Abstract: A portable device for data communication using a body as a conductor to transmit data to a receiver, the portable device includes a data receiving unit to receive data, a controller unit to control processing of data to be transmitted, a current limiting circuit to limit a current of a signal corresponding to the data to be transmitted to a predetermined value, and transmitting electrodes connected to the current limiting circuit and to contact the body to transmit the signal having the current of predetermined value to the receiver.
Type:
Grant
Filed:
August 1, 2011
Date of Patent:
October 15, 2013
Assignee:
Korea Institute of Science and Technology
Inventors:
Tae-Song Kim, Jong-Oh Park, Byung-Kyu Kim, Jin-Seok Kim, Han Cheung, Won-Woo Cho, Nan-Young Yoon, Young-Rok Kim
Abstract: Various embodiments for providing solid state illumination in conjunction with wavelength multiplexing imaging schemes for mono and stereo endoscopy or borescopy are provided. In one embodiment, the current disclosure provides a device configured for insertion into a body cavity. The device can include a tubular portion having a proximal end and a distal end. The distal end of the tubular portion can be configured to be at least partially inserted into the body cavity. The device can also include a solid state electro-optic element located on the tubular portion. Furthermore, the device can include a power source electrically coupled to the solid state electro-optic element.
Abstract: An endoscope image is obtained by imaging a subject with a scope. Then, an edge portion of the endoscope image is extracted and a complexity degree of the edge portion is detected. Thereafter, a determination is made as to whether the endoscope image is an image obtained through near view imaging or distant view imaging according to the complexity degree and an imaging condition is changed according to the determined near view imaging or distant view imaging.
Abstract: A system and method for wirelessly transmitting a video image signal from an endoscopic camera to a receiver or control unit for storage and/or display on a video monitor. Use of a frame-specific, variable compression algorithm capable of progressively encoding a data stream provides for a better performing and higher quality wireless endoscopic camera system capable of generating images at varying resolutions. Use of a short-range, high-performance wireless technology, such as Ultrawideband (UWB), improves the performance capabilities of the system, while minimizing power consumption and extending battery life. Implementations of error correcting codes, as well as the use of multiple transmitting and receiving antennas, further improve the fidelity of the wireless communication.
Abstract: The diagnosability of diseased parts is improved by precisely correcting fluorescence images without being affected by specular reflection and without being affected by thick blood vessels.
Abstract: A medical instrument is provided with: an illumination section radiating excitation light for exciting a fluorescent substance given to a subject, to the subject; an image pickup section photoelectrically converting reflected light from the subject to which the excitation light is radiated, to pick up an image of the subject; a reading section holding pixel signals obtained by the photoelectrical conversion and capable of reading the pixel signals non-destructively while changing amplification factors of the held pixel signals by a predetermined unit of pixels; and an image processing section determining an arithmetic mean of the pixel signals read with different amplification factors by the reading section to generate an image. The medical instrument improves visibility of each fluorescent area without occurrence of position displacement even in the case where multiple fluorescent areas with a relatively large brightness/darkness difference exist within one screen.
Abstract: An endoscope comprises an image sensor incorporated in a distal portion of an insert section to be inserted in a body cavity, a heat dissipation substrate, a multi-core cable, and a connection member. The heat dissipation substrate is attached to the back of a circuit board that supports the image sensor. The multi-core cable has signal lines and a second shield member. The signal lines, each covered with a first shield member, transmit signals to/from the image sensor. The second shield member covers and holds the signal lines together. The second shield member has an electrically conductive layer. The connection member transmits heat, generated in the image sensor, from the heat dissipation substrate to the second shield member.
Abstract: The embodiments disclosed herein is related to a system for optical coherence tomographic imaging of turbid (i.e., scattering) materials utilizing multiple channels of information. The multiple channels of information may be comprised and encompass spatial, angle, spectral and polarization domains. More specifically, the embodiments disclosed herein is related to methods and apparatus for utilizing optical sources, systems or receivers capable of providing (source), processing (system) or recording (receiver) a multiplicity of channels of spectral information for optical coherence tomographic imaging of turbid materials. In these methods and apparatus the multiplicity of channels of spectral information that can be provided by the source, processed by the system, or recorded by the receiver are used to convey simultaneously spatial, spectral or polarimetric information relating to the turbid material being imaged tomographically.
