WO2010114920A1 - Endoscopes à réglage automatique - Google Patents

Endoscopes à réglage automatique Download PDF

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Publication number
WO2010114920A1
WO2010114920A1 PCT/US2010/029466 US2010029466W WO2010114920A1 WO 2010114920 A1 WO2010114920 A1 WO 2010114920A1 US 2010029466 W US2010029466 W US 2010029466W WO 2010114920 A1 WO2010114920 A1 WO 2010114920A1
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Prior art keywords
distal end
shaft
sensors
infra
actuators
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PCT/US2010/029466
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English (en)
Inventor
Jung Hun Choi
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Ohio University
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Publication of WO2010114920A1 publication Critical patent/WO2010114920A1/fr

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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • A61B1/31Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor for the rectum, e.g. proctoscopes, sigmoidoscopes, colonoscopes
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • A61B1/00147Holding or positioning arrangements
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • A61B1/005Flexible endoscopes
    • A61B1/0051Flexible endoscopes with controlled bending of insertion part
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • A61B1/005Flexible endoscopes
    • A61B1/0058Flexible endoscopes using shape-memory elements

Definitions

  • the invention relates to endoscopes and endoscopy systems and methods.
  • Endoscopy is a medical procedure that permits a clinician to access remote organs and tissues in a minimally invasive manner for diagnostic and surgical purposes. Endoscopy is performed with an endoscope, a medical device that can pass through anatomical structures in the body of an animal, thereby providing a clinician access to the interior surfaces of the structures for visual inspection, imaging, biopsy, manipulation, and other diagnostic and surgical procedures.
  • endoscopes have been developed and adapted for use in the context of accessing and visualizing particular anatomical structures, such as the gastrointestinal tract (eg., colonoscopes and sigmoidoscopes), the respiratory tract (eg., rhinoscopes and bronchoscopes), the abdominal or pelvic cavity (eg., laparascopes), the joint (eg., arthroscopes), and the reproductive system (eg., hysteroscopes and falloscopes).
  • the gastrointestinal tract eg., colonoscopes and sigmoidoscopes
  • the respiratory tract eg., rhinoscopes and bronchoscopes
  • the abdominal or pelvic cavity eg., laparascopes
  • the joint eg., arthroscopes
  • reproductive system eg., hysteroscopes and falloscopes.
  • endoscopes typically comprise a rigid or flexible body, an illumination means (eg., light or light delivery system), and an imaging means (eg. lens system or camera), all of which are in communication with equipment that controls the functions of the device and allows for image visualization and capture.
  • Endoscopes can generally be categorized as dependent or independent, with the dependent-type typically having a tubular body and long cables for the purpose of operations, and biopsy or other medical tools at the distal end; and the independent-type typically having a cylindrical body and no attachments for ease of navigation.
  • Independent-type endoscopes are typically characterized as being either passive or active, wherein the passive-type do not have actuators and are dependent upon peristalsis for mobility, and wherein the active-type have externally controlled actuators for mobility.
  • a passive independent-type endoscope is typically used in a mouth-to-anus method in which the capsule is swallowed and natural bowel movements are relied upon to move the endoscope through the digestive tract.
  • An active independent-type endoscope typically utilizes shape memory alloys (SMAs) or magnets for controlling the movement of a capsule through the digestive tract.
  • SMAs shape memory alloys
  • dependent-type endoscopes are typically characterized as having actuators attached at or near the distal end of the scope for locomotion, so that a clinician does not have to rely solely on pushing or pulling the shaft of the endoscope for advancement or retraction. Instead, the clinician controls actuators, such as SMAs, pneumatic/hydraulic actuators, or motors, to navigate the endoscope.
  • actuators such as SMAs, pneumatic/hydraulic actuators, or motors
  • sigmoidoscopes Many types are known in the art. Among the most commonly used are sigmoidoscopes and colonoscopes, which are dependent-type endoscopes. Sigmoidoscopes may be flexible or rigid and enable a physician to examine the rectum and sigmoid colon in a sigmoidoscopy procedure. Sigmoidoscopes are useful in diagnosis of colon disorders, such as inflammatory bowel disease, bowel obstruction, polyps, and cancer in the descending colon and rectum. Sigmoidoscopy can also determine the cause of blood, mucus, or pus in the stool and confirm findings of another test by taking a biopsy.
