Abstract: Systems and methods are provided for illuminating a surface to be observed microscopically using a retractable beamsplitter. The retractable beamsplitter allows the use of coaxial illumination when the beamsplitter is positioned in the operator's line of sight. The retractable beamsplitter allows the use of non-coaxial illumination without reducing the amount of illumination that reaches the operator when the beamsplitter is retracted from the operator's line of sight. As a result a single system can be used effectively to provide various types of illumination.

Abstract: The invention relates to a light source for coupling light into a hand-held medical device, especially a hand-held surgical device, preferably for using in ophthalmology. The light source is characterized by a hand lamp/flashlight provided with a lamp head comprising at least one lamp, and a fiber-optic light guide leading towards the hand-held device. The fiber-optic light guide can be connected to an adapter associated with the lamp head.

Abstract: Embodiments of endo-illuminators and related methods are disclosed. One embodiment of an illuminator can comprise a cannula defining a passage, an optical element disposed at an end of the cannula, and an optical fiber running through the passage with the distal end of the optical fiber in contact with the optical element. The optical fiber includes at least a heat preconditioned distal portion that terminates in the distal end that is in contact with the optical element.

Abstract: A flat panel light source (100) for a transillumination device of a microscope comprises a plate-shaped light guide (110) having a lower and an upper boundary surface, and at least one lateral surface (113 to 116), and having at least one light-emitting means (120, 122) arranged to radiate light into the light guide (110) from at least two different directions, via at least one lateral surface serving as a light entrance surface, such that the light propagates in the light guide (110) as a result of total reflection, the total reflection being disrupted in defined fashion, by an element (140) abutting against a contact surface at the lower boundary surface of the light guide (110), so that an outcoupling of light occurs on the upper boundary surface of the light guide (110), the planar area of the contact surface being smaller than the planar area of the lower boundary surface.

Abstract: Embodiments of endo-illuminators and related methods are disclosed. One embodiment of an illuminator can comprise a cannula defining a passage, an optical element disposed at an end of the cannula, and an optical fiber running through the passage with the distal end of the optical fiber in contact with the optical element. The optical fiber includes at least a heat preconditioned distal portion that terminates in the distal end that is in contact with the optical element.

Abstract: Embodiments of the present invention provide a system and method for shaping an annular focal spot pattern to allow for more efficient optical coupling to a small gauge optical fiber. An embodiment of the present invention can include an illumination source operable to transmit an optical beam along an optical path, an optical fiber, and a correcting element positioned in the optical path between the illumination source and the optical fiber, the correcting element configured to reshape the optical beam to increase an amount of light received by the optical fiber.

Abstract: A structured illumination surgical system is disclosed, one embodiment comprising: a light source for providing a light beam; an optical cable, comprising an optical fiber, optically coupled to the light source for receiving and transmitting the light beam; a handpiece, operably coupled to the optical cable; an optical element, a proximal end of the optical element optically coupled to a distal end of the optical fiber, for receiving the light beam and scattering the light beam to illuminate an area (e.g., a surgical site), wherein the surface area of the proximal end of the optical element is greater than the surface area of the distal end of the optical fiber; and a cannula, operably coupled to the handpiece, for housing and directing the optical fiber and the optical element.

Abstract: Disclosed herein is an improved dental operatory lamp having an LED light source that directs light to a reflector that in turn reflects the light to illuminate a treatment area. In one embodiment, the lamp is adapted for efficient transfer of heat from the light source and into the environment. In another embodiment, the lamp is adapted to generate a predetermined pattern of light optimal for the treatment area. In other embodiments, the lamp includes structural features that enable the lamp to maintain optimum light intensity and/or temperature. Also, disclosed herein are unique reflector embodiments that intentionally provide a generally smooth surface, without facets, that reflect light at all visible and infrared wavelengths.

Abstract: Skin disorders such as, for example, atopic dermatitis, dyshidrosis, eczema, lichen planus, psoriasis, and vitiligo, are treated by applying high doses of ultraviolet light to diseased regions of a patient's skin. The dosage exceeds 1 MED as determined for the particular patient and may range from about 1 MED to about 20 MED or higher. The ultraviolet light has a wavelength within the range of about 295 nanometers to about 320 nanometers. High doses of ultraviolet light are preferably restricted to diseased tissue areas. A specialized handpiece provides a beam profile especially suitable for application of controlled doses. A specialized delivery device is useful for UV treatment of tissue within the mouth.

