Methods of applying microcurrent stimulation to a subject may include providing a mask supplying at a minimum moisture to a region to be treated, applying a first electrode connected to a first polarity of microcurrent stimulation circuitry to the mask, applying a second electrode connected to a second polarity of the microcurrent stimulation circuitry to the subject outside of the mask, and providing microcurrent to the first electrode and the second electrode from the microcurrent stimulation circuitry. The method may further include inserting feet of the subject into a liquid having a minimum conductivity of 5 mS/m and vibrating the liquid.

An electrical venous stimulation apparatus comprising a powered signal generator, the signal generator configured to generate a specified electrical output signal. The apparatus also includes a plurality of electrodes in electrical communication with the signal generator and configured, to be placed in electrical communication with a subject, The electrical output signal sent to the subject, includes an output voltage, electrical current, and waveform that changes with time in a preprogrammed repeating cycle. The output voltage, electrical current, and waveform are configured to elicit a physiological response that stimulates a plurality of peripheral nerves in the subject, activates a venous muscle pump mechanism in one or more limbs of the subject, and non-invasively alter the physiology of target vein(s), wherein the target vein(s) is caused to distend under the surface of the subject's skirt.

A laser ionization therapy assembly having a reservoir defined by a peripheral wall and a base; a support device having a support coupling member and a support opening; and a laser module accommodating a laser diode, the laser module having an opening and a laser module coupling member, wherein the support device is fixedly attached to the peripheral wall of the reservoir and the laser module is detachably coupled thereto, wherein the laser diode is positioned at an angle relative to the base of the reservoir so that laser light is directed through the openings of the laser module and support device to a predetermined location within the reservoir at a height of between ½ inch to 1 inch above the base, and wherein the laser light has a wavelength of between about 630 and 640 nm and a peak power of about 10 mW.

A foot spa includes a body and an electrolysis device. The body has a receiving space for containing water. The electrolysis device is mounted on a bottom of the body and includes a case, a control module and two electrolyte plates. The control module is mounted inside the body. The two electrolyte plates are mounted on a top portion of the case and are electrically connected to the control module. When the foot spa is operated, salt water is added to the receiving space for the two electrolyte plates to be soaked into the salt water in generation of an electrolytic reaction, such that sodium hydroxide and hypochlorous acid can be generated from the salt water to sterilize and deodorize the feet of users and provide the hygienic advantage.

A laser ionization therapy assembly having a reservoir defined by a peripheral wall and a base; a support device having a support coupling member and a support opening; and a laser module accommodating a laser diode, the laser module having an opening and a laser module coupling member, wherein the support device is fixedly attached to the peripheral wall of the reservoir and the laser module is detachably coupled thereto, wherein the laser diode is positioned at an angle relative to the base of the reservoir so that laser light is directed through the openings of the laser module and support device to a predetermined location within the reservoir at a height of between inch to 1 inch above the base, and wherein the laser light has a wavelength of between about 630 and 640 nm and a peak power of about 10 mW.

A foot spa includes a body and an electrolysis device. The body has a receiving space for containing water. The electrolysis device is mounted on a bottom of the body and includes a case, a control module and two electrolyte plates. The control module is mounted inside the body. The two electrolyte plates are mounted on a top portion of the case and are electrically connected to the control module. When the foot spa is operated, salt water is added to the receiving space for the two electrolyte plates to be soaked into the salt water in generation of an electrolytic reaction, such that sodium hydroxide and hypochlorous acid can be generated from the salt water to sterilize and deodorize the feet of users and provide the hygienic advantage.

A laser ionization therapy assembly having a reservoir defined by a peripheral wall and a base; a support device having a support coupling member and a support opening; and a laser module accommodating a laser diode, the laser module having an opening and a laser module coupling member, wherein the support device is fixedly attached to the peripheral wall of the reservoir and the laser module is detachably coupled thereto, wherein the laser diode is positioned at an angle relative to the base of the reservoir so that laser light is directed through the openings of the laser module and support device to a predetermined location within the reservoir at a height of between inch to 1 inch above the base, and wherein the laser light has a wavelength of between about 630 and 640 nm and a peak power of about 10 mW.

Apparatus and methods which enable the stimulation of neurons oriented in all directions within a biological structure using applied magnetic fields.

A laser ionization therapy assembly having a reservoir defined by a peripheral wall and a base; a support device having a support coupling member and a support opening; and a laser module accommodating a laser diode, the laser module having an opening and a laser module coupling member, wherein the support device is fixedly attached to the peripheral wall of the reservoir and the laser module is detachably coupled thereto, wherein the laser diode is positioned at an angle relative to the base of the reservoir so that laser light is directed through the openings of the laser module and support device to a predetermined location within the reservoir at a height of between ? inch to 1 inch above the base, and wherein the laser light has a wavelength of between about 630 and 640 nm and a peak power of about 10 mW.

A laser ionization therapy assembly having a reservoir defined by a peripheral wall and a base; a support device having a support coupling member and a support opening; and a laser module accommodating a laser diode, the laser module having an opening and a laser module coupling member, wherein the support device is fixedly attached to the peripheral wall of the reservoir and the laser module is detachably coupled thereto, wherein the laser diode is positioned at an angle relative to the base of the reservoir so that laser light is directed through the openings of the laser module and support device to a predetermined location within the reservoir at a height of between inch to 1 inch above the base, and wherein the laser light has a wavelength of between about 630 and 640 nm and a peak power of about 10 mW.