A phototherapy device (100) and a phototherapy instrument (500), comprising a near infrared irradiation module (110) used for emitting near infrared light to the head, and a control component (120) used for controlling the operation of the near infrared irradiation module (110) and coupled to the near infrared irradiation module (110). A method for using near infrared light for therapy, which comprises applying a first, optional second, optional third or more near infrared lights to the head of a patient. The device and method are used for treating Alzheimer's disease, improving brain mitochondrial function and ATP levels, promoting amyloid beta protein (Aβ) decomposition, reducing Aβ deposition, reducing damage to nerve cells, improving nerve tissue repair and regeneration capabilities, improving cognitive ability etc. A therapy method using the phototherapy device (100) or the phototherapy instrument (500), and a computer readable recording medium controlling required near infrared light.

Exemplary embodiments described herein provide systems and methods for administer multiple stimulus to a patient in order to improve the efficacy of the administered stimulus on the brain activity of the patient. Exemplary embodiments described herein may combined magnetic stimulation along with sensory stimulation to influence the intrinsic frequency of an EEG band of a person.

The subject matter of the invention is a therapeutic device in the form of a cylindrical chamber which comprises a hyperbaric chamber, LED matrices (5) and inductive coil rings (10, 11, 12, 13), constructed in one inseparable set in the form of a chamber of 200-280 cm in length and diameter of the round cylinder (70-130 cm).

Systems and method for destroying or inhibiting cancer cells and other rapidly-dividing cells include applying AP magnetic fields having a defined frequency of 5 Hz-500 kHz and a field strength of 0.1-5000 μT to a target body area that includes the cancer or other rapidly-dividing cells, and modifying the cancer or tumor microenvironment to increase the presence of cancer-suppressive cells or decrease the presence of cancer-promoting cells. In various embodiments, the systems and methods may include adjusting the therapy based on the dosage of an immunotherapy drug administered to the patient before, during, or after the application of the AP magnetic fields.

A method of stimulation treatment for medical disorders using stimulation parameters that provide stimulation of a target site directly or create partial stimulation signals that combine into vector signals that stimulate a target site. Stimulation signals have characteristics such as frequency, timing, temporal content that is adjusted for the person being treated. Signals are designed with advantageous characteristics to influence target tissue in an intended manner and avoid producing unwanted side-effects. Stimulation signals are designed to match or avoid internal/endogenous activity (e.g., brain patterns and rhythms) of a patient. Methods for choosing, creating and partial signals are provided. Tissue modulation may be accomplished with electrical and/or magnetic stimulation, such as repetitive transcranial magnetic stimulation.

A magnetic stimulation system may include first and second subsystems. The first subsystem may include a first stimulator, a first coil, and a first processor configured to determine stimulation parameter data for a subject. The second subsystem may include a second stimulator, a headpiece including an identifier and a second coil mounted to a headpiece body at a fixed location, an image recording device, and a second processor configured to: receive first image data for one or more first images of the subject and headpiece; receive, from the image recording device, second image data for one or more second images of the subject and headpiece; determine, using the first and second image data, that the stimulation parameter data corresponds to the subject; determine, using the second image data, that the headpiece corresponds to the subject; and determine, using the second image data, that the headpiece is at a pre-determined position.

Magnetosomes for use in a sequential laser radiation medical treatment, wherein the magnetosomes are administered to a body part of an individual. In a first step, the magnetosomes are irradiated by a laser radiation, and in a second step, the magnetosomes are irradiated by a laser radiation of lower power than in the first step or no laser irradiation of the magnetosomes is performed. The sequence of the first step and second step is repeated at least once.

A composition for targeting low-density lipoprotein receptor-related protein 6 (LRP6)-overexpressed cells. The composition includes a peptide including at least one of SEQ ID NO: 1 and SEQ ID NO: 3.

A method facilitates altering consciousness by transcranial stimulation to adjust the membrane potential duration of sensory cortex dendritic spine necks. Sensory cortex spine neck membranes are conscious. The method comprises the steps of placing electrodes on or near a scalp; applying electric fields to spine neck membranes in sensory cortex; adjusting stimulation parameters; and altering consciousness for a predetermined duration.

Provided herein are methods and devices for inductively heating a tissue to effect a biological response in the tissue or in a biomolecule comprising the same. The methods and devices comprise means for applying a high frequency alternating magnetic field via an inductive coil comprising an applicator to the tissue and means for monitoring feedback from the alternating magnetic field to control and/or adjust heat, for example, in the tissue, which further includes a means for cooling the tissue. Particularly, the device may be a hand held piece that incorporates or has at least an applicator, including a radiofrequency energy generator and output, an inductive coil, an impedance matching system, a cooling system, including a thermally conductive surface and a coolant housing containing a coolant that circulates through the thermally conductive surface, and a feedback monitor. Optionally, the device may comprise a tissue-shaper.