Abstract: A video endoscope has an endoscope part having a central image signal conductor, at least one optical waveguide, and a light supplying part which can be coupled to a proximal end of said endoscope part. The light supplying part has a central image signal conductor connection at a distal end thereof, and a light supply arranged coaxially around said central image signal conductor connection. The light supply has a plurality of light-emitting elements, each of said light-emitting elements can be supplied by means of a switchable semiconductor light source. Position sensors are arranged in an area of said light-emitting elements, and position indicators are arranged in an area of said optical waveguide. A position of said position indicators can be detected by said position sensors when said endoscope part and said light supplying part are coupled. Based on a detection of said position indicator, at least those light-emitting elements lying opposite to said optical waveguide are activated.

Abstract: An illumination apparatus is attachable to surgical instruments, and provides illumination of the operating field, particularly those requiring good illumination of normally poorly illuminated organ cavities, during surgical procedures. The illumination apparatus includes a light source (1) connected to a power supply (2). The light source (1) and part or all of the power supply source are housed in a casing (3) that has at least one attaching means (5) on its outer surface which is suitable for removably attaching the illumination apparatus to a surgical instrument, and desirably, to several different surgical instruments at various times during a particular surgical procedure. Due to its weight, design and size, the illumination apparatus allows for easy shifting of the illumination apparatus along the surgical instrument without interfering with the normal use of the surgical instruments.

Abstract: A luminaire includes a light-emitting unit, a main body frame, a support frame, and a lighting unit. The light-emitting unit mounts light-emitting elements. The main body frame supports the light-emitting unit, and is formed rectangular having a hook-shaped engaging piece on one side. The support frame is formed rectangular surrounding the outer periphery of the main body frame, and has a groove-shaped receiving place to engage with the engaging piece of the main body frame, on one internal side. The lighting unit turns on the light-emitting elements.

Abstract: An electrically powered light source including a light emitting diode (LED) having variable chromaticity, which is adapted for use in a dental operatory. A dental operatory lamp includes a thermally conductive housing having a front directed toward the operating area and a rear away from the operating area; a generally elliptical reflector located on the rear of the thermally conductive housing; at least one heat pipe; a plurality of color LEDs projecting light toward the elliptical reflector, the plurality of LEDs being in thermal contact with the at least one heat pipe; and an optical light guide for combining light from said LEDs. Another embodiment of the lamp includes at least two user selectable light spectra, one of said spectra providing white light with color temperature in the range 4000° K-6000° K and one spectra having reduced output in the wavelength range 400-500 nm.

Abstract: The invention relates to a light curing device, comprising a light source which is accommodated in a housing which has a light exit, through which light leaves the housing. It is provided that the light exiting direction of the light beam is variable, in particular infinitely variable.

Abstract: Systems and methods are provided for illuminating a surface to be observed microscopically using a retractable beamsplitter. The retractable beamsplitter allows the use of coaxial illumination when the beamsplitter is positioned in the operator's line of sight. The retractable beamsplitter allows the use of non-coaxial illumination without reducing the amount of illumination that reaches the operator when the beamsplitter is retracted from the operator's line of sight. As a result a single system can be used effectively to provide various types of illumination.

Abstract: An illumination unit includes a distal end frame member having a through opening, a plurality of illumination sections, and a holding member which is arranged in the through opening and holds the illumination sections to incline the illumination sections at a desired angle with respect an opening surface of the through opening and to form a cascade along the axial direction of the through opening. The illumination unit includes a reflective member which is configured to reflect the illumination light emitted from the illumination sections toward the opening surface, the reflective member being held by the holding member to face the illumination sections and to apply the illumination light externally emitted from the illumination sections from the inside of the through opening via the opening surface.

