There are provided an endoscope system capable of suppressing an increase in the size of a first connector of an endoscope and of performing non-contact electric power supply and non-contact signal transmission, an endoscope, and an endoscope connector. A power receiving unit and a power supply unit are disposed opposite to each other along an insertion direction of first and second connectors, and an image signal transmission unit and an image signal receiving unit are disposed opposite to each other along the insertion direction of the first and second connectors. A first circuit board is disposed on the opposite side to the power supply unit with respect to the power receiving unit so as to partially overlap the power receiving unit in the insertion direction. The power receiving unit and the image signal transmission unit are disposed so as not to overlap each other in the insertion direction.

There are provided an endoscope system capable of suppressing an increase in the size of a first connector of an endoscope and of performing non-contact electric power supply and non-contact signal transmission, an endoscope, and an endoscope connector. A power receiving unit and a power supply unit are disposed opposite to each other along an insertion direction of first and second connectors, and an image signal transmission unit and an image signal receiving unit are disposed opposite to each other along the insertion direction of the first and second connectors. A first circuit board is disposed on the opposite side to the power supply unit with respect to the power receiving unit so as to partially overlap the power receiving unit in the insertion direction. The power receiving unit and the image signal transmission unit are disposed so as not to overlap each other in the insertion direction.

A feeding tube assembly and feeding tube tip secure a viewing lens proximal of the distal end of the feeding tube tip. The feeding tube tip can include a plurality of protrusions that extend radially inward to secure the viewing lens. The feeding tube assembly and feeding tube tip can be used to improve image quality by keeping tissue from abutting the viewing lens as the feeding tube tip is inserted into a patient.

A feeding tube assembly and feeding tube tip secure a viewing lens proximal of the distal end of the feeding tube tip. The feeding tube tip can include a plurality of protrusions that extend radially inward to secure the viewing lens. The feeding tube assembly and feeding tube tip can be used to improve image quality by keeping tissue from abutting the viewing lens as the feeding tube tip is inserted into a patient.

The present invention relates to a cover having a plurality of moveable, external, angled projecting elements for use with flexible medical scoping devices such as endoscopes or enteroscopes. The invention includes the cover with an over cuff and use of the disposable removable covering in methods of medical scoping procedures or examinations. The invention also includes an applicator for assisting in placing the covering about or over a medical device and a kit of parts.

One or more triggers, fluorescence or auto-fluorescence triggers, NIRAF triggers, methods of using triggers, fiber optic rotary joints (FORJ), free space beam combiners, OCT, SEE and/or fluorescence devices and systems for use therewith, methods of using and/or manufacturing same and storage mediums are provided. One or more embodiments using one or more triggers achieve structural compactness and/or high-speed acquisition while avoiding or reducing the need for high computational power. One or more embodiments use one or more triggers, one or more fluorescence triggers, one or more auto-fluorescence triggers, or NIRAF triggers, and/or one or more rotary joints, for performing pullback and/or image recording. Examples of optical applications that may involve the use of a trigger, fluorescence/auto-fluorescence trigger or NIRAF trigger, and/or a fiber optic rotary joint, include imaging, evaluating and characterizing/identifying biological objects or tissue, such as, but not limited to, for gastro-intestinal, otolaryngologic, cardio and/or ophthalmic applications.

One or more triggers, fluorescence or auto-fluorescence triggers, NIRAF triggers, methods of using triggers, fiber optic rotary joints (FORJ), free space beam combiners, OCT, SEE and/or fluorescence devices and systems for use therewith, methods of using and/or manufacturing same and storage mediums are provided. One or more embodiments using one or more triggers achieve structural compactness and/or high-speed acquisition while avoiding or reducing the need for high computational power. One or more embodiments use one or more triggers, one or more fluorescence triggers, one or more auto-fluorescence triggers, or NIRAF triggers, and/or one or more rotary joints, for performing pullback and/or image recording. Examples of optical applications that may involve the use of a trigger, fluorescence/auto-fluorescence trigger or NIRAF trigger, and/or a fiber optic rotary joint, include imaging, evaluating and characterizing/identifying biological objects or tissue, such as, but not limited to, for gastro-intestinal, otolaryngologic, cardio and/or ophthalmic applications.

A treatment device used together with an endoscope, has a guide pipe and a movement mechanism. The guide pipe has a first pipe having a curving portion and a second pipe continuous with a proximal side of the curving portion. The curving portion has, in its inner circumferential surface, a bent surface bent to the second pipe, and bending the flow direction of the fluid discharged from the distal end of the sheath in a state where the distal end of the sheath is located near the distal end of the second pipe. The movement mechanism protrudes a distal surface of the insertion portion from the distal end of the sheath and brings the distal surface closer to or into abutment with the bent surface in a state where the distal end of the sheath is disposed near the distal end of the second pipe.

A treatment device used together with an endoscope, has a guide pipe and a movement mechanism. The guide pipe has a first pipe having a curving portion and a second pipe continuous with a proximal side of the curving portion. The curving portion has, in its inner circumferential surface, a bent surface bent to the second pipe, and bending the flow direction of the fluid discharged from the distal end of the sheath in a state where the distal end of the sheath is located near the distal end of the second pipe. The movement mechanism protrudes a distal surface of the insertion portion from the distal end of the sheath and brings the distal surface closer to or into abutment with the bent surface in a state where the distal end of the sheath is disposed near the distal end of the second pipe.

A system may comprise a first catheter having a first steerable segment and a second catheter disposed within the first catheter. The second catheter may have a second steerable segment. The system may also comprise an imaging element supported at a distal end of the second catheter, a coil reference sensor supported at a distal portion of the second catheter, and a processor in electrical communication with the coil reference sensor. The processor may be configured to determine a position of a distal portion of the first catheter with reference to the coil reference sensor.