An endoscopic device comprising a housing, first imaging means in the housing for detecting light emanating from objects from a predetermined first surrounding region annularly surrounding the endoscopic device and for producing a first image of the first surrounding region, a first image sensor for detecting the first image and for producing a first image signal, a first image sensor for sensing the first image and for generating a first image signal representing the first image, a second imaging means in the housing for sensing light emanating from objects in a predetermined second surrounding region and for generating a second image of the second surrounding region, and a second image sensor for sensing the second image and for generating a second image signal representing the second image. The first imaging device comprises a catadioptric imaging system with a first reflective surface, a second reflective surface, and a light refracting interface.

A capsule device configured to navigate through a patient's GI track is disclosed. System and method to turn on the capsule device based on acceleration is described. First the capsule is monitored at a slow sampling mode. Then the capsule is monitored at a fast sampling mode. A user can input hand motion to change the acceleration to turn on the capsule device.

An aspect of an embodiment of the invention, relates to an imaging capsule for scanning inside a living body with a fail-safe radiation mechanism that prevents the emission of radiation from the imaging capsule until the imaging capsule is instructed to emit radiation and power is available to activate a motor to unblock the emission of radiation. Optionally, when power is not available the imaging capsule automatically, blocks the emission of radiation.

A helix antenna structure includes loop antennas and a multilayered printed circuit board including printed circuit board layers. Each printed circuit board layer includes a peripheral loop antenna and each adjacent two loop antennas are electrically connected by a connection bridge functioning as a monopole antenna. A selected printed circuit board layer physically and electrically accommodates a transmitter inside ‘its’ peripheral loop antenna, and it further includes a first antenna feeding line which is connected to the loop antenna that is disposed on the selected printed circuit board layer and electrically connectable to a first output terminal of the transmitter. A second antenna feeding line is disposed on another printed circuit board layer and electrically connected to its loop antenna and connectable to another output terminal of the transmitter. The two antenna feeding lines lie in a plane perpendicular to an axis of the printed circuit board after its folding.

A method is disclosed comprising providing a biological sample on a swab, directing a spray of charged droplets onto a surface of the swab in order to generate a plurality of analyte ions, and analysing the analyte ions.

In at least one embodiment of a device configured for insertion into a gastrointestinal tract of the present disclosure, the device comprises a core comprising a core material which is solid, semi-solid or compressible, one or more sensors embedded in an interior of the device and/or on a surface of the device, at least one of the one or more sensors configured to obtain a pressure measurement within the gastrointestinal tract and during defecation of the device, and a plurality of electrodes within or upon the device and configured to obtain impedance planimetric measurements within the gastrointestinal tract and during defecation of the device, the impedance planimetric measurements useful to determine cross-sectional areas.

An image processing apparatus includes an image input that receives input of image data of a captured human being, a region detector that detects a specific color region of the image data, a filter that smooths a pixel value in the specific color region detected by the region detector by using a frame of the image data input into the image input and each of previous and subsequent frames of the image data of the inputting into the image input, a coder that codes an output image of the filter, and an output that outputs the output image of the filter coded by the coder.

A signal processing device includes: a connection detector that detects whether an endoscope including one or more operation members is connected; an input unit to which an operation state signal is input from an external input device including one or more buttons that correspond to the one or more operation members included in the endoscope when the endoscope is not connected; and an operation execution unit that executes an operation according to the operation state signal that is input to the input unit.

A body-insertable apparatus includes an image sensor including a first pixel configured to receive light of a first wavelength band and to generate a first signal, a second pixel configured to receive light of a second wavelength band different from the first wavelength band and to generate a second signal, and a third pixel configured to receive a third wavelength band different from the first and second wavelength bands and to generate a third signal; and a processor comprising hardware, the processor being configured to allocate part of at least one of the first signal and the second signal to the third signal, when first light is received on the first and second pixels, the first light including at least one of the light of the first wavelength band and the light of the second wavelength band and excluding the light of the third wavelength band.

An endoscope system 10 includes: an image acquiring unit 54 that acquires an endoscope image obtained by imaging an observation target; a baseline information calculating unit 86 that calculates baseline information by using the endoscope image or a display endoscope image 101 generated by using the endoscope image, the baseline information being information about light scattering characteristics or light absorbing characteristics of the observation target and information that is at least not dependent on particular biological information; an imaging scene determination unit 87 that determines the imaging scene by using the baseline information; and a condition setting unit 88 that sets a condition for imaging or image processing, by using a determination result of the imaging scene determination unit.