Abstract: An endoscopic device has a handle including an adapter, a shaft connected to the handle, and one or more wires within the handle. The adapter defines one or more openings in a side or proximal end of the adapter. The shaft has a plurality of lumens extending from a proximal end of the shaft to a distal end of the shaft. A first lumen of the plurality of lumens is a working channel for receiving a medical instrument. Each of the one or more wires enter through the one or more openings in the adapter for guiding the one or more wires to a corresponding lumen other than the first lumen and to the distal end of the shaft.

Abstract: A torque detection vascular therapy system employing a vascular therapy device (101) and a torque detection controller (130). The vascular therapy device (101) is operable to be transitioned from a pre-deployed state to a post-deployed state, and includes a matrix of imageable markers representative of a geometry of the vascular therapy device (101).

Abstract: A rigid endoscope including: a shaft; a body disposed at a proximal end of the shaft, a fiber image guide mounted to move longitudinally within the shaft and body; a securing section for securing the fiber image guide, the securing section being positioned within the body; a sliding element mounted to move longitudinally within the body; and a protective sheath encasing the fiber image guide; wherein the fiber image guide is twisted, for image rotation, in a longitudinal portion corresponding to the protective sheath.

Abstract: An image-capturing apparatus and a repair method thereof are provided. The image-capturing apparatus includes a lens frame to which one or more lenses are fixed; an image-capturing frame to which an image-capturing device is fixed; and a fixing member for fixing the lens frame and the image-capturing frame to each other without adhering a fitted portion between the lens frame and the image-capturing frame. The repair method for the image-capturing apparatus includes destructing a fixing member for fixing to each other a lens frame to which one or more lenses are fixed and an image-capturing frame to which an image-capturing device is fixed, and releasing fixing between the frames; replacing at least either of the lens frame and the image-capturing frame; and fixing to each other the lens frame and the image-capturing frame.

Abstract: The invention provides lenses at low cost, which form an illumination optical system for endoscopes that has high efficiency and achieves improved light distribution. The illumination optical system for endoscopes is used in opposition to a light beam exit end 1 of a transmission means F for light emitted from a light source, and comprises, as viewed from the light beam exit end 1, a lens group 10 having positive power and an optical member 20 subsequent thereto which has a spherical surface 20a that functions as a lens, has a radius of curvature R, and satisfies the following condition: 1.48?S/?R2?4??(1) where R is the radius of curvature of the spherical surface, in mm, and S is a surface area of the spherical surface, in mm2.

Abstract: An endoscope apparatus includes an insertion portion inserted into a body, an optical member arranged exposed from an outside surface at a distal end of the insertion portion, an objective optical system that condenses light impinged from the optical member, an electronic image pickup circuit that photoelectrically converts the light condensed by the objective optical system, a heat absorbing section arranged in the vicinity of the electronic image pickup circuit for absorbing heat generated from the electronic image pickup circuit, a heat transfer section extending toward the optical member side for transferring heat of the heat absorbing section, a heat radiation section arranged in the vicinity of the optical member for radiating heat transferred by the heat transfer section to the optical member, and a heat transfer member that is formed by patterning a metal foil on an insulating, flexible film member and includes the heat absorbing section, the heat transfer section and the heat radiation section.

Abstract: The present invention relates, generally, to reporting the approximate three-dimensional orientation of the steerable distal portion of an endoscope to the user of the endoscope. More particularly, the present invention relates to a system and method for providing the endoscope-user a display from which to more easily determine the approximate three-dimensional orientation of the steerable distal portion of the endoscope, thereby facilitating navigation of the endoscope. The present invention also relates to a system and method for limiting the amount the steerable distal portion can bend overall to reduce or eliminate the user's ability to over-retroflex the steerable distal portion of the endoscope.

Abstract: An endoscope has a tubular shaft whose interior contains components, in particular lenses, spacers, diaphragms, prisms and filters of an optical system, said components being at least partially surrounded by a support piece made of shrunk material. It is proposed that the components be surrounded by a transparent and tube-sleeve-shaped shrunk material which has been shrunk before the components are introduced into the tubular shaft.

Abstract: An endoscope has a tubular shaft whose interior contains components, in particular lenses, spacers, diaphragms, prisms and filters of an optical system, said components being at least partially surrounded by a support piece made of shrunk material. It is proposed that the components be surrounded by a transparent and tube-sleeve-shaped shrunk material which has been shrunk before the components are introduced into the tubular shaft.

Abstract: A position control apparatus for controlling position along an axis, comprising: an extensible member that can be extended and contracted along said axis, comprising shape memory alloy locatable to expand and contract along said axis, heating means for controlling said temperature of said shape memory alloy, and a feedback mechanism for controlling said heating means and responsive to variations in said position, wherein said position is controllable by means of said heating means and can be stabilized by means of said feedback mechanism.

Abstract: A rigid endoscope includes an outer housing subassembly that supports an optics subassembly. The outer body subassembly includes concentric tubes with optical fiber for providing object illumination. The optics subassembly includes a tubular sheath sealed at both ends. A compression spring is positioned between a proximal most relay lens element and a distal most eyepiece element. The spring exerts a distally acting force on the elements of an optical objective and relay lens system. It also produces a proximally directed force on optical elements in the eyepiece. This minimizes differential thermal expansion stresses during autoclaving operations.

