An instrument head is provided for attachment to a plurality of instrument handles having different power profiles. The instrument head contains an illumination assembly including at least one LED as well as a drive circuit for detecting a power profile of an attached instrument handle and converting variable voltages received from the attached instrument handle to a constant current for powering the at least one LED based on the power profile. Accordingly, the instrument head enables use with a plurality of instrument handles, including those originally configured for use only with incandescent light sources.

Medical endoscope imaging systems and methods of using the same are disclosed. The imaging systems can have an endoscope having an image sensor, a display housing having an image display, a communication link configured to couple the image sensor to the image display, and a camera housing having a camera-sensor. The display housing can be configured to be detachably coupled to the camera housing. The camera-sensor can be configured to receive signals from the image display.

A urolithiasis removing device according to one embodiment can comprise: an insertion tube; a guide which is inserted into the insertion tube and which is relatively movable with respect to the insertion tube; a wire which is inserted into the guide and which is relatively movable with respect to the guide; a basket positioned in front of the wire and capable of holding urolithiasis; and a control unit for determining the size of the urolithiasis on the basis of the relative movement of the guide with respect to the insertion tube or the relative movement of the wire with respect to the guide.

Disclosed are lighting and optical devices, systems, and methods for use in laparoscopic surgical procedures. The disclosed devices, systems, and methods advantageously do not require tethers in order to receive power or transmit data, such as camera images, to and from an external device. In addition, the disclosed devices, systems, and methods utilize improved camera mechanisms and reduce costs and improve accessibility with respect to laparoscopic surgical procedures.

A stylet assembly and method of forming an in vivo image acquiring stylet assembly. The stylet assembly includes an elongate flexible body and an image acquiring device that is supported at a location that is offset from an in vivo facing terminal end of the stylet assembly. A terminal end portion of the stylet assembly is defined by a manipulator that is oriented to extend in a crossing direction relative to a longitudinal axis of the elongate body. The terminal end portion of the stylet assembly is steerable relative to the elongate body and is operable to manipulate positions or adjacent anatomy and/or effectuate guidance of the imaging device relative thereto during use.

The present disclosure relates to an apparatus and method for intubation. The present disclosure relates to an image-guided laryngoscope comprising a housing having a translational assembly, a primary blade coupled to a distal end of the housing and having a channel, a camera assembly having an image capture device, a display holder coupled to a proximal end of the housing and configured to hold a display, and an endotracheal tube configured to translate within the channel of the primary blade.

Portable surgical systems, methods, and kits are described. The surgical systems may include a camera configured to capture images, viewing equipment configured to receive and display the captured images, a processor, and a stand. The camera, the viewing equipment, the processor, and the stand are configured to be housed in a case. Surgery may be performed using the surgical system by retrieving surgical components from the case, assembling the retrieved surgical components into a surgical system, positioning a patient within the surgical system for surgery, configuring the surgical system, performing the surgery with the surgical system, reconfiguring the surgical system during the surgery, disassembling the surgical system after the surgery, and placing the components in the case.

An endoscopic peripheral includes a flexible cable connecting a first end and a second end. The first end of a flexible cable including at least a camera and one or more lights positioned at a time of the first end. The tip is configured for insertion of at least a portion of the first end into a body of patient. The second end of the flexible cable terminates in a connector configured to physically connect the endoscopic peripheral to an electronic device external to the body of a patient. The electronic device powers the camera and the one or more lights and displays content captured by the camera.

A laparoscopic medical device includes an oximeter sensor at its tip, which allows the making of oxygen saturation measurements laparoscopically. The device can be a unitary design, wherein a laparoscopic element includes electronics for the oximeter sensor at a distal end (e.g., opposite the tip). The device can be a multiple piece design (e.g., two-piece design), where some electronics is in a separate housing from the laparoscopic element, and the pieces (or portions) are removably connected together. The laparoscopic element can be removed and disposed of; so, the electronics can be reused multiple times with replacement laparoscopic elements. The electronics can include a processing unit for control, computation, or display, or any combination of these. However, in an implementation, the electronics can connect wirelessly to other electronics (e.g., another processing unit) for further control, computation, or display, or any combination of these.

Presented are systems and methods for the accurate acquisition of medical measurement data of a body part of patient. To assist in acquiring accurate medical measurement data, an automated diagnostic and treatment system provides instructions to the patient to allow the patient to precisely position a medical instrument in proximity to a target spot of a body part of patient. Based on a series of images acquired from a kiosk camera and an instrument camera, these instructions are generated. Subsequent images from instrument camera are analyzed by automated diagnostic and treatment system utilizing a database and deep convolution neural network (DCNN) to obtain measured medical data. An error threshold measurement by the automated diagnostic and treatment system may determine the accuracy of the instrument positioning and the medical measured data. The measured medical data may be communicated to a physician.