Type:
Grant
Filed:
July 7, 2010
Date of Patent:
September 24, 2013
Assignee:
Board of Regents, The University of Texas System
Inventors:
Marc D. Feldman, Thomas E. Milner, Jung Hwan Oh, Eunha Kim, Karthik Kumar, Chris Condit, Robert Grant, Nate Kemp, Jeehyun Kim, Shaochen Chen, Li-Hsin Han
Abstract: An endoscope device in which endoscope images and patient information can be recorded in a removable storage medium and in which the endoscope images and patient information recorded in the storage medium can be reproduced. The endoscope device has a selection means for reproducing the endoscope images in a list form and selecting at least one endoscope image from the reproduced list; a display means for inputting additional information other than the patient information, adding the additional information to the endoscope image selected by the selection means, and displaying the result; and a recording/reproduction means for recording the selected endoscope image and the additional information in the storage medium or reproducing the image and the information.
Abstract: A capsule endoscope is disclosed that includes first and second objective optical systems for forming images of objects viewed in the capsule insertion direction and in the opposite direction on separate areas of one plane where an image pickup surface of an image pickup device is located. The capsule endoscope also includes illuminators for illuminating the objects, and a deflector or deflectors, such as reflecting prisms, for folding light from the objective optical systems to the image pickup surface so that the image pickup surface is parallel to the capsule insertion direction. The objective optical systems are retrofocus optical systems. The illuminators may have emission surfaces centered on the centers of spheres defined by dome-shaped transparent covers aligned along a central axis of the capsule endoscope. The objective optical systems, the deflector or deflectors, and the image pickup device are arranged completely off the central axis of the capsule endoscope.
Abstract: A body-insertable apparatus system has a body insertable apparatus that is inserted into a subject and a control apparatus. The body-insertable apparatus includes a magnetic responding unit that is provided within a casing forming the body-insertable apparatus and has a magnetization direction; and a needle that is protruded and retracted with respect to a surface of the casing. The control apparatus includes a magnetic field generator that generates a magnetic field; and a control unit that causes the magnetic field generator to generate a magnetic field for changing an orientation of the magnetic responding unit based on the magnetization direction of the magnetic responding unit in the body-insertable apparatus, a position of the needle in the body-insertable apparatus, and a distal end direction of the needle, thereby changing an orientation of the entire body-insertable apparatus to enable the protruded needle to puncture a puncture target layer.
Abstract: A receiver of capsule endoscopic system downloads diagnostic information of a patient obtained by a past diagnosis from a data storage of work station. A data analyzer of the receiver compares the diagnostic information and present information obtained by use of a capsule endoscope during endoscopy. A CPU produces a control command in which a frame rate of image shooting by use of the capsule endoscope is set based on an analysis result of the data analyzer. The produced control command is wirelessly transmitted via a radio wave from the receiver. The capsule endoscope wirelessly receives the control command from the receiver via the radio wave, and performs image shooting with the frame rate set by the control command.
Abstract: An endoscope system is able to stably obtain an image free from speckle interference. A captured image including a first basic color component B on which a speckle noise of a laser beam is superimposed and a second basic color component G not including the speckle noise. A speckle noise component Bs is extracted based on difference information between the first basic color component B and the second basic color component G Based on the extracted speckle noise component Bs, the speckle noise component Bs is removed from the first basic color component B, so as to obtain a good observation image free from the speckle noise.
Abstract: A capsule-type endoscope includes a capsule, an objective optical system, an image pickup element, and at least one illumination light source having a light-emitting surface, and a transparent cover. In several embodiments of the capsule-type endoscope according to the present invention, an inner surface of the transparent cover is spherical within a field of view of the objective optical system so as to have a center of curvature, the center of curvature is offset from the optical axis of the objective optical system, and a specified condition is satisfied so as to avoid flare in the objective optical system caused when light from the one (or more) illumination light source(s) enters the entrance pupil of the objective optical system. In another embodiment, the inner surface of the transparent cover has the shape of an ellipsoid. Observation methods using the capsule-type endoscope are also disclosed.
