Sage Journals: Discover world-class research

Abstract

Introduction. Trajectories of surgical instruments in laparoscopic surgery contain rich information about surgeons’ performance. In a simulation environment, instrument trajectories can be taken by motion sensors attached to the instruments. This method is not accepted by surgeons working in the operating room due to safety concerns. In this study, a novel approach of acquiring instrument trajectories from surgical videos is reported. Methods. A total of 12 surgical videos were obtained for this study. The videos were captured during simulated laparoscopic procedures where subjects were required to pick up and transport an object over 3 different targets using a laparoscopic grasper. An algorithm was developed to allow the computer to identify the tip of the grasper on each frame of video, and then compute the trajectories of grasper movement. Results. The newly developed algorithm successfully identified tool trajectories from all 12 surgical videos. To validate the accuracy of this algorithm, the location of the tooltip in these videos were also manually labeled. The rate of accurate matching between these 2 methods was 98.4% of all video frames. Discussion. Identifying tool movement from surgical videos creates an effective way to track instrument trajectories. This builds up the foundation for assessing psychomotor performance of surgeons in the operating room without jeopardizing patient safety.

Keywords

tool tracking motion detection video processing laparoscopy surgery simulation

Get full access to this article

View all access options for this article.

References

Stylopoulos

Vosburgh

. Assessing technical skill in surgery and endoscopy: A set of metrics and an algorithm (C-Pass) to assess skills in surgical and endoscopic procedures. Surg Innov. 2007;14:113-121.

Oropesa

Chmarra

Sánchez-González

. Relevance of motion-related assessment metrics in laparoscopic surgery. Surg Innov. 2012;20:299-312.

Helsen

Elliott

Starkes

Ricker

. Coupling of eye, finger, elbow, and shoulder movements during manual aiming. J Motor Behav. 2000;32:241-248.

Anderson

. Objective Surgical Skill Evaluation [master’s thesis]. Edmonton, Alberta, Canada: University of Alberta; 2010.

Sánchez-González

Cano

Oropesa

. Laparoscopic video analysis for training and image-guided surgery. Minim Invasive Ther Allied Technol. 2011;20:311-320.

Allen

Kasper

Nataneli

Dutson

Faloutsos

. Visual tracking of laparoscopic instruments in standard training environments. Stud Health Technol Inform. 2011;163:11-17.

Oropesa

Sánchez-González

Chmarra

. EVA: Laparoscopic instrument tracking based on endoscopic video analysis for psychomotor skills assessment. Surg Endosc. 2013;27:1029-1039.

Cano

Lamata

Gayá

Gómez

. New methods for video-based tracking of laparoscopic Tools. In: Proceedings of the Third International Conference on Biomedical Simulation, Zurich, Switzerland. Berlin, Germany: Springer-Verlag; 2006:142-149.

Tonet

Ramesh

Megali

Dario

. Tracking endoscopic instruments without localizer: Image analysis-based approach. Stud Health Technol Inform. 2006;119:544-549.

10.

Spagnolo

Orazio

Leo

Distante

. Moving object segmentation by background subtraction and temporal analysis. Image Vision Comput. 2006;24:411-423.

11.

Duchowski

. A breadth-first survey of eye-tracking applications. Behav Res Methods Instrum Comput. 2002;34:455-470.

12.

Atkins

Tien

Khan

Meneghetti

Zheng

. What do surgeons see: capturing and synchronizing eye gaze for surgery applications. Surg Innov. 2013;10:243-250.

13.

Tien

Atkins

Zheng

. Measuring gaze overlap on videos between multiple observers. In: Publication of Conference on Eye Tracking Research and Applications (ETRA) March 28-30, 2012, Santa Barbara, CA. New York, NY: ACM: 2012:309-312.

14.

Wilson

Vine

Bright

Masters

Defriend

Gaze

McGrath J.

Training enhances laparoscopic technical skill acquisition and multi-tasking performance: a randomized, controlled study. Surg Endosc. 2011;25:3731-3739.

15.

Ritter

Scott

. Design of a proficiency-based skills training curriculum for the fundamentals of laparoscopic surgery. Surg Innov. 2007;14:107-112.

16.

Jiang

Zheng

Tien

Atkins

. Pupil response to precision in surgical task execution. Stud Health Technol Inform. 2013;184:210-214.

17.

Jiang

Tien

Huang

Zheng

Atkins

. Capturing and evaluating blinks from video-based eyetrackers. Behav Res Methods. 2013;45:656-663.

18.

Cristani

Farenzena

Bloisi

Murino

. Background subtraction for automated multisensor surveillance: a comprehensive review. EURASIP J Adv Signal Proces. 2010;2010:343057.

19.

Bradski

Kaehler

. Learning Opencv: Computer Vision With the Opencv Library. Sebastopol, CA: O’Reilly Media; 2008.

20.

Colque

Cámara-Chávez

. Progressive background image generation of surveillance traffic videos based on a temporal histogram ruled by a reward/penalty function. In: Proceedings of the 24th SIBGRAPI Conference on Graphics, Patterns and Images at Maceio, Brazil. Washington, DC: IEEE Computer Society; 2011:297-304.

21.

Brown

. Tracker video analysis and modeling tool. http://www.cabrillo.edu/~dbrown/tracker/. Accessed February 6, 2013.

22.

Aggarwal

Dosis

Bello

Darzi

. Motion tracking systems for assessment of surgical skill. Surg Endosc. 2007;21:339.

Video Processing to Locate the Tooltip Position in Surgical Eye–Hand Coordination Tasks

Abstract

Keywords

Get full access to this article

References