• Title/Summary/Keyword: Capsule-type endoscope

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Influence of Dither Motion on the Friction Coefficient of a Capsule-type Endoscope (디더 운동이 캡슐형 내시경의 마찰계수 감소에 미치는 영향)

  • Hong Y.S.;Choi M.J.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.06a
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    • pp.1068-1073
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    • 2005
  • Development of a locomotive mechanism for the capsule type endoscopes will largely enhance the ability to diagnose disease of digestive organs. In connection with it, most of the researches have focused on an installable locomotive mechanism in the capsule. In this paper, it is introduced that the movement of a capsule type endoscope in digestive organ can be manipulated by magnetic force produced outside human body. Since the magnetic force is provided by permanent magnets, no additional power supply to the capsule is required. Using a robotic manipulator for locating the external magnet, the capsule motion control system can cover the whole human digestive organs. This study is particularly concentrated on dither motion effect to improve the mobility of capsule type endoscope. It was experimentally found out that the friction coefficient between the capsule and digestive organ can be remarkably reduced by superposing yawing or rolling dither motion on the translatory motion. In this paper, the experimental results obtained while the direction, amplitude and frequency of sinusoidal dither motion were changed are reported.

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Influence of Dither Motion on the Friction Coefficient of a Capsule-type Endoscope (디더운동이 캡슐형 내시경의 마찰계수 감소에 미치는 영향)

  • Hong Yeh-Sun;Choi Il-Soo;Kim Byung-Gyu
    • Journal of the Korean Society for Precision Engineering
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    • v.22 no.8 s.173
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    • pp.57-63
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    • 2005
  • Development of a locomotive mechanism fer the capsule type endoscopes will largely enhance the ability to diagnose disease of digestive organs. In connection with it, most of researches have focused on an installable locomotive mechanism in the capsule. In this paper, it is introduced that the movement of a capsule type endoscope in digestive organ can be manipulated by magnetic force produced outside human body. Since the magnetic force is provided by permanent magnets, no additional power supply to the capsule is required. Using a robotic manipulator for locating the external magnet, the capsule motion control system can cover the whole human digestive organs. This study is particularly concentrated on dither motion effect to improve the mobility of capsule type endoscope. It was experimentally found out that the friction coefficient between the capsule and digestive organ can be remarkably reduced by superposing yawing or rolling dither motion on the translatory motion. In this paper, the experimental results obtained with the direction, amplitude and frequency of sinusoidal dither motion changed is reported.

Position Detection of a Capsule-type Endoscope by Magnetic Field Sensors (자계 센서를 이용한 캡슐형 내시경의 위치 측정)

  • Park, Joon-Byung;Kang, Heon;Hong, Yeh-Sun
    • Journal of the Korean Society for Precision Engineering
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    • v.24 no.6
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    • pp.66-71
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    • 2007
  • Development of a locomotive mechanism for the capsule type endoscopes will largely enhance their ability to diagnose disease of digestive organs. As a part of it, there should be provided a detection device of their position in human organs for the purpose of observation and motion control. In this paper, a permanent magnet outside human body was employed to project magnetic field on a capsule type endoscope, while its position dependent flux density was measured by three hall-effect sensors which were orthogonally installed inside the capsule. In order to detect the 2-D position data of the capsule with three hall-effect sensors including the roll, pitch and yaw angle, the permanent magnet was extra translated during the measurement. In this way, the 2-D coordinates and three rotation angles of a capsule endoscope on the same motion plane with the permanent magnet could be detected. The working principle and performance test results of the capsule position detection device were introduced in this paper showing that they could be also applied to 6-DOF position detection.

A Paddling Based Locomotive Mechanism for Capsule Endoscopes

  • Park Suk-Ho;Park Hyun-Jun;Park Sung-Jin;Kim Byung-Kyu
    • Journal of Mechanical Science and Technology
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    • v.20 no.7
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    • pp.1012-1018
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    • 2006
  • Diagnosis and treatment using the conventional flexible endoscope in gastro-intestinal tract are very common since advanced and instrumented endoscopes allow diagnosis and treatment by introducing the human body through natural orifices. However, the operation of endoscope is very labor intensive work and gives patients some pains. As an alternative, therefore, the capsule endoscope is developed for the diagnosis of digestive organs. Although the capsule endoscope has conveniences for diagnosis, it is passively moved by the peristaltic waves of gastro-intestinal tract and thus has some limitations for doctor to get the image of the organ and to diagnose more thoroughly. As a solution of these problems, various locomotive mechanisms for capsule endoscopes are introduced. In our proposed mechanism, the capsule-type microrobot has synchronized multiple legs that are actuated by a linear actuator and two mobile cylinders inside of the capsule. For the feasibility test of the proposed microrobot, a series of in-vitro experiments using small intestine without incision were carried out. From the experimental results, our proposed microrobot can advance along the 3D curved and sloped path with the velocity of about $3.29\sim6.26mm/sec$ and $35.1\sim66.7%$ of theoretical velocity. Finally, the proposed locomotive mechanism can be not only applicable to micro capsule endoscopes but also effective to advance inside of gastro-intestinal tract.

