivers weak electrical currents to the brain via electrodes that are affixed to the scalp. NIBS can excite or inhibit the brain in areas that are impacted by that electrical current during and for a short time following stimulation. Electrical NIBS can be used to change brain structure in terms of increasing white matter integrity as measured by diffusion tensor imaging. Together the electrical NIBS can induce changes in brain structure and function. The present methods and devices are adaptable to and configurable for facilitating the enhancement of brain performance, and the treatment of neurological diseases and tissues. The present methods and devices are advantageously designed to utilize modern electrodes deployed with, inter alia, various spatial arrangements, polarities, and current strengths to target brain areas or networks to thereby enhance performance or deliver therapeutic interventions.

A novel photobiomodulation (PBM) system and method that comprehensively directs therapeutic light energy into the brain from a combination of transcranial (through the skull) and intranasal (via the nasal channels) locations. In a preferred embodiment, the PBM device works in combination with a diagnostic tool to provide enhanced treatment of abnormal brain function intelligently, automatically, and unrestricted by geographical distances.

A novel photobiomodulation (PBM) system and method that comprehensively directs therapeutic light energy into the brain from a combination of transcranial (through the skull) and intranasal (via the nasal channels) locations. In a preferred embodiment, the PBM device works in combination with a diagnostic tool to provide enhanced treatment of abnormal brain function intelligently, automatically, and unrestricted by geographical distances.

Techniques are described for a non-invasive detection of a health condition of an organ. In an example, the electrical conductivity of the organ reflects the organ's health of. An inductive damping sensor can be used to detect the organ's electrical conductivity and, thus, its health. The inductive damping sensor can be placed in proximity of the organ such as the organ is within the magnetic field generated based on a coil of the inductive damping sensor. The conductivity of the organ impacts the inductance and the resistance of the coil. Hence, the inductance and/or resistance of the coil can be measured, where the measurements can be associated with the health of the organ.

Techniques are described for a non-invasive detection of a health condition of an organ. In an example, the electrical conductivity of the organ reflects the organ's health of. An inductive damping sensor can be used to detect the organ's electrical conductivity and, thus, its health. The inductive damping sensor can be placed in proximity of the organ such as the organ is within the magnetic field generated based on a coil of the inductive damping sensor. The conductivity of the organ impacts the inductance and the resistance of the coil. Hence, the inductance and/or resistance of the coil can be measured, where the measurements can be associated with the health of the organ.

A method of making an array of vapor cells for an array of magnetometers includes providing a plurality of separate vapor cell elements, each vapor cell element including at least one vapor cell; arranging the vapor cell elements in an alignment jig to produce a selected arrangement of the vapor cells; attaching at least one alignment-maintaining film onto the vapor cell elements in the alignment jig; transferring the vapor cells elements and the at least one alignment-maintaining film from the alignment jig to a mold; injecting a bonding material into the mold and between the vapor cell elements to bond the vapor cell elements in the selected arrangement; removing the at least one alignment maintaining film from the vapor cell elements; and removing the bonded vapor cells elements in the selected arrangement from the mold to provide the array of vapor.

Provided are methods and systems of for enhancing or increasing memory performance and/or memory retrieval in a subject using neurofeedback training. Also provided herein are methods and systems for modulating hippocampal replay in a subject using neurofeedback training. Also provided herein are methods and systems for modulating sharp wave ripple (SWR) activity in a subject using neurofeedback training

Provided are methods and systems of for enhancing or increasing memory performance and/or memory retrieval in a subject using neurofeedback training. Also provided herein are methods and systems for modulating hippocampal replay in a subject using neurofeedback training. Also provided herein are methods and systems for modulating sharp wave ripple (SWR) activity in a subject using neurofeedback training

Various embodiments comprise systems and methods to model the shape of a target subject to coregister an image generated by an on-subject sensor array to the anatomy of the subject. In some examples, a system constrains sensors to follow the contour of the target subject. The system generates a surface contour representation of the target subject based on the locations of the individual ones of the sensors. The system fits the surface contour representation of the target subject to an outer surface feature of an anatomical scan.

Various embodiments comprise systems and methods to model the shape of a target subject to coregister an image generated by an on-subject sensor array to the anatomy of the subject. In some examples, a system constrains sensors to follow the contour of the target subject. The system generates a surface contour representation of the target subject based on the locations of the individual ones of the sensors. The system fits the surface contour representation of the target subject to an outer surface feature of an anatomical scan.