An examination device includes a processor, and the processor detects, in swallowing videoendoscopy in which an inflow object is given to a subject and a swallowing action is observed, at least two timings among a swallowing instruction timing at which a swallowing instruction is given, an inflow timing of the inflow object into the pharynx during the swallowing action, and a swallowing reflex triggering timing in the subject.

A manually articulated stylet assembly for placing an endotracheal tube. The stylet assembly has a steering shaft that carries a flexible distal tip at one end and is attached to a handle at the other end. The distal tip is manipulated via sheathed cables controlled by a remote actuator in the handle. A biasing member inside the remote actuator maintains continuous tension on the cables to improve control. A video camera is carried in a recessed lens pocket in the steering shaft but spaced from the distal tip. The camera FOV captures movement of the distal tip with foreshortened perspective. A collar seat in the handle receives the collar connector of a standard endotracheal tube, providing quick disconnect when removing the stylet assembly upon placement.

An esophageal monitoring device includes a camera and, optionally, one or more lights to enable visualization of an interior of a subject's esophagus. Visualization of the interior of the subject's esophagus before and after a left atrial ablation procedure may enable a healthcare provider to determine whether or not the left atrial ablation procedure has damaged the subject's esophagus before the subject experiences any symptoms of such damage. An esophageal monitoring device may also include sensors and/or markers that enable a determination of its location within a subject's esophagus. Such an esophageal monitoring device may be configured for three-dimensional mapping, and enable the generation of an accurate three-dimensional map of the physical relationship between a subject's esophagus and the left atrium of his or her heart. Methods of monitoring a subject's esophagus while a left atrial ablation procedure is being conducted on the subject's hear are also disclosed.

An apparatus includes a body, a shaft assembly, and a first sensor. The shaft assembly extends distally from the body. The shaft assembly includes a first outer shaft member and a second outer shaft member. The first outer shaft member has a first distal end. The second outer shaft member has a second distal end. The second outer shaft member is translatable relative to the first outer shaft member. A distal portion of the second outer shaft member is configured to encircle an anatomical structure of a patient and couple the second distal end with the first distal end while encircling the anatomical structure of the patient. A first sensor is configured to detect an outer diameter of the anatomical structure encircled by the distal portion of the second outer shaft member.

An apparatus includes a first shaft extending distally from a proximal end to a distal end. The first shaft is sized to fit within an esophagus of a patient. The first shaft includes a first shaft lumen extending distally to the distal end. The apparatus further includes a second shaft slidably positioned within the first shaft lumen. The second shaft is sized to fit within the shaft lumen and extend through the transverse bore. The second shaft is configured to receive a guide element and a sphincter augmentation device so that the sphincter augmentation device may be deployed through an interior of the esophagus to an exterior of the esophagus.

Disclosed are methods for performing endoscopy comprising directing a distal end of an endoscope to proximity of a portion of a surface of a bodily cavity; and directing a liquid-gas stream at a portion of the surface of the bodily cavity. Disclosed are also devices useful in endoscopy, comprising: an elongated body having a proximal end and a distal end; a nozzle at the distal end; a gas channel configured for conveying a gas from the proximal end to the nozzle; and a liquid channel configured for conveying a liquid from the proximal end to the nozzle, wherein the nozzle is configured to generate a liquid-gas stream directed in a specified direction from a gas conveyed by the gas channel and a liquid conveyed by the liquid channel.

A flexible endoscope insertion method includes: rotating a hollow organ by changing the body position to semilateral position or lateral position for observing the lateral wall of the lumen; turning the tip of the flexible endoscope to the lateral wall of the lumen by rotating the endoscope in the counter direction of the lumen; and retracting the organ with the endoscope itself by rotating the endoscope in the counter direction of the lumen. In other embodiments, the method includes: rotating a body cavity by changing the body position to the appropriate position for observing the lateral side of the organ; turning the tip of the flexible endoscope to the lateral side of the organ by rotating the endoscope in the direction of the lateral side of the organ; and retracting the organ with the endoscope itself by rotating the endoscope in the direction of the lateral side of the organ.

An image processing apparatus interpolates a signal of a missing color component based on first, second, and third color signals respectively generated by first, second, and third pixels of an image sensor, to generate color signals. These pixels are arranged in a matrix. The first pixels generate the first color signal of a first luminance component of white light. The second pixels generate the second color signal of a second luminance component of narrow band light. Density of the first pixels being higher than density of the second pixels and density of the third pixels. The apparatus extracts a specific frequency component signal from a color signal of the first luminance component among the color signals generated by interpolation, and adds the specific frequency component signal to a color signal of a color component different from the first luminance component depending on white light imaging or narrow band imaging.

An endoscopy system including a balloon-equipped endoscope including a balloon which is configured for slidable frictional engagement with an interior wall of a body passageway and axial stretching of the interior wall when inflated to a slidable frictional engagement pressure and displaced axially along the body passageway and a balloon inflation subsystem operative to selectably inflate the balloon to the slidable frictional engagement pressure.

An attachment unit rotates in directions around a longitudinal axis with respect to an insertion main body when rotary drive force is transmitted from a drive force transmission unit provided to an insertion section, and allows propulsive force in one of directions parallel to the longitudinal axis to act on the insertion section by rotating in contact with a paries. The attachment unit includes a fin portion which is spirally extended along the longitudinal axis and whose dimension from the longitudinal axis to an outer peripheral end vary in accordance with how external force different from the propulsive force acts in the directions parallel to the longitudinal axis in a state that the attachment unit does not rotate with respect to the insertion main body.