Abstract: In an embodiment, an attachment system for communicating light energy from a light source to a light-conducting fiber includes a light pipe body sufficiently designed to engage a distal end of a light pipe, the light pipe body comprising at least one opening configured to dissipate heat buildup from light energy; a front assembly sufficiently designed to engage the light pipe body, the front assembly comprising an orifice and at least one opening configured to dissipate heat buildup from light energy; a light-conducting fiber body sufficiently designed to engage the front assembly and to hold a proximal portion of a light-conducting fiber, the light-conducting fiber body positioned in the orifice of the front assembly; and an optical taper assembly sufficiently designed to hold an optical taper, the optical taper assembly positioned between and spaced apart from the front assembly, and positioned between and spaced apart from the light pipe.

Abstract: An ophthalmic illuminator is disclosed, one embodiment comprising: an illumination source and an optical fiber for transmitting a combined light beam from the illumination source to a site, such as a surgical site within an eye, wherein the illumination source comprises a plurality of light emitting diode (LED) chips optically coupled to a corresponding plurality of light pipes, the LED chips and light pipes arranged in a configuration such that the light pipes converge together at their distal ends to form a cubic box having five sides formed by the distal ends of the light guides and an open side from which the combined light beam, composed of light from a plurality of light beams generated by the LED chips and transmitted to the cubic box by the light guides, is emitted. The luminance of the combined light beam has a luminance greater than the luminance of any one of the plurality of LED chips.

Abstract: A surgical lamp that includes a carrying system, a lamp body, and at least one handle having an illuminant. The handle is at least partially formed of a translucent material.

Abstract: Headgear for mounting a headlight on a surgeon's head includes a headband and a stabilizer. The headband encircles the wearer's head and the stabilizer is connectable to a rear section of the headband for engaging and cradling a substantial portion of at least a lower back region of a wearer's head when the headgear is worn by the wearer. The stabilizer includes a peripheral extending portion extending beneath the headband on opposite sides of the wearer's head corresponding to a location of a lower portion of an occipital bone of the wearer's head and a peripheral portion extending above the headband on opposite sides of the wearer's head corresponding to a location of a top of the occipital bone. The headgear can also include a connection element for removably connecting the stabilizer to the headband so that the headgear can be worn with or without the stabilizer.

Abstract: An LED based light source unit for an endoscopic imaging system produces illumination for a camera through an endoscope. The light source unit includes an array of LEDs mounted to a thermally conductive substrate, a light guide to collect light emitted from the LEDs and to couple the light into a group of optical fibers within the endoscope, and an interface to allow the light source unit to be removably attached to the endoscope at the endoscope's external light port. The LEDs therein may be overdriven by power for increased light output. When the LEDs reach their lifetime, the light source unit can be discarded.

Abstract: The invention relates to a light emitting device comprising a light emitting element (100) and a light guide (101) arranged on a textile substrate (102). The light guide has a back surface (103) facing the textile substrate, a front surface (104) facing away from the substrate, and a light receiving surface (105). The light emitting element (100) is arranged such that at least part of the light emitted by the light emitting element (100) is coupled into the light guide (101) through the light receiving surface (105), and is subject to total internal reflection in the light guide (101). Furthermore, the light guide (101) is arranged such that at least part of the light coupled into the light guide (101) exits the light guide (101) through the front surface (104) and/or the back surface (103).

Abstract: In an embodiment, an attachment system for communicating light energy from a light source to a light-conducting fiber includes a light pipe body sufficiently designed to engage a distal end of a light pipe, the light pipe body comprising at least one opening configured to dissipate heat buildup from light energy; a front assembly sufficiently designed to engage the light pipe body, the front assembly comprising an orifice and at least one opening configured to dissipate heat buildup from light energy; a light-conducting fiber body sufficiently designed to engage the front assembly and to hold a proximal portion of a light-conducting fiber, the light-conducting fiber body positioned in the orifice of the front assembly; and an optical taper assembly sufficiently designed to hold an optical taper, the optical taper assembly positioned between and spaced apart from the front assembly, and positioned between and spaced apart from the light pipe.

Abstract: A light source device includes an excitation light source which generates excitation light, a fluorescent member containing a fluorescent substance which absorbs the excitation light to generate fluorescence, an emitting side optical member which is provided on an emitting end face of the fluorescent member, and a reflector which is provided on the side surface of the fluorescent member. The reflector has an optical property of reflecting the excitation light and the fluorescence. The emitting side optical member has an optical property of reflecting the excitation light and transmitting the fluorescence.

