Disclosed is a process whereby galvanic skin response is measured after the stimulation of the cranium by micro direct current. The body is stimulated through the cranium by micro direct current by creating a cybernetic loop of a loop of current-carrying material, after which the body's responses are measured. The process uses a galvanic skin response and voltage measuring and frequency counting unit; this galvanic skin response data is then used in the same process cycle to generate secondary stimulation. The cybernetic loop is attached to the upper part of the cranium with three connection points to the upper forehead. All parts are connected with the electrode coil, consisting of five clockwise and five counter-clockwise loops, the silver necklace around the neck used as grounding, and the appropriate jack outputs. The method uses the input signals processed by the control software and the emitted micro direct current.

Disclosed is a process whereby galvanic skin response is measured after the stimulation of the cranium by micro direct current. The body is stimulated through the cranium by micro direct current by creating a cybernetic loop of a loop of current-carrying material, after which the body's responses are measured. The process uses a galvanic skin response and voltage measuring and frequency counting unit; this galvanic skin response data is then used in the same process cycle to generate secondary stimulation. The cybernetic loop is attached to the upper part of the cranium with three connection points to the upper forehead. All parts are connected with the electrode coil, consisting of five clockwise and five counter-clockwise loops, the silver necklace around the neck used as grounding, and the appropriate jack outputs. The method uses the input signals processed by the control software and the emitted micro direct current.

An apparatus of self-adjustment belt with bumps is used during physical exercise, stretching, or just worn around a user's body to provide support, resistance, create compression, and offer a self-guided automatic adjustment. The apparatus provides constant conscious body awareness and can help enhance balance reactions and re-educate muscles. The bumps of the apparatus help relieve muscle tension by applying pressure and gentle massage to chiropractic trigger points of the user's body. The apparatus is equipped with sensors providing health data and monitoring activity or any health changes. Additionally, the apparatus provides heating and/or cooling to desired areas of the user's body. Further, the vibrators inside the bumps of the apparatus offer a better massage through vibration, which can also be light tapping, or electric stimulation, to relieve muscle tension and strain, tone muscles, and stimulate the circulatory system of the user.

The present invention promotes the activation of various physiological functions according to the stimulation of the body by superimposing a reference wave microcurrent of a low frequency and a main wave microcurrent of a high frequency into a preset pattern, or by additionally superimposing a multiple superimposed wave microcurrent discretely having a frequency of a larger magnitude sequentially than the main wave microcurrent and applying it to living organisms, and enables that the use and expandability can be increased by providing an additional configuration in which a multifunctional portable housing that can select AC electric stimulation and DC electric stimulation is worn on the wrist of the human body, thereby enabling the application of an electrical stimulation tailored to the body or disease/health condition of a user.

The present invention promotes the activation of various physiological functions according to the stimulation of the body by superimposing a reference wave microcurrent of a low frequency and a main wave microcurrent of a high frequency into a preset pattern, or by additionally superimposing a multiple superimposed wave microcurrent discretely having a frequency of a larger magnitude sequentially than the main wave microcurrent and applying it to living organisms, and enables that the use and expandability can be increased by providing an additional configuration in which a multifunctional portable housing that can select AC electric stimulation and DC electric stimulation is worn on the wrist of the human body, thereby enabling the application of an electrical stimulation tailored to the body or disease/health condition of a user.

A biological function measurement and analysis system, a biological function measurement and analysis method, and a recording medium storing program code causing a computer to execute the biological function measurement and analysis method. The biological function measurement and analysis system includes an input acceptance unit configured to accept selection of a biological function to be measured, and a measurement and analysis procedure determining unit configured to access a memory in which measurement and analysis procedure data, indicating a combination of measurement and analysis of reaction of a live subject caused by stimulation on a biological-function-by-biological-function basis, is stored to specify measurement and analysis procedure data corresponding to the selected biological function. The biological function measurement and analysis method includes accepting the selection of biological function to be measured, accessing the memory, and specifying the measurement and analysis procedure data corresponding to the selected biological function.

A device for transcutaneous electrical stimulation is provided. The device comprises circuitry configured to generate transcutaneous stimulation signals. The device also comprises a first signal output component for electrically connecting to a first electrode connector to deliver generated transcutaneous stimulation signals. The first signal output component comprises a first four-pole electrical connector part. The device further comprises a second signal output component for electrically connecting to a second electrode connector to deliver generated transcutaneous stimulation signals. The second signal output component comprises a second four-pole electrical connector part. The device further comprises a controller to selectively control output of the stimulation signals to selected pairs of poles across the first and second four-pole electrical connector parts. Each selected pair of poles comprises one pole from the first four-pole electrical connector part and one pole from the second four-pole electrical connector part.

A device for transcutaneous electrical stimulation is provided. The device comprises circuitry configured to generate transcutaneous stimulation signals. The device also comprises a first signal output component for electrically connecting to a first electrode connector to deliver generated transcutaneous stimulation signals. The first signal output component comprises a first four-pole electrical connector part. The device further comprises a second signal output component for electrically connecting to a second electrode connector to deliver generated transcutaneous stimulation signals. The second signal output component comprises a second four-pole electrical connector part. The device further comprises a controller to selectively control output of the stimulation signals to selected pairs of poles across the first and second four-pole electrical connector parts. Each selected pair of poles comprises one pole from the first four-pole electrical connector part and one pole from the second four-pole electrical connector part.

An electrode connector assembly for the use in transcutaneous electrical stimulation includes a flexible web extending in a plane and first, second, third and fourth electrode connectors carried by the web and spaced from each other about the web in the plane. The electrode connector assembly further includes an electrical connector and first, second, third and fourth conductors electrically coupling the respective first, second, third and fourth electrode connectors to the electrical connector.

An electrode connector assembly for the use in transcutaneous electrical stimulation includes a flexible web extending in a plane and first, second, third and fourth electrode connectors carried by the web and spaced from each other about the web in the plane. The electrode connector assembly further includes an electrical connector and first, second, third and fourth conductors electrically coupling the respective first, second, third and fourth electrode connectors to the electrical connector.