An optical fibre having a functionalised distal exploration end including a sheath, and a ferrule rigidly connected to the sheath at the distal exploration end, characterised in that the distal exploration end has a functionalised head which is removably attached on the ferrule. Also, a method of assembling the optical fibre.

A surgical apparatus includes a housing, a test port retainer, a pressure test chamber, and an image capture assembly. The housing includes a pressure test port. The test port retainer includes a test port retainer housing, a probe seal, and a liquid exclusion barrier. In one aspect, the test port retainer also includes a hydrophobic membrane mounted within the test port retainer housing. The pressure test chamber includes a manifold and a central tube. The first end of the central tube is affixed to the image capture assembly to form a pressure seal, and the second end of the central tube is coupled to the test port retainer so that the pressure test port communicates with the interior volume of the central tube through the test port retainer.

An endoscope system includes at least any one of a processor device that is attachable to and detachable from an endoscope or a light source device that is attachable to and detachable from the endoscope. In a case where the endoscope is mounted on the processor device or the light source device, the processor device or the light source device performs a request sequence in which a request signal, for requesting a start of execution of encoding processing with respect to digital image signals, is transmitted to the endoscope.

A video endoscope, in particular a video mediastinoscope, comprises an elongate rigid shaft and a handle detachably attached to a proximal end section of the shaft, wherein the shaft comprises an optics shaft comprising an imaging optics and an electronic image sensor, wherein the optics shaft and a plug connector housing arranged at a proximal end of the optics shaft form a hermetically sealed unit enclosing the imaging optics and the image sensor, and wherein the handle comprises a handle housing in which an electronics unit is accommodated, wherein the electronics unit is hermetically sealed. The invention also relates to a method for configuring a video endoscope.

One aspect of the present disclosure can include an intubating airway. The intubating airway can include a first having a first guiding surface and a second articulating component that is attached to the first component via a hinge and has a second guiding surface. In a closed configuration, the first and second guiding surfaces can be flush with one another so that the first and second components collectively define a conduit having an interior passage that is dimensioned to direct a fiber-optic scope or an endotracheal tube extending through the interior passage for tracheal intubation. In an open configuration, the first and second guiding surfaces are not flush with one another so that no such conduit is formed.

Endoscope apparatuses for generating at least one image of a portion of an object are described herein. The endoscope apparatus includes an ultrafine needle adapted for insertion into the object; a fiber probe that is slidably disposed in the ultrafine needle, the fiber probe including a plurality of optical fibers or cores that act as illumination optical fibers and collection optical fibers; an optical assembly that is coupled to the fiber probe, the optical assembly including: at least one transmission optical pathway to provide at least one excitation light signal to the portion of the object to be imaged during use; and at least one return optical pathway that is adapted to transmit reflected light signals from the portion of the object when it is illuminated during use with at least one sensor for generating at least one image via at least one set of optical elements.

Disclosed are devices, systems, and methods for characterizing tissue using light scattering spectroscopy. A tissue characterization probe includes an elongate member having a proximal end and a plurality of distal probe tips at a distal end. A plurality of illumination fibers extend through the elongate member to the distal probe tips such that each distal probe tip includes at least one illumination fiber. A plurality of detection fibers also extend through the elongate member such that each probe tip includes at least one detection fiber. The disclosed devices and systems beneficially enable characterization of tissues within depths greater than 100 gm. The disclosed devices and systems also enable effective characterization of anisotropic tissues, such as cardiac myocardium.

A cart or man-portable system and method for performing endoscopic procedures is provided. A portable display device, such as a laptop computer, is coupled to a handle comprising a miniature camera and fiber optic illumination subsystem. A sterile disposable portion is fitted over the illumination subsystem and inserted into a target area on a patient. Images of the target area are conveyed from the camera to the display device while an endoscopic procedure is performed, thus facilitating real-time diagnosis during the procedure.

The catheter probe comprises a catheter tip and a catheter body. The catheter tip comprises a plurality of channels for housing a plurality of optical sensors. Each one of said plurality of optical sensors comprises a ferrule comprising a via, a microlens aligned with said via and attached to said ferrule and an optical fiber for optically coupling said microlens to a monitoring means.

An imaging system (100) comprises a multimode waveguide (Wm) configured to receive input light (Li) from a light source (20) into its proximal side (13p) and output a corresponding speckle pattern (Pn) based on the input light (Li) out of its distal side (13d) for illuminating a sample (S) to be imaged. A single-mode waveguide (Ws) is connected to the multimode waveguide (Wm) for coupling the input light (Li) from the light source (20) to the multimode waveguide (Wm). The multimode waveguide (Wm) has a relatively short length (Zm) and relatively high flexural rigidity (R) for maintaining a unique relation between the input characteristic (λ,A) of the input light (Li) into the multimode waveguide (Wm) and a spatial distribution (Ixy) of the speckle pattern (Pn). The single-mode waveguide (Ws) may be relatively long and flexible (F) for allowing movement of the short rigid multimode waveguide (Wm).