Abstract: The invention is a novel stereoscopic illumination system for a microscope which delivers at least two collimated light beams to a subject surface. Each of the two collimated light beams is delivered for an eye of the user. Additionally, a third light beam is provided at an angle oblique to the other two collimated light beams.

Abstract: In an endoscope in which light transmitted from an optical fiber bundle using a positive lens is irradiated as illumination light, a glass rod having a diffusion face disposed on one of end faces is arranged between an aperture diaphragm that adjusts an amount of light from a light source and the optical fiber bundle that guides the light from the aperture diaphragm to a distal end portion of the endoscope, and light without a biased angular component is supplied to the optical fiber bundle so as to eliminate illumination light unevenness.

Abstract: A variable-angle, wide-angle illuminator is disclosed, one embodiment being a small-gauge, variable-angle illumination surgical system comprising: a light source for providing a light beam; an optical cable, optically coupled to the light source for receiving and transmitting the light beam; a handpiece, operably coupled to the optical cable; an optical fiber, operably coupled to the handpiece, wherein the optical fiber is optically coupled to the optical cable to receive and transmit the light beam; an optical assembly, optically coupled to a distal end of the optical fiber, for receiving the light beam and providing the light beam to illuminate a surgical field; and a cannula, operably coupled to the handpiece and optical assembly, for housing and directing the optical assembly to illuminate selected area. The optical assembly can comprise a fiber/polymer-dispersed-liquid-crystal (“PDLC”) diffuser optically coupled to an optical needle or a nested compound parabolic concentrator (“CPC”) cone.

Abstract: Embodiments of the invention are directed medical devices for illuminating and viewing a patient's internal body portion. The device may include an elongated flexible tube including a distal end and a proximal end. The tube defines a channel extending from the proximal end to an aperture at the distal end. An illumination device is housed within the channel and configured to emit a distally directed path of light. A light source is provided at the distal end of the flexible tube and configured to emit a laterally directed path of light. In one embodiment the light source is a organic light emitting diode.

Abstract: An illuminator film system may include one or more pre-cut sections of optical film applied to a waveguide to allow light to exit the waveguide through the film in a predetermined manner. The one or more pre-cut sections may be removed and reapplied during a procedure to redirect the light. A laminated illuminator film may be provided that uses a laminated optical film structure to direct light from a fiber optic input. Such a laminated illuminator film may be very low profile, low cost and easy to apply to a retractor for providing illumination during a surgical procedure.

Abstract: An endoscope system comprises first and second emitters, a fiber, and a controller. The first emitter emits illumination light to a photographic subject. The second emitter emits infrared light. Emission intensity of the second emitter is stronger than that of the first emitter. The fiber has a tip which moves in a spiral when viewed from the photographic subject during scan periods. The controller controls emission timing of the first and second emitters. Light emitted by the first and second emitters is cast from the tip of the fiber onto the photographic subject. The second emitter emits in a predetermined period of one of the scan periods, based on control of the emission timing, so as to shine infrared light with the second emitter to at least one part of the photographic subject, in order to perform marking.

Abstract: A light source device includes a xenon lamp, a rotary shutter, a main CPU for controlling drive of these components, and a sub CPU. The main CPU operates when receiving a reset cancel signal from a reset circuit. Between the sub CPU and the reset circuit, an AND circuit is provided. When the reset cancel signal from the reset circuit and a lighting completion signal indicating completion of lighting the xenon lamp are both input, the AND circuit outputs the reset cancel signal to the sub CPU. After the output of the lighting completion signal, the sub CPU operates to drive the rotary shutter. When high-frequency noise which occurs at the time of discharging the xenon lamp stops, the rotary shutter is activated and thereby generating pulses of illumination light.

Abstract: A medical examination apparatus is provided. The examination apparatus includes an examination area in which an examinee is examined using an imaging device. The examination apparatus includes at least one planar lighting device emitting homogeneous light via its light radiating surface. The lighting device includes at least one light source by which at least part of the examination area and/or of the area peripheral to the examination area can be illuminated.