  • colon disorders such as inflammatory bowel disease, bowel obstruction, polyps, and cancer in the descending colon and rectum.
  • Sigmoidoscopy can also determine the cause of blood, mucus, or pus in the stool and confirm findings of another test by taking a biopsy.
  • colonoscopes Similar to sigmoidoscopes are colonoscopes, which are flexible endoscopes used in a colonoscopy procedure in which the entire length of the colon can be examined for tumors or polyps, or to identify the source of gastrointestinal bleeding, although there are other diagnostic and therapeutic uses as well.
  • colonoscope is meant to refer to colonoscopes and sigmoidoscopes
  • colononoscopy is meant to refer to colonoscopy and sigmoidoscopy.
  • Colonoscopes and colonoscopy are discussed more particularly herein to illustrate known endoscopes, needs in the art, and embodiments of the present invention. However, one of skill in the art will understand that the invention is applicable to endoscopes and endoscopy procedures having similar requirements for positioning and steering through an anatomical structure, and that nothing herein shall be construed as limiting the invention to colonoscopes and colonoscopy.
  • a typical colonoscope has an elongated, flexible body, and is controlled at the proximal end with a handle mechanism for controlling the scope's movement and its various functions.
  • the typical scope also includes a mechanism, often associated with the handle, for steering the distal end using wires running through the interior of the elongated, flexible body.
  • the clinician inserts the distal end of the scope through the patient's rectum and navigates the device through the length of the colon under examination, starting with the sigmoid colon, and passing as needed through the descending colon, the transverse colon and the ascending colon. Once the ascending colon has been navigated, inspection of the cecum typically completes a full colonoscopy procedure.
  • Another potential complication is that a clinician can have difficulty finding the intestine lumen, especially while advancing the colonoscope. In part, this can be due to the complicated shapes of the colon, closed intestine lumen, or simply losing sense of direction in the colon. Often clinicians lose their sense of direction due to the severe maneuvering of the distal end involed in the search for polyps or other possible diseases. This loss of direction can increase the time of the operation and cause the need for more medicine for anesthesia, which leads to increased costs and risk associated with the procedure.
  • endoscopes including but not limited to colonoscopes, that aid navigation through the target anatomical structures and that minimize contact between the distal end of the scope and surrounding tissue of such structures.
  • Embodiments of the present invention meet such needs by providing an endoscopy system that can automatically reduce direct contact between the distal end of an endoscope and surrounding tissue of the target anatomical structures, thereby reducing the potential for mechanical trauma.
  • the provided endoscopy system can also allow a clinician to maintain orientation of the distal end of the endoscope and sense of direction through an anatomical structure when performing an endoscopy procedure, thereby allowing for reduced surgery time, anesthesia needs of the patient, and cost of the procedure.
  • endoscopy systems comprise an adjustable endoscope with various combinations of sensors, actuators, and a control system that are in communication with each other.
  • Such endoscopy systems are dynamic in that the sensors, actuators, and control system may be engaged so as to allow for automation of scope positioning when desired, and may also be disengaged so as to allow for conventional control of scope positioning by a clinician.
  • the described endoscopy systems may also cooperate with a variety of conventional endoscopes to provide additional clinician- selected functionality.
  • Figure 1 illustrates various embodiments of one example of a colonoscopy system
  • Figure 2 illustrates embodiments of one example of A, the distal end of a colonoscope; B, the distal end within a straight and curved sections of a colon.
  • actuator is intended to refer to a means for moving or controlling movement of a mechanism or device.
  • anatomical structure is intended to refer to an organ, cavity, or passage of the body, or subparts thereof, that may be examined by an endoscope.
  • clinical practice is intended to refer to a health professional, such as a physician, nurse, or technician, that is involved in administering an endoscopy procedure to a patient.
