Abstract: A system for wirelessly powering various devices positioned on an endoscope, including, for example, a light source, various electronics including an imager and/or a memory device. The system is further provided such that video signal processing parameters are automatically set for an endoscopic video camera system based upon characteristics of an attached endoscope, with reduced EMI and improved inventory tracking, maintenance and quality assurance, and reducing the necessity for adjustment and alignment of the endoscope and camera to achieve the data transfer.

Abstract: An evaluation board for a medical monitoring module is provided. The evaluation board includes a socket configured to receive a medical monitoring module and a plurality of connections for connection to a host or host simulator and a second device. The evaluation board may include a non-isolated power supply to provide power to the medical monitoring module. The evaluation board may also provide communication in a protocol between the host or host simulator and the medical monitoring module.

Abstract: The diagnosability of diseased parts is improved by precisely correcting fluorescence images without being affected by specular reflection and without being affected by thick blood vessels.

Abstract: An endoscopic system is composed by connecting an endoscope and peripheral equipment. The endoscope has an endoscope main body, and an imaging unit, which is slender imaging optics. The endoscope is constructed so that the endoscope main body and imaging unit are freely connectable and separable. The endoscope main body has an insertion part which is inserted into an abdominal cavity, a branch member, which is a middle end of the endoscope main body, and provided in a proximal end portion of the insertion part, a first extension part provided in the proximal end portion of the branch member, a main body operation unit provided in a proximal end portion of the first extension part, a universal cord, and a connection unit, which is provided in a proximal end portion of the universal cord, and is connected to the peripheral equipment.

Abstract: An endoscope insertion assembly for performing endoscopy, including an endoscope insertion tube operative for passage through a body cavity, and an optical assembly operative for inspection of the body cavity, the optical assembly being selectably insertable within the endoscope insertion tube.

Abstract: In a method for controlling a multi-color output of an image of a medical object for assisting medical personnel, the medical object is illuminated with light with an illumination spectrum. By means of an image sensor, image data are acquired for a group of one or more color channels. Image information concerning an additional color channel, which is not among the group of one or more color channels, is generated depending on the acquired image data. An image output device for multi-color output of the image is controlled depending on the acquired image data and the acquired image information.

Abstract: Embodiments of the disclosure may include a medical device comprising an elongate member and a handle assembly connected to the elongate member. The handle housing may house a steering mechanism movable relative to the handle assembly and configured to steer the elongate member along a first plane and a second plane different from the first plane, a camera system configured to capture images from a distal end of the elongate member, and an illumination system configured to provide illuminating light from the distal end of the elongate member.

Abstract: An endoscope main body constituting an endoscope in a state in which an elongated detachable observation optical system is attached to the endoscope main body, and in a proximal end of an insertion section of the endoscope main body, a branch member is disposed. The branch member is provided so that a first extended section and a second extended section are branched from each other and thereby first and second operating sections are separately arranged. Furthermore, the branch member has an opening as an inlet which guides an imaging module in a distal end of the observation optical system to a hard portion of the insertion section.

Abstract: Devices and methods are provided which shield at least one turbinate from trauma or damage during sinus surgery that could be caused by direct contact with diagnostic and therapeutic devices. The devices and methods provided are particularly useful for protecting nasal turbinates during FESS and FTIS procedures.

Abstract: An endoscope control apparatus of the invention includes: a first connector receiving portion and a second connector receiving portion, to and from which an endoscope is attachable and detachable; a connection detection portion for detecting a connecting state of the endoscope in the first connector receiving portion and the second connector receiving portion and outputting a connection detection signal; a first patient circuit electrically connected to a post stage of the first connector receiving portion and connected also to a first reference potential point; and a second patient circuit electrically connected to a post stage of the second connector receiving portion, and connected also to a second reference potential point different from the first reference potential point.

