Markov modeling of minimally invasive surgery based on tool/tissue interaction and force/torque signatures for evaluating surgical skills.
Identifieur interne : 000210 ( Ncbi/Curation ); précédent : 000209; suivant : 000211Markov modeling of minimally invasive surgery based on tool/tissue interaction and force/torque signatures for evaluating surgical skills.
Auteurs : J. Rosen [États-Unis] ; B. Hannaford ; C G Richards ; M N SinananSource :
- IEEE transactions on bio-medical engineering [ 0018-9294 ] ; 2001.
English descriptors
- KwdEn :
- Algorithms, Animals, Cholecystectomy, Laparoscopic (instrumentation), Cholecystectomy, Laparoscopic (methods), Computer Simulation, Computer-Assisted Instruction, General Surgery (education), Internship and Residency, Laparoscopy (methods), Markov Chains, Swine, User-Computer Interface, Video Recording.
- MESH :
- education : General Surgery.
- instrumentation : Cholecystectomy, Laparoscopic.
- methods : Cholecystectomy, Laparoscopic, Laparoscopy.
- Algorithms, Animals, Computer Simulation, Computer-Assisted Instruction, Internship and Residency, Markov Chains, Swine, User-Computer Interface, Video Recording.
Abstract
The best method of training for laparoscopic surgical skills is controversial. Some advocate observation in the operating room, while others promote animal and simulated models or a combination of surgery-related tasks. A crucial process in surgical education is to evaluate the level of surgical skills. For laparoscopic surgery, skill evaluation is traditionally performed subjectively by experts grading a video of a procedure performed by a student. By its nature, this process uses fuzzy criteria. The objective of the current study was to develop and assess a skill scale using Markov models (MMs). Ten surgeons [five novice surgeons (NS); five expert surgeons (ES)] performed a cholecystectomy and Nissen fundoplication in a porcine model. An instrumented laparoscopic grasper equipped with a three-axis force/torque (F/T) sensor was used to measure the forces/torques at the hand/tool interface synchronized with a video of the tool operative maneuvers. A synthesis of frame-by-frame video analysis and a vector quantization algorithm, allowed to define F/T signatures associated with 14 different types of tool/tissue interactions. The magnitude of F/T applied by NS and ES were significantly different (p < 0.05) and varied based on the task being performed. High F/T magnitudes were applied by NS compared with ES while performing tissue manipulation and vise versa in tasks involved tissue dissection. From each step of the surgical procedures, two MMs were developed representing the performance of three surgeons out of the five in the ES and NS groups. The data obtained by the remaining two surgeons in each group were used for evaluating the performance scale. The final result was a surgical performance index which represented a ratio of statistical similarity between the examined surgeon's MM and the MM of NS and ES. The difference between the performance index value, for a surgeon under study, and the NS/ES boundary, indicated the level of expertise in the surgeon's own group. Using this index, 87.5% of the surgical procedures were correctly classified into the NS and ES groups. The 12.5% of the procedures that were misclassified were performed by the ES and classified as NS. However in these cases the performance index values were very close to the NS/ES boundary. Preliminary data suggest that a performance index based on MM and F/T signatures provides an objective means of distinguishing NS from ES. In addition, this methodology can be further applied to evaluate haptic virtual reality surgical simulators for improving realism in surgical education.
DOI: 10.1109/10.918597
PubMed: 11341532
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pubmed:11341532Le document en format XML
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<wicri:regionArea>Department of Electrical Engineering, University of Washington, Seattle 98195</wicri:regionArea>
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<author><name sortKey="Sinanan, M N" sort="Sinanan, M N" uniqKey="Sinanan M" first="M N" last="Sinanan">M N Sinanan</name>
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<sourceDesc><biblStruct><analytic><title xml:lang="en">Markov modeling of minimally invasive surgery based on tool/tissue interaction and force/torque signatures for evaluating surgical skills.</title>
<author><name sortKey="Rosen, J" sort="Rosen, J" uniqKey="Rosen J" first="J" last="Rosen">J. Rosen</name>
<affiliation wicri:level="4"><nlm:affiliation>Department of Electrical Engineering, University of Washington, Seattle 98195, USA. rosen@u.washington.edu</nlm:affiliation>
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<author><name sortKey="Sinanan, M N" sort="Sinanan, M N" uniqKey="Sinanan M" first="M N" last="Sinanan">M N Sinanan</name>
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<series><title level="j">IEEE transactions on bio-medical engineering</title>
<idno type="ISSN">0018-9294</idno>
<imprint><date when="2001" type="published">2001</date>
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<term>Animals</term>
<term>Cholecystectomy, Laparoscopic (instrumentation)</term>
<term>Cholecystectomy, Laparoscopic (methods)</term>
<term>Computer Simulation</term>
<term>Computer-Assisted Instruction</term>
<term>General Surgery (education)</term>
<term>Internship and Residency</term>
<term>Laparoscopy (methods)</term>
<term>Markov Chains</term>
<term>Swine</term>
<term>User-Computer Interface</term>
<term>Video Recording</term>
</keywords>
<keywords scheme="MESH" qualifier="education" xml:lang="en"><term>General Surgery</term>
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<keywords scheme="MESH" qualifier="instrumentation" xml:lang="en"><term>Cholecystectomy, Laparoscopic</term>
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<keywords scheme="MESH" qualifier="methods" xml:lang="en"><term>Cholecystectomy, Laparoscopic</term>
<term>Laparoscopy</term>
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<keywords scheme="MESH" xml:lang="en"><term>Algorithms</term>
<term>Animals</term>
<term>Computer Simulation</term>
<term>Computer-Assisted Instruction</term>
<term>Internship and Residency</term>
<term>Markov Chains</term>
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<front><div type="abstract" xml:lang="en">The best method of training for laparoscopic surgical skills is controversial. Some advocate observation in the operating room, while others promote animal and simulated models or a combination of surgery-related tasks. A crucial process in surgical education is to evaluate the level of surgical skills. For laparoscopic surgery, skill evaluation is traditionally performed subjectively by experts grading a video of a procedure performed by a student. By its nature, this process uses fuzzy criteria. The objective of the current study was to develop and assess a skill scale using Markov models (MMs). Ten surgeons [five novice surgeons (NS); five expert surgeons (ES)] performed a cholecystectomy and Nissen fundoplication in a porcine model. An instrumented laparoscopic grasper equipped with a three-axis force/torque (F/T) sensor was used to measure the forces/torques at the hand/tool interface synchronized with a video of the tool operative maneuvers. A synthesis of frame-by-frame video analysis and a vector quantization algorithm, allowed to define F/T signatures associated with 14 different types of tool/tissue interactions. The magnitude of F/T applied by NS and ES were significantly different (p < 0.05) and varied based on the task being performed. High F/T magnitudes were applied by NS compared with ES while performing tissue manipulation and vise versa in tasks involved tissue dissection. From each step of the surgical procedures, two MMs were developed representing the performance of three surgeons out of the five in the ES and NS groups. The data obtained by the remaining two surgeons in each group were used for evaluating the performance scale. The final result was a surgical performance index which represented a ratio of statistical similarity between the examined surgeon's MM and the MM of NS and ES. The difference between the performance index value, for a surgeon under study, and the NS/ES boundary, indicated the level of expertise in the surgeon's own group. Using this index, 87.5% of the surgical procedures were correctly classified into the NS and ES groups. The 12.5% of the procedures that were misclassified were performed by the ES and classified as NS. However in these cases the performance index values were very close to the NS/ES boundary. Preliminary data suggest that a performance index based on MM and F/T signatures provides an objective means of distinguishing NS from ES. In addition, this methodology can be further applied to evaluate haptic virtual reality surgical simulators for improving realism in surgical education.</div>
</front>
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