  • control system is intended to refer to a means for managing, commanding, directing, or regulating the operation of sensors, actuators, or other aspects of a provided endoscopy system.
  • a control system may comprise logic or sequential control, feedback or linear control, fuzzy logic control, or combinations thereof.
  • endoscope is intended to refer to an instrument used to examine the interior tissues of an organ or cavity of the body, including but not limited to, the gastrointestinal tract, the respiratory tract, the abdominal or pelvic cavity, joints, and the reproductive system.
  • the term "sensor,” as used herein, is intended to refer to a means for detecting, measuring, or otherwise determining a physical quantity and converting it into a form that can be read by an instrument or observer.
  • sensors include, but are not limited to, optical sensors, temperature sensors, magnetic sensors, mechanical sensors, acoustic sensors, and MEMs sensors. Some sensors merely receive a signal, whereas other sensors emit and receive signals.
  • the distal end of a conventional colonoscope is inserted through the anus and after passing the rectum, the first curve of the sigmoid colon is encountered.
  • the scope is then navigated through the sigmoid colon and remaining length of the colon by pushing and advancing the shaft and distal end. Due in part to the complex shape of the colon, the clinician can lose directional sense of the intestine lumen.
  • the pushing and advancing maneuvers required can result in the shaft causing trauma near the junction of the rectum and the sigmoid colon or in the sigmoid colon, and the distal end can cause mechanical trauma to the colon wall.
  • elements of the provided endoscopy system can be engaged to automatically aid a clinician in maintaining directional sense and avoid unintentional contact of the distal end with tissue of a structure.
  • such elements may also be disengaged so as to allow for conventional control of distal end positioning by a clinician.
  • the provided endoscopy systems comprise (i) an endoscope comprising a shaft having a distal end for insertion into an anatomical structure of a subject's body and a proximal end that remains substantially outside of the body; (ii) one or more sensors in communication with the distal end; (iii) one or more actuators in communication with the distal end; and (iv) a control system in communication with at least one of the one or more sensors and at least one of the one or more actuators; wherein the control system is configured to receive from the one or more sensors data corresponding to distance between the distal end and surrounding tissue of the anatomical structure, and based upon the data received, direct the one or more actuators to move the distal end such that it is maintained at a pre-determined position with respect to the surrounding tissue.
  • the provided endoscopy system may also comprise
  • each secondary sensor independently attached to the shaft between the distal and proximal ends;
  • one or more secondary actuators not in communication with the distal end; each secondary actuator independently attached to the shaft between the distal and proximal ends; or (iii) combinations thereof.
  • the secondary sensors may be of the same type as those in communication with the distal end, be of some alternative type, or combinations thereof.
  • the secondary actuators may be of the same type as those in communication with the distal end, be of some alternative type, or combinations thereof.
  • the provided endoscopy system may also comprise a control system in communication with (i) at least one of the one or more secondary sensors, (ii) at least one of the one or more secondary actuators, or (iii) combinations thereof.
  • Said control system may have, but is not required to have, the same components as the controller that is configured to control movement of the distal end in response to sensor data.
  • the provided endoscopy system is a colonoscopy system that can reduce unintended contact between the distal end of a colonoscope with the colon wall and allow a clinician to maintain orientation of the distal end of the colonoscope within, and sense of direction through, the intestine lumen when performing a colonoscopy procedure.
  • the provided endoscopes comprise one or more sensors that are in communication with the distal end of the endoscope and that can detect its position in relation to an anatomical structure. Sensors generate data corresponding to the distance between themselves and the surrounding tissue of the structure and relay the data to a control system.
  • a colonoscope may comprise sensors that can detect the position of the distal end of the scope in relation to the colon wall as the scope is advanced through or manipulated in the colon by a clinician.
  • sensors may be positioned at or proximate to the distal end of the endoscope.
  • sensors may be positioned at a different location on the endoscope and collect information about positioning of the distal end by remote means, such as through fiber optic cables.
  • a sensor may be attached at or near the proximal end of the shaft of an endoscope, wherein the sensor is also attached to a first end of a fiber optic cable that runs through an interior cavity of the shaft and attaches at its second end at or near the distal end.