Abstract: An instrument support apparatus is disclosed. In some embodiments, the instrument support apparatus may be for supporting an instrument having a shaft extending along a shaft axis relative to a patient positioned adjacent to an external frame. In some embodiments, the instrument support apparatus may include a base fixedly mountable onto the external frame, a pivot assembly mounted for pivoting relative to the base, an arm assembly extending along a longitudinal axis, and a support assembly configured to support the instrument on the arm assembly.

Abstract: There is provided herein, an endoscope comprising an elongated shaft terminating with a tip section wherein said tip section comprises a permanent section connected to the elongated shaft and a removable section securely connectable to the permanent section, wherein the removable section comprises at least one capture device and at least one light source.

Abstract: Methods and apparatuses for space-optimized visualization catheters are provided. Some embodiments utilize complimentary metal-oxide-semi-conductor (“CMOS”) technology integrated into a CMOS camera train holder system that may be a stand-alone component for use with a visualization catheter, such as a baby endoscope, or may be fabricated/extruded as a part of the catheter itself. Some embodiments of apparatuses, methods, and equivalents thereto provide better direct visual feedback to the medical personnel performing the procedure while providing a similarly-sized outer diameter visualization catheter device having an increased space therein for additional lumens and equipment or by reducing the overall outer diameter of the visualization catheter.

Abstract: Methods and apparatuses for space-optimized visualization catheters are provided. Some embodiments utilize complimentary metal-oxide-semi-conductor (“CMOS”) technology integrated into a CMOS camera train holder system that may be a stand-alone component for use with a visualization catheter, such as a baby endoscope, or may be fabricated/extruded as a part of the catheter itself. Some embodiments of apparatuses, methods, and equivalents thereto provide better direct visual feedback to the medical personnel performing the procedure while providing a similarly-sized outer diameter visualization catheter device having an increased space therein for additional lumens and equipment or by reducing the overall outer diameter of the visualization catheter.

Abstract: An otoscope includes an instrument head, a tip element and an optical system. The instrument head has a distal insertion portion for insertion into an ear of a human or veterinary subject. The distal insertion portion has a distal opening. The tip element is releasably attached to the distal insertion portion. The tip element has a distal opening. The optical system is contained within the instrument head. The optical system includes a plurality of optical components. The optical system further comprises a viewing component for viewing of an image of a target of interest aligned along an optical axis disposed within said distal opening.

Abstract: In an image pickup unit, a first optical system holding frame has a hole axis orthogonal to an optical axis of photographing light made incident on a first object lens group, and a through-hole portion through which a second optical system holding frame can be inserted and arranged is formed in the first optical system holding frame and the first optical system holding frame and the second optical system holding frame are set relatively movable in a direction orthogonal to the optical axis of the photographing light made incident on the first object lens group and the second optical system holding frame and a third optical system holding frame are set relatively movable in a direction along the optical axis of the photographing light made incident on a solid-state image pickup device such that predetermined optical performance adjustment can be performed during assembly.

Abstract: A device (10) for laparoscopic or thoracoscopic surgery, the device (10) comprising: a first member (20) to be moved across the body (5) of a patient; and a second member (30) to be placed within the body (5), the second member (30) comprising an image capturing device (32) to capture images from within the body (5) and to transmit the captured images for display; wherein the second member (30) is in magnetic engagement with the first member (20) such that the movement of the second member (30) within the body (5) is in response to movement of the first member (20) across the body (5).

Abstract: A rigid scope apparatus including a rigid scope body to be inserted into a body for guiding and projecting an inputted illumination light on an examination area of the body, and receiving and guiding a light from the examination area caused by projection of the illumination light, and a camera head section to be connected to the rigid scope body and having an imaging section for receiving the light from the examination area and guided by the rigid scope body, and outputting an image signal. The camera head section includes an illumination light output section for outputting the illumination light and the rigid scope body receives and guides the illumination light outputted from the illumination light output section.

