TY  - JOUR
IS  - 4
KW  - Medical robotics
KW  -  Needle steering
KW  -  Motion planning
KW  - 
Homotopy analysis method.
AV  - public
JF  - Annals of Biomedical Engineering
SN  - 1573-9686
SP  - 924
ID  - discovery10046667
N2  - The performance of needle-based interventions depends on the accuracy of needle tip positioning. Here, a novel needle steering strategy is proposed that enhances accuracy of needle steering. In our approach the surgeon is in charge of needle insertion to ensure the safety of operation, while the needle tip bevel location is robotically controlled to minimize the targeting error. The system has two main components: (1) a real-time predictor for estimating future needle deflection as it is steered inside soft tissue, and (2) an online motion planner that calculates control decisions and steers the needle toward the target by iterative optimization of the needle deflection predictions. The predictor uses the ultrasound-based curvature information to estimate the needle deflection. Given the specification of anatomical obstacles and a target from preoperative images, the motion planner uses the deflection predictions to estimate control actions, i.e., the depth(s) at which the needle should be rotated to reach the target. Ex-vivo needle insertions are performed with and without obstacle to validate our approach. The results demonstrate the needle steering strategy guides the needle to the targets with a maximum error of 1.22 mm.
EP  - 938
A1  - Khadem, M
A1  - Rossa, C
A1  - Usmani, N
A1  - Sloboda, RS
A1  - Tavakoli, M
UR  - http://doi.org/10.1007/s10439-016-1736-x
VL  - 45
Y1  - 2017/04/01/
TI  - Semi-Automated Needle Steering in Biological Tissue Using an Ultrasound-Based Deflection Predictor
PB  - SPRINGER
N1  - This version is the author accepted manuscript. For information on re-use, please refer to the publisher?s terms and conditions.
ER  -