Abstract: In a method for controlling a multi-color output of an image of a medical object for assisting medical personnel, the medical object is illuminated with light with an illumination spectrum. By means of an image sensor, image data are acquired for a group of one or more color channels. Image information concerning an additional color channel, which is not among the group of one or more color channels, is generated depending on the acquired image data. An image output device for multi-color output of the image is controlled depending on the acquired image data and the acquired image information.
Abstract: Devices, systems and methods for detecting in vivo pathology are provided. An in vivo sensing device comprises a reacting layer with at least one type of binding agent attached thereon, a sensor configured for sensing an optical change occurring on the reacting substrate, and at least one illumination source. In-vivo fluids are in constant contact with the reacting substrate so that in vivo marker indicating pathology may bind to the binding agent attached onto the reacting layer and may be viewed by the sensor.
Type:
Grant
Filed:
June 16, 2009
Date of Patent:
August 20, 2013
Assignee:
Given Imaging Ltd.
Inventors:
Elisha Rabinovitz, Osnat Sella-Tavor, Amit Pascal, Noam Emanuel
Abstract: The inventive subject matter is generally directed to an illumination system for staged illumination in an endoscopic procedure. The inventive system generally includes an illumination apparatus supporting a light source that is configured for removable assembly with an endoscope. The assembly is configured for insertion into a natural or artificial passageway in a body. The illumination apparatus has one or more light sources providing a first, relatively high level of illumination suitable for imaging a first, relatively large target area, either alone or in combination with a light source for the endoscope, and after removal of the illumination apparatus from the assembly, the endoscope provides a second relatively lower level of illumination suitable for imaging a relatively small target area.
Type:
Grant
Filed:
September 8, 2009
Date of Patent:
August 20, 2013
Assignee:
Gyrus ACMI, Inc.
Inventors:
Elliott Rothberg, Doron Adler, Mark Schnoerr, Shai Finkman
Abstract: An in vivo imaging device having a flexible circuit board, for example, a one-sheet flexible circuit board. The flexible circuit board may enable folding components attached to the flexible circuit board according to a predefined angle.
Abstract: An endoscope includes an elongated insertion portion having a distal end portion provided with an illumination window and an observation window. A single solid-state image sensing device whose image pickup face is provided at an image forming position of an objective optical system mounted on the observation window. In the vicinity of the image pickup face of the solid-state image sensing device, a filter portion that has a first filter having a wideband wavelength transmission characteristic in a visible band and a second filter having a narrowband wavelength transmission characteristic in the visible band two-dimensionally arranged is disposed.
Abstract: An endoscopic video system and method using a camera with a single color image sensor, for example a CCD color image sensor, for fluorescence and color imaging and for simultaneously displaying the images acquired in these imaging modes at video rates in real time is disclosed. The tissue under investigation is illuminated continuously with fluorescence excitation light and is further illuminated periodically using visible light outside of the fluorescence excitation wavelength range. The illumination sources may be conventional lamps using filters and shutters, or may include light-emitting diodes mounted at the distal tip of the endoscope.
Type:
Grant
Filed:
December 26, 2007
Date of Patent:
July 30, 2013
Assignee:
Novadaq Technologies Inc.
Inventors:
Paul Westwick, David Potkins, John Fengler
Abstract: The invention is directed to a method and an arrangement for high-resolution microscopic imaging in laser endoscopy based on laser-induced object reaction radiation and for performing microscopic cuts in biological tissue. In using multiphoton processes for endoscopic applications in biological materials with an accuracy of under one millimeter, radiation of a pulsed femtosecond laser is focused into an object by means of a transmission focusing optics unit comprising a transmission system and miniature focusing optics having a high numerical aperture greater than 0.55 to trigger a local object reaction radiation in the micrometer to nanometer range, and the distal end of the transmission focusing optics unit is moved in at least two dimensions for highly spatially resolved scanning of the object and for transmitting object reaction radiation which is scanned in a locally progressive manner to an image-generating system with a photon detector.