Abstract: Apparatus for accessing a bodily passageway, the apparatus comprising: a flexible tube having a distal end and a proximal end, a longitudinal axis extending between the distal end and the proximal end, and a lumen extending from the distal end to the proximal end, the lumen being sized to receive matter to be transported through the bodily passageway; and an external thread disposed over the distal end of the tube, the external thread having a sufficient structural integrity, and a sufficient surface profile, such that when the tube is disposed in a bodily passageway, rotation of the tube about the longitudinal axis will result in longitudinal motion of the tube along said bodily passageway.

Abstract: An endoscope includes an insertion tube having an end, and an imaging catheter assembly. The imaging catheter assembly includes a tubular body, an imaging device, and a shape memory link that connects the imaging device to the tubular body.

Abstract: A viewer 4 as a compact display device displays a body cavity image picked up by a capsule endoscope 3. When a communication-cable connection detector 48 detects a communication cable connection between a receiving apparatus 2 and the viewer 4, a control unit 49 switch controls a changeover switch 44 based on this connection detection, thereby switching a display of an LCD 41 to a display of image data from wire. Next, information necessary for an examination such as image data is taken in from the receiving apparatus 2 via a communication cable 5, and is displayed in an LCD 41. With this arrangement, a display unit is not necessary in the receiving apparatus 2, and a circuit configuration becomes simple. The receiving apparatus can be made compact and light, and power consumption can be decreased.

Abstract: The present invention relates to a small diameter endoscope in which a handle is removably attached to a probe. The probe includes a fiber optic illumination channel that is concentric about an imaging channel. The handle includes an imaging device that detects light from the imaging channel and a sterile barrier that can be extended over the handle for use. Relay optics couples the small diameter imaging channel to the imaging device in the handle. The probe has a mounting hub that connects the probe to the handle and also serves to optically couple the fiber optic illumination channel to a light source.

Abstract: An endoscope apparatus, includes: an explosion-proof unit that has an image pickup device that outputs photographed video images as video image signals; and an A/D converter that converts the video image signals into digitalized image signals; a control unit that controls the explosion-proof unit; and an energy limiting circuit that is provided at the control unit and that limits electrical energy of digital signals to satisfy intrinsic safety when sending and receiving of the digital signals, wherein the explosion-proof unit is connected to the control unit via the energy limiting circuit with a signal line.

Abstract: There is provided herein a camera assembly for use with a medical probe, such as an endoscope, the assembly comprising a main body configured to be mounted on an endoscope tip section, wherein said main body comprises at least one camera and at least one illumination source.

Abstract: A surgical imaging device is provided, including a housing configured to couple to an outer surface of a surgical device and an image capture arrangement configured to generate image data; the surgical imaging device may also include a circuit arrangement disposed within the housing and electrically coupled to the camera arrangement, in which the circuit arrangement is configured to communicate the image data to at least one remote device.

Abstract: An endoscope includes a detachable wireless imaging device and an insertion tube having a distal end region. The attachment of the detachable wireless imaging device detachably attaches the detachable wireless imaging device to the distal end region of the insertion tube.

Abstract: The present invention is directed to an endoscope that comprises a telescope, an imaging means, an image sensor for converting optical images produced by the imaging means to electrical signals, and a circuit board for receiving and outputting the electrical signals, the imaging means, image sensor and circuit board being located in the telescope. In some embodiments, the endoscope includes a connector that electrically connects the image sensor and the circuit board to form a first assembly.

Abstract: A catheter with an imaging assembly is disclosed. The catheter is used with a console for viewing and/or storing images obtained from the catheter. The catheter may be a feeding tube assembly. The imaging assembly on the feeding tube assembly allows a user to confirm placement of the feeding tube assembly in the patient's alimentary canal.