  • the fiber optic cable can relay a signal between the remote sensor and the distal end.
  • the sensors relay information about the position of the distal end to the control system, which in turn can direct function of actuators.
  • Actuators are in communication with the sensors through the control system and mechanically communicate with the distal end to direct its movement such that the tip maintains a controlled distance from tissue of an anatomical structure, such as the colon wall. Sensors can detect distance of the distal end from the tissue, and positioning by the actuators may be controlled by the control system for the directions of up, down, right, and left, and various combinations thereof.
  • Sensors used with the provided endoscopy system may be of one type or may be used in combination with other types of suitable sensors, all of which may be attached to or integrated with the endoscope in various configurations.
  • suitable sensors include, but are not limited to, infra-red sensors.
  • sensors may be attached to or integrated with the distal end, wherein the emitting direction of the signal is selected from perpendicular to the shaft, parallel to the shaft, or perpendicular to the distal face of the distal end.
  • the signal may be emitted in a direction of from 0° to 180° to the shaft.
  • infra-red sensors may be attached to or integrated with the distal end such that the emitted infra-red signal may be in a direction selected from orthogonal to the endoscope's stem or shaft, toward the distal face of the distal end, or a combination thereof.
  • sensors may be attached to or integrated with the endoscope base and the signal is carried by fiber optic cables to the distal end, wherein attachment or integration of the fiber optic cables at the distal end may be such that the emitting direction of the signal is selected from perpendicular to the shaft, parallel to the shaft, or perpendicular to the distal face of the distal end.
  • the signal may be emitted from the fiber optic cables in a direction of from 0° to 180° to the shaft.
  • infra-red sensors may be attached to or integrated with the proximal end and fiber optic cables attached to or integrated with the distal end such that the signal travels through the fiber optic cables between the proximal infra-red sensors and the distal end.
  • the sensor is an infra-red sensor and the emitting direction of the signal is solely toward the distal face of the distal end, the overall percentage of infra-red reception will be lowered, thereby degrading accuracy and response time of the actuators.
  • the infra-red signal may be emitted in a direction of from about 45° to about 135° to the shaft.
  • the direction of emission may be from 45°-55°, 55°-65°, 65°-75°, 75°-85°, 85°-95°, 95°- 105°, 105°-115°, 115°-125°, and 125°-135°.
  • the range of suitable infra-red sensors for use with the provided endoscopes can be determined by the dimensions of the anatomical structure in which the scope is to be used.
  • the range of infra-red sensors used in conjunction with a colonoscope can be determined by the dimensions of a sigmoid colon, which has an average width of 3.5 to 4.2 centimeters.
  • the provided endoscopes comprise one or more infrared sensors suitably arranged to detect an anatomical structure and allow for measurement of the distance between it and the distal end.
  • each infra-red sensor has signal-emitting and signal-receiving elements. It will be understood by one of skill in the art that positioning of the sensors and cables at or with respect to the distal end can be configured in a variety of ways.
  • a colonoscope of the invention may have three sensors at or proximate to the end of the distal end for detection of the colon wall, each sensor positioned around the circumference of the distal end at 120° or other suitable angle from a neighboring sensor.
  • a colonoscope may have sensors at the endoscope base and ends of three fiber optic cables positioned at or proximate to the end of the distal end, each cable end positioned around the circumference of the distal end at 120° or other suitable angle from a neighboring cable end.
  • a colonoscope of the invention may have four sensors at or proximate to the end of the distal end for detection of the colon wall, each sensor positioned around the circumference of the distal end at 90° or other suitable angle from a neighboring sensor.
  • a colonoscope may have sensors at the endoscope base and ends of four fiber optic cables positioned at or proximate to the distal end, each cable end positioned around the circumference of the distal end at 90° or other suitable angle from a neighboring cable end.
  • each sensor can be located directly above tendons that are attached to the distal end, said tendons being connected internally to one or more knobs on the endoscope that allow for positioning of the distal end.
  • one or more actuators are also connected to such one or more knobs.
  • four sensors can be located directly above tendons, said sensors forming right angles to each other.
