Abstract
Background
An understanding of differences in expert and novice neural behavior can inform surgical skills training. Outside the surgical domain, electroencephalographic (EEG) coherence analyses have shown that during motor performance, experts display less coactivation between the verbal-analytic and motor planning regions than their less skilled counterparts. Reduced involvement of verbal-analytic processes suggests greater neural efficiency. The authors tested the utility of an implicit motor learning intervention specifically devised to promote neural efficiency by reducing verbal-analytic involvement in laparoscopic performance.
Methods
In this study, 18 novices practiced a movement pattern on a laparoscopic trainer with either conscious awareness of the movement pattern (explicit motor learning) or suppressed awareness of the movement pattern (implicit motor learning). In a retention test, movement accuracy was compared between the conditions, and coactivation (EEG coherence) was assessed between the motor planning (Fz) region and both the verbal-analytic (T3) and the visuospatial (T4) cortical regions (T3-Fz and T4-Fz, respectively).
Results
Movement accuracy in the conditions was not different in a retention test (P = 0.231). Findings showed that the EEG coherence scores for the T3-Fz regions were lower for the implicit learners than for the explicit learners (P = 0.027), but no differences were apparent for the T4-Fz regions (P = 0.882).
Conclusions
Implicit motor learning reduced EEG coactivation between verbal-analytic and motor planning regions, suggesting that verbal-analytic processes were less involved in laparoscopic performance. The findings imply that training techniques that discourage nonessential coactivation during motor performance may provide surgeons with more neural resources with which to manage other aspects of surgery.
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Recently, study investigating the neural substrate that underpins how trainees and experts produce surgical skills at a cortical level has begun to provide a foundation upon which to base the development and refinement of surgical training strategies [1–5]. Trainee surgeons, for example, have been shown to display significant activation of the prefrontal cortex early in learning when their skills are error-prone but not later in learning when their skills have automated [4, 6]. However, a greater understanding of how cortical regions interact in response to surgical training is needed [7].
Outside the surgical domain, electroencephalographic (EEG) measurement has shaped much of our current understanding concerning the neurocognitive aspects of skilled motor performance [8–10]. Experts display “neural efficiency,” in which cortical activity is refined and nonessential interaction between the motor planning regions and other regions of the brain is attenuated [11–16]. Neuroplasticity of the cortical architecture is thought to reflect lowered demands on attention and reduced cognitive interference in motor planning and execution [8].
A specific neural measure with potential to discriminate between expert and novice motor performance is EEG cortical coherence between the verbal-analytic (T3) and motor planning (Fz) regions [17, 18]. High coherence suggests extensive coactivation (communication) between the two regions, whereas low coherence implies trivial coactivation (regional independence). Elite marksmen, for example, exhibit lower T3-Fz alpha band coherence than their subelite counterparts [17]. Interestingly, coherence between the visuospatial processing (T4) and motor planning (Fz) regions (T4-Fz) does not differ, suggesting that neural efficiency is not represented by a uniform decrease in cerebral activity, but rather by an appropriate “fit” of neural resources to specific task demands and a consequent reduction in irrelevant processing [8]. By withdrawing verbal-analytic engagement from motor performance, experts reduce neuromotor “noise” and limit potential interference from nonessential processes.
The need for verbal-analytic involvement in motor performance at any stage of learning has been questioned [19–21]. Verbal-analytic processes can interfere with motor performance and have been implicated in skill breakdown under psychological stress [19, 20, 22, 23] and physiologic fatigue [24, 25]. Additionally, inexperienced performers who depend on verbal-analytic processes tend to be disrupted by multitasking conditions [26–28].
Implicit motor learning techniques are designed to circumvent verbal-analytic interference during training. They result in low conscious awareness of what is learned and subsequently limited verbal-analytic involvement in motor performance [19, 29], as reflected by low T3-Fz alpha band co-activation [30]. Implicit motor learning has potential, therefore, to promote neural efficiency in surgical training. We examined this possibility in a laparoscopic surgery task.
