The present invention relates to a uterine cervical image acquisition apparatus which acquires and displays images of a uterine cervix, and in some cases can automatically diagnose the onset of a disease related to the uterine cervix, the apparatus being characterized by comprising: a main body in which a camera for acquiring uterine cervical images is installed on one side, a user interface for displaying the uterine cervical images and inputting user touch commands is installed on the opposite side, and a handlebar unit is formed in a downward direction; a light source unit which emits light toward the front of the main body; a battery which is positioned inside the handlebar unit to supply power for charging and operation; an operation button unit which includes at least an image capturing button, a zoom-in button, and a zoom-out button formed on the handlebar unit; a memory for storing the captured uterine cervical images; a communication unit for transmitting the uterine cervical images to a reading computer; an image transmission control unit for controlling to store the captured uterine cervical images in the memory, encrypt selected uterine cervical images, and transmit the encrypted images to the reading computer; a display screen control unit which controls to display, on the left and right or above and below the captured uterine cervical display images, a menu bar for receiving the user touch commands; and a camera control unit which controls zooming and auto-focusing of the camera and the brightness of the light source unit according to operations of the provided button.

A system for self-imaging a body portion includes a self-imaging device and an ancillary device that is attachable to the self-imaging device. The self-imaging device has a base member, a camera located within the base member and a guide element for transmitting light along a path extending between the camera and an exposed tip of the guide element that opens out of the self-imaging device at a given side of the device. The ancillary device is arranged to attach to the self-imaging device at said same given side while substantially not obstructing incoming light arriving towards the self-imaging device from being transmitted via the guide element towards the camera.

Embodiments of the present invention may be used to perform measurement of surfaces, such as external and internal surfaces of the human body, in full-field and in 3-D. Embodiments of the present invention may include an electromagnetic radiation source, which may be configured to project electromagnetic radiation onto a surface. The electromagnetic radiation source may be configured to project the electromagnetic radiation in a pattern corresponding to a spatial signal modulation algorithm. The electromagnetic radiation source may also be configured to project the electromagnetic radiation at a frequency suitable for transmission through the media in which the radiation is projected. An image sensor may be configured to capture image data representing the projected pattern. An image-processing module may be configured to receive the captured image data from the image sensor and to calculate a full-field, 3-D representation of the surface using the captured image data and the spatial signal modulation algorithm. A display device may be configured to display the full-field, 3-D representation of the surface.

An endoscope system includes an endoscope including an insertion portion including a bending portion, a grasping portion arranged at a proximal end portion of the insertion portion, and an electric actuator configured to bend the bending portion, and an operation unit including an operation member configured to operate the electric actuator and a transmission member configured to wirelessly transmit operation information of the operation member to the electric actuator.

A stimulation probe device including a first electrode, a stimulation module, a control module and a physical layer module. The stimulation module is configured to (i) wirelessly receive a payload signal from a console interface module or a nerve integrity monitoring device, and (ii) supply a voltage or an amount of current to the first electrode to stimulate a nerve or a muscle in a patient. The control module is configured to generate a parameter signal indicating the voltage or the amount of current supplied to the electrode. The physical layer module is configured to (i) upconvert the parameter signal to a first radio frequency signal, and (ii) wirelessly transmit the first radio frequency signal from the stimulation probe to the console interface module or the nerve integrity monitoring device.

There is provided a system for cardiac electromagnetic/magnetic catheterization for diagnosing and treating blood vessels of a patient. The system having at least one electromagnetic intraluminal capsule able to force its way through a narrowing blood vessel, the capsule carrying a camera allowing visualization of blood vessels of a patient. There is a portable electromagnetic tip, where the tip pulls the electromagnetic capsule by electromagnetic force, and when the magnetic tip moves along a body of a patient and pulls the intraluminal electromagnetic capsule along with it towards a narrowing blood vessel visualized by the camera, so that the capsule then treats the narrowing site and clears the blood vessel from coronary plaque. In addition working capsule can replace diseased valve in any cardiac position for either temporary or permanent needs.

An auxiliary operation structure (1) for an endoscope, comprising: a control module (10), a human-machine interface module (30) and a clamping module (12). A plurality of pressing units (P1, P2, P3, P4, P5, P6), a plurality of dial driving units (D1, D2) and a plurality of knob driving units (S1, S2) of the control module (10) are connected to a plurality of control units on an operation module (21) of an endoscope (2) of the control module (10). With the auxiliary operation structure (1) for the endoscope (2), a physician can control a joystick (15) via the hands to perform manipulation, such that the operation module (21) of the endoscope (2) can be controlled and operated easily to perform an invasive examination or a minimally invasive operation by means of the endoscope (2). In an invasive examination or a minimally invasive operation, a physician is not required to hold the operation module (21) of the endoscope (2) with the hands, avoiding excessive load on the wrists or arms of the physician and occupational injury thereto.

An image processing apparatus includes a processor including hardware, the processor being configured to: determine whether or not an overlapping portion is present in imaging areas included in a plurality of images captured by a plurality of imagers, respectively, the plurality of imagers being are inserted into a subject to capture images of an observation target at different positions from each other; determine whether or not each of the plurality of imagers is inserted to a focal point position at which the observation target is in focus; and generate a composite image that is composed of the plurality of images when it is determined that each of the plurality of imagers is inserted to the focal point position and that the overlapping portion is present in the imaging areas.

Provided is a tooth analysis server including: a server communication unit linked with a tooth photographing device for photographing teeth to communicate with a user terminal; a database management unit for managing an image of the photographed teeth as data; an analysis unit for analyzing a state of the teeth of the user according to the request; and a result providing unit for providing an analysis result for the state of the teeth of the user to the user terminal, wherein the analysis unit receives a first image obtained by photographing the teeth of the user at a first speed from the tooth photographing device to perform a first analysis, and receives a second image obtained by photographing the doubtful area at a second speed slower than the first speed from the tooth photographing device to perform a second analysis.

An endoscope navigation system is provided that updates an anatomy model based on a live camera signal. As the endoscope advances within the patient, a camera signal, and corresponding position signal, of the endoscope, is provided and used to update the anatomy model based on identified divergences between the camera signal at a particular position and anatomy model.