Provided is an in vivo implantable nerve stimulation platform which includes: a light source emitting light having a plurality of wavelength bands; and a photoelectric generator generating electricity for stimulating a nerve or a tissue by the light emitted from the light source, in which the light source and the photoelectric generator are implanted in vivo.

The present disclosure relates to systems, methods, and uses of systems for treating a skin condition with phototherapy. A system comprises (a) a phototherapy device comprising a phototherapy light source; (b) a patient computing device comprising a processor and a memory, the patient computing device configured to: transmit a first signal to the phototherapy device enabling operation of the phototherapy device according to one or more conditional prescription parameters, activate the phototherapy light source, and transmit a second signal reporting operation of the phototherapy device; and (c) a server configured to communicate with the patient computing device and receive the second signal.

A laser treatment system includes a laser device configured to produce a laser beam at a wavelength in an ultraviolet spectrum to provide for tissue ablation, a lens configured to focus and direct the laser beam to a site to form an opening in a surface of the site, a valve connected to a first channel, and a nozzle that emits the laser beam and controls delivery of at least a first substance and a second substance to the site. A portion of the first channel is disposed within a first sidewall of the nozzle to deliver the first substance, and a second channel unconnected with the valve is disposed within a second sidewall of the nozzle to deliver the second substance.

Low level light (LLL) can be used to restore a subject's gut microbiota to a state of health. The LLL can be applied directly to the subject's abdomen and/or back, or the LLL can be applied to a feces sample obtained from the subject, which is subsequently administered back to the subject. The subject may be suffering from guy dysbiosis resulting from a variety of different types of bodily stress, such as chemotherapy or radiation therapy.

A light therapy bed including multiple LEDs positioned in individually controllable modules is disclosed. The modules of LEDs are configured to have direct contact or in close proximity to the skin or tissue of the user, through an acrylic or similar cover. The LEDs light the surface and underlying layers of tissue for photodynamic stimulation of the cells. Iterations of the device utilize light known to have a bactericidal effect in the case of acne, MRSA, etc. The bed is fabricated and formed in a curved configuration to optimize contact between the LEDs and the skin of a user. Each of the LED modules may be mounted with a PCB in an arrangement to provide even lighting and temperature upon the skin or tissue surface of a user. Each module also has one or more thermal sensors that evenly and quickly heat all of the areas of a user's body.

The present disclosure relates to systems, methods, and uses of systems for treating a skin condition with phototherapy. A system comprises (a) a phototherapy device comprising a phototherapy light source; (b) a patient computing device comprising a processor and a memory, the patient computing device configured to: transmit a first signal to the phototherapy device enabling operation of the phototherapy device according to one or more conditional prescription parameters, activate the phototherapy light source, and transmit a second signal reporting operation of the phototherapy device; and (c) a server configured to communicate with the patient computing device and receive the second signal.

A method for treating an oral cavity malady of a patient, comprising: applying a spot of a laser beam to a target area around the oral cavity, said laser beam having a wavelength of about 800 to 840 nm and a power of between 1000 and 4000 mW, and wherein said spot has a spot size of about 1 to about 10 mm; and moving said spot on said target area for a treatment time sufficient to deliver a dose of about 0.5 to about 30 J/cm.sup.2 to said target area.

A device that is connectable to a phototherapy apparatus for applying targeted phototherapy to an area of skin to place a skin condition into remission and a method of determining a maximum tolerable dose of phototherapy applied to a treatment area to determine an optimum therapeutic dose to quickly place a skin condition into remission. The dosimetry device can include a housing and an optical matrix arranged within the housing. The optical matrix includes a plurality of at least one of absorptive, reflective and/or partially transmissive regions that each permits a different percentage of light to be delivered to an individual's skin. An assessment can then be made as to the maximum tolerable dose of phototherapy that can be applied to the individual's skin in order to place a skin condition into remission.

A computerized method for controlling the operation of a laser therapy device is disclosed. A laser therapy device comprising laser diodes has a microprocessor for storing and executing instructions pertaining to the operation of the laser diodes within certain parameters. The computerized method detects the movement of the laser therapy device and alters the output of the laser diodes when a movement signal exceeds predetermined threshold parameters. The computerized method detects difference in temperature in certain areas, and patterns in temperature differences, for assistance in diagnosing ailments. The computerized method also detects differences in skin color to determine treatment areas. The computerized method also measures the distance of the laser therapy device to a treatment area. The microprocessor executes instructions then which can alter the output of the laser diodes or generate an alarm signal based on measurements received.

A photodynamic therapy (PDT) apparatus and method are disclosed. The PDT apparatus includes a light flap that includes a plurality of light emitting devices wherein each of the light emitting devices has a plurality of operating states. The plurality of operating states are used to train a neural network model capable of producing a treatment irradiance profile. The method includes using an image of an area of interest for targeted treatment of PDT wherein the image is used an input to the trained neural network model. The neural network model produces a plurality of optimized feature states and the apparatus in turn produces a treatment irradiance profile closely matching the area of interest.