A catheter assembly including one or more conductive pathways to assist with placement of the catheter assembly into a patient's vasculature by enabling ECG signals emanating from the patient's heart to be detected, and a method for reconfirming an initial position of a distal end of a catheter tube of the catheter assembly. The conductive pathways can be configured to reconfirm via ECG signal detection proper placement of the catheter tube at a time subsequent to initial catheter placement into the vasculature. The catheter assembly can include an outer conductive pathway deposited on an outer surface of the catheter tube. The outer conductive pathway can have a distal end located distal to a portion of the catheter tube at a skin insertion site when the catheter tube is inserted into a patient.

An endoscope includes a control module, a lens module, a cover, and an encapsulation. The lens module is electrically connected to the control module. The cover has a transparent area, and the cover covers the lens module in a sealing manner. The encapsulation encapsulates the cover and the control module, and exposes the transparent area, such that the encapsulation serves as a shell of the endoscope.

Medical borescopes, such as laparoscopes. In some embodiments, a medical borescope may comprise a handle and a tube extending from the handle, which tube may be configured to reduce electromagnetic interference within the tube. The borescope may further comprise a tip assembly positioned at a distal end of the tube, which may comprise an image sensor configured to take images through the distal end of the tube. The borescope may further comprise a dongle comprising an image processor configured to receive image data from the image sensor. The dongle may be removably coupleable with the medical borescope such that the dongle can be coupled with a plurality of distinct medical borescopes.

An endoscope connector includes: a fitting portion that has a cylindrical shape, and electrically connects an endoscope for observation of a subject to an external apparatus, the external apparatus processing information of the observed subject; a planar part provided on at least a portion of the cylindrical shape of the fitting portion; and an electroconductive part that is provided to be electrically conductive on the planar part and performs communication with the external apparatus.

The present invention relates to a portable medical platform system of an endoscope, which includes a camera head, a tube, a handle, and a portable main system. The camera head having light sources, a sensor, and an image signal processor is mounted in a distal end of the tube. The other proximal end of the tube is connected with the handle which has provided with several functional buttons thereon for electrically connecting with a control board to control actions of light sources and the camera head wherein the portable main system is also connected with the control board. By providing the control system on the handle with separated control board, the invention therefore obtains utility and improvement for a medical surgery.

A lighted swivel laparoscopic imaging apparatus has a shaft having a proximal end opposite a distal end, wherein the proximal end is configured for attachment to an actuator, wherein a longitudinal axis extends through the shaft, between the proximal and distal ends, wherein the distal end is configured for insertion into patient anatomy and for attachment of one or more laparoscopic tools, wherein at least a first laparoscopic tool at the distal end pivots on a first gimbal apparatus that is actable, from the actuator at the proximal end of the shaft, to rotate the at least the first laparoscopic tool about the longitudinal axis of the shaft and, further, to rotate the at least the first laparoscopic tool about at least a second axis, orthogonal to the longitudinal axis. The images from the laparoscopic instrument may be viewed in virtual format with a virtual overlay of where the instruments exist and are moving inside the body from an AR/XR headset or other 3D viewing device.

An electronic device may include a shaft insertable into a target area, and an electronic component configured to generate a signal. The electronic component may be on or within the shaft. The electronic device may also include at least one antenna on or within the shaft. The electronic device may also include a receiver operatively coupled to the antenna. The receiver may monitor an electrical characteristic of the antenna to identify an effect of an electromagnetic field on the electrical characteristic of the antenna. The electronic device may also include a processor communicatively coupled to the receiver. At least one of the receiver and the processor may predict an effect of the electromagnetic field on the signal generated by the electronic component, based at least in part on the effect of the electromagnetic field on the electrical characteristic of the antenna.

A photoelectric composite module including a first connecting member having an outer frame having a tubular shape, and a plurality of contacts provided in an interior of the outer frame, a first printed board on which a photoelectric conversion element configured to convert an electrical signal into an optical signal is mounted, and which is configured to act as a relay between the contacts and the photoelectric conversion element and a second printed board configured to act as a relay between the contacts and an electrical signal cable. The first printed board and the second printed board are three-dimensionally arranged.

An apparatus, system and methods that comprise adding a removable or detachable carrier containing a camera and illumination to a TEE probe, thereby allowing the user to view the placement of the probe and minimize or reduce the risk of esophageal and pharyngeal complications during the positioning of the TEE probe into the patient's esophagus. The reduction or minimization of complications occurs by allowing the cardiologist direct visualization of pharyngeal and esophageal structures during intubation. This device and procedure eliminate any “blind procedure”, whereby direct visualization of the pharyngeal structures and esophagus present a possible solution to these mechanical complications. Once the TEE probe has been properly positioned in the esophagus, the carrier is removed from the esophagus. The removable or detachable camera of the present disclosure can be used in other industries.

An endoscope has an imaging unit at a tip portion of an insertion unit to be inserted into a body cavity, and the imaging unit includes: a solid-state imaging device which is disposed in such a manner that a photodetecting surface thereof crosses a longitudinal direction of the insertion unit and which performs photoelectric conversion on an optical image formed on the photodetecting surface; a circuit board having a connection surface which is opposed to a surface, opposite to the photodetecting surface and formed with connection terminals, of the solid-state imaging device and which serves for electrical connection to the connection terminals of the solid-state imaging device, wherein the circuit board is a rigid board that is L-shaped as defined herein; and a first leg and a second leg that constitute the L-shaped circuit board and are perpendicular to each other are provided as defined herein.