A system is described herein. The system includes a smart nasogastric tube and a computing device. A distal end of the smart nasogastric tube is received by an internal area of a patient and includes a tip, a non-heating light source, and a camera. The tip includes a plurality of side holes or slots used for suctioning and an offset diagonal funneled slot proximate the camera used to pass a sponge brush under direct visualization. The camera is configured to capture a high definition and color video of the internal area of the patient and transmit the video to an application of a computing device. The smart nasogastric tube also includes a central tube for suctioning, feeding or lavage with a proximal port. The application of the computing device receives the video from the camera such that a healthcare professional can view the video in real-time. The video may further be transmitted to a third-party via a Health Insurance Portability and Accountability Act (HIPPA) compliant message or live video stream. The smart nasogastric tube may be presented to patients in many points of implementation, such as emergency departments, urgent care centers, a family practitioners officer, or a medical ward.

There is provided a surgical system including a monitoring sensor configured to sense a characteristic of a surgical site within a body, in a sensing region of the surgical site which includes at least a part of a region outside a display field of an endoscope, and circuitry configured to detect an occurrence of a medical abnormality in the region outside the display field of the endoscope based on a result of the sensing by the monitoring sensor, and generate notification information regarding the detected medical abnormality.

An overtube including: a manipulator channel through which is passed a long manipulator in which a movable portion disposed at a distal end is driven by a driving portion disposed at a proximal end; and a storage unit that stores identification information for the manipulator channel in a readable manner from outside.

Provided is a capsule endoscope that includes a light source configured to emit light to an internal surface of an organ of a human body, an image sensor configured to use light reflected from the internal surface of the organ to generate image data, a processor configured to perform coding on the image data to generate coded data, and perform logical operation on the coded data and a binary code to generate final data, and a communication circuit configured to output the final data to an outside of the human body.

Systems and methods that can improve the safety and efficacy of chest tube thoracostomy are described. For example, this document provides systems and methods that facilitate direct visual confirmation of the proper placement of a chest tube within the thoracic space.

A capsule endoscope according to one embodiment includes: a camera; a transceiver; a tubular receiving coil for receiving power supplied from an external power transmitting antenna via magnetic flux; a tubular capsule accommodating these components; and an X-ray marker to be used in location and orientation detection. In the capsule endoscope, a magnetic body is arranged along the inner periphery of the receiving coil, and a self-propelling drive device including an electromagnet and a permanent magnet is arranged in series with the receiving coil along the tubular axial direction of the capsule so that the permanent magnet does not enter the inside of the receiving coil.

An endoscope including: a shaft; a main body arranged at a proximal end of the shaft; an eyepiece arranged at a proximal end of the main body; an eyepiece system tube, in which the eyepiece is arranged; an eyepiece cone arranged at a proximal end of the eyepiece, wherein the eyepiece cone comprises at least two parts; and an electronic component arranged between the at least two parts of the eyepiece cone; wherein the electronic component is connected to an electronic circuit arranged inside the endoscope and outside the eyepiece system tube.

A digital dental tray system is described including a dental tray shaped to at least partially surround a plurality of teeth and a plurality of three-dimensional (3D) optical imaging elements attached to the dental tray. Each of the 3D optical imaging elements comprises a structured light projector to project a light pattern onto one or more teeth of the plurality of teeth and a camera to capture an image of the one or more teeth.

Endoscopic systems and methods that provide wireless power transmission from a camera head to at least one solid-state light source housed in an endoscopic device. The endoscopic systems and methods employ a multi-stage electromagnetic induction coupling mechanism that can wirelessly transfer power from the camera head to an endocoupler, as well as from the endocoupler to the solid-state light source, while allowing axial rotational motion of at least the camera head, the endocoupler, and/or the endoscopic device relative to one another.