  • two of the sensors may be assigned to left-right sensing and the other two sensors assigned for up-down sensing; wherein movement of the distal end is achieved via the tendons with up-down motion governed by the distance measured through the two up- down sensors and right-left motion governed by the distance measured through the two right- left sensors.
  • the provided endoscopes comprise actuators that are in communication with the endoscope and can position the distal end of the scope.
  • the positioning of the distal end by the actuators may be controlled to be in relation to an anatomical structure such that the distance between each portion of the tip and the anatomical structure becomes approximately the same within an allowable tolerance.
  • Such actuators are also in communication with the sensors via the control system.
  • a provided colonoscope may comprise sensors that can detect the position of the distal end of the scope in relation to the colon wall, as well as actuators that can position or reposition the distal end in relation to the colon wall as the scope is advanced through or manipulated in the colon by a clinician.
  • Actuators suitable for use with the inventive endoscopy system may be selected from a variety of actuators and may be attached to or integrated with the endoscope in a manner allowing for mechanical control of the distal end of the scope.
  • suitable actuators may be selected from pneumatic/hydraulic actuators, shape memory alloys, magnetic actuators, electric motors, and combinations thereof.
  • SMAs shape memory alloys
  • any shape memory alloy actuator suitable for use with the provided endoscopy system may be used alone, in combination with other SMAs, or in combination with other types of actuators.
  • Any magnetic actuator suitable for use with the provided endoscopy system may be used alone, in combination with other magnetic actuators, or in combination with other types of actuators.
  • AC and DC electric motors are known in the art for use with endoscopes, including but not limited to servo motors, brushless DC motors, brush-type DC motors, stepper motors, and DC motors with encoders.
  • Any electric motor actuator suitable for use with the provided endoscopy system may be used alone, in combination with other electric motor actuators, or in combination with other types of actuators.
  • electric motors may be attached to tendons that are in mechanical communication with the distal end, thereby allowing for mechanical communication between the motor and the distal end.
  • a colonoscope of the provided invention may comprise DC servo motors at its base that push or pull attached tendons, wherein said tendons are also attached to a knob on the scope that is in mechanical communication with the distal end. Movement of the distal end can thereby be controlled by the servo motors until the distance between each side of the distal end and the colon wall becomes approximately the same within the tolerance.
  • the provided endoscopes comprise a control system that communicates electronically with, directs, and coordinates the action of the sensors and the actuators.
  • the control system enables real time adjustment of the position of the distal end of the endoscope via the actuators in response to the detected location of the scope tip by the sensors.
  • the sensors act as input components and the actuators as output components.
  • the control system comprises a logic component and one or more components selected from power sources, drivers processors, and analog/digital converters.
  • an embedded system comprising sensors and actuators controlled by a micro-controller can be utilized.
  • An embedded control system may be configured on one board.
  • a Programmable Intelligent Controller (PIC) micro-controller which contains an internal Analog to Digital Converter (ADC) for the sensors may be utilized.
  • PIC Programmable Intelligent Controller
  • ADC Analog to Digital Converter
  • the sensitivity of the sensor and response time of the actuator may be related to the advancing speed of an endoscope shaft.
  • the provided endoscopy system may also include an image processing module or other sensor system capable of recognizing the speed of the shaft and adjusting sensor sensitivity and actuator response time.
  • the response time of servo motors utilized by a colonoscopy system of the invention may be directly related to the advancing speed of a shaft through a colon, and thus, such system may include an image processing module to recognize the speed of the shaft as it moves through the colon and adjust the response time of the distal end accordingly.
  • the provided endoscopy systems may also allow for selectable sensitivity of the distal end motion, wherein a clinician can select the sensitivity of the tip movement and a washout algorithm can be utilized to maximize the movement of the tip to the zero reference position for the maximum availability of the next motion.
  • each motion (i.e., up, down, right, and left, and combinations thereof) of the distal end of a provided endoscope is governed by one or more infra-red sensors and one or more decoupled servo motors.