Abstract: Apparatus including an optical system (20) for use in an endoscope is provided. The optical system has distal and proximal ends, and includes an image sensor (32), positioned at the proximal end of the optical system. The optical system also includes an optical member (34) having distal (36) and proximal ends, and shaped so as to define: (a) a lateral surface, at least a distal portion of which is curved, configured to provide omnidirectional lateral viewing, (b) a distal indentation (44) in the distal end of the optical member, and (c) a proximal indentation (48) in the proximal end of the optical member. The optical system also includes a convex mirror (40), coupled to the distal end of the optical member, and shaped so as define an opening through which the distal indentation passes. A distal lens (52) is positioned distal to the mirror. The optical member, the mirror, and the distal lens have respective rotational shapes about a common rotation axis.
Type:
Grant
Filed:
May 11, 2005
Date of Patent:
July 30, 2013
Assignee:
G.I. View Ltd.
Inventors:
Gideon Dotan, Oz Cabiri, Boaz Shpigelman
Abstract: A biological measurement apparatus includes: an endoscope including a treatment instrument insertion channel provided inside an insertion portion; a pump that delivers water into the treatment instrument insertion channel; an optical system, etc., that guide light from a light source that emits light in a predetermined wavelength band into the water delivered into the treatment instrument insertion channel; and a spectroscope that detects return light resulting from the light passing through the water, falling on and being reflected by an object and returning while passing through the water when the water is delivered from the pump.
Abstract: To stably and properly monitor an inside of a body by using an easily operable placement technique, a capsule endoscope 101 to be swallowed from an oral cavity 200 to acquire in-vivo information of a subject 201 and to wirelessly output for a transmission of the in-vivo information to an outside of a body, a string member 103 that is connected to the capsule endoscope 101 for positioning the capsule endoscope 101 at a gastric cardia 202, and a fixing portion 104 that is a portion of the string member 103, is provided on a position with which a length from the capsule endoscope 101 corresponds to a length from the gastric cardia 202 to the inside of an esophageal region 203 for fixing the string member 103 that has located the capsule endoscope 101 at the gastric cardia 202 to the inside of the esophageal region 203 by an endoscopic fixture are included.
Type:
Grant
Filed:
July 10, 2006
Date of Patent:
July 23, 2013
Assignees:
Olympus Corporation, Olympus Medical Systems Corp.
Abstract: The invention is an endoscopic method for viewing a target portion of a patient's anatomy with access through the oral or nasal cavity. The method includes adjusting a variable direction of view endoscope to a direction of view of between about 0 degrees and 20 degrees relative to a longitudinal axis of the endoscope and a shaft orientation pointing toward the target portion of the patient's anatomy. The endoscope is then introduced straight into the oral or nasal cavity of a patient until the endoscope is positioned in the back of the cavity. The direction of view is adjusted to view the target portion of the patient's anatomy.
Type:
Application
Filed:
July 18, 2012
Publication date:
July 18, 2013
Inventors:
Eric A. Goldfarb, Thomas R. Jenkins, John Y. Chang, Joshua Makower
Abstract: The present invention provides a capsule type medical apparatus that can receive, in a subject, an external signal transmitted from an outside of the subject and transmitted via a conductor existing in the subject, including: a cover member that is formed of a dielectric and covers components of the capsule type medical apparatus; a plurality of electrodes that are formed of conductors, are provided in tight contact with an inner wall side of the cover member, and receive the external signal; an inductor circuit that is connected in series to each of the plurality of electrodes, and has an inductance value set to configure a resonant circuit having a frequency substantially equal to a carrier frequency of the external signal as a resonant frequency; and a signal receiving circuit to which the external signal received by the plurality of electrodes and a potential difference of the external signal are inputted.
Type:
Grant
Filed:
March 31, 2010
Date of Patent:
July 9, 2013
Assignee:
Olympus Corporation
Inventors:
Tetsuo Minai, Kazuaki Tamura, Jin Ohara
Abstract: A capsule medical apparatus capable of injecting a medical agent into a living tissue includes a casing, a pressing member that presses the surface of the living tissue, a driving unit that causes the pressing member to protrude from the casing in a predetermined direction and to press the surface of the living tissue while rotating the pressing member around a rotation axis parallel to the protruding direction, and a needle-like puncturing member that is arranged on the pressing member and punctures the living tissue in an oblique direction with respect to the surface of the living tissue to thereby inject the medical agent into the living tissue along with the rotation of the pressing member driven by the driving unit.
