An endoscope can comprise a proximal section, an insertion section extending longitudinally from the proximal section and comprising an elongate tubular body disposed along an insertion section longitudinal axis and a lumen extending through the elongate tubular body, and a distal section extending from the insertion section and comprising an elevator portion comprising an elevator configured to position and orient one or more endotherapy tools extending from the lumen, and a camera module comprising an illumination unit and an imaging unit. The camera module can be positioned longitudinally spaced apart from the elevator portion in an in-line configuration, such that the insertion tube longitudinal axis passes through the elevator portion and the camera module. The camera module can be user-detachable from the elevator portion. The camera module can be cleaned and sanitized for reuse and the insertion section can be disposable.

An endoscope device includes a signal processing unit that processes a captured image signal, which is obtained by imaging a subject through an imaging optical system including an objective lens of an endoscope, to generates captured image, an auxiliary measurement light emitting unit that emits planar auxiliary measurement light from the distal end part, a display control unit that causes a display unit to display the captured image including an intersection line formed in a portion where a plane formed by the auxiliary measurement light intersects the subject. The auxiliary measurement light emitting unit emits the auxiliary measurement light in a state where the plane and an optical axis intersects each light at one specific point on the optical axis of the objective lens. A distance from a distal end part of the objective lens of the one specific point is 5 mm or more and 20 mm or less.

Cardiac tissue ablation catheters including an inflatable and flexible toroidal or spherically shaped balloon disposed at a distal region of an elongate member, a flexible circuit carried by an outer surface of the balloon, the flexible circuit including, a plurality of flexible branches conforming to the radially outer surface of the balloon, each of the plurality of flexible branches including a substrate, a conductive trace carried by the substrate, and an ablation electrode carried by the substrate, the ablation electrode in electrical communication with the conductive trace, and an elongate shaft comprising a guidewire lumen extending in the elongate member and extending from a proximal region of the inflatable balloon to distal region of the inflatable balloon and being disposed within the inflatable balloon, wherein a distal region of the elongate shaft is secured directly or indirectly to the distal region of the inflatable balloon.

The disclosure relates to an endoscopic system that includes an image sensor, an emitter and an electromagnetic radiation driver. The image sensor includes a pixel array and is configured to generate and read out pixel data for an image based on electromagnetic radiation received by the pixel array. The pixel array includes a plurality of lines for reading out pixel data. The pixel array also has readout period that is the length of time for reading out all plurality of lines of pixel data in the pixel array. The emitter is configured to emit electromagnetic radiation for illumination of a scene observed by the image sensor. The electromagnetic radiation driver is configured to drive emissions by the emitter. The electromagnetic radiation driver includes a jitter specification less than or equal to about 10% to about 25% percent of the readout period of the pixel array of the image sensor.

Exemplary apparatus for coupling to a probe and providing information regarding at least one structure can be provided. For example, the apparatus can include an electronics arrangement which is configured to obtain the information and transmit the information wirelessly, and a structural connection configuration which is structured and configured to be attached to the probe. The electronics arrangement can include a detector arrangement which is configured to detect at least one return radiation from at least one portion of at least one sample based on the predetermined patterns, and provide the data for the portion(s) based on the return radiation(s). In addition, a computer arrangement can be provided which is configured to generate the information with includes image data for the portion(s) as a function of the data and prior knowledge of the predetermined patterns.

An optical path deflecting prism for endoscope which is used for observing an object in an oblique direction, includes a first prism and a second prism, and the first prism and the second prism are cemented. The first prism has a first polished surface and a second polished surface. The first reflecting surface is a mirror surface having a mirror coating applied to a polished surface of a flat plate, and is fixed by gluing to the fifth polished surface of the second prism upon adjusting an angle so as to correct an optical-axis shift which occurs due to a manufacturing error of the first prism and the second prism.

A catheter comprises an imaging core, an inner sheath enclosing the imaging core, an outer sheath surrounding the inner sheath, and a flexible membrane arranged on the outer sheath and configured to deflect in response to intravascular pressure. At least part of the inner sheath and part of the outer sheath are nested within each other. A chamber is defined by the membrane, and the parts of the inner and outer sheaths that are nested within each other. The chamber provides a space into which the membrane is deflected when surrounded by fluids. A processor controls the imaging core to acquire pressure data by scanning the membrane with light transmitted through the chamber, and to acquire image data by scanning a vessel wall with light transmitted through the inner sheath. If the membrane breaks, the chamber prevents fluids from entering the imaging core, and the catheter continues acquiring image data.

An optical probe assembly as a confocal endomicroscope includes an optical focusing stage that focuses an output beam onto a sample and a mirror scanning stage that is movable for scanning the output beam in both a lateral two dimensional plane and an axial direction, using a side-view configuration. The side-view configuration allows for output beam illumination and fluorescent imaging of the sample with greater imaging resolution and improved access to hard to reach tissue within a subject.

An endoscopy system that includes a computer system with a high definition display monitor and a handheld portion. The handheld portion includes a re-usable handle portion and a single use portion that is configured to be disposed of following a single use. The single-use portion includes an elongated cannula with an imaging module and illumination modules at its distal tip. The handheld portion includes multiple sensors that can detect and measure rotation of the cannula relative to the handle portion, and rotation of the entire handheld portion. The sensor data is used to correctly orient and display images captured by the imaging module onto the high definition display monitor.

The disclosure relates to an endoscopic system that includes an image sensor, an emitter and an electromagnetic radiation driver. The image sensor includes a pixel array and is configured to generate and read out pixel data for an image based on electromagnetic radiation received by the pixel array. The pixel array includes a plurality of lines for reading out pixel data. The pixel array also has readout period that is the length of time for reading out all the plurality of lines of pixel data in the pixel array. The emitter is configured to emit electromagnetic radiation for illumination of a scene observed by the image sensor. The electromagnetic radiation driver is configured to drive emissions by the emitter. The electromagnetic radiation driver includes a jitter specification that is less than or equal to about 10% to about 25% percent of the readout period of the pixel array of the image sensor.