Design of a Wireless Medical Capsule for Measuring the Contact Pressure Between a Capsule and the Small Intestine

Li, Pengbo; Kreikemeier-Bower, Craig; Xie, Wanchuan; Kothari, Vishal; Terry, Benjamin S.

doi:10.1115/1.4036260

Cited by 23 publications

(11 citation statements)

References 36 publications

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“…Research to integrate autofluorescence imaging into capsule endoscopy has been conducted by developing several prototype imaging devices [42][43][44], and research on apply- Research to integrate autofluorescence imaging into capsule endoscopy has been conducted by developing several prototype imaging devices [42][43][44], and research on applying volumetric imaging technology to capsule endoscopy using optical coherence tomography is also being conducted [45,46]. In addition, in terms of biophysical measurements, studies are being conducted to measure temperature [47,48], motility [49][50][51], slow wave [52], and pH [53,54] using capsule endoscopy.…”

Section: Non-white Light Imagingmentioning

confidence: 99%

Capsule Endoscopy: Pitfalls and Approaches to Overcome

Kim

Chun

2021

Diagnostics

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Capsule endoscopy of the gastrointestinal tract is an innovative technology that serves to replace conventional endoscopy. Wireless capsule endoscopy, which is mainly used for small bowel examination, has recently been used to examine the entire gastrointestinal tract. This method is promising for its usefulness and development potential and enhances convenience by reducing the side effects and discomfort that may occur during conventional endoscopy. However, capsule endoscopy has fundamental limitations, including passive movement via bowel peristalsis and space restriction. This article reviews the current scientific aspects of capsule endoscopy and discusses the pitfalls and approaches to overcome its limitations. This review includes the latest research results on the role and potential of capsule endoscopy as a non-invasive diagnostic and therapeutic device.

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Section: Non-white Light Imagingmentioning

confidence: 99%

Capsule Endoscopy: Pitfalls and Approaches to Overcome

Kim

Chun

2021

Diagnostics

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“…Li et al have designed a pressure sensor on the smooth surface of the capsule robot, which is used to measure the contact pressure between the capsule and the inner wall of the pipe when the capsule moves, and can receive data wirelessly. 10 Sliker et al have studied the friction resistance and interface friction coefficient when the capsule robot is moving on the surface of the split pig intestine in vitro. 11 Zhang and Liu have measured the friction resistance when the capsule robot is moving in the pig intestine in vitro.…”

Section: Introductionmentioning

confidence: 99%

Measurement and simulation of fluid flow field in the pipe of magnetic capsule robot

Tang

Liang

Yanghui

2020

Advances in Mechanical Engineering

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Through the combination of experimental measurement and CFD (computational fluid dynamics) method, the fluid flow characteristics in the pipe of magnetic capsule robot for intestinal tract are studied. The PIV (particle imaging velocimetry) system is used to measure the fluid flow field around the magnetic-controlled capsule robot under certain translational and rotational speeds, and the rich flow field information (streamline, velocity, and vorticity) is obtained. At the same time, the CFD software is used to calculate the corresponding flow field and the force acting on the capsule robot, and the calculated value is basically consistent with the experimental value. The results show that, driven by the external permanent magnet, the magnetic capsule robot makes corresponding precession movement in the pipe filled with silicone oil, and the movement track is wavy. When the pipe diameter is increased, the fluid streamline around the capsule robot is more stable, the vorticity value is smaller, the resistance and resisting moment of the capsule robot in the forward direction become smaller. The PIV measurement method and CFD method used in this paper can be applied to the fluid flow field measurement and mechanical analysis of the smaller size capsule robot in the liquid environment.

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“…It also allowed for the diet and timing protocols to be tested and provided evidence that simultaneous measurement of oxygen and hydrogen concentrations allowed localisation of the capsule and thus assessment of the sites at which fermentation of carbohydrate substrates was occurring. Altogether, the initial success of the gas‐sensing capsule provides another path for strengthening the global trend towards ingestible electronic devices …”

Section: Introductionmentioning

confidence: 99%