The present technology relates to a medical system, a communication method, an imaging device, an information processing device, and an endoscope system capable of stably transmitting sensor signals output from a sensor that obtains data in a living body by wireless communication. A medical system includes a sensor that is provided in or connected to an insertion part to be inserted into a living body via an insertion aid and obtains data in the living body, and a sensor communication unit that serves as a communication unit that transmits, by wireless communication, a first sensor signal output from the sensor to an aid communication unit that serves as a communication unit provided in the insertion aid. The present technology can be applied to, for example, an endoscope system.

endoscope includes an illumination source for generating a coherent laser illumination beam; an optical sensor; a multicore fiber comprising: at least one core for transferring the illumination beam from the illumination source through said at least one core to a distal end of the fiber, for illumination of a surface to be inspected; and a plurality of cores for transferring light reflected off the surface to the optical sensor; a temporal modulation sequencer for separating a specular image of the illumination beam from an image of the surface; and a processor, for processing sensed data from the optical sensor to generate the image of the surface.

A method for providing light to an endoscope includes emitting light from a plurality of light emitting diodes, filtering the light with a plurality of dichroic filter elements, collimating and mixing light received from the dichroic filter elements into a combined light, sensing the combined light at a color sensor and determining a sensed color balance of the combined light, comparing the sensed color balance with a predetermined color balance, and varying at least one power signal to control a light intensity output by at least one of the plurality of light emitting diodes so that the sensed color balance corresponds to the predetermined color balance.

A hand-held vision sensor apparatus comprises a plurality of light sources, control activation elements and an image sensing array, encased within a housing such that the control activation elements are disposed at a user-accessible location on the housing. The housing further includes a pair of exit apertures for emitting illumination directed toward a medical specimen and an entrance aperture for capturing reflected light from the medical specimen. The light sources are disposed in alignment with the pair of exit apertures, and the image sensing array is aligned with the entrance aperture. The control activation elements are utilized to energize the light sources and control the functioning of the image sensing array. A computer port may be included and used to communicate command controls to the light sources, image sensing array and control activation elements in a manner that allows for a remotely-located technician to communicate with the hand-held vision sensor.

There is provided a medical dimming control apparatus including: a dimming control section configured to control a dimming in relation to an imaging of an observation target by an imaging device in accordance with a set dimming mode. The dimming mode at least includes a first dimming mode that controls the dimming at a first tracking speed and a second dimming mode that controls the dimming at a second tracking speed that is slower than the first tracking speed, and the dimming control section sets the first dimming mode on the basis of a change in an imaging-related behavior in the imaging device, and sets the second dimming mode in a case of determining that a predetermined condition is satisfied while executing the control in accordance with the first dimming mode.

An imaging system, such as a surgical microscope, laparoscope, or endoscope or integrated with these devices, includes an illuminator providing patterned white light and/or fluorescent stimulus light. The system receives and images light hyperspectrally, in embodiments using a hyperspectral imaging array, and/or using narrowband tunable filters for passing filtered received light to an imager. Embodiments may construct a 3-D surface model from stereo images, and will estimate optical properties of the target using images taken in patterned light or using other approximations obtained from white light exposures. Hyperspectral images taken under stimulus light are displayed as fluorescent images, and corrected for optical properties of tissue to provide quantitative maps of fluorophore concentration. Spectral information from hyperspectral images is processed to provide depth of fluorophore below the tissue surface. Quantitative images of fluorescence at depth are also prepared. The images are displayed to a surgeon for use in surgery.

A method for supplementing a component (20) of a medical instrument (10) by way of a plastic component comprises the steps of inserting (106) the component (20) of the medical instrument (10) into a casting mold (70) and closing (107) the casting mold (70), a first region (72) of a mold surface of the casting mold (70) being placed against the component (20) and a casting chamber (78) remaining between a second region (74) of the mold surface of the casting mold (70) and the component (20); a step of supplying (108) a liquid plastic to the casting chamber (76); and a step of coupling (111) electromagnetic radiation into the liquid plastic within the casting chamber (76) in order to trigger a solidification of the plastic and in order to form the plastic component.

An endoscope comprising a camera handle used to fix the camera lens and a wired connector; the camera handle comprises of an outer shell, an end cap and an inner shell; an sensing element is provided inside the inner shell; a lens group is provided between the sensing element and the end cap; the inner shell is fixedly connected with the outer shell through assembling components; the outer shell is fixedly connected with the inner shell through fixing components; a light hole corresponding to the position of the sensing element is cut in the middle of the end cap. The present invention has following advantages: The inner shell is inside the outer shell; both the inner shell and the outer shell are fixedly connected with the end cap; overall sealing, waterproof and dustproof performances of the camera handle are excellent; the removable waterproof cover is provided at the end of the sleeve; the elastic sealing ring is provided between the waterproof cover and the assembling tube; the connector is in a sealed space and protected from being damaged by penetrated disinfectant; with excellent waterproof performance and safe use, the wired connector is suitable for medical equipment.

A medical observation system, a control method, and a program are provided, which are capable of easily reducing the possibility that illumination light directly enters an eye by accident. A medical observation system 1 includes: an imaging unit 21 that captures an object and generates an image signal; a light output unit 22 that outputs illumination light in a capturing direction of the imaging unit 21; a determining unit 942 that determines the usage state of the imaging unit 21; and an illumination controller 944 that controls illumination light emitted by the light output unit 22 based on a determination result of the determining unit 942.

An imaging probe comprises a camera or endoscope with an external detector array, in which the probe is sized and shaped for surgical placement in an eye to image the eye from an interior of the eye during treatment. The imaging probe and a treatment probe can be coupled together with a fastener or contained within a housing. The imaging probe and the treatment probe can be sized and shaped to enter the eye through an incision in the cornea and image one or more of the ciliary body band or the scleral spur. The treatment probe may comprise a treatment optical fiber or a surgical placement device to deliver an implant. A processor coupled to the detector can be configured with instructions to identify a location of one or more of the ciliary body band, the scleral spur, Schwalbe's line, or Schlemm's canal from the image.