Abstract: An adapter-type endoscope includes a distal end adapter and an insertion portion. The distal end adapter includes a light-emitting device substrate and an adapter-side electrical connection portion. The insertion portion includes a distal end portion to which the distal end adapter is detachably mounted, and has an insertion portion-side electrical connection portion connected to an adapter-side electrical connection portion, and a dual-purpose wire for power supply and heat release serving as both a heat releasing wire and a power source wire. The adapter-side electrical connection portion includes an electrical connection portion main body serving as both an electrical connection portion and a heat conducting portion and whose distal end surface closely contacts the light-emitting device substrate.
Abstract: An endoscope apparatus includes: an endoscope that generates an image of an object; a display portion that displays the image and a cursor that designates a position on an image based on the image; a characteristic quantity calculating portion that calculates, based on the image, a characteristic quantity of the image on the basis of the position designated by the cursor; and a control portion that controls movement of the cursor in accordance with the characteristic quantity.
Abstract: In one embodiment, the invention relates to a processor based method for generating positional and other information relating to a stent in the lumen of a vessel using a computer. The method includes the steps of generating an optical coherence image data set in response to an OCT scan of a sample containing at least one stent; and identifying at least one one-dimensional local cue in the image data set relating to the position of the stent.
Abstract: A medical procedure and a system are provided so that two visions are obtainable through natural orifices by means of two observational apparatuses, or one the two visions is selectable. The medical procedure through a natural orifice comprises: forming an orifice in a hollow organ by using a device inserted into the hollow organ from a natural orifice of a patient; introducing a first observation device from said orifice formed in said hollow organ into an abdominal cavity; introducing a second observation device from said orifice formed in said hollow organ into the abdominal cavity; arranging said second observation device in a position different from that of said first observation device; simultaneously or selectively displaying an image obtained from said first observation device and an image obtained from said second observation device; and performing a desired procedure in the abdominal cavity while confirming the images.
Type:
Grant
Filed:
January 5, 2007
Date of Patent:
July 2, 2013
Assignee:
Olympus Medical Systems Corp.
Inventors:
David E Barlow, Takayasu Mikkaichi, Kensei Nakahashi
Abstract: An endoscope system of the invention includes: a first endoscope capable of picking up an image of a subject; a first illuminating section capable of emitting first illuminating light; a second endoscope capable of picking up an image of the subject illuminated by the first light from a direction different from the first endoscope; a second illuminating section capable of emitting second illuminating light; a video signal processing section for generating a video signal based on a signal picked-up by the second endoscope; a display section for displaying an image of the subject obtained by the video signal processing section; an emphasis instructing section for instructing an emphasis on an image obtained based on the first light; and an emphasis control section for controlling to emphasize the subject image obtained based on the first light according to an operation of the emphasis instructing section.
Abstract: The present invention involves a new type of capsule pattern endoscope intended to greatly reduce the effective internal volume of the capsule pattern endoscope through reasonable structure arrangement. The technical proposal to implement the above invention is: a kind of capsule pattern endoscope comprises an intelligent capsule and an image-receiving device. The intelligent capsule includes a shell with an electronic circuit printed thereon, and an image information pick-up device including an image sensor and a lens optical system, an image signal processing and transmitting device, a light source, and a power supply, which are arranged inside the shell.
Abstract: A capsule medical apparatus includes a capsule exterior member and a sensor that can detect the change of an atmospheric physical quantity caused outside the exterior member in the non-contact state, and performs, based on the temporary change in atmospheric physical quantity detected by the sensor, at least one of first control for switching operation from the ON-state of energy supply to the electric circuit from the battery to the OFF-state of the energy supply and of second control for switching operation from the OFF-state of the power supply to the ON-state of the power supply, and holds the state of energy supply switched by the control until another change of atmospheric physical quantity is detected.
