An unattended approach can increase the reproducibility and safety of the treatment as the chance of over/under treating of a certain area is significantly decreased. On the other hand, unattended treatment of uneven or rugged areas can be challenging in terms of maintaining proper distance or contact with the treated tissue, mostly on areas which tend to differ from patient to patient (e.g. facial area). Delivering energy via a system of active elements embedded in a flexible pad adhesively attached to the skin offers a possible solution. The unattended approach may include delivering of multiple energies to enhance a visual appearance.

A system and method for brainwave entrainment using virtual objects and gamification, in which brainwave entrainment is applied using some combination of gaming elements, brainwave is enhanced by virtue of the user's active participation, and long-term use is encouraged by virtue of the entertaining nature of the gamification. Depending on configuration, the system and method may comprise a display comprising virtual objects, a light-producing device (other than the display), an audio-producing device such as speakers or headphones, a haptic feedback device such as a vibratory motor, a means for monitoring the user's attention, and a software application which applies brainwave entrainment using some combination of the display, the light-producing device, the audio-producing device, and the haptic feedback device.

A wearable device that selectively reflects biophotons emitted naturally from the user's body back into the body, achieving beneficial health effects similar to low-level laser therapy without requiring an external laser device. Illustrative wavelengths that may be reflected may include 550 nm, 630 nm, 632 nm, 660 nm, 694 nm, 810 nm, and 980 nm. Radiation of wavelength 810 nm in particular has been shown to affect mitochondrial energy production. The device may be worn for example as a bracelet or pendant. Internal components may include one or more filters to select the desired wavelengths, and a parabolic mirror to reflect these selected wavelengths back into the body. Some embodiments may also include a polarizer so that reflected waves are polarized.

A wearable device that selectively reflects biophotons emitted naturally from the user's body back into the body, achieving beneficial health effects similar to low-level laser therapy without requiring an external laser device. Illustrative wavelengths that may be reflected may include 550 nm, 630 nm, 632 nm, 660 nm, 694 nm, 810 nm, and 980 nm. Radiation of wavelength 810 nm in particular has been shown to affect mitochondrial energy production. The device may be worn for example as a bracelet or pendant. Internal components may include one or more filters to select the desired wavelengths, and a parabolic mirror to reflect these selected wavelengths back into the body. Some embodiments may also include a polarizer so that reflected waves are polarized.

A therapeutic lighted catheter that can provide therapeutic light within a biological fluid passage for purposes of treatment and/or curing of materials within the passage. The catheter includes an elongated shaft having a first end and a second end positioned opposite the first end, the elongated shaft including a lumen extending substantially therebetween, and at least one light emitting element positioned within the elongated shaft. A control system is in electronic communication with the light emitting element and provides power thereto such that the powered light emitting element applies a light within the biological fluid passage for therapy and/or curing. The catheter can also include a means to apply a curable material.

Method and apparatus can be provided according to an exemplary embodiment of the present disclosure. For example, with at least one first section of an optical enclosure, it is possible to provide at least one first electro-magnetic radiation. In addition, with at least one second section provided within the enclosure, it is possible to cause, upon impact by the first radiation, a redirection of the first radiation to become at least one second radiation. Further, with at least one third section of the optical enclosure, it is possible to cause at least one second radiation to be provided to a tissue. For example, the redirection of the first radiation causes, at least approximately, a uniform optical illumination on of a surface of the tissue.

An adjustable illuminator for photodynamically diagnosing or treating a surface includes a plurality of first panels and at least one second panel. The plurality of first panels have wider widths and the at least one second panel has a narrower width. The narrower width is less than the wider widths. The illuminator further includes a plurality of light sources, each mounted to one of the plurality of first panels or the at least one second panel and configured to irradiate the surface with substantially uniform intensity visible light. The plurality of first panels and the at least one second panel are rotatably connected. The at least one second panel is connected on each side to one of the plurality of first panels. The second panel acts as a “lighted hinge” to reduce or eliminate optical dead spaces between adjacent panels when the illuminator is bent into a certain configuration.

A method of macular disease treatment (500) may include introducing nanocapsules into a body of a patient (502). The nanocapsules may be introduced such that the nanocapsules circulate through at least a portion of a body of the patient. A therapeutic substance and a colorant may be encapsulated into the nanocapsules. After a portion of the nanocapsules enters choroidal neovessels of an eye of the patient, the method may include emitting a pulsed laser radiation through a pupil of the eye (504). Additionally, after a portion of the nanocapsules enters choroidal neovessels of an eye of the patient, the method may include heating the portion of the nanocapsules present in the eye (506) such that at least a portion of the nanocapsules transfer phase and release the therapeutic substance.

A tooth whitening kit and method of whitening teeth using the same. The method may include applying a tooth whitening composition directly to surfaces of a user's teeth, exposing the surfaces of the user's teeth to ambient air for a first period of time to form a film of the tooth whitening composition on the surfaces of the user's teeth, applying light to the surfaces of the user's teeth for a second period of time while the film of the tooth whitening composition remains on the surfaces of the user's teeth, ceasing application of the light to the surfaces of the user's teeth and leaving the film of the tooth whitening composition on the surfaces of the user's teeth for a third period of time, and removing the film of the tooth whitening composition from the surfaces of the user's teeth.

Systems and techniques for configuring a light therapy oral guard include receiving sensed data from a first sensor associated with the light therapy oral guard, providing the sensed data from the first sensor to a machine learning model, receiving a machine learning output from the machine learning model based on the sensed data from the first sensor, the machine learning output comprising a light therapy oral guard configuration, and configuring the light therapy oral guard based on the light therapy oral guard configuration.