Advanced control for a novel biologically inspired needle steering system

File Description SizeFormat 
Burrows-C-2016-PhD-Thesis.pdfThesis20.66 MBAdobe PDFView/Open
Title: Advanced control for a novel biologically inspired needle steering system
Authors: Burrows, Christopher Anthony
Item Type: Thesis or dissertation
Abstract: Percutaneous intervention is a common type of minimally invasive procedure used to treat and diagnose many disorders. Typically, the needle used is rigid and straight and therefore requires a straight-line path to the target. Problems though arise in complex scenarios, where there is a narrow region the needle must travel through while avoiding critical tissue. As the tissue deforms, the needle may need to be reinserted to achieve the correct path, increasing the risk of tissue trauma. Needle steering aims to solve this, as well as enable procedures that would otherwise not be possible. Within this context, this thesis describes the development of less intrusive control schemes for a novel biologically inspired needle steering system codenamed STING. This thesis presents several research contributions to needle steering, which advance the STING needle towards clinical use. A characterisation of the steering behaviour in three dimensions was performed, which demonstrates the ability of the multi-segment design to follow curvilinear paths through planar movements in full three dimensions. A planar on-line path planning method and constrained closed-loop controller were proposed that allow the needle to be used in dynamic, multi-target environments. Experimental validation through one and two moving targets scenarios demonstrated the STING’s multi-targeting capabilities, and a reduction in the placement error compared to the existing literature. Finally, a cyclic actuation control scheme was developed, with the aim of reducing tissue motion arising due to the insertion process. in vitro validation of the scheme within gelatine tissue phantoms demonstrated no increase in error over standard actuation methods, but a significant reduction in tissue deformation. A reduction of the outside diameter of the STING needle from 12mm to 2.5mm was also achieved within this work, culminating in a clinically viable prototype. The thesis concludes with a summary of the research and suggestions for future work.
Content Version: Open Access
Issue Date: Jul-2016
Date Awarded: Jan-2017
Supervisor: Rodriguez y Baena, Ferdinando
Davies, Brian
Sponsor/Funder: European Research Council
Funder's Grant Number: 258642-STING
Department: Mechanical Engineering
Publisher: Imperial College London
Qualification Level: Doctoral
Qualification Name: Doctor of Philosophy (PhD)
Appears in Collections:Mechanical Engineering PhD theses

Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.

Creative Commonsx