Abstract: An observation optical system has a negative lens unit placed at the most object-side position; an annular prism placed on the image side of the negative lens, having a reflecting surface on the negative lens side; and an imaging lens unit arranged on the image side of the negative lens and the annular prism.
Abstract: A capsule endoscope system includes a contact detector that detects contact with an inner wall of a lumen in the subject; a magnet which is equipped in the capsule endoscope; a magnetic field generating device that is provided at a position, which is fixed with respect to the magnet, and generates a guidance magnetic field to apply to the magnet from the outside of the subject; and a magnetic field generation controller that performs control for guidance in a direction in which the capsule endoscope moves, which is the direction of the axis of the lumen, and performs guidance control for separating the capsule endoscope from the inner wall of the lumen based on a result of detection by the contact detector.
Abstract: An optical head for an endoscope is fitted with an imaging system comprising a solid state imaging sensor and with an illuminating system comprising illuminating means, e.g. LED's. At least one illuminating means is defined by a parameter, which value is different from the value of the same parameter of the remaining illuminating means. Among the parameters are luminous intensity, luminous intensity distribution angle, and direction of the longitudinal axis of the illuminating means.
Type:
Grant
Filed:
September 1, 2005
Date of Patent:
May 28, 2013
Assignee:
Stryker GI Services C.V.
Inventors:
Amram Aizenfeld, Victor Levin, Omer Shezifi, Dan Oz, Yuri Gershov, Leonid Krivopisk, Yakov Bar-Or
Abstract: An in-vivo sensing system incorporating a sensing device movably disposed within a housing such that the orientation of the sensing device may be moved or changed in response to substantially small forces. The in-vivo sensing device may be ingested and may naturally traverse a lumen such as the GI tract or may be anchored at a surgical site. In a preferred embodiment, the in vivo sensing system is an imaging system (100) incorporating a sensing device such as an imaging device (112) suspended in a liquid (114) encapsulated in an covering or housing (110).
Abstract: A body-insertable apparatus that is used in a state of being introduced inside the body of a subject and that executes a predetermined function inside the body of the subject, comprises a driving controller that controls the driving condition of the predetermined function.
Abstract: A capsule guidance system includes a capsule including an imaging unit that captures an in-vivo image, a transmitting unit that transmits the image, and a magnetic field response unit; a magnetic field generation unit that generates a magnetic field; a receiving unit that receives the image; a display unit that displays the image; an operation input unit that inputs operation information for magnetically guiding the capsule; a control unit that controls the magnetic field generation unit to guide the capsule in accordance with the operation information; and a selection unit that selects at least two of a liquid surface, a submerged area, and a liquid bottom that is a lower boundary surface between the liquid and the outside as guidance areas into which the capsule medical device is guided. The control unit switches the magnetic field to be generated in accordance with the selected guidance area.
Abstract: An insertion unit has a channel through which a treatment tool can be inserted. A distal end of the insertion unit has a single-focus objective optical system or a focal-point-variable objective optical system to focus the optical image on a light receiving surface of an image capturing element. At a short object distance from the distal end, an image signal with a sufficient resolution is obtained from the image capturing element. In this state, a treatment tool projected by a reduced amount from a distal end opening of the channel is captured on a light receiving surface of the image capturing element. A required resolution is also provided for a far side.
Abstract: The invention relates to an in vivo sensing device having a specific gravity of about 1 or a volume to weight ratio that enables it essentially to float. In one embodiment the in vivo sensing device consists of an image sensor system and a buoyant body. The buoyant body, which is attached to the sensor system or which can optionally house one or more elements of the sensor system, keeps the sensor system essentially floating in a body lumen liquid.
Type:
Grant
Filed:
December 12, 2006
Date of Patent:
May 21, 2013
Assignee:
Given Imaging Ltd.