  • maintenance of the position of the distal end in the center of the colon when the colonoscope is stationary or moving may be governed by one or more infrared sensors and one or more decoupled servo motors. Since sensitivity of the sensors in the detection of distal end motion may be dependent upon the advancing speed of the colonoscope, an additional sensor system could be utilized to measure the advancing speed of the colonoscope.
  • the sensitivity of the distal end motion can be adapted by having the clinician select the sensitivity so that he or she can comfortably perform the procedure.
  • the general principle of operation of a provided endoscopy system is that the distal end of the endoscope maintains the same distance from tissue of an anatomical structure with respect to the directions of up, down, right, left, or combinations thereof within the structure.
  • the distal end of the endoscope can be manually manipulated by knobs (eg., knobs positioned at the base of the scope), wherein each knob is internally connected to a push-pull mechanism comprising at least one pair of tendons (eg., steel tendons) and wherein such tendons are also connected to actuators, the activation of which also manipulates the tip.
  • two sets of tendons may be orthogonally positioned with respect to each other so that the distal end can make left-right and up-down motions in response to manipulation of the corresponding knobs, actuators, or combination thereof.
  • a diagonal motion of the tip may be achieved by the combined manipulation of the various knobs, actuators, or combinations thereof.
  • Rotation of the tip can also be achieved by turning the base of the endoscope.
  • infra-red sensors detect the tissue of the structure and measure the distance between portions of the tip (for example, upper, lower, right, and left, and combinations thereof) and the tissue.
  • a servo motor or other actuator attached to the tendons automatically pushes or pulls the tendons to control the same distance.
  • Each sensor and corresponding actuator may be decoupled and work independently so that the positioning response of the distal end approximates real-time.
  • FIG. 1 embodiments of one example of a provided colonoscopy system are illustrated, wherein the depicted system has at least three components: sensors, actuators, and an embedded control system.
  • the dashed lines represent the mechanical attachment of the sensors and the actuators to the colonoscope.
  • the system includes three infra-red sensors and two DC servo motors mechanically connected to the colonoscope.
  • alternative numbers, types, and configurations of sensors and actuators would be suitable.
  • four infra-red sensors and two DC servo motors may be mechanically connected to the colonoscope.
  • the system also comprises an embedded control system configured on one board. This allows for control of the infra-red sensors as input sources and actuators as output sources to make a closed loop control system.
  • the control system comprises a microprocessor and an analog/digital converter. Any microprocessor, analog/digital converter, or combination thereof suitable for the application may be used. For example, an 8 bit microprocessor, a 10 bit analog/digital converter, or combinations thereof may be suitable for use with the provided colonoscope.
  • the control system and DC servo motors may be housed in one enclosure (not shown) remote from the endoscope, and may include a power source, such as an AC power supply or battery packs for portability (not shown).
  • FIG. 2 embodiments of one example of a provided endoscopy system are illustrated, wherein the depicted system comprises at three infra-red sensors at or proximate to the distal end.
  • the system has three infra-red sensors 1 (two visible) located on the shaft 2 proximate to the distal face 3 of the distal end 4.
  • Each sensor 1 has signal-emitting and signal-receiving elements (not labeled) and is positioned around the circumference of the shaft 2 at approximately 120° from the neighboring sensor 1.
  • the distal end 4 may maneuver through straight sections of an anatomical structure 5 while maintaining a central position within the structure 5 such that contact between the distal end 3 and the structure 5 is avoided.
  • the sensors 1 emit and receive a signal 6 detecting the distance between the distal end 4 and the structure 5; the signal 6 is transmitted to the control system (not shown); and the control system directs response of the actuators (not shown) to move the distal end 4 to, or maintain its location at, the central position.
  • the provided system also allows for maneuvering of the distal end 4 through curved sections of an anatomical structure 5 while maintaining the distal end 4 in the central position.
  • An endoscopy system of the invention may be designed to automatically avoid direct contact between the distal end of the scope and the surrounding anatomical structure.
  • the system includes sensory elements, control elements, and actuator elements.
  • a colonoscope comprising four infra-red sensors positioned around the circumference of the distal end of the colonoscope, wherein each sensor comprises signal-emitting and signal-receiving elements and is located 90° from its neighboring sensor.
