A tube assembly for a living organism includes a tube and a first ferrule. The tube is partially placeable into a living organism. The tube includes a first end, a second end, a through-hole, and a lens. The through-hole extends in a first direction from the second end to the first end. The first ferrule covers an outer periphery of the tube in the first direction. The lens is located in a portion of the through-hole including at least the first end. The tube and the first ferrule contain a ceramic material.

The force of a piezoelectric element is efficiently transferred to an optical fiber without attenuation, so that the vibration of the optical fiber becomes large. Provided is an optical fiber scanner including an optical fiber which has an elongated cylindrical shape in which illumination light emitted from a light source is guided and can emerge from a distal end thereof and whose distal end can be vibrated in a direction intersecting the longitudinal direction thereof; and at least one piezoelectric element which have a plate shape polarized in a thickness direction thereof and which are separately bonded to an outer circumferential surface of the optical fiber closer to a base side than to a distal end thereof.

In certain embodiments, an optical system for obtaining surgical information includes a probe housing a first optical fiber, a light source, a photoanalyzer, and an optical circulator optically coupled to each of the first optical fiber, the light source, and the photoanalyzer. The optical circulator has a first port configured to receive source light generated from the light source, a second port configured to transmit the source light from the first port to the first optical fiber, and a third port configured to transmit return light in the first optical fiber from the second port to the photoanalyzer. The first optical fiber is configured to emit at least a portion of the source light in the first optical fiber from the probe to contact a body structure, and collect light returning from the body structure as a result of the portion of the source light contacting the body structure.

Disclosed is an endoscope for measuring intra-organ pressure (e.g., intragastric pressure), and more particularly an endoscope for measuring intra-organ pressure (e.g., intragastric pressure) and visualizing the response of an adjacent sphincter (e.g., lower esophageal sphincter) to changes in the intra-organ pressure.

Endoscopes having a tip section with viewing elements coupled to a CMOS image sensor and/or a CCD image sensor for transforming light captured by the viewing element into digital and/or analog signals are described. A main connector is coupled with the tip section for transmitting the signals to a main control unit of the endoscope. The main connector includes a pad for transmitting digital signals provided by the CMOS image sensor to a push pin probe in a receptacle of the main control unit. The main connector also include another interface for transmitting analog signals to the main control unit.

A continuous flow endoscope device includes an elongated tubular member defining an interior, a first channel disposed within the interior of the elongated tubular member, a second channel disposed within the interior of the elongated tubular member, and an optics device disposed in a free space of the interior of the elongated tubular member. The second channel is configured to receive an instrument therein during a first portion of an operation. A lumen defined through the second channel is fluidly isolated from a lumen defined through the first channel. The free space of the interior of the elongated tubular member being a space within the interior of the elongated tubular member not occupied by either the first channel or the second channel.

Disclosed herein are configurations for few-mode fiber optical endoscope systems employing distal optics and few-mode, double-clad or other optical fiber wherein the systems directing an optical beam to a sample via the optical fiber; collecting light backscattered from the sample; direct the backscattered light to a detector via the optical fiber; and detect the backscattered light; wherein the directed optical beam is single mode and the collected light is one or more higher order modes.

A multi-conductor cable for use in a catheter is described. The conductor-cable is isotropically flexible to allow catheter steering, but is also longitudinally stiff enough to push and pull the entire cable through the catheter lumen. In one implementation, the multi-conductor cable is bundled for most of its length, to provide longitudinal stiffness and support pushing and pulling the cable through a catheter lumen. However, in one such implementation, the portion of the cable within a steerable section of the catheter is unbundled and divided into individual conductors or groups that are flexible enough that they do not bias or otherwise interfere with the steering of the catheter. In one such approach, a spring wire or other stiffening element is added to the cable at that location to preserve or enhance longitudinal stiffness (tension and compression) of the cable through the unbundled flexible section.

Embodiments of the disclosure may include a medical device comprising an elongate member including a proximal region and a distal region. The elongate member can further include a handle at the proximal region and a tip at the distal region. The tip can include one or more openings, wherein one of the one or more openings at least partially houses an illumination unit. The illumination unit may further comprise a light source, a near-field diffuser proximate to the light source, and a far-field aperture proximate to the light source.

The system includes a catheter with an internal optical fiber that carries an optical beam and an optical element, which reflects the optical beam substantially orthogonal to a rotational axis of the catheter and is coupled to the end of the optical fiber. A motor drive unit (MDU) is coupled to the catheter, wherein the MDU comprises: a rotary collimator; a catheter interface, which couples the optical fiber to the rotary collimator; and a drive motor, which rotates the rotary collimator. The MDU also includes a first dichroic mirror that combines optical paths for a fluorescence-lifetime imaging (FLIm) system and an optical coherence tomography system into a single optical path, which is coupled to the optical fiber through the rotary collimator and the catheter interface. The MDU additionally includes a multispectral detector for the FLIm system, which is electrically coupled to a data acquisition unit forthe FLIm imagin system.