A sensor system, for use in a phototherapy system for treatment of neonatal jaundice, designed to harvest energy from the phototherapy system. The sensor system is wirelessly connected to the phototherapy system and provides measurements of the total serum bilirubin levels of the infant. The continuous measurement of the total serum bilirubin allows the phototherapy system to personalize the treatment of each infant, minimizing any unwanted side effects of the phototherapy. The energy harvesting performed by the sensor removes the need to manually replace or recharge batteries, which may disturb the infant during treatment, and may enable the sensor system to operate without an energy storage device, such as a battery, altogether.

A phototherapy blanket configured to cover, support, and/or envelop at least part of a subject, the phototherapy blanket comprising: a set of light sources configured to emit electromagnetic radiation, wherein the set of light sources is held and/or carried in by the phototherapy blanket; a temperature sensor configured to generate a first signal conveying information related to a temperature of a region of a surface of the at least part of the subject covered, supported, and/or enveloped in the phototherapy blanket, a surface sensor configured to provide information about presence of the surface of the at least part of the subject, wherein the surface sensor is positioned proximate to the temperature sensor such that the surface sensor is configured to generate a second signal indicative of presence of the region of the surface of the at least part of the subject, and a control module configured to control the intensity of the set of light sources based on the first and the second signal.

A phototherapy device for treating neonatal hyperbilirubinemia comprises a plurality of LEDs coupled to a support structure configured to absorb and dissipate heat generated by the LEDs without requiring a fan. The LEDs provide a uniform dose of radiation on a treatment surface of the subject over a distance range of 20 cm to 45 cm. The support structure can comprise a heat-conductive metal plate. The LEDs have an emission range of 400 nm to 520 and a light output intensity of at least 30 W/cm2/nm and at most 65 W/cm2/nm at the treatment surface. The device can be adjustably coupled to a mounting structure. Power supplied to the LEDs is adjustable based on the total number of hours of use of he LEDs, the intensity of the LED radiation, the distance between the LEDs and the treatment surface, and/or the tilt or orientation of the phototherapy device.

A phototherapy apparatus includes: a light irradiation module that radiates light for treatment; and a spacer that is disposed on a light output side of the light irradiation module and contacts a surface of a body to keep a distance between the light irradiation module and a part to be treated on the surface of the body constant, in which a spacer opening that avoids contact of the part to be treated and the spacer is formed on a surface of the spacer, which contacts the surface of the body.

A blanket for use in phototherapy treatment integrates a phototherapy element for delivering phototherapy to a patient placed on the blanket and a heating element for warming the patient. In one example, the phototherapy element includes a light emitting panel made from woven optical fibers and the heating element includes a heating wire secured to the light emitting panel. In another example, both phototherapy and warming are provided by a woven optical fiber panel. Blue light is emitted from the panel for phototherapy and infrared light is emitted from the panel for warming.

A kit comprising a wearable lamp platform a frame for holding the wearable lamp platform in a fixed orientation spaced from the user's body, an adapter arranged and configured to couple a data acquisition device to the optical lens of the at least one port; and a power source controller electrically coupled to the wearable lamp platform provides a simple and elegant solution to providing economic, at-home skin condition analyses. The wearable lamp platform includes a plurality of treatment lamps arranged and configured to irradiate a portion of a wearer's body, and at least one port extending through the lamp platform from the outer surface to the inner surface. The at least one port has disposed therein an optical lens and a plurality of image-acquisition lamps disposed thereabout. The inner surface of the wearable lamp platform is reflective and is arranged and configured to reflect light scattered by the wearer's body back to the body, and the at least one port and the adapter are arranged and configured to couple in a single operative position.

A method for at-home skin condition analyses includes coupling an adapter to a port of a wearable lamp platform. placing the wearable lamp platform on a portion of a user's body, coupling a data acquisition device to the adapter and activating the data acquisition device to acquire data pertaining to the user's body through the optical lens, analyzing the data pertaining to the user's body, determining a light treatment regimen for the user's body, and applying light treatment to the user's body according to the determined light treatment regimen. The port has disposed therein an optical lens and having a plurality of image image-acquisition lamps disposed thereabout. The image-acquisition lamps are energized by a power source electrically coupled to the wearable lamp platform, and the wearable lamp platform comprises a plurality of treatment lamps arranged and configured to irradiate a portion of a wearer's body.

A phototherapy device for delivering light emitted by a light source to an infant. The phototherapy device includes two or more light pads configured to be optically connected to a light source via a connector. Light emitted by the light source is received by the connector and propagated through the connector to the light pads. The phototherapy device also includes a flexible garment configured to maintain the position of the pads on a front and back of an infant.

The invention provides a light therapy device for providing therapeutic treatment to a user's body, wherein the user may be a person or an animal. The device is using a light projection method for treating the body problems and/or skin disorders. Further, the device is having a rotatable assembly that automatically follows the movement of the desired area of the body needs to be treated. The device uses artificial intelligence, machine learning, localization modules, object detection module, image processing module, and 3D-mapping to automatically identify and treating the desired area of the body. Furthermore, the user can manually identify, select and prioritize desired treatment portion and can select the type of treatment required.

A device for providing phototherapy. The device has lights that emit irradiance to provide phototherapy. The lights are positionable to emit the irradiance towards a patient. An enclosure is connected to a base and supports the lights. A control module is operatively connected to the lights and controls the irradiance emitted from the lights. A non-transitory memory module is operatively connected to the control module and stores a control program. A plurality of sensors is operatively connected to the control module and are configured to sense a current position of the lights. The control program is configured to receive inputs that include at least the current position of the lights and to provide outputs to the control module based at least in part on the inputs. The control module controls the irradiance emitted from the plurality of lights based at least in part on the outputs.