  • the colonoscope has two knobs located at its base, with each knob internally connected to the distal end by one set of steel tendons.
  • the two sets of tendons are orthogonally positioned with respect to each other so that the distal end can make left-right and up-down motions.
  • a DC servo motor that can push or pull the tendons attached to the knob and thus control the distal end movement.
  • the system also has an embedded control system comprising a DC servo motor driver, an infra-red sensor driver, a microprocessor, and an analog/digital converter.
  • Each DC servo motor is linked by the control system to two infra-red sensors such that two sensors are assigned to left-right motion control, and the other two are assigned to up-down motion control.
  • the infra-red sensors detect the inside colon wall and measure the distance between each portion of the distal end (i.e., up, down, left, right, and combinations thereof) and the colon wall.
  • the relevant servo motor pushes or pulls the corresponding tendons attached to the relevant knob to control the tip until that tip portion becomes approximately the same distance (within tolerance) from the colon wall as the other portions.
  • the system automatically responds to the distal end's placement within the colon to avoid it making contact with the colon wall. Since each servo motor and corresponding pair of infra-red sensors are decoupled and work independently, the positioning response approximates real-time. The automation of sensing and positioning may also be selectively disengaged to allow for manual control of the distal end by the clinician via the knobs.
  • a colonoscopy system may also be designed to automatically detect the colon lumen.
  • the system includes sensory elements, control elements, and actuator elements.
  • Three infra-red sensors are positioned around the circumference of the distal end of a colonoscope, wherein each is located 120° from its neighboring sensor.
  • the distal end is connected internally by two sets of steel tendons to two knobs located at the scope base, with each knob connected to one set of steel tendons.
  • the two sets of tendons are orthogonally positioned with respect to each other so that the tip can make left-right and up- down motions.
  • Two DC servo motors are attached to the base of the scope, with each attached to one of the knobs by steel tendons. Each DC servo motor can push or pull the tendons attached to the knob and thus control the distal end positioned within the colon.
  • the system also has an embedded control system comprising a DC servo motor driver, an infra-red sensor driver, a microprocessor, and an analog/digital converter.
  • Each DC servo motor is linked by the control system to the infra-red sensors.
  • the infra-red sensors detect the inside colon wall and measure the distance between each portion of the tip and the colon wall. If the distance between a portion of the distal end and the colon wall is different, the relevant servo motor pushes or pulls the corresponding tendons attached to the relevant knob to control the tip until that tip portion becomes approximately the same distance (within tolerance) from the colon wall as the other portions.
  • the colon wall is automatically detected, and by an approximately real-time response, the distal end is automatically positioned to be in the lumen.

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Abstract

Dans divers modes de réalisation, l'invention porte sur des systèmes d'endoscopie aptes à détecter la position de l'extrémité distale de l'endoscope par rapport à la structure anatomique environnante sous examen. Lesdits systèmes d'endoscopie peuvent également être aptes à déplacer ou maintenir automatiquement l'extrémité distale dans une position prédéterminée par rapport à la structure anatomique.
PCT/US2010/029466 2009-03-31 2010-03-31 Endoscopes à réglage automatique WO2010114920A1 (fr)

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CN102090877A (zh) * 2010-12-10 2011-06-15 广州宝胆医疗器械科技有限公司 具有红外线热扫描功能的经皮肾镜系统
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WO2016064870A1 (fr) * 2014-10-20 2016-04-28 Ohio State Innovation Foundation Intubation avec guidage audio-vibratoire
US10646288B2 (en) 2017-04-12 2020-05-12 Bio-Medical Engineering (HK) Limited Automated steering systems and methods for a robotic endoscope

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CN102100525A (zh) * 2010-12-10 2011-06-22 广州宝胆医疗器械科技有限公司 一体化红外线热扫描喉镜系统
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WO2012075710A1 (fr) * 2010-12-10 2012-06-14 广州宝胆医疗器械科技有限公司 Système intégré de cystoscopie par balayage thermique infrarouge
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