A phototherapy system can provide functions such as user account management, skin type evaluation, treatment parameter determinations and adjustments, treatment blocking or warnings for some hazard prevention, treatment education and guidance, session records access, treatment regime determination, scheduling, and converting treatment parameter determinations into kiosk controls. The phototherapy system functions can be performed based on user input, records of user data, guidelines and algorithms for treatment parameter selection, direct measurements, etc. These data sources can be accessed or implemented though one or more of: a phototherapy kiosk, a personal computing device, a server system, a third-party system, or any combination thereof. An interactive user interface can be used though any of these devices to facilitate user control and user feedback for the phototherapy system.

A chamber providing controlled amounts of IR and visible light within an internal space sized to seat at least one human being. The chamber includes at least one heater configured to emit FIR energy, at least one heater configured to emit NIR energy, and at least one heater configured to emit at least MIR energy. The chamber includes at least one light emitting source configured to emit a selected wavelength of visible light, and a control panel configured to control the amount and duration of FIR, MIR, NIR and visible light within the chamber.

Dynamic dosing systems for phototherapy and associated devices, systems, and methods are disclosed herein. In some embodiments, a dynamic dosing phototherapy system can include a self-service phototherapy kiosk (SPK) configured to emit UV radiation, a user interface communicatively coupled to the SPK, and a dynamic dosing system communicatively coupled to the user interface and the SPK. The dynamic dosing system can determine initial, user-specific parameters specific to define a first individual phototherapy protocol, and then determine adjustments to the initial parameters and the first individual phototherapy protocol based on user inputs related to erythema response to a previous phototherapy treatment session. The SPK can deliver UV radiation to a user in accordance with the first individual phototherapy protocol and/or an adjusted, second phototherapy protocol that takes into account the user's erythema response.

Technology for a light therapy device is disclosed. The light therapy device can comprise: a housing; and a combination of light sources coupled to the housing in an orientation operable to radiate a subject, and provide light therapy from the combination of light sources. The combination of light sources can include: a first discrete light source configured to emit light at a wavelength limited to between about 500 nanometers (nm) to about 700 nm; a second discrete light source configured to emit light at a wavelength limited to between about 700 nm to about 850 nm; a third discrete light source configured to emit light at a wavelength limited to between about 800 nm to about 900 nm; and a fourth discrete light source configured to emit light at a wavelength limited to between about 850 nm to about 1050 nm.

Photobiomodulation therapy systems provide a highly effective way to treat many common ailments to the human body. Many embodiments described herein enable two or more light therapy devices to be communicatively coupled together in various ways. In some embodiments, the light therapy system includes a first light device and a second light device arranged and configured to be communicatively coupled to the first light device. Each of the light devices may include a housing, a communication module, and a plurality of lights arranged and configured to emit at least one of red light and near infrared light.

Photobiomodulation therapy systems provide a highly effective way to treat many common ailments to the human body. Many embodiments described herein enable two or more light therapy devices to be communicatively coupled together in various ways. In some embodiments, the light therapy system includes a first light device and a second light device arranged and configured to be communicatively coupled to the first light device. Each of the light devices may include a housing, a communication module, and a plurality of lights arranged and configured to emit at least one of red light and near infrared light.

Photobiomodulation therapy systems provide a highly effective way to treat many common ailments to the human body. Many embodiments described herein enable two or more light therapy devices to be coupled together in various ways. In some embodiments, the light therapy system includes a first light device and a second light device arranged and configured to be mechanically and/or electrically coupled to the first light device. Each of the light devices may include a housing and a plurality of lights arranged and configured to emit at least one of red light and near infrared light. The first light device and the second light device can be coupled in a side-by-side orientation or a top-to-bottom orientation. The light therapy system can also be coupled to a mobile stand or a door stand.

Systems and methods for biomodulation of a target volume of tissues within a living subject are provided. A biomodulation system can include a number of features, including a light-emitting system to produce an elevated molecular excitation state and coherent resonance energy transfer within a fluid volume, a fluid container configured to hold a fluid and the living subject to be treated, and a fluid management system of the fluid volume. The biomodulation system can implement a treatment regime involving variable control parameters including wavelength, irradiance, energy density, pulse frequency, peak power, irradiation time and others to affect biomodulation depending upon the characteristics and condition of a target volume within the living subject.

A phototherapeutic system in accordance with an embodiment of the present technology includes a housing at least partially defining an irradiation zone configured to accommodate at least a portion of a human subject. The system further comprises an ultraviolet (UV) radiation source configured to direct UV radiation along a radiation path extending from the radiation source to the irradiation zone. The radiation source includes a concentrated source at which UV radiation is generated, and a collimating reflector (or lens) configured to reflect (or refract) the UV radiation and thereby increase collimation of the UV radiation. The system still further comprises a filter, a spreader, and a collimator disposed successively farther downstream from the radiation source along the radiation path. The spreader and the collimator respectively decrease and increase collimation of the UV radiation before the UV radiation reaches the subject.

A whole body health chamber device is disclosed. The whole body health chamber device has a base portion, a lid portion, and a patient treatment area for receiving a patient disposed between the base portion and the lid portion. The health chamber device utilizes a plurality of emitter modules configured to emit radiation into the treatment area. Each of the emitter modules contains a plurality of light emitting diodes configured in an array. Each of the light emitting diodes preferably emits a different wavelength of radiation from the other light emitting diodes. The operation of the light emitting diodes are programmed such that the operation of each diode is controlled independently. The power level of any specific diode may be adjusted through pulse width modulation. The frequency of pulsing may vary for each specific diode. Emitter modules may be grouped together to be controlled in unison.