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Abstract

BACKGROUND:

As an innovative technique without cable connection, targeted drug-delivery capsules improve diagnostic and therapeutic capabilities in the gastrointestinal (GI) tract.

OBJECTIVE:

To fast track targeted drug-delivery capsules in the GI tract, a tracking method based on the multiple alternating magnetic sources with adaptive adjustment of the excitation intensity has been investigated.

METHODS:

The functional prototype of the tracking system has been developed. The tracking model between the magnetic field strength and the capsule’s location has been established, which shows a nonlinear equation group with multiple local extremum. Particularly, an improved back-propagation (BP) neural network by particle swarm optimization (PSO) is investigated to solve the tracking problem in real time. The PSO is introduced at an early stage to optimize the weights and thresholds of the BP neural network to improve the generalizability and global search ability. Consequently, the Levenberg-Marquardt (LM) algorithm is used as the learning rule to obtain $a$ higher accuracy and convergence rate.

RESULTS:

The performance on the PSO-BP neural network is experimentally analyzed by comparing it with the standard BP network and the LM-BP network.

CONCLUSIONS:

The tracking experiments show that the PSO-BP neural network can solve the tracking problem successfully. The PSO-BP network can get the solution faster than iterative search algorithms.

Keywords

Drug-delivery capsules gastrointestinal tract fast tracking neural network particle swarm optimization

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References

Ciuti

Menciassi

Dario

. Capsule endoscopy: from current achievements to open challenges. IEEE Rev Biomed Eng 2011; 4: 59-72.

Mapara

Patravale

. Medical capsule robots: a renaissance for diagnostics, drug delivery and surgical treatment. J. Control. Release 2017; 261: 337-351.

Ciuti

Caliò

Camboni

. et al. Frontiers of robotic endoscopic capsules: a review. J Micro-Bio Robot 2016; 11: 1-18.

Boese

Rahn

Sandkamp

. Method for determining the position and orientation of an object, especially of a catheter, from two-dimensional X-ray images. U.S. Patent 7; 801 342, 2010.

Wilding

Coupe

Davis

. The role of gamma-scintigraphy in oral drug delivery. Adv Drug Del Rev 2001; 46: 103-124.

Bao

Pahlavan

. A video aided RF localization technique for the wireless capsule endoscope (WCE) inside small intestine. In Proceedings of the 8th International Conference on Body Area Networks, Boston, USA, September 30-October 2 2013; pp. 55-61.

Brida

Machaj

. A novel enhanced positioning trilateration algorithm implemented for medical implant in-body localization. Int J Antennas Propag 2013; 2013: 607-610.

Nafchi

Goh

Zekavat

. High performance DOA/TOA-based endoscopy capsule localization and tracking via 2D circular arrays and inertial measurement unit. In Proceedings of the IEEE International Conference on Wireless for Space & Extreme Environments, Baltimore, USA, 7–9 November 2013; pp. 1-6.

Nafchi

Shu

Zekavat

SAR

. Circular arrays and inertial measurement unit for DOA/TOA/TDOA-based endoscopy capsule localization: performance and complexity investigation. IEEE Sens J 2014; 14: 3791-3799.

10.

Liu

Chen

Khan

. et al. Wideband characterization of RF propagation for TOA localization of wireless video capsule endoscope inside small intestine. In Proceedings of the IEEE 24th International Symposium on Personal Indoor and Mobile Radio Communications, London, UK, 8–11 September 2013; pp. 326-331.

11.

Pourhomayoun

Jin

Fowler

. Accurate localization of inbody medical implants based on spatial sparsity. IEEE Trans Biomed Eng 2014; 61: 590-597.

12.

Pourkhaatoun

Zekavat

. High-resolution low-complexity cognitive-radio-based multiband range estimation: concatenated spectrum vs. fusion-based. IEEE Syst J 2014; 8: 83-92.

13.

Chandra

Johansson

Tufvesson

. Localization of an RF source inside the human body for wireless capsule endoscopy. In Proceedings of the 8th International Conference on Body Area Networks, Boston, USA, September 30–October 2 2013; pp. 48-54.

14.

Kong

. et al. A new localization system for tracking capsule endoscope robot based on digital 3-axis magnetic sensors array. In Proceedings of 2017 Chinese Intelligent Systems Conference, Mudanjiang, China, 14–15 October 2017; pp. 487-494.

15.

Umay

Fidan

. Adaptive wireless biomedical capsule tracking based on magnetic sensing. Int J Wirel Inform Netw 2017; 6: 1-11.

16.

Turan

Shabbir

Araujo

. et al. A deep learning based fusion of RGB camera information and magnetic localization information for endoscopic capsule robots. Int J Intel Robot Appl 2017; 4: 442-450.

17.

Son

Yim

Sitti

. A 5-d localization method for a magnetically manipulated untethered robot using a 2-d array of hall-effect sensors. IEEE/ASME Trans. Mechatron 2016; 21: 708-716.

18.

Umay

Fidan

. Adaptive wireless biomedical capsule tracking based on magnetic sensing. Int J Wirel Inform Netw 2017; 24: 189-199.

19.

Umay

Fidan

Barshan

. Localization and tracking of implantable biomedical sensors. Sensor 2017; 17: 583-602.

20.

Grzeskowiak

Hatmi

Diet

. et al. Coils for ingestible capsules: near-field magnetic induction link. CR Phys 2015; 16: 819-835.

21.

Ren

You

. et al. Locating intra-body capsule object by three-magnet sensing system. IEEE Sensor J 2016; 16: 5167-5176.

22.

Wei

Chao

. Qing

. et al. An hybrid localization system based on optics and magnetics. In Proceedings of the IEEE International Conference on Robotics and Biomimetics, Tianjin, China, 14–18 December 2010; pp. 1165-1169.

A novel fast solving method for targeted drug-delivery capsules in the gastrointestinal tract

Abstract

BACKGROUND:

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSIONS:

Keywords

Get full access to this article

References