Abstract: An endoscope (1) has a handle (2) as well as a probe part (3) that can be connected thereto via a coupling (4), with an illumination device as well as an eye-piece (17) with an imaging optic being arranged in the handle (2) and image conductors and light conductors in the probe part (3). The coupling includes an image interface and a light interface. In the coupling area, at least one axially engaging guide (6, 8) as well as bayonet-like engaging coupling parts (6, 5) are provided, one of which is embodied as a rotational locking part (5). In the final locked position the locking part (5) is secured by a snap. Preferably, the coupling (4) is provided with an axially engaging guide and additionally axially engaging guides (13, 15; 14, 16) are provided of the illumination system and the image transmission system, which are particularly arranged side-by-side.

Abstract: A scope unit 2 including a control unit 3 and an insertion portion 4 is attached to a main unit 1 via a scope connector 5. An optical adaptor 8 is attached to a tip of the insertion portion 4. The CCD 31, HICs 32, 33, and the thermistor 34 are attached to the tip of the insertion portion 4. A liquid crystal module 36 is attached to the optical adaptor 8. A barrier circuit 64 limits energy supplied to these components in a circuit disposed in the scope unit 2. By disposing the barrier circuit 64 in the scope connector 5, the portion extending from the barrier circuit 64 to, i.e., the control unit 3, the insertion portion 4, and the optical adaptor 8 are of the explosion-proof construction. Thus, these can be used in a hazardous explosive location. Thus, an endoscope apparatus that can be used in combustible gas or dust can be provided.

Abstract: A portable hand-held endoscopy system adapted for interchangeable use with a variety of endoscopes. The system includes an endoscope having a first end and a second end, the first end having an eyepiece and the second end having a viewing end, the endoscope further having a coupler for coupling to a light source; and a battery operated unitary digital camera having an optical input, viewing screen, digital signal processor, memory with embedded software for processing data from the processor and for displaying an image on the viewing screen, and a coupler having a first end and a second end, wherein the first end includes a connector for removably connecting to the eyepiece, and the second end is coupled to the optical input of the digital camera. The video display is rotatable and pivotable about several different axes of rotation and a pivot point spaced distally from the main camera body.

Abstract: An image pickup portion picks up an image of a suspected substance and produces a video signal. Optical fibers transmit the video signal output from the image pickup portion. A video signal processing portion processes the video signals transmitted by the optical fibers and then outputs the processed video signals to a monitor. A trouble detection portion detects trouble in a transmission state of the optical fibers. The video signal processing portion outputs to the monitor only the video signal transmitted by the optical fiber in which the trouble detection portion has not detected trouble.

Abstract: An in-vivo image acquiring apparatus includes an imaging unit which is introduced inside a subject and picks up image information inside the subject, an illuminating unit which illuminates an imaging portion imaged by the imaging unit, a transmission processing unit which performs a process to wirelessly transmit the image information acquired by the imaging unit to an external apparatus. A light-control unit determines light-control amount information based on brightness of the image information acquired by the imaging unit, and performs a control of light control of the illuminating unit according to the light-control amount information. Further, the transmission processing unit performs a process to wirelessly transmit the image information acquired by the imaging unit along with the light-control amount information used for the control of light-control.

Abstract: An endoscope (1) is provided having a handle (2) and a probe part (3) that can be connected thereto, with an illumination system comprising at least one light emitting diode (6) and a video system having an image receiver being arranged in the handle (2). A carrier element (12) made of a heat-conducting material is provided for at least one light emitting diode (6) inside the handle (2), to which the light emitting diode (6) is directly connected. The carrier element thermally contacts the housing parts and/or installation parts of the handle (2) and the probe part (3) for heat conductivity and/or dissipation.

Abstract: A system, device and method for constructing an in-vivo image stream from in-vivo raw data base files. The in-vivo imaging system may include, for example an in-vivo imaging device, a receiver/recorder and a computing device such as a workstation a portable device and/or a portable memory.

