Systems, methods, and devices for taking bioelectric measurements of a test subject using an automated bioelectric measurement system. A bioelectric testing device may include a conductive tip that is disposed at a distal end of the bioelectric testing device, and a vibration motor for vibrating the conductive tip during bioelectric testing of a test subject. The bioelectric testing device may further include a motor that applies a motor output force to the conductive tip during bioelectric testing to maintain proper force between a test subject and the conductive tip during the bioelectric testing. The one or more vibration motors may vibrate to provide alerts about operation or operability of the bioelectric testing device to a technician or test subject, to improve conductance between the device and the test subject, or to decrease discomfort and pain for the test subject.

The present invention provides an acumoxa therapy device utilizing energy waves for preventing, alleviating or treating COVID-19 (SARS-CoV-2) coronavirus infection. In one embodiment, the device delivers energy in a non-invasive manner. In one embodiment, the device is configured to include an energy pin and one or more energy rings. In one embodiment, the device delivers sufficient energy to certain body parts such as acupoints to achieve an intervening and/or therapeutic effect. In one embodiment, the device can maintain or improve general health, or can alleviate or treat a subject with COVID-19 infection and one or more other conditions. In one embodiment, the present invention also discloses a system comprising the device and uses thereof.

Embodiments of dermatological cell treatment are described generally herein. Other embodiments may be described and claimed.

A body physiotherapy machine contains a conductive sphere member and a body configured to output electric physiotherapy energy to the conductive sphere member. The conductive sphere member is held by a user to contact his/her discomfort or acupuncture points so as to comfort the user and to enhance metabolism by ways of the electric physiotherapy energy, thus maintaining health easily.

The present methods and apparatus can provide improved efficacy with improved tolerance. The methods and apparatus can be configured to alter the stimulus, which can decrease neural adaptation of the subject and provide an improved response. The acoustic stimulus can be delivered as a tone, which can make the stimulus more acceptable to the subject receiving the stimulus. The stimulus may comprise a varying stimulus in order to decrease neural adaptation to the stimulus. The stimulus can be varied by varying one or more of a duty cycle, a frequency, or a shape of the waveform. The waveform may comprise a plurality of individual pulses, in which the waveform varies among pulses of the plurality. Acoustic stimulation can be combined with electrical stimulation. The device may comprise a plurality of sensors to determine the response of the subject.

A composition that includes at least one clinochlore and a resin is described. A method of treating a user that includes applying a composition including a piezoelectric material such as a clinochlore and a polymerized resin to at least one acupuncture or acupressure point of a user is also described.

Devices, systems and methods for stimulating (e.g., noninvasively) a subject's inflammatory reflex are provided to reduce bleed time. The method may include the step of non-invasively stimulating the inflammatory reflex (e.g., the vagus nerve, the splenic nerve, the hepatic nerve, the facial nerve, and the trigeminal nerve) of a subject, such as by mechanical stimulation, in a manner which significantly reduces bleed time in the subject. Devices for non-invasively stimulating the inflammatory reflex may include a movable tip or actuator that is controlled to mechanically stimulate the ear. The devices may be hand-held or wearable, and may stimulate the cymba conchae region of the subject's ear.

A piezoelectric system for ultrasonic thermotherapy and electrotherapy comprises a first piezoelectric element, a proof mass, a second piezoelectric element and an output unit. The proof mass is disposed between the first piezoelectric element and the second piezoelectric element. The first piezoelectric element is powered by a power source to generate oscillation, which is transferred by the proof mass to the second piezoelectric element so as to cause the second piezoelectric element to move and generate power. The output unit comprises a connecting surface and a tip surface. The output unit is electronically connected with the second piezoelectric element, wherein the connecting surface is connected with the first piezoelectric element and the tip surface is formed in a tapered shape. The oscillation from the first piezoelectric element and the power generated by the second piezoelectric element are output through the tip surface.

The disclosure provides for a device and method for vibrational, electrical, and magnetic therapy. The device may include a main controller board, a power source, a power switch harness connected to the power source, a vibration module comprising two to more motors capable of generating a multidirectional mechanical vibration, and an input controller. The device may further produce a micro-electrical current and a micro-magnetic field.

Control method for oscillating motor and osculating motor The control unit is further used for storing the set pulse parameters, and outputting alternating pulses with corresponding pulse widths and frequencies according to the set pulse parameters, so that the oscillating arm oscillates in an oscillation mode corresponding to the pulse parameters; wherein the oscillation mode comprises at least one of a full-amplitude oscillation mode, a sub-amplitude oscillation mode, an in-situ shaking mode and a composite oscillation mode, wherein the composite oscillation mode is generated by superposition of the full-amplitude oscillation mode and the in-situ shaking mode, or is generated by superposition of the sub-amplitude oscillation mode and the in-situ shaking mode.