Optimization design of extensor for improving locomotion efficiency of inchworm-like capsule robot

An inchworm-like capsule robot (ILCR) is a promising device for a minimally invasive diagnosis and treatment of colon diseases. It consists of two expanders and one extensor, the former provides a traction force by expanding the colon and the latter can elongate and retract to enable active locomotion. However, the locomotion efficiency of the ILCR can be seriously lowered by the complex colon environment featuring slippery, viscoelastic, and suspend properties, which has been a main obstacle to its clinical application. This paper aims at improving the locomotion efficiency of the ILCR by optimizing its extensor design. To do this, the locomotion resistance of the ILCR in the colon is analyzed, and complying with a requirement that the traction force must be larger than the locomotion resistance to avoid slipping, a restriction on the extensor design is obtained. Then under the restriction and with reference to the Hyperelastic model which correlates stress and strain of colon tissue, a model for analyzing the influence of the design parameters of the extensor on the locomotion efficiency of the ILCR is built. With this model, the extensor has been optimized and the optimized results have been used to guide the development of a novel extensor, which employs two pairs of lead-screws and nuts and is actuated by one motor. Ex-vivo experiment has shown that the novel extensor can improve the locomotion efficiency of an ILCR prototype by 57%, without changing its total length.

[1]  Zhuan Liao,et al.  The application value of magnetic-controlled capsule endoscopy for gastric diseases in physical examination of asymptomatic population , 2017 .

[2]  E. Yoon,et al.  Active locomotion of a paddling-based capsule endoscope in an in vitro and in vivo experiment (with videos). , 2010, Gastrointestinal endoscopy.

[3]  Dianhai Zhang,et al.  Magnetostriction of Silicon Steel Sheets Under Different Magnetization Conditions , 2016, IEEE Transactions on Magnetics.

[4]  Jake J. Abbott,et al.  Five-degree-of-freedom manipulation of an untethered magnetic device in fluid using a single permanent magnet with application in stomach capsule endoscopy , 2016, Int. J. Robotics Res..

[5]  Gursel Alici,et al.  Modeling and Experimental Investigation of Rotational Resistance of a Spiral-Type Robotic Capsule Inside a Real Intestine , 2013, IEEE/ASME Transactions on Mechatronics.

[6]  Paolo Dario,et al.  Modeling and Experimental Validation of the Locomotion of Endoscopic Robots in the Colon , 2004, Int. J. Robotics Res..

[7]  M. Neurath,et al.  Wireless capsule endoscopy of the small intestine: a review with future directions , 2014, Current opinion in gastroenterology.

[8]  Jiwoon Kwon,et al.  Evaluation of the critical stroke of an earthworm-like robot for capsule endoscopes , 2007, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[9]  David Zarrouk,et al.  Conditions for Worm-Robot Locomotion in a Flexible Environment: Theory and Experiments , 2012, IEEE Transactions on Biomedical Engineering.

[10]  Paolo Dario,et al.  Analysis and development of locomotion devices for the gastrointestinal tract , 2002, IEEE Transactions on Biomedical Engineering.

[11]  Guozheng Yan,et al.  Design and Testing of a Motor-Based Capsule Robot Powered by Wireless Power Transmission , 2016, IEEE/ASME Transactions on Mechatronics.

[12]  Peng Gao,et al.  Microgroove cushion of robotic endoscope for active locomotion in the gastrointestinal tract , 2012, The international journal of medical robotics + computer assisted surgery : MRCAS.

[13]  Paolo Dario,et al.  A New Mechanism for Mesoscale Legged Locomotion in Compliant Tubular Environments , 2009, IEEE Transactions on Robotics.

[14]  Dae-Eun Kim,et al.  Novel Propelling Mechanisms Based on Frictional Interaction for Endoscope Robot , 2010 .

[15]  Zhen-Jun Sun,et al.  Study on a magnetic spiral-type wireless capsule endoscope controlled by rotational external permanent magnet , 2015 .

[16]  Guozheng Yan,et al.  Wireless powered capsule endoscopy for colon diagnosis and treatment. , 2013, Physiological measurement.

[17]  Xingling Shao,et al.  Pole-Zero Temperature Compensation Circuit Design and Experiment for Dual-Mass MEMS Gyroscope Bandwidth Expansion , 2019, IEEE/ASME Transactions on Mechatronics.

[18]  Sheng Liu,et al.  Design and Fabrication of a Magnetic Propulsion System for Self-Propelled Capsule Endoscope , 2010, IEEE Transactions on Biomedical Engineering.

[19]  Minglu Chi,et al.  Critical Coupling Magnetic Moment of a Petal-Shaped Capsule Robot , 2016, IEEE Transactions on Magnetics.

[20]  David Zarrouk,et al.  Analysis of Wormlike Robotic Locomotion on Compliant Surfaces , 2011, IEEE Transactions on Biomedical Engineering.

[21]  Silvestro Micera,et al.  Hyperelastic Model of Anisotropic Fiber Reinforcements within Intestinal Walls for Applications in Medical Robotics , 2009, Int. J. Robotics Res..

[22]  M D Jensen,et al.  Measurement of abdominal and visceral fat with computed tomography and dual-energy x-ray absorptiometry. , 1995, The American journal of clinical nutrition.

[23]  Hongyi Li,et al.  Modeling of Velocity-dependent Frictional Resistance of a Capsule Robot Inside an Intestine , 2012, Tribology Letters.

[24]  Guozheng Yan,et al.  Locomotion Analysis of an Inchworm-Like Capsule Robot in the Intestinal Tract , 2016, IEEE Transactions on Biomedical Engineering.

[25]  Guozheng Yan,et al.  A wireless capsule robot with spiral legs for human intestine , 2014, The international journal of medical robotics + computer assisted surgery : MRCAS.

[26]  Metin Sitti,et al.  Design and Rolling Locomotion of a Magnetically Actuated Soft Capsule Endoscope , 2012, IEEE Transactions on Robotics.

[27]  G. Iddan,et al.  Wireless capsule endoscopy , 2003, Gut.

[28]  Hao Liu,et al.  Experimental investigation of intestinal frictional resistance in the starting process of the capsule robot , 2014 .

[29]  Na Wang,et al.  Control theorem of a universal uniform-rotating magnetic vector for capsule robot in curved environment , 2013 .

[30]  Levin J. Sliker,et al.  An Automated Traction Measurement Platform and Empirical Model for Evaluation of Rolling Micropatterned Wheels , 2015, IEEE/ASME Transactions on Mechatronics.

[31]  S. Kudo,et al.  Blinded nonrandomized comparative study of gastric examination with a magnetically guided capsule endoscope and standard videoendoscope. , 2012, Gastrointestinal endoscopy.

[32]  P. Dario,et al.  Frontiers of robotic endoscopic capsules: a review , 2016, Journal of Micro-Bio Robotics.