Abstract: An endoscope comprises an elongated shaft, a headpiece at a proximal end of the shaft, the headpiece having a housing, at least one light source which is arranged in the shaft in a distal area thereof, and produces lost heat, and a passive cooling which has at least one heat pipe which is arranged in the shaft and is thermally coupled to the at least one light source in order to lead away the lost heat in the proximal direction. The at least one heat pipe extends into the headpiece, and a heat sink body is arranged in the headpiece, to which heat sink body the at least one heat pipe is thermally coupled, and which absorbs the lost heat from the at least one heat pipe and emits the lost heat to the environment directly or via the housing of the headpiece.

Abstract: A digital otoscope for capturing live and still digital images of body tissue and having associated optical characteristics that improve the quality of visual information gathered for medical inspection of both human and veterinary subjects. The digital otoscope includes a tip element having dimensions that are small enough to fit into a small body cavity, such as an ear canal. The tip element and the otoscope enclose an assembly of optical components yielding optical characteristics that provide a substantially wide field of view and a substantially wide range of optimal focus from which to form visual information within a small and confined body cavity.

Abstract: Various compositions, methods, and devices are provided that use fluorescent nanoparticles to function as markers, indicators, and light sources. In one embodiment, an endoscopic adaptor is provided for viewing fluorescent nanoparticles. The adaptor can be configured to removably mate to a portion of an endoscope, such as an eyepiece, and it can be adapted to contain a filter for filtering light received through the viewing lumen of the eyepiece. In an exemplary embodiment, the filter is configured to transmit fluorescent light while blocking visible light, to thereby enable a structure containing one or more fluorescent nanoparticles to be viewed through the endoscope.

Abstract: A low cost camera and light emitting diode are coupled to the distal end of an endotracheal tube to obtain an image in real time of tissue at the distal end of the endotracheal tube. Power for the light emitting diode and camera, along with a signal reflective of the image captured by the camera, are transmitted through electrical conductors embedded in the wall of the endotracheal tube and are coupled with a plug. The plug is detachably attached to a radio frequency transmitter module to provide electrical power to the light emitting diode and to the camera and for transmitting the signal of the captured image to a receiver for real time display of the image on a video monitor.

Abstract: An endotracheal tube includes an inflatable balloon close to the distal end. A camera is mounted on the wall of the endotracheal tube proximate and upstream from the balloon to provide a real time image of any accumulation of secretions in the area. A light emitting diode is also mounted in the wall of the endotracheal tube to provide illumination for the camera. Sets of electrical conductors may be embedded in the wall of the endotracheal tube to provide electrical power to the camera and to the light emitting diode and to convey a signal from the camera representative of the image captured by the camera. Connectors attached to the electrical conductors are mated with a transmitter module housing electrical power (such as batteries) for providing electrical power to the light emitting diode and to the camera and electrical circuitry for transmitting the signal from the camera with a radio frequency transmitter.

Abstract: A solid-state image pickup device, comprising: a solid-state image pickup element; a circuit-board main body to which the solid-state image pickup element is connected; a shield piece consecutively connected to the circuit-board main body, capable of being folded, and having a shield pattern disposed; and a signal cable which is connected to a connection terminal disposed on the circuit-board main body and transmits an input/output signal to the solid-state image pickup element, wherein the shield piece is folded at least to one face side of a region where the connection terminal is formed.

Abstract: A laryngoscope including a control circuit and a camera having a housing enclosing the camera that is detachably connectable to a handle, where the camera functions and is compatible with a wide variety of displays. The laryngoscope may optionally be used in either the video mode where the user views a display presenting image data of the area ahead of the blade, or the user may use the laryngoscope in the direct visualization where the user uses the laryngoscope in a traditional manner directly viewing the area ahead of the blade during the intubation procedure. When used in the video mode, an LED is positioned adjacent to a window enclosing the digital image sensor to defog the window.

Abstract: An electronic endoscope according to the present invention has a video-scope that has a first image sensor and a second image sensor, and a light supplier that selectively irradiates white light and excitation-light on an observed portion. The electronic endoscope further has a first color filter that has spectral transmitting characteristics, such that light having a first wavelength range corresponding to blue color is transmitted, and a second color filter that has spectral transmitting characteristics, such that light having a second wavelength range corresponding to green and red colors is transmitted. The electronic endoscope has a first signal processor, a second signal processor, and a third signal processor. The first signal processor generates normal image video signals. The second signal processor generates narrow-band video signals. The third signal processor generates auto-fluorescent video signals.

