Implementation of an Intuitive Writing Interface and a Laparoscopic Robot for Gynaecological Laser Assisted Surgery

Abstract

The research reported in this paper aims at applying the human handwriting skill to improve and facilitate the control of laser-assisted laparoscopic surgery operations performed by gynaecological surgeons. For the purpose, a laparoscopic robot was interfaced with a digitizing tablet. This interface, further called the intuitive writing interface (IWI), directly converts the hand trajectory, handwritten on the tablet, into an input signal to the robot. It replaces the traditional complex manipulations performed by the surgeon during manual laparoscopic surgery by natural handwriting. It provides the surgeon with an intuitive ‘what-you-draw-is-what-you-cut’ control facility by employing his/her familiar handwriting skills to control the laser ablation process accurately.

The system was successfully built and tested in vitro. Performance tests on the robot resulted in tracking errors in the order of 1 mm in the target plane at an ablation speed of 20 mm/s. The high accuracy of the system was successfully demonstrated by cutting characters 4 mm high on an apple. These results indicate that laser ablation performance is upgraded by the IWI to the accuracy levels of human handwriting, which is much higher than can be obtained with manual laser laparoscopy.

Safety features include the use of pen contact with the tablet as a safety switch, and back drivability in the robot joints for easy manual positioning and evacuation in case of emergency.

Keywords

laparoscopic robot intuitive writing interface minimally invasive surgery surgical robot what-you-draw-is-what-you-cut (WYDIWYC)

Get full access to this article

View all access options for this article.

References

Bruhat

Mage

Manhes

Use of the CO2 laser via laparoscopy. In Proceedings of the Third Conference on

Laser Surgery, Tel Aviv, Israel, 1979, pp. 274–276.

Koninckx

Laser surgery for endometriosis. last update 1 May 2003, accessed 28 April 2004. http://www.gynsurgery.org/cgi-bin/ols.items.html?22.csv

Darzi

Mackay

Recent advances in minimal access surgery

Br. Med. J., 2002, 324 (7328), 31–34.

Nezhat

Winer

W. K.

Nezhat

Laparoscopic treatment of endometriosis with laser and videocamera augmentation (videolaseroscopy)

J. Gynec. Surg., 1989, 5 (2), 163–168.

Adamson

Subak

Pasta

Kurd

von Franque

Rodriguez

Comparison of CO2 laser laparoscopy with laparotomy for treatment of endometriomata

Fertility Sterility, 1992, 57 (5), 965–973.

Madhani

Niemeyer

Salisbury

The black falcon: A teleoperated surgical instrument for minimally invasive surgery. In Proceedings of the IEEE-RSI International Conference on

Intelligent Robots and Systems, Victoria, British Columbia, Canada, 1998, pp. 936–944 (IEEE, New York).

Adrales

G. L.

Chu

U. B.

Hoskins

J. D.

Witzke

D. B.

Park

A. E.

Development of a valid, cost-effective laparoscopic training program

Am. J. Surg., 2004, 187 (2), 157–163.

Panait

Doarn

C. R.

Merrell

R. C.

Applications of robotics in surgery

Chirurgia (Bucur), 2002, 97 (6), 549–555.

Davies

A review of robotics in surgery

Proc. Instn Mech. Engrs, PartH:J. Engineering in Medicine, 2000, 214 (1), 129–140.

10.

Cleary

Nguyen

State of the art in surgical robotics: Clinical applications and technology challenges

Computer Aided Surg., 2001, 6 (6), 312–328.

11.

Langenburg

S. E.

Knight

C. G.

Klein

M. D.

Robotic surgery: An update

J. Long-Term Effects Med. Implants, 2003, 13 (5), 429–436.

12.

Lanfranco

A. R.

Castellanos

A. E.

Desai

J. P.

Meyers

W. C.

Robotic surgery: A current perspective

Ann. Surg., 2004, 239 (1), 14–21.

13.

Hecht

Robosurgeon - Aesop never tires or shakes and always obeys orders

New Scientist, 1998, 157 (2122), 14.

14.

Guthart

G. S.

Salisbury

J. K.

The intuitive telesurgery system: Overview and application. In Proceedings of the IEEE International Conference on

Robotics and Automation, San Francisco, California, USA, 2000, pp. 618–621 (IEEE, New York).

15.

Accot

Zhai

Performance evaluation of input devices in trajectory-based tasks: An application of the steering law. In Proceedings of the ACM Conference on

Human Factors in Computing Systems, Pittsburgh, Pennsylvania, USA, 1999, pp. 466–472 (ACM Press, New York).

16.

Fitts

P. M.

The information capacity of the human motor system in controlling the amplitude of movement

J. Exp. Psychol., 1954, 47, 381–391.

17.

Accot

Zhai

Beyond Fitts law: Models for trajectory-based HCI tasks. In Proceedings of the ACM Conference on

Human Factors in Computing Systems, Atlanta, Georgia, USA, 1997, pp. 295–302 (ACM Press, New York).

18.

Teulins

Handwriting movement control In Handbook of Perception and Action, 1996, pp. 561–613 (Academic Press, London).

19.

Tang

H.-W.

Van Brussel

Koninckx

P. R.

Vander Sloten

Reynaerts

Auto-focussing of an endoscopic laser using image tracking with an endoscopic robot. In Proceedings of the Second European Medical and Biological Engineering Conference, Vienna, Austria, 2002, pp. 1150–1151 (International Federation for Medical & Biological Engineering (IFMBE), Vienna).

20.

Verdaasdonk

R. M.

Medical laser fundamentals and application In Advances in Lasers and Applications, Proceedings of the 52nd Scottish Universities Summer School in Physics, 1999, pp. 181–226 (Scottish Universities Summer School, Edinburgh; Institute of Physics, Bristol).

21.

Miall

R. C.

Reckess

G. Z.

The cerebellum and the timing of coordinated eye and hand tracking

Brain Cognition, 2002, 48 (1), 212–226.

22.

Davies

B. L.

A discussion of safely issues for medical robots In Computer-Integrated Surgery Technology and Clinical Application, 1995, pp. 287–296 (MIT Press, Cambridge, Massachusetts).