An electronic endoscope system is provided with an electronic endoscope, a processor provided with a still image acquisition unit that acquires a part of a moving image imaged by the electronic endoscope as a still image, an association processing unit that associates place information regarding an imaging place of living tissue in a the lumen with the still image, and a recording unit, a monitor, and an input operation device that transmits a capture instruction for acquiring the still image from the moving image to the still image acquisition unit in response to an operation of determining one place out of a plurality of places in the lumen set in advance as a selected place as a trigger, and further transmits information of the selected place to the association processing unit as the place information regarding the imaging place during an imaging period of the moving image.

In embodiments set forth herein, an intraoral scanning system includes a first intraoral scanner, a second intraoral scanner, and a computing device wirelessly connected to both the first intraoral scanner and the second intraoral scanner. The computing device receives first intraoral scan data from the first intraoral scanner and generates a first three-dimensional (3D) surface of at least a portion of a first patient's dental arch based on the first intraoral scan data. The computing device further receives second intraoral scan data from the second intraoral scanner and generates a second 3D surface of at least a portion of a second patient's dental arch based on the second intraoral scan data.

A first computing device receives a command to associate the first computing device with an intraoral scanner, the command comprising an identifier. The first computing device wirelessly connects with a second computing device, and sends the identifier to the second computing device. The second computing device wirelessly connects to the intraoral scanner and associates the first computing device with the intraoral scanner. Subsequently, intraoral scan data generated by the first intraoral scanner is sent to the second computing device, the intraoral scan data is processed by the second computing device to generate a three-dimensional surface of a dental site, the three-dimensional surface or a view of the three-dimensional surface of the dental site is sent to the first computing device, and the three-dimensional surface or the view of the three-dimensional surface of the dental site is displayed by the first computing device.

A physician performing a physical examination can miss subtle abnormalities, such as alterations of respiratory rate or dangerous skin lesion. A surgeon performing surgery can miss small areas of bleeding or tumor implants. This invention comprises head display unit comprising sensors including low light level TV (L3TV) cameras that gather data and in real time analyzes the data for potential hazards and alerts the user of a potential hazardous scenario.

A fluid management system for an endoscopic procedure including: a pump configured to deliver liquid from a reservoir to a medical device; a processor comprising hardware, the processor being configured to control operation of the pump; a footswitch in communication with the processor, the footswitch being configured to actuate the pump; and a user input device configured to program the processor to operate the pump at a plurality of predetermined levels of an operational parameter of the pump and to allow a user to select one of the plurality of predetermined levels for pump operation, wherein the processor is further configured to disable at least parts of the user input device when the footswitch is engaged.

A medical image processing apparatus includes a medical image acquisition unit that acquires the medical image including a subject image, a medical image analysis result acquisition unit that acquires an analysis result obtained by analyzing the medical image, a display unit that displays at least one medical image and at least information on presence or absence of a treatment tool or a type of a treatment tool in the analysis result acquired by the medical image analysis result acquisition unit, and an input receiving unit that receives an input regarding whether or not the information on presence or absence of a treatment tool or a type of a treatment tool included in the analysis result is correct.

Systems and methods are provided for preparation of orthodontics and prosthodontics. A method may include scanning a patient's teeth to form first 3D data of the patient's teeth including a removable element that obscures part of the dental surfaces of the patient's teeth and non-obscured tooth surfaces, removing the removable element form the patient's teeth so that the removable element no longer obscures the part of the dental surfaces of the patient's teeth, and scanning the previously obscured part of the dental surfaces of the patient's teeth and the non-obscured tooth surfaces.

A surgical hub may have cooperative interactions with one of more means of displaying the image from the laparoscopic scope and information from one of more other smart devices. The surgical hub may have the capacity of interacting with these multiple displays using an algorithm or control program that enables the combined display and control of the data distributed across the number of displays in communication with the surgical hub. The hub can obtain display control parameter(s) associated with a surgical procedure. The hub may determine, based on the display control parameter, different contents for different displays. The hub may generate and send the display contents to their respective displays. For example, the visualization control parameter may be a progression of the surgical procedure. The surgical hub may determine different display contents for the primary and the secondary displays based on the progression of the surgical procedure.

An image of a field of view is captured by the endoscope and a portion of the image is displayed on a display. A popup image is generated and displayed upon image analysis identification of an occurrence of bleeding or motion of edges of an incision that is within the field of view, but outside the portion of the field of view displayed on the display.

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.