Abstract: A videoendoscopic surgery training system includes a housing defining a practice volume in which a simulated anatomical structure is disposed. Surgical instruments can be inserted into the practice volume to access the anatomical structure. A digital video camera is disposed within the housing to image the anatomical structure on a display. The position of the digital video camera is supported within the practice volume by a camera bracket that enables a position of the video camera relative to the bracket to be selectively changed, thereby changing a viewing angle achieved by the video camera. In one embodiment the camera bracket is coupled to a boom, a proximal end of which extends outside the housing to enable additional positioning of the digital video camera by user adjustment of the proximal end of the boom. The housing preferably includes a light source configured to illuminate the anatomical structure.

Abstract: In a camera head for an endoscope, a camera system for an endoscope, and an endoscope system of the invention, a camera head section has: an adaptor connection section to be connected to an eyepiece section of an endoscope that enables observation of inside of a body cavity of a subject; a CCD which picks up an observation image from the eyepiece section connected by the adaptor connection section; an image signal processing device which processes an image signal of the observation image picked up by the CCD; a cable including a connector as an output device which outputs the image signal from the image signal processing device; and a recording device which records the image signal.

Abstract: A low cost camera and radio frequency transmitter are detachably coupled to an endotracheal tube to obtain an image in real time of tissue at the distal end of the endotracheal tube. The image recorded by the camera is transmitted to a low cost radio frequency receiver nearby and conveyed to a video monitor to display the image. The use of a wireless transmission system avoids the presence of wires and cords that otherwise might become entangled and cause the endotracheal tube to be inadvertently repositioned or pulled out of the patient.

Abstract: A system and method for endoscopic path planning is provided. The method comprises: identifying a target in a lung, wherein the target is located in a peripheral airway of the lung; generating an endoscopic path to the target, wherein a peripheral artery is used as a surrogate for the peripheral airway; and viewing the endoscopic path.

Abstract: A veterinary otoscope permitting examination of an ear is defined by an instrument head including a proximal end and a distal insertion portion that is insertable into the ear. The veterinary otoscope includes an imaging lens train disposed within the instrument head, wherein each of the imagine lens train, an eyepiece and a distal opening of said insertion portion are aligned along an optical axis. The veterinary otoscope further includes a focusing mechanism for selectively moving at least one of the imagine lens train and the optics contained within the eyepiece relative to one another along the optical axis. The imagine lens train and the optics in the eyepiece define an optical system such that an entrance pipil is substantially located in the distal insertion portion of the instrument head, thereby enabling the entire tympanic membrane to be viewed at once by the user.

Abstract: A camera assembly for positioning within a bodily passageway, including a camera, a catheter adapted to retain the camera, and a rotary coupling interconnecting the catheter and the camera. The catheter is provided with helically-wound threads thereon. The rotary coupling permits the catheter to rotate and thereby move axially while the camera remains rotationally stationary.

Abstract: An endoscope includes an elongated insertion portion inserted into a lumen, an operation portion coupled with a proximal end portion of the insertion portion, and an imaging unit which is arranged in a distal end portion of the insertion portion and which is configured to acquire an endoscopic image. The endoscope includes an imaging unit attachment, portion which is provided at the distal end portion of the insertion portion and detachably holds the imaging unit, an imaging unit insertion/removal portion which is provided in the operation portion and enables insertion/removal of the imaging unit with respect to the insertion portion, and an operating mechanism which includes a distal end portion fixed to the imaging unit and a proximal end portion extended to a imaging unit insertion/removal portion side, and which is configured to perform an attachment/detachment operation of the imaging unit on the imaging unit insertion/removal portion side.