An oral care appliance having a housing, the housing having a first end, a second end that is at least partially transparent, and a cavity. The cavity having a light source and a light-diffusing fiber optically coupled to the light source and arranged within the second end of the housing wherein the light-diffusing fiber is arranged to produce a first light visible through the second end of the housing.

Disclosed is an optical fiber illumination apparatus configured for ensuring high light efficiency and uniform luminosity when displaying an illumination pattern with flexible optical fibers in fiber optic lighting.

An illumination device for an interior space of a vehicle includes at least one light source and at least one light surface. The light surface is formed by at least one at least partially mirrored optical fiber, and the optical fiber can be adjusted to a shape of a windscreen.

The present disclosure relates to a lighting device configured to mimic the appearance of a flame. In one embodiment, the lighting device includes a power subsystem configured to receive an alternating current input and to generate a direct current output. The lighting device also includes a reflector to reflect light generated by a lighting subsystem. A movement subsystem may move the reflector to mimic the appearance of a flame. A communication subsystem may receive at least one parameter associated with at least one of the lighting subsystem and the movement subsystem. A control subsystem may implement the at least one parameter.

An implantable light generation arrangement for an optical or optical/electrical stimulation system includes a light source having an emission surface, wherein the light source is configured to generate light and emit the light from the emission surface; an optical waveguide having a first end and a core; a ball lens disposed between the light source and the optical waveguide and configured to receive the light emitted from the light source and direct the light onto the core at the first end of the optical waveguide; and a fixture holding the light source, optical waveguide, and ball lens in a fixed arrangement.

An illumination device for an interior space of a vehicle includes at least one light source and at least one light surface. The light surface is formed by at least one at least partially mirrored optical fiber, and the optical fiber can be adjusted to a shape of a windscreen.

A method of fitting a structural member having a passage with fiber optical lighting, the method comprising: a) drilling a first hole through the structural member across the passage and through opposite first and second surfaces of the structural member; (b) enlarging the first hole at the second surface of the structural member forming a second hole; (c) inserting a cable puller having a cable hooking end through the passage to a point such that the cable hooking end is disposed inwardly from the first hole and second hole; (d) inserting a first end of a fiber optic cable first through the second hold and then through the corresponding first hole; (e) securing the first end of the fiber optic cable against being pulled back through the first hole; (f) withdrawing the cable feeder from the passage, hooking the fiber optic cable by the cable hooking end; (g) pulling a second end of the fiber optic cable from the passage; (h) injecting curable material into the passage through the second hole to encapsulate at least a length of the fiber optic cable within the curable material; and (i) cutting the first end of the fiber optic cable flush with the first surface.

Aspects of systems and apparatuses for medical infusion illumination are disclosed. In one aspect a system for medical infusion line illumination is disclosed. The system comprising an electronic illuminator. The electronic illuminator comprising a printed circuit board (‘PCB’), a light emitting diode (‘LED’), a lens configured with the LED, a power source to supply power to the PCB and LED; and at least one sensory assembly. The LED and lens of the electronic illuminator are configured to a side scattering fiber optic cable. The side scattering fiber optic cable comprises a fiber funnel cap at a proximal end to receive light from the LED through the lens of the electronic illuminator. The side scattering fiber optic cable further comprises a protective end cap at a distal end, wherein the protective end cap is polished on an interior surface to reflect light from the LED of the electronic illuminator.

Aspects of systems and methods for controlling SAR in medical infusion illumination are disclosed herein. In one aspect a system for reducing microorganism load in an environment surrounding an electronic illuminator is disclosed. In the system an electronic illuminator is disclosed comprising an LED module, a power driver equipped to the LED module for driving power to the LED, housing to protect the contents of the electronic illuminator and dissipate heat, and a PCB configured with an MCU for controlling operations within the electronic illuminator. Further, the system comprises a side emitting fiber optic line or line, also known as side glow fiber. The side emitting fiber optic line comprises a funnel cap for engaging with the electronic illuminator and a protective end cap for protecting and reflecting light radiation. In other aspects, a method for reducing microorganism count in an environment surrounding an electronic illuminator is disclosed. The method comprises provisioning an electronic illuminator equipped with an LED module and a side emitting fiber optic line. Then transmitting a signal, to a power driver of the LED module to begin the microorganism reduction. Next, emitting light radiation, by the LED module, and lastly terminating the light radiation after a set duration.

Aspects of a dual lumen fiber optic medical infusion line and method of manufacture are disclosed herein. The dual lumen fiber optic medical infusion line includes a first elongate body that is substantially cylindrical and extends from a proximal end to a distal end and includes a first lumen extending throughout the entire length of the first elongate body, and a second elongate body that is substantially cylindrical and extends from a proximal end to a distal end and includes a first lumen extending throughout the entire length of the second elongate body, The second elongate body is engaged to the first elongate body. A fiber optic cable is disposed within the first elongate body. A distal end cap is engaged to the distal end of the fiber optic cable, and a fiber funnel cap is engaged to the proximal end of the fiber optic cable.