An apparatus includes a device interface system having a first connector and second connector, each with a respective optical signal path arrangement operatively aligned when the two connectors are in a connected position. The operative alignment allows a base optical signal to be transmitted from the first connector to the second connector. An optical signal modification arrangement is included in the second connector and is operable to provide a predefined modification to the base optical signal to result in an optical ID signal that is transmitted back to the first connector. An identification processing unit associated with the first connector receives an ID input signal corresponding to the optical ID signal and produces an identification output responsive to the ID input signal.

Embodiments generally relate to propulsion devices, systems, or components thereof, for progressing instruments along passages, as well as associated methods of manufacture. For example, the instruments may include tools, sensors, probes and/or monitoring equipment for medical use (such as endoscopy) or industrial use (such as mining). The described embodiments may also be suitable for applications in other fields to progress an instrument along a passage. Some embodiments relate to an endoscope comprising or configured to receive a propulsion tube configured to assist in progressing the endoscope along a passage.

An endoscope for imaging a fluorescent agent in a patient, the endoscope having a first optical channel communicating light from a first light source and a second light source, the first light source having an excitation wavelength and the second light source having a wavelength different than the wavelength of the first light source; a field stop having a fluorescent indicator; and a second optical channel in optical communication with the first light source and in optical communication with the fluorescent indicator on the field stop. When light from the first light source illuminates the fluorescent indicator on the field stop, the fluorescent indicator is detectable. Image processing components used with the endoscope can identify the fluorescent indicator, or lack thereof, and transmit information to a user.

The invention relates to an endoscopic device, in particular for medical applications, comprising an endoscope with a shaft that is introducible into a subject under examination, and a data processing unit, three or more optical imaging units having respective imaging elements arranged distally on the shaft and image sensors associated therewith for providing image data sets for the data processing unit, wherein the data processing unit is configured and programmed such that it uses the image data sets to determine corresponding image points therein and generates a 3D surface data set of an object imaged by the imaging units in the subject under examination. Moreover, the invention relates to a method for endoscopic examination.

A medical visualisation system including a first medical visualisation device having a first device colour identifier, a second medical visualisation device having a second device colour identifier, a third medical visualisation device having a third device colour identifier, and a monitor device, the first device colour identifier being a first colour, the second device colour identifier being a second colour, and the third device colour identifier being a third colour. The first colour has a first hue angle, the second colour has a second hue angle, and the third colour has a third hue angle, wherein the first hue angle and the second hue angle differ by more than 40 degrees, the second hue angle and the third hue angle differ by more than 40 degrees, and the third hue angle and the first hue angle differ by more than 40 degrees.

Anti-fogging system for an endoscope including an endoscope having an outer housing, an imaging arrangement, and a distal window. A filter lens is located at the distal window, with the filter lens allowing a first portion of electromagnetic light to pass therethrough while absorbing a second portion of electromagnetic light in order to heat the filter lens.

Systems, devices, methods, and program products are provided for operating a medical system that is operable within at least two different medical device regulatory classes. A device control module receives an indicator for performing at least one procedure with a medical device. Based on the indicator, it selects a binary image for booting the control module from among multiple images including a controlled-type and a non-controlled type, which operate in different regulatory classes. A controlled-type image, which may be FDA PMA or other regulatory classes, is verified to be unaltered, and is then used to operate as a regulated medical device. The indicator can be automatic or manual. The indicator may result from connection of a specific medical device or peripheral device or may be user input.

A surgical system comprises a network accessible database configured to store calibration data for an endoscopic image capture device. The surgical system also comprises an image processor configured to be communicatively coupled to the endoscopic image capture device to receive image data of a surgical site during a surgical or diagnostic procedure. The image processor is configured to retrieve the calibration data from the network accessible database via a network connection. The image processor is further configured to process the received images based on the retrieved calibration data. The surgical system further comprises a user control system coupled to the image processor and configured to receive the processed images from the image processor. The user control system comprising a display configured to display the processed images. The calibration data is periodically or dynamically updated on the database to account for changes in the surgical system or new calibration methodologies.

A medical detection attachment includes: an attachment body attached to a connection portion between a light guide configured to guide a laser beam and a rigid endoscope configured to irradiate a subject with the laser beam via the light guide; a first detector provided in the attachment body and configured to detect connection between the attachment body and the rigid endoscope; and a second detector provided in the attachment body and configured to detect connection between the attachment body and the light guide.

A medical system comprises an elongate instrument including a camera configured to capture at least one real-time image of anatomy within a patient anatomy. The medical system further comprises a processor configured to display, on one or more display screens: a three-dimensional patient computer model of the patient anatomy; a synthetic representation of the elongate instrument registered to the three-dimensional patient computer model; over the patient computer model, a representation of a view angle of the elongate instrument, the representation of the view angle being displayed so as to appear to project from a distal tip of the synthetic representation of the elongate instrument; and in a position based on the registration of the synthetic representation of the elongate instrument to the patient computer model, the at least one captured real-time image so as to appear to project from the distal tip of the synthetic representation of the elongate instrument.