Abstract: A suspension has a holding element to which an arm is rotatably fastened, wherein a coupling element is provided which is rotatable around the holding element independently of the arm and which forms a security against rotation.

Abstract: A light source for coupling light into a medical device, particularly a surgical handheld device, preferably for use in ophthalmology, comprising a lamp (1), a light guide (2) extending from the lamp (1), and a power supply (3) for the lamp (1), is characterized in that the lamp (1) is arranged in an adapter-like housing (4), which comprises a connection (5) for the power sup ply (3) and a connection (6) for the light guide (2).

Abstract: Techniques, apparatus and systems that use an optical probe head to deliver light to a target and to collect light from the target for imaging, monitoring, medical diagnostics and medical treatment applications.

Abstract: A light source (110) is fixed at a position and emits light in a direction away from an optical axis (A) of an objective lens. An outer reflecting mirror (an optical member) (130) and an inner reflecting mirror (an optical member) (140) are provided as a unit so that relative positions thereof are fixed. A reflecting mirror unit (120) can be moved in directions along the optical axis (A), i.e. up and down relative to the light source (110). A free-form curved surface portion (131) of the outer reflecting mirror (130) and a reflecting surface of the inner reflecting mirror (140) reflect light in different directions depending on a position of the light incident thereon.

Abstract: An LED based light source unit for an endoscopic imaging system produces illumination for a camera through an endoscope. The light source unit includes an array of LEDs mounted to a thermally conductive substrate, a light guide to collect light emitted from the LEDs and to couple the light into a group of optical fibers within the endoscope, and an interface to allow the light source unit to be removably attached to the endoscope at the endoscope's external light port. The LEDs therein may be overdriven by power for increased light output. When the LEDs reach their lifetime, the light source unit can be discarded.

Abstract: An electrically powered light source including a light emitting diode (LED) having variable chromaticity, which is adapted for use in a dental operatory. A dental operatory lamp includes a thermally conductive housing having a front directed toward the operating area and a rear away from the operating area; a generally elliptical reflector located on the rear of the thermally conductive housing; at least one heat pipe; a plurality of color LEDs projecting light toward the elliptical reflector, the plurality of LEDs being in thermal contact with the at least one heat pipe; and an optical light guide for combining light from said LEDs. Another embodiment of the lamp includes at least two user selectable light spectra, one of said spectra providing white light with color temperature in the range 4000° K-6000° K and one spectra having reduced output in the wavelength range 400-500 nm.

Abstract: Method for creating a three dimensional imaging system is disclosed. There is a first source of laser light and a second source of laser light having a wavelength different from the wavelength of the laser light of the first source. The laser light from the first and second sources are combined, and the combined laser light is transmitted to a scanner. The scanner further transmits the combined light to a surface to be imaged.

Abstract: Disclosed is an illuminating device that includes a light source and a mouthpiece. The mouthpiece is configured to adapt the light source thereon and is capable of being accommodated within a user's mouth. The mouthpiece includes a switch and a power source. The switch is electrically connected to the light source. The power source is electrically connected to the switch and the light source and is capable of providing electrical power to the light source for illumination. Upon receipt of the mouthpiece within the user's mouth and application of pressure on the switch by the user's teeth, the light source is illuminated.

Abstract: An optical surgical probe includes a handpiece, a light guide within the handpiece, and a multi-spot generator at a distal end of the handpiece. The handpiece is configured to optically couple to a light source. The light guide is configured to carry a light beam from the light source to a distal end of the handpiece. The multi-spot generator includes a faceted optical element with a faceted end surface spaced from a distal end of the light guide. The faceted end surface includes at least one facet oblique to a path of the light beam.

Abstract: A medical illumination unit (1) has an LED chip (15) and a rod-shaped body (5) with a proximal end (11) and a distal end (7). A distal hollow section (9) begins before the distal end (7) and reaches the distal end (7), and a supply lead section (12) begins at the proximal end (11) and reaches the distal hollow section (9). The LED chip (15) is in the distal hollow section of the rod-shaped body (5) and is supplied with energy through the supply lead (12). A luminescent converter is between the LED chip (15) and the distal end (7) of the rod-shaped or tubular body or at the distal end of the rod-shaped body (5), the converter properties of which are selected to convert light emitted by the LED chip (15) into light with a desired wavelength distribution.