Abstract: A rigid endoscope includes an outer housing subassembly that supports an optics subassembly. The outer body subassembly includes concentric tubes with optical fiber for providing object illumination. The optics subassembly includes a tubular sheath sealed at both ends. A compression spring is positioned between a proximal most relay lens element and a distal most eyepiece element. The spring exerts a distally acting force on the elements of an optical objective and relay lens system. It also produces a proximally directed force on optical elements in the eyepiece. This minimizes differential thermal expansion stresses during autoclaving operations.

Abstract: An endoscope has an outer tube that is joined to an optical head having an observation element at its end, which elements are sealingly fitted forming a first module element. An inner tube sealingly fitted together with a housing containing optical elements form a second module element having the optical components hermetically closed. The second module element is disposed in the first module element having its distal ends rigidly and sealingly fitted together. The housing of the second module elements extends into said optical head of that first module element and is supported therein allowing relative movement between housing and optical head when thermally stressed.

Abstract: An endoscope has a tubular shaft in whose interior is arranged at least one component of an optical system. At least one support element made from a shrinkable material surrounds at least partially said component in a radial gap between the outer side of said component and the inner side of said tubular shaft. After shrinking of said support element the radial gap is filled up in a manner such that the component is immobilized on the inner side of the tubular shaft via the shrunken support element (FIG. 1).

Abstract: An endoscope has a distal objective and proximal devices for image viewing including a fiber optical image guide, which extends within the endoscope between the objective and the devices for viewing the image and one of whose end regions is fixedly mounted on the endoscope and the other end region of which is axially movably mounted, and the image guide is secured in its proximal end region and the remaining distal end region of the image guide is freely movable, the objective also being movably received relative to the endoscope and the distal end of the image guide and the objective being connected together for common axial movement.

Abstract: A illuminated surgical instrument (11) includes an optical fiber (21) with a proximal end and a distal end, a connector (15) disposed at the proximal end of the optical fiber, and a handpiece (13) disposed generally at the distal end of the optical fiber. The handpiece has a handpiece body and a needle (25) extending distally from the handpiece body, the optical fiber (21) extending generally through the handpiece and extending slightly past the distal end of the needle (25). The handpiece (13) is suitable for one-handed operation by a human user, and the needle (25) is of a size suitable for insertion into a human eye. The instrument (11) includes structures at the distal end of the optical fiber (21) for dispersing light passing from an illumination source through the cable to broaden the area on which light impinges, and a shield (47) disposed proximally of a portion of the dispersing structure to prevent light from impinging upon a predetermined area.

Abstract: A illuminated surgical instrument (11) includes an optical fiber (21) with a proximal end and a distal end, a connector (15) disposed at the proximal end of the optical fiber, and a handpiece (13) disposed generally at the distal end of the optical fiber. The handpiece has a handpiece body and a needle (25) extending distally from the handpiece body, the optical fiber (21) extending generally through the handpiece and extending slightly past the distal end of the needle (25). The handpiece (13) is suitable for one-handed operation by a human user, and the needle (25) is of a size suitable for insertion into a human eye. The instrument (11) includes structures at the distal end of the optical fiber (21) for dispersing light passing from an illumination source through the cable to broaden the area on which light impinges, and a shield (47) disposed proximally of a portion of the dispersing structure to prevent light from impinging upon a predetermined area.

Abstract: An endocoupler system having an endocoupler (110) and a myeloscope (210). The present invention relates to an endocoupler system. More particularly, the present invention relates to an endocoupler system consisting of an endocoupler connected to a myeloscope. The present invention is a system to directly view the pathology of the epidural space in the lower spine region using a miniature endoscopic catheter device. This device is currently used by physicians to diagnose and treat patients who suffer from chronic low back pain. The present invention consists of a developed medical procedure, disposable procedure access kit, multi-lumen steerable catheter (Video Guided Catheter), small fiber optic endoscope (Myeloscope), endocoupler (Endocoupler), light source, and camera system.

Abstract: An improved endoscope prevents abrasion of a fiberoptic image guide with a braid reinforced sheath. Abrasion of fiberoptic image guides within articulating endoscopes quickly wear through a conventional fiberoptic mantle, decreasing the useful life of the endoscope. Preferably, the sheath comprises a metal braid disposed within a polyimide, which effectively protects the image guide from abrasion against the endoscope components and substantially extends useful life.

Abstract: A surgical illumination probe includes an optical fiber with a proximal end and a distal end, a connector disposed at the proximal end of the optical fiber (the connector being adapted for connection to a source of illumination and for holding the proximal end of the optical fiber in position to accept light from the illumination source), and a handpiece disposed generally at the distal end of the optical fiber. The handpiece has a handpiece body and a needle extending distally from the handpiece body, with the optical fiber extending generally through the handpiece and extending slightly past the distal end of the needle. The handpiece is of a size suitable for one-handed operation by a human user, and the needle is of a size suitable for insertion into a human eye.

Abstract: A fiberoptic endoscope includes an axially movable optical fiber guide to compensate for focusing effects, such as thermal expansion or mechanical tolerances. The distal end portion of the optical fiber guide is secured to the distal end of the endoscope while the proximal end portion is permitted to move axially relative to a proximal housing portion of the endoscope. The proximal housing portion includes an eye lens unit secured thereto. A decoupling lens unit is fixed to the proximal end portion of the optical fiber guide so as to move therewith with respect to the eye lens unit.

Abstract: The endoscopic instrument has a long, stretched out shaft (5) and at least one rod-shaped lens (6) arranged therein. The rod lens (6) is provided on its peripheral surfaces (10) with a coating that increases the breaking strength. The coating may be, for example, polyimide, amorphous carbon, or silicon-oxide carbide. To increase adhesion of the coating the rod lens may be pretreated with caustic on its peripheral surfaces.