In one embodiment, a system for monitoring acne is disclosed. A sensor device includes an image sensor and a position sensor. A processing device receives image data and position data from the sensor device. The processing device then combines portions of the image data for different images to generate composite image data, the combination being based on the corresponding position data for each image. A user interface displays a composite image of the user's skin based on the composite image data, the composite image including a skin condition indicator.

A photodynamic therapy device of this disclosure includes: a light emitting unit (112, 112) including light sources (110) each belonging to any one of groups; a photodetector (120X, 120Y) configured to output an electrical signal corresponding to an amount of light received from the light sources (110); a light emission control unit (160) configured to sequentially cause the light sources (110) to emit light for each group; and a computing unit (151) configured to calculate, based on a distance coefficient related to a distance between the photodetector (120X, 120Y) and the light sources (110) belonging to the each group, and on a value of the electrical signal output by the photodetector (120X, 120Y) in accordance with light emitted from the light sources belonging to the corresponding group, a group light amount value related to a light amount of the light sources belonging to the each group.

Systems and method relate to administering phototherapy. A device includes a hollow structure having at least a first open end. The hollow structure includes a rotatable member, one or more coherent light generators, and, for each coherent light generator, one or more lenses or mirrors optically connected to the coherent light generator and configured to alter at least one aspect of a beam of coherent light. The device further includes a processing circuit including a processor and a memory storing instructions. The instructions, when executed by the processor, cause the processor to accept an input from an operator and generate one or more beams of coherent light according to a plurality of settings configured to produce a therapeutic effect at a targeted treatment site. Additionally, the rotatable member is configured to be rotated to direct the one or more beams of coherent light to the targeted treatment site.

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.

Systems tune, control, or remediate the intrinsic Circadian clock. A light controller sets spectral distribution, intensity of a bioactive spectral band to shift or entrain circadian response to enhance performance and/or synchronize with local or expected conditions. The systems enhance performance under conditions that might be changing, disrupted, or otherwise present an irregular phase or unnatural change in the subject's circadian status, for example, due to geographically discontinuous activity or spectrally deficient workplace illumination, or due to divergent individual sleep/wake behaviors of subjects in a structured group activity. An illumination recipe that compensates for the deficiency of lighting or of participant sleep or behavior patterns, or age- or disease-related changes, to evoke, shift, or align circadian response and improve behaviors such as classroom alertness, relaxation, excitability, attention, or focus. Systems may receive sensed light values and automatically apply high- and/or low-CER illumination to effect the intended circadian phase.

A method of delivering light energy to a pathological tissue includes emitting light energy from a first optical element within a cannula, producing a substantially uniform irradiance profile from the light energy within the cannula, transmitting the light energy emitted from the first optical element through a second optical element in thermal contact with a distal end of the cannula to the pathological tissue without ablating the pathological tissue, and conducting thermal energy from the pathological tissue through the second optical element and to the cannula.

Provided is a light irradiation system and a light irradiation device that irradiate an eye of a subject with light having a predetermined wavelength band to produce a non-visual effect in mind and body of the subject. A light irradiation system according to an aspect of the present disclosure includes an irradiator configured to irradiate an eye of a subject with irradiation light having a predetermined wavelength band, and a shielding mechanism configured to decrease illuminance of light different from the irradiation light or decrease illuminance of light included in light different from the irradiation light and having a wavelength band different from the predetermined wavelength band.

Medical conditions in tissues are simultaneously imaged and treated using light within selected wavelength ranges. By treating conditions, such as wounds, lesions, and tumors, at the same time that they are imaged, the overall diagnostic and treatment time is substantially reduced.

In order to achieve improved dose control, a device for irradiating an object having an optically observable property is provided. The device includes an applicator for irradiating the object, and a detector system that is configured to capture light being emitted from an irradiated region and, based thereon, to generate a detector signal. A processor unit is configured to calculate a value for the property based thereon and, based on the calculated value, to determine a dose for the irradiation.

Methods and systems are described for implementing a photodynamic therapy. An example method may comprise determining, during photodynamic therapy and using a plurality of optical probes spatially distributed within a patient, data indicative of one or more of a photodynamic therapy dosage, a fluence rate of a photodynamic therapy treatment light, or a reactive oxygen species concentration associated with corresponding locations of the plurality of optical probes. The example method may comprise changing, based on the data, one or more treatment parameters associated with providing a photodynamic therapy.