Abstract: The inventive surgical light comprises a body provided with main light-emitting diodes and additional light-emitting diodes arranged therebetween, which are spaced on said body and fixed thereto, wherein said additional light-emitting diodes are grouped and are characterised in that the spatial orientation thereof differs from the spatial orientation of the main light-emitting diodes. A light field control device comprises a control unit to which the groups of light-emitting diodes are connected by means of adjusters each of which is connected to a power supply unit. The main light-emitting diodes are fixed to the light body in such a way that the optical axes thereof cross the light axis in the center of a light spot. The additional light-emitting diodes are fixed to the light body in such a way that the optical axes thereof form a concentric light spot in the form of a ring around the main light spot.

Abstract: An object of the preset invention is to provide a medical lighting apparatus capable of illuminating an affected part with proper illuminance while assuring a work space for an operator near the affected part. A medical lighting apparatus for irradiating an affected part with light includes: a light source (a light emitting element); a light condenser (a collimate lens and a condenser lens) for condensing light emitted from the light source; an image forming unit (an image lens) for forming an image on the affected part from the light condensed by the light condenser; and an aperture portion provided between the light condenser and the image forming unit and regulating passage of the light condensed by the light condenser.

Abstract: Described herein is a surgical instrument that includes a tubular member having first and second opposite ends and a longitudinal axis, an instrument dock extending from the first end of the tubular member that includes an opening for receiving a rod, and a light source. Light from the light source is directed out of the opening in the instrument dock. In a preferred embodiment, the article of manufacture includes a nose cone and a tail cone that actuates the light source.

Abstract: In one embodiment, an illuminator configured to emit light into an optical fiber includes at least one pump light source configured to emit short-wavelength light. The illuminator further includes a white phosphor disposed to receive the short-wavelength light and to emit white light in response. The illuminator also includes a light collector configured to collect the short-wavelength light at the white phosphor such that a brightness of the white light is greater than a brightness of the short-wavelength light.

Abstract: A multi-light apparatus (10) for primary use in dental or medicinal operatory workspaces and for interconnection with a modular operating chair (12), so as to form the headrest thereof, preferably includes first and second radiation sources (36,72) and a selection mechanism (70) for selecting a desired radiation source, a rigidly flexible light pipe (16) that may be alternatively coupled to each light source (36,72) and is configured to transmit selected radiation to a patient (14), a reflective surface (78) configured to direct the selected radiation to the pipe (16), a power supply (50), a cooling fan (56), and at least one potentiometer (66,68) for varying the voltage delivered to the sources (36,72) and fan (56).

Abstract: The transillumination device has an orange light, in the range of 580-620 nm. Orange light has been found to be beneficial for superficial veins. Red light is used for deeper veins and darker skin. The transillumination device may have a single light source able to change colors. Two different light sources, each having a different color or different transillumination devices, each having a different color, may be used for diagnostic purposes.

Abstract: A battery pack for a sterilizable instrument, such as a medical endoscope. The battery pack includes batteries removably positioned within an enclosure which mounts a first grouping of electrical contacts engaged with the battery contacts. The enclosure includes an outer end wall which sealingly encloses the first grouping of contacts. The outer end wall mounts a second grouping of electrical contacts which are normally resiliently maintained in a first position spaced from the contacts of the first grouping. The contacts of the second grouping sealingly penetrate through the outer end wall. When the battery pack is engaged on the instrument, the contacts of the second grouping engage third contacts on the instrument, causing the contacts of the second grouping to move into a second position where they directly engage contacts of the first grouping to provide electrical power to the instrument.

Abstract: A transillumination device can use an adapter to make it more appropriate for neonatal and pediatric application. The adapter attaches to the bottom of the transillumination device and covers the illumination source. An aperture in the adapter allows part of the light generated by the illumination source through the adapter and blocks the remaining light. The reduces light enhances the transillumination device's ability for viewing pediatric patients.