Inventors:
Shlomo Lewkowicz, Daniel Gat, Arkady Glukhovsky, Semion Khait, Gavriel Joseph Iddan, Harold Jacob, Christopher Paul Swain
Abstract: In an endoscope, a solid-state image pickup device images an object, to output an image signal. In a processing apparatus, an illuminator applies normal light and specific light having spectral distribution different from the normal light to the object. A display control unit operates according to the image signal, to cause display of a normal image of the object produced by applying the normal light, and a specific image of the object produced by applying the specific light. A motion detector detects information of relative motion of the object. A controller controls the illuminator, causes alternate emission of the normal and specific light periodically at a storage period of the image pickup device if the motion information is equal to or smaller than a threshold level, and causes emission of the normal light without emitting the specific light if the motion information is greater than the threshold level.
Abstract: A capsule endoscope includes a capsule-shaped casing and an imaging unit for taking an image of an inside of an organ in a state where the capsule endoscope is floating in liquid introduced inside the organ of a subject. Specific gravity of the capsule endoscope to the introduced liquid is ?; a plane divides the capsule endoscope such that a volume ratio is to be ?:1??. A straight line that connects a center of volume of a portion whose volume ratio is ? and a center of gravity of the capsule endoscope is substantially perpendicular to the plane. The center of gravity is present at a position farther distant from the plane than the center of volume. A surface of a boundary of a field of view that forms an angle of view of the imaging unit and the plane do not intersect outside the capsule endoscope.
Abstract: A method for controlling movement of an imaging device in vivo, the method comprising the steps of providing an imaging device having a longitudinal axis and a magnetic component, said device to be inserted into a patient's body; providing a rotating magnetic field outside the patient's body; and advancing the rotating magnetic filed along the patient's body in a desired direction.
Type:
Grant
Filed:
May 15, 2008
Date of Patent:
April 23, 2013
Assignee:
Given Imaging Ltd.
Inventors:
Paul Christopher Swain, Frank Volke, Elisha Rabinovitz, Jeremy Pinchas Gerber, Boaz Aizenshtark, Bertram Manz, Martin Benecke
Abstract: A transmitting/receiving system includes a transmitting apparatus that generate modulated signals each containing a broadband signal component and a narrowband signal component, and transmits the modulated signals to the outside; and a receiving device that receives the modulated signals via at least three receiving antennas. The receiving device includes a signal processing system that processes the broadband signal component contained in the modulated signal; and a received-strength detecting system that processes the narrowband signal component contained in the modulated signal.
Abstract: An endoscope system includes: an endoscope equipped with an insertion portion, and an image pickup unit disposed at a distal end portion of the insertion portion; an illumination unit detachably connected to the endoscope; an imaging mode input unit used to set an imaging mode of the endoscope to one of a normal-light mode and a special-light mode; a processing condition selection unit which selects a processing condition for a color correction process of an endoscopic image based on the imaging mode; and a processor detachably connected to the endoscope and equipped with an image processing unit which performs the color correction process, under the processing condition selected by the processing condition selection unit, with respect to each of hue regions partitioned by at least eight reference color axes including six reference color axes which divide a color space into R (red), M (magenta), B (blue), C (cyan), G (green), and Y (yellow) hue regions and at least two reference color axes established additio
Abstract: An apparatus for introduction into a test body includes a functional portion for obtaining information on an inside of a test body; a power source for supplying power for driving the functional portion; and an enclosed container for accommodating the functional portion and the power source. A cross-sectional shape orthogonal to a longitudinal direction of the enclosed container is an elliptical shape to make an outer shape small to alleviate a burden on a test subject during introduction into a body by swallowing or the like for test.
Abstract: A capsule endoscope system includes a capsule endoscope which is introduced into a subject; a change unit which changes a position or posture of the capsule endoscope in the subject with respect to the subject; a storage unit which stores in advance a change procedure of the capsule endoscope as a control parameter of the change unit; and a controller which controls the change unit in accordance with the parameter stored in the storage unit.
Abstract: An encapsulated endoscope system in accordance with the present invention comprises: an encapsulated endoscope that rotates to develop a thrust; a controller that moves the encapsulated endoscope in an intended direction of advancement; an imaging unit incorporated in the encapsulated endoscope; and an image processing unit that receives image data sent from the imaging unit, and produces an image, which results from rotation of the received image data, according to the rotational phase of the encapsulated endoscope.