INVESTIGATION OF ENDOSCOPE CAPSULE DESIGN ON THE FRICTIONAL RESISTANCE INSIDE THE INTESTINE

  • Baek, N.K.;Sung, I.H.;Kim, J.S.;Kim, D.E.
    • Proceedings of the Korean Society of Tribologists and Lubrication Engineers Conference
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    • 2002.10b
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    • pp.367-368
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    • 2002
  • The design of capsule body for self-propelled endoscope is important from the frictional resistance point of view. The capsule should be able to overcome the frictional resistance in order to move along the intestine. The motivation of this work was to gain a better understanding of the capsule body design on the frictional resistance of the capsule inside an intestine. A special experimental set-up was built to measure the frictional resistance as the capsule was being pulled inside the pig intestine specimen. Tests were performed with open and closed intestine specimens. Experimental data showed that smooth cylindrical capsule geometry resulted in the least frictional resistance. The resistance inside the closed intestine specimen was about four times higher than that of the open specimen. It is expected that the results of this work will be used to design the optimum propulsion system for the microendoscope.

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Technical Characteristics and Trends of Capsule Endoscope (캡슐 내시경의 기술적 특징과 동향)

  • Kim, Ki-Yun;Won, Kyung-Hoon;Choi, Hyung-Jin
    • The Journal of Korean Institute of Communications and Information Sciences
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    • v.37 no.4C
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    • pp.329-337
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    • 2012
  • Capsule Endoscope(CE) is a capsule-shaped electronic device which can examine the lesions in digestive tract of human body. Recently the medical procedure using capsule endoscope is receiving great attention to both doctors and patients, since the conventional push-typed endoscope using cables brings great pain and fear to the patients. The technique was firstly available in 2000 and is based on a convergence techniques among BT(Bio Technology), IT(Information Technology), and NT(Nano Technology). The device consists of an optical parts including LEDs(Light Emitting Diodes), an image sensor, a communication module and a power module. Capsule endoscope is the embodiment of the state-of-the art technology and requires key technologies in the various engineering fields. Therefore, in this paper, we introduce the composition of the capsule endoscope system, and compare the communication method between RF(Radio Frequency) communication and HBC(Human Body Communication), which are typically used for data transmission in the capsule endoscope. Furthermore, we analyze the specification of commercialized capsule endoscopes and present the future developments and technical challenges.

Tribological Characteristics of Endoscope Capsule Inside of Small Intestine (캡슐형 내시경 개발을 위한 소장 내에서의 캡슐저항력 특성)

  • 백남국;김대은
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2002.05a
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    • pp.142-145
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    • 2002
  • In order to develop a self-propelled microendoscope, the frictional resistance of the capsule-type endoscope inside the intestine should be understood. In this work the frictional resistance behaviors of capsules with different designs were experimentally investigated using a pig intestine. It was found that cylindrical capsule design had the least frictional resistance. Also, the resistance increased as the speed of the capsule motion was decreased. It is expected that the results of this work will be used to design the optimum propulsion system for the microendoscope.

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Development of a Wheel Type Locomotive Mechanism Using Micro motor for a Capsule-Type Endoscope (모터를 이용한 바퀴형 체내이동 메커니즘의 개발)

  • Lee, Young-Jae;Kim, Byung-Kyu;Lim, Young-Mo;Park, Jong-Oh;Hong, Yeh-Sun;Kim, Soo-Hyun
    • Proceedings of the KSME Conference
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    • 2001.06b
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    • pp.289-294
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    • 2001
  • The two prototypes of a Wheel Type Locomotive Mechanism Using Micro motor for a Capsule-Type Endoscope are outlined and realized. Basic concept of these mechanisms is to use a rod-shaped wheel, with which these mechanisms can go over the haustral folds inside colon. The actuator of Prototype I is geared dc motor and the actuator for steering is Shape Memory Alloy. Prototype I goes through the whole area of colonoscopy training model. Prototype II can not only go forward and backward, but also be steerable with 2 geared dc motors. Prototype II goes through dead pig colon.

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