Materials and methods
For this study, 18 volunteers with no prior laparoscopy experience were recruited from the University of Hong Kong student community. All the participants were right-handed, with normal or corrected-to-normal vision.
A continuous tracking task [31–33] was modified to be highly relevant to laparoscopy training. In continuous tracking paradigms, a learner tracks a target moving in a sinusoidal waveform across a monitor by manipulating a handheld device in the horizontal plane. The waveform contains a prescribed movement pattern that is repeated in every trial but embedded between two random movement patterns that differ in every trial (Fig. 1). With training, participants become very skilled at tracking the repeated segment of the pattern. They can be informed that the pattern repeats and asked to search consciously for it (explicit motor learning), or they can be completely unaware that the pattern repeats (implicit motor learning).
To modify the tracking task for laparoscopy, the handheld device was replaced by laparoscopic graspers inserted through a trocar in a simulated skin pad. The graspers were used bimanually to maneuver a tracker across an Intuos3 tablet (Wacom, JP, Saitama, Japan). The position of the tracker on the tablet (horizontal plane) corresponded to the position of a cursor on a 17-in. liquid crystal display (LCD) monitor adjusted to the height of the operator.
To simulate scaling of sensorimotor mappings in laparoscopy due to magnification of the operating area by the endoscope, the movement of the cursor was scaled to match the movement of the tracker (×8). The study participants were required to track as accurately as possible a red target dot that moved in a sinusoidal waveform across the computer screen. The task was designed in response to recent criticism of the overemphasis on completion time measures in surgical training curricula [34].
The participants were assigned to an explicit motor learning condition (n = 9) or an implicit motor learning condition (n = 9).Footnote 1 All the participants were informed that they would see a red dot on the screen for 36 s and that the dot would display a waveform pattern of movement.
The participants in the explicit motor learning condition were told that the middle 12-s segment of the pattern would be the same for every trial and that they would need to learn the pattern to improve the accuracy of their movements. Additionally, they were shown a pictorial representation of the repeating segment at the beginning of training and after every three practice trials (Fig. 1, middle segment). This information was designed explicitly to encourage verbal-analytic involvement in performance of the laparoscopy task. The participants in the implicit motor learning condition were not informed that the middle segment of the waveform pattern repeated, nor did they see a pictorial representation of the repeated segment.Footnote 2
Training consisted of eight blocks of three trials (n = 24 trials). A 1-min rest interval was provided between blocks. At 5 min after the final training block, all the participants completed a retention test (n = 3 trials). Retention tests typically are used to assess “true” learning once participants have recovered from fatigue or boredom that accumulates during training [35].
A custom Java program (Sun Microsystems, Santa Clara, CA, USA) generated the movement patterns and recorded both the target and cursor locations at a sampling rate of 32 Hz. Tracking accuracy, indexed by root mean square error (RMSE), was calculated for the repeated pattern of movement in each trial. The mean RMSE was computed for each block of learning and the retention test.
Electroencephalographic activity was recorded throughout the retention test and in a 1-min standing baseline that immediately preceded the test. Activity was recorded from seven scalp locations (Fp1, Fp2, T3, T4, Fz, Cz, Pz) referenced to linked earlobes using a stretchable electrode cap (ElectroCap Inc., Eaton, OH, USA) in accordance with the standard international 10–20 system [36]. The ground electrode was located at the mid forehead. The EEG was recorded and stored (bandpass filter, 1–45 Hz; notch filter, 50 Hz; sample rate, 1,000 Hz) using a NeuroTop EEG system (Symtop Instruments, Beijing, People’s Republic of China). Before each measurement, an impedance test ensured a sufficient signal-to-noise ratio. The EEG data for the 12 s of the repeated movement pattern were extracted for processing and analysis.
Electroencephalographic artifacts caused by eye blinks were removed by independent component analysis (ICA [37]). An experienced EEG technician visually inspected the recordings and removed any other potential biologic artifacts (e.g., muscle activation or glosso-kinetic artifacts). Artifacts were distinguished from cortical activity according to the duration, morphology, and rate of firing. A Hamming window (1,024 sample and 50% overlap) then was applied to the data in preparation for coherence analysis.
Neural efficiency in visuomotor tasks is characterized by reduced T3-Fz but not T4-Fz alpha band coherence [14, 17]. Therefore, T3-Fz and T4-Fz coherences were calculated in 0.49-Hz frequency bins and averaged across the alpha frequency bandwidth (8–12 Hz) [14, 17]. Both coherence estimates were subjected to a Fisher’s z transformation before analysis to ensure normal distribution. The processing and analysis steps described earlier were implemented with the EEGLAB toolbox [37] and custom scripts in MATLAB (MathWorks, Natick, MA, USA). Figure 2 provides a schematic of the cortical sites subjected to coherence analysis.
Results
Laparoscopic task performance
To determine whether the implicit and explicit training interventions resulted in improved movement accuracy (RMSE), a group × block (2 × 8) analysis of variance (ANOVA) with repeated measures on the latter factor was performed. A main effect of block was evident (F = 14.156, df = 7.112; P < 0.001; η 2 = 0.469), with mean RMSE decreasing for both conditions during training. No group × block interaction was evident (F = 0.459; df = 7.112; P = 0.862; η 2 = 0.028), but there was a main effect of group (F = 5.180; df = 1.16; P = 0.037; η 2 = 0.245).
The mean RMSE tended to be lower for the explicit motor learning condition than for the implicit motor learning condition during training. However, this difference was not present during the retention test (t = 1.245; df = 16; P = 0.231) (Fig. 3).
EEG coherence
To determine whether implicit and explicit training resulted in different levels of neural coactivation between the verbal-analytic (T3) and motor planning (Fz) regions (T3-Fz coherence) and between the visuospatial (T4) and motor planning (Fz) regions (T4-Fz coherence), separate one-way analyses of covariance (ANCOVA) were computed using standing baseline coherence as the covariate. The analyses showed a significant difference in T3-Fz coherence scores during the retention test (F = 5.984; df = 1.15; P = 0.027; η 2 = 0.285) but no difference in T4-Fz coherence scores (F = 0.023; df = 1.15; P = 0.882; η 2 = 0.002). As illustrated in Fig. 4, T3-Fz coherence was lower for the participants in the implicit condition than for the participants in the explicit condition, suggesting that verbal-analytic involvement in performance of the repeated movement pattern was reduced by implicit motor learning.
Discussion
This study aimed to further our understanding of how different motor learning paradigms have an impact on the neural architecture, underpinning laparoscopic performance. Specifically, we examined whether implicit motor learning promotes more efficient deployment of neural resources, as quantified by EEG coherence. We predicted that implicit motor learning would limit verbal-analytic involvement in performance of the laparoscopy task, thereby reducing nonessential alpha bandwidth coactivation of the left temporal region responsible for verbal-cognitive processing (T3) and the frontal midline premotor region of the cortex involved in movement planning (Fz) [14, 38].
Movement accuracy improved in both training conditions, although accuracy in the implicit motor learning condition was generally lower than in the explicit motor learning condition during training. This difference was not present in the retention test (Fig. 3), suggesting that with respect to movement accuracy at least, the training interventions were equally effective for the laparoscopy task. Informing participants that there was a repeating segment (explicit condition) appears to have benefited performance but not learning. This phenomenon is not uncommon in the motor learning literature, in which benefits of one form of practice over another are seen in training but not in retention tests (e.g., see guided learning vs trial-and-error learning [39]; blocked practice vs random practice [40]).
Regardless, our analysis of the neural activity underpinning performance suggests that the training interventions culminated in different levels of neural efficiency. Consistent with our predictions, EEG alpha bandwidth T3-Fz coherence was lower for the implicit motor learning condition