A light source for an endoscope system includes a receptacle for receiving a first end of a light guide cable, a light engine with at least one LED configured to provide light transmitted from the first end of the light guide cable to a second end of the light guide cable connected to an endoscope, and a light output controller configured to adjust an intensity level of the light engine according to a set intensity level when an imaging mode is selected and at least one auxiliary mode to indicate to the user a status of the system such as a standby mode, a disconnected light guide cable, or additional statuses related to the functioning of the endoscope system.

An intubation device for use in an endotracheal intubation procedure includes: a laryngoscope blade having a tip and a base; a handle attached to the base of the blade; a channel, the channel including a blade channel portion extending along the blade substantially from the tip to the base and including an outlet proximate to the tip and a handle channel portion extending partially along the handle from the blade channel portion; and a tube movement mechanism in the handle, the tube movement mechanism including a thumb interface.

A multifunctional laryngoscope is provided that includes a handle comprising a proximal end and a distal end and a display screen on the handle. The laryngoscope includes a laryngoscope camera at the distal end of the handle and connects to an introducer comprising an orientation sensor at a distal end of the introducer. The laryngoscope includes a processor programmed to execute instructions for receiving from a steering input a steering command in a first reference frame, and mapping the steering command to a second reference frame oriented to the distal end of the introducer based on an orientation signal from the orientation sensor.

An intubation device for use in an endotracheal intubation procedure, the intubation device including: a laryngoscope blade having a tip and a base; a handle attached to the base of the blade for allowing the intubation device to be held in a hand of a user; a channel for receiving an endotracheal tube, the channel including a blade channel portion extending along the blade substantially from the tip to the base and including an outlet proximate to the tip for allowing a distal end of the endotracheal tube to be advanced from the outlet and a handle channel portion extending partially along the handle from the blade channel portion; and a tube movement mechanism in the handle for moving the endotracheal tube through the channel to thereby advance the endotracheal tube, the tube movement mechanism including a thumb interface for allowing the user to operate the tube movement mechanism using a thumb of the hand that is holding the intubation device, to thereby allow the user to hold the intubation device and advance the endotracheal tube in an endotracheal intubation procedure using a single hand.

A head-mounted display device for interface with a blood processing machine using a disposable component having tubing and a blood component receptacle includes a frame configured to be mounted on a person's head and configured to hold a lens in front of an eye of the person. The display device includes a display, a wireless transceiver configured to communicate with a network, and a processing circuit. The processing circuit is coupled to the frame, the display and the wireless transceiver and receives instructions for training the person how to use the blood processing machine. The processing circuit overlays indicators, text, highlighting and/or icons on the blood processing machine as seen from a field of view of the person based on the instructions to train the person in using the blood processing machine.

Destination management processing units (13,23) of a video processor and a peripheral device each perform destination management processing in a communication between the video processor and the peripheral device. A plurality of communication processing units are situated above the destination management processing unit, respectively correspond to functions of a plurality of peripheral devices, and each process a command. When the destination management processing unit transmits a command, the destination management processing unit adds, to the command to be transmitted, destination information that indicates which of the plurality of communication processing units is to be used. When the destination management processing unit has received a command, the destination management processing unit determines a destination of the received command using destination information added to the received command and distributes the received command to a communication processing unit from among the plurality of communication processing units that is indicated by the destination.

A capsule medical device guidance system includes: a capsule medical device including a permanent magnet and configured to be introduced into a subject; a magnetic field generator configured to generate a magnetic field to be applied to the capsule medical device; an operation input device configured to input operation information; and a processor including hardware. The processor is configured to: control the magnetic field generator, based on the operation information input from the operation input device, to change the magnetic field to change at least one of the position and the posture of the capsule medical device; obtain control information for the magnetic field generator in a state where forces acting on the capsule medical device are balanced before starting or when starting operation on the operation input device; and control the magnetic field generator by using the control information after the operation is finished.

According to one aspect, an endoscope system may include a shaft having a proximal end and a distal portion configured for insertion into a subject. The distal portion may have a distal end. The shaft may also include a lumen extending between the proximal end and the distal end. The lumen may be configured to receive an instrument extendable through the lumen of the shaft. The endoscope system may also include a visualization system coupled to the shaft for visualizing a region distal to the distal end of the shaft. The endoscope system may also include a handle coupled to the proximal end of the shaft. The handle may be configured for gripping by a user. The handle may include a shaft control system for controlling operation of the shaft. The handle may also include an instrument control system for controlling operation of an instrument extendable through the shaft.

A steerable endoscope is provided that includes a tubular body with a plurality of wires that, when deflected in a non-axial direction, cause a distal end of the endoscope to change orientation. A controller for the endoscope generates instructions to cause the deflection of one or more of the plurality of wires according to a steering input.

A system and method for instant tongue sampling and diagnosis includes acquiring a plurality of tongue images from a plurality of digital oral devices, and a current health conditions, building a diagnosis framework for diagnosing a current health condition of a user by: i) analyzing the collected tongue images with a visual recognition engine to determine tongue characteristics of each tongue captured in the tongue images, and ii) correlating the tongue characteristics with the current health condition, identifying tongue characteristics from a received image of the tongue using the visual image recognition engine, applying the diagnosis framework to the tongue characteristics of the tongue to diagnosis the current health condition of the user, and modifying a graphical user interface of the digital oral device to display a custom health report indicative of the current health condition of the user, in response to applying the diagnosis framework.