A processor for an endoscope includes: an acquisition unit that acquires a detection value detected by an endoscope or a captured image captured by the endoscope; a specification unit that specifies operation information of a next stage based on the detection value or captured image acquired by the acquisition unit; and an output unit that outputs the operation information specified by the specification unit.

The present invention provides a sampling capsule and a sampling capsule system. The sampling capsule includes an enclosure, a partition wall arranged in the enclosure, and a sample chamber enclosed by the partition wall and the enclosure at a first side of the partition wall. The sampling capsule further includes an inner sample inlet on the partition wall, an outer sample inlet, a sampling tube and a switch assembly. The outer sample inlet is on the enclosure at a second side of the partition wall. The sampling tube connects the outer sample inlet and the inner sample inlet, and the switch assembly clamps or unclamps a portion of the sampling tube. When sampling is needed, the switch assembly unclamps the sampling tube to sample liquid. When sampling ends, the switch assembly tightly clamps the sampling tube to prevent sample liquid leak or contamination.

Provided are robotic systems and methods for navigation of luminal network that detect physiological noise. In one aspect, the system includes a set of one or more processors configured to receive first and second image data from an image sensor located on an instrument, detect a set of one or more points of interest the first image data, and identify a set of first locations and a set of second location respectively corresponding to the set of points in the first and second image data. The set of processors are further configured to, based on the set of first locations and the set of second locations, detect a change of location of the instrument within a luminal network caused by movement of the luminal network relative to the instrument based on the set of first locations and the set of second locations.

A sensor device, in particular a sensor head, for an inspection camera, in particular an endoscope, has at least one illumination unit for illuminating an examination object. The sensor device further has at least one camera unit for detecting the examination object. In addition, the sensor device has at least one housing unit in which the camera unit and the illumination unit are arranged. The housing unit is designed to taper along a longitudinal axis of the housing unit.

An articulated tip part for an endoscope, and an endoscope, including segments including a distal end segment having an outer wall defining an inner spacing adapted to accommodate a camera assembly therein and a proximal wall having a proximal surface, the distal end segment having an outer surface, wherein adjacent of the segments are interconnected by at least one hinge member to enable bending of the articulated tip part; and an insertion guide adapted to guide a steering wire and including an entry provided in the outer surface of the distal end segment, the insertion guide also including an exit fluidly coupled with and leading to the inner spacing of the distal end segment, whereby an end of a steering wire can be guided into the inner spacing of the distal end segment via the entry of the insertion guide.

An exemplary system includes a memory storing instructions and a processor communicatively coupled to the memory. The processor is configured to execute the instructions to receive, from a sensor of a surgical instrument, environmental condition information associated with the surgical instrument and detected by the sensor while the surgical instrument is disconnected from an external power source, the surgical instrument including circuitry configured to be powered and operate only while the surgical instrument is connected to the external power source, determine, based on the environmental condition information, an operational condition of the surgical instrument, and provide a notification indicating the determined operational condition of the surgical instrument.

An endoscope system includes an endoscope that can be inserted in and pulled out from a subject, and includes a tip portion provided with an imaging unit including an optical system and an image sensor, a posture control sensor that is arranged at the tip portion of the endoscope, and detects posture information in at least three directions, a front-rear direction, an up-down direction, and a left-right direction, of the tip portion, and a calculation device that calculates presence or absence of deviation in the up-down direction of an image captured by the imaging unit, based on the posture information in the three directions detected by the posture control sensor. The calculation device displays an indicator indicating the presence or absence of deviation in the up-down direction of the image in association with the image on a monitor.

An endoscope having an insertion tube with a distal optical module and a releasable handle. In a semi-robotic embodiment, the handle comprises haptic controllers and a computer configured for steering and/or adjusting physical properties of the insertion tube in response to one or more command inputs from the haptic controllers. The computer may also convert image data received from the optical module into two-dimensional images displayable on a monitor. The endoscope may have inertial measurement units (IMUs) for providing data to the computer for creating a digital three-dimensional image representation of an anatomy model and/or for facilitating handling properties of the endoscope.

A catheter system includes an elongated tube structure configured for insertion into a luminal space, such as the vasculature, of a body. The catheter is conductive and configured to conduct electrical signals. The catheter includes one or more power and data coupling devices configured to send and receive power and/or data signals, such as from an underlying guidewire disposed within a lumen of the catheter. One or more sensors are coupled to a distal section of the catheter and are electrically connected to the one or more power and data coupling devices.

For determining a precise orientation and positioning of an endoscope in an electromagnetic field, an endoscope device has a proximal insertion head and has a shaft extending distally therefrom having a center axis. The shaft extends with at least one elongated lumen through the device. A sensor rod has at least two sensor coils arranged with finite spacing in relation to one another in the longitudinal direction. The at least two sensor coils are oriented in relation to one another at a finite angle.