An optical therapeutic device comprising a front body portion, a light source provided in said front body portion, a spherical, translucent quartz lens provided in front of said light source, a bezel provided on said front body portion and configured to hold said spherical, translucent quartz lens such that a portion of the quartz lens protrudes outside the rim of the bezel. Also described is a method of using the device to apply light stimulation to acupuncture points of a human or animal body and a method for manufacturing the device.

The present disclosure relates to a vaginal treatment device using LEDs, high-frequency waves, and EMS, the vaginal treatment device including: a main body part configured to be inserted into a vagina and having one or more LED irradiation units configured to irradiate an interior of the vagina with light, and electrode units configured to transfer radio frequency (RF) energy or electro muscular stimulation (EMS) energy into the vagina; a handle part embedded with a battery and having a power source member connected to one end of the main body part and configured to control transmission and reception to/from the LED irradiation units or the electrode units; and a housing part electrically connected to the handle part and configured to charge the battery.

A color temperature fusion lighting apparatus includes a first light source with a first color temperature, a second light source with a second color temperature, and a driver circuit. The driver circuit operates the lighting apparatus in two modes. In the first mode, the driver circuit operates the lighting apparatus in a first linear combination of the first light source and the second light source, resulting in a first operating color temperature for the lighting apparatus. In the second mode, the driver circuit operates the lighting apparatus in a second linear combination of the first light source and the second light source, resulting in a second operating color temperature. Moreover, the driver circuit is configured to alternate the operation of the lighting apparatus between the first mode and the second mode at a frequency F between 35 to 45 Hz, resulting in a blended color temperature of the first operating color temperature and the second operating color temperature for the lighting apparatus.

Methods and devices are disclosed for the non-invasive treatment of autoimmune diseases or disorders through the delivery of energy to target nervous tissue, particularly the vagus nerve.. A device for treating an autoimmune disease or disorder comprises one or more electrodes having a contact surface configured for contacting an anterior portion of an outer skin surface of a neck of a patient and an energy source coupled to the electrodes. The energy source is configured to generate one or more electrical impulses and to transmit the electrical impulses to the electrodes and transcutaneously through the anterior portion of the outer skin surface of the neck of the patient at or near a vagus nerve. The electrical impulses are sufficient to modulate the vagus nerve and to inhibit inflammation and treat the disorder.

Methods and therapeutic devices with noninvasive means for improving brain function and treating senile dementia including Alzheimer’s disease are described. The noninvasive means is selected from electrical stimulation, heat stimulation, IR (infrared) radiation or their combinations. In some embodiments, the method and device utilize electrical current passed through acupuncture sites on the human head to achieve desired therapeutical effects.

A light applicator (1) executes a transcutaneous photodynamic therapy (PDT), in tissue (25) of an organic body (23) and includes a needle section (5), extending longitudinally along an insertion axis (L), and at least one light-emitting element (7) at the distal end (3) of the needle section (5). An at least partially light-transparent applicator tip (9) extends at least distally from the at least one light-emitting element (7), for insertion of the needle section (5) into the tissue (25) of the organic body (23) along the insertion axis (L). A handgrip element (19) is arranged proximally with respect to the needle section (5) for manual positioning of the light applicator (1). The handgrip element (19) can be coupled to the needle section (5) for positioning and/or insertion, and is configured to be detachable from the needle section (5) for the execution of the PDT.

A system, for transcutaneous photodynamic therapy in an organ or organ segment of an organic body, includes a plurality of light applicators (9), a supply unit (23) and a placement template (39) placeable relative to the organic body for defined orientation of the light applicators. The light applicators include a needle-shaped insertion portion (15) for transcutaneous piercing along a piercing axis (E), a light-emitting applicator tip (19) at the distal end (13) of the insertion portion, and a fixing point (43) at a proximal distance d from the applicator tip. The placement template defines a plurality of fixing point receptacles (51) for fixing the light applicators with a defined fixing point and includes a first and second template parts (71, 75) defining first and second subsets (73, 77) of fixing point receptacles. The first template part is guidingly displaceable relative to the second template part along the piercing axis.

A system, for transcutaneous photodynamic therapy in an organ or organ segment of an organic body, includes a plurality of light applicators, a supply unit and a placement template placeable relative to the organic body for defined orientation of the light applicators. The light applicators include a needle-shaped insertion portion for transcutaneous piercing along a piercing axis, a light-emitting applicator tip at the distal end of the insertion portion, and a fixing point at a proximal distance from the applicator tip. The placement template defines fixing point receptacles for fixing the light applicators with a defined fixing point wherein the receptacles are arranged in accordance with a three-dimensional fixing point grid structure, that corresponds to a virtual organ-specific target point grid structure for the light-emitting applicator tips in the organ that is arranged parallel-displaced relative to the target point grid structure by the distance d along the piercing axis.

The present invention relates to a flexible skin patch equipped with an ultra-thin LED assembly that emits light in a specific wavelength range and an invention for manufacturing the same, and is related to an invention capable of providing a flexible skin patch that has the excellent effect of promoting vitamin D production in a localized area of the skin, and has the effect of alleviating or treating local skin psoriasis, fungi, fungal tumors and eczema, and has excellent antiviral effect, and is easy to attach and detach.

The present disclosure is directed to systems and methods that can apply low level light (LLL) to facilitate platelet biogenesis or extend platelet lifespan. While not wishing to be bound by theory, it is believed that LLL can enhance the ATP synthesis by the mitochondria within platelets and/or platelet precursor cells, which, thereby, helps to enhance platelet biogenesis and extend the platelet lifespan. In some instances, LLL can facilitate in vitro and/or in vivo platelet biogenesis. In other instances, LLL can extend platelet lifespan in circulation. In still other instances, LLL can be employed to prolong the shelf-life of stored platelets.