Performance of medical students on a virtual reality simulator for knee arthroscopy: an analysis of learning curves and predictors of performance

Simulator training is gaining popularity and there are many reasons for the rising interest for its role in orthopaedic resident selection and education. The restriction of work hours of residents directly correlates with fewer hours in the operating room observing and performing operations under supervision [1], to the extent that residents do not feel prepared for this technically difficult field after regular residency training [2]. For nearly every joint, arthroscopy simulators have been built and it has been shown that training on simulators improves simulator skills but a clear correlation between simulator training and improved arthroscopic skills in the operating room has not yet been fully confirmed [3‐6]. Only in one study until this time the transfer validity has been shown [7]. The role of factors potentially facilitating surgical skill development such as parental job, experience with computer games or talents like spatial sense or manual skill or others have not been assessed.

For the selection of a future arthroscopic surgeon it would be helpful to know whether factors outside the operating room, respectively even outside the arthroscopic simulation could identify a certain potential for becoming a skilled arthroscopic surgeon. This fact could be path breaking to select a specialty for both, the educator and the candidate. In non-orthopaedic surgical fields there have been studies testing the aptitude of future surgeons with psychomotor testing. It seems to be useful but yet debatable even though baseline visuospatial abilities have been shown to correlate with operative skill [8‐14].

So far it is not known whether visuospatial and/or other factors are predictive for arthroscopic simulator performance. We therefore designed a prospective study to analyze the learning curve and test the hypothesis that baseline factors and measures of visuospatial, motor and mathematical abilities of medical students could predict knee simulator performance and the progression of it using a validated reality-based knee arthroscopy simulator.

This study shows that medical students, participating in a standardized virtual-reality based knee arthroscopy simulator training program, have a significant, but surprisingly steep and short learning curve. This improvement of skills was relevant until the forth test (score 4), which represents about two hours of training, without significant further improvement afterwards. Reasons for this plateau are hypothetical, but this learning curve is consistent with other results in the current literature [3, 16, 17] and might be a result of the so far limited possibility to simulate difficult arthroscopically guided surgical interventions (i.e. meniscal repair, ACL reconstruction). Since the first score does not correlate with the last score, it would be unreasonable to grade a medical student after the first 30 min of arthroscopy of simulator training and it is notable that the the participant who ultimately reached the highest performance in the final session, was amongst the five weakest participants in the first session. This is in sharp contrast to the correlation of score 4 to the final score 8. When looking at the five best participants in score 4 they reached the very high ranking of 3, 4, 5, 6 and 7 in the final score 8. Further the weakest five participants in score 4 reached the low ranking of 11, 15, 17, 19 and 20 in the final score 8. These results show that after a period of two hours of training a reasonably precise predictive statement can be made regarding the future performance of a participant. How a two hour assessment could be carried out during an application process might deserve further study.

Disappointingly, we were unable to identify strong and relevant factors identifying “talented” arthroscopic surgeons. The only factor which correlated significantly to the final performance was to be right handed. This fact might be biased by the fact that an anterolateral portal of a right knee was used for the arthroscope which therefore was held by the left hand. The arthroscopic working tools were inserted through the anteromedial portal and were therefore used with the right hand. In the tested simulators current version, there is only a right knee available even though it should bi possible to change it in the future. The only other factor, which showed a significant but weak correlation to the primary test result was the sportsmanship in the past, but it did afterall not predict final simulator performance. Whether this test result could be related to athletically active persons are more competitive and try harder at the first effort is unknown but a possibility.

Our findings were in contrast to previous laparoscopic simulator studies, which were able to identify different predictive factors. Risucci et al. [13] suggested that age, experience and visual spatial perceptual ability may play a role in determining the speed a surgeon can acquire and perform laparoscopic skills using a laparoscopic intracorporal simulator. Madan et al. [18] found that the only predicting factor, which correlated with the laparoscopic simulator performance was eating with chop sticks. There were, however no visuospatial or other tests used in the study of Madan et al. as predicting factors. Stefanidis et al. [12] showed that residents training on a laparoscopic simulator performed 50 % better after a mean of 12 h and that the only test, which correlated with the simulator performance was the visuospatial test “card rotation”, which is similar to the visuospatial test used in this present study. Further Stefanidis et al. found training duration and repetition correlated with prior video gaming, billiard exposure, grooved pegboard (time to place different pegs with a key with one hand in a pegboard), finger tapping with the index finger as fast as possible and map planning (a mental test for visuospatial capability and concentration).

We are aware of the potential limitations of this study. Although this study was prospectively conducted, the limited number of participants (n = 20) was possibly too small to detect subtle differences but did allow to exclude substantial differences and trends in the study group which would have made impact on selection of trainees. Furthermore, we are aware of the fact that in arthroscopic simulator surgery there have been attempts to not only measure performance with metric parameters but also with subjective scores. We however considered the Arthroscopic Surgery Skill Evaluation Tool (ASSET) [19], which seems to be a valid and reliable pass-fail examination of diagnostic knee arthroscopy simulation, as being not precise enough to quantitatively evaluate and compare the longitudinal participants performance. Furthermore as this was the first study investigating predictive factors in arthroscopic simulator training there were no established guidelines about visuospatial, manual or mathematical tests. Therefore it remains hypothetical if the chosen tests were either not appropriate to detect the expected predictive factors, or it is simply not possible to predict simulator performance using demographics or psycho-motoric tests.

Despite the above mentioned limitations, this study revealed some interesting information about potential arthroscopy simulator training programs and the potential use recruiting medical students in orthopaedic residents programs. Medical students without any previous arthroscopic experience improve significantly after a two-hour training virtually based simulator program of increasing difficulty levels. The level which is reached after this two hour training on the arthroscopy simulator does not change relevantly after training of more than 2 h. As transfer validity of simulator training in to the operating room was proven before [20], even though this was on an other virtual reality based arthroscopic simulator, it seems reasonable to state that these trainees do not only improve there simulator skills, but thereof should be able to benefit in real arthroscopic surgeries.

There is a significant learning curve of medical students when completing a standardized training program performed on a validated virtual-reality-based knee arthroscopy simulator during the first 2 h of training. The “good” and the “less good” arthroscopic surgeon can then be evaluated and further training will not change that finding. We however failed to identify factors, which help to predict talent and potential development of arthroscopic skills. Further studies are needed to become more and precise information about the transfer validity to the operating room and the amount of training time and type to make a sophisticated recommendation about the potentially best educational program for future orthopaedic surgeons providing best health care for our patients.