An exemplary system, method and computer-accessible medium can be provided that can, for example, can be provided so as to receive regarding at least one portion of an ophthalmic sample(s) based on a radiation(s) provided from the sample(s). In addition, it is possible to determine whether an inflammation marker(s) is present in a portion(s) of the sample(s) based on the information. Further, an identification can be performed as to that an abnormality(s) exists in a further anatomical structure based on the determination. The further anatomical structure can be different from the sample(s).

A method of enhanced motor learning is provided. The method includes stimulating a cutaneous distribution of a patient's vagus nerve within the patient's ear with a nerve stimulating signal. The method also includes assisting the patient in performing a physical activity while the patient's vagus nerve is stimulated. The method further includes monitoring one or more statistics of the patient during the physical activity.

The present disclosure provides a method for improving imaging resolution of electrical impedance tomography (EIT). More specifically, the present disclosure forms virtual electrode(s) using an electric current steering technique, which is used to improve imaging resolution of an EIT system without physically increasing a number of conducting electrodes. The EIT system of the present disclosure may includes a plurality of conducting electrodes, at least one signal generator, at least one signal receiver and at least one electric current steering device. In other words, the present disclosure applies both the electric current steering technique and the virtual electrode technique to EIT. Consequently, imaging resolution of EIT can be improved without physically increasing the number of conducting electrodes.

The present invention relates to a non-invasive system with diagnostic and treatment capacities that use a unified code that is intrinsic to physiological brain function. In an embodiment of the present invention, an approach to the treatment of disorders that supplements existing diagnostic and treatment methods with robust quantitative data analysis are presented. This is achieved by a unification of cognitive and neural phenomena known as the Fundamental Code Unit (FCU), representing identifiable patterns of brain activity at the submolecular, molecular, and cellular levels (intra-brain communications), as well as their manifestations in thought and language (inter-brain communications).

Techniques for determining the location of a physiological midline are disclosed. A first technique evaluates the response to stimulation of spinal electrodes at peripheral electrodes on different sides of the body. In this technique, a spinal electrode's position relative to a physiological midline is determined based on a relationship between responses to its stimulation observed on different sides of the body. A second technique evaluates the response of spinal electrodes to stimulation of peripheral electrodes on different sides of the body. In this technique, a spinal electrode's position relative to a physiological midline is determined based on the different responses that it observes to stimulation on different sides of the body.

A method of analyzing a spinal region of a subject. The method includes steps of obtaining a first sagittal image of the spinal region of the subject using an upright magnetic resonance imaging unit; identifying a first vertebral edge on a first side of a first disc in the first sagittal image; identifying a second vertebral edge on a second side of the first disc in the first sagittal image; and determining a first angle between the first vertebral edge and the second vertebral edge for the first disc.

An implantable device for the electrical and/or pharmaceutical stimulation of the central nervous system, especially the spinal cord, is suggested. The device comprises a conformable substrate which is primarily composed of a flexible and stretchable polymer, and a plurality of flexible electrodes and conductive leads embedded in the conformable substrate. Not only the substrate, but also the leads are stretchable. The substrate may consist of PDMS, and the leads may consist of a conductive PDMS, in particular, PDMS with an electrically conductive filler material, and may optionally be metal-coated. The device defines a multi-electrode array which may be employed for neurostimulation in the epidural or subdural space of an animal or human.

A spinal implant includes a link having a first surface and a second surface connectable with a spinal construct. The spinal construct is attachable with one or more vertebral levels. A plurality of electrodes includes at least one electrode disposed with the first surface and at least one electrode disposed with the second surface such that the electrodes conduct an electric current to stimulate tissue growth adjacent the spinal construct. Systems, surgical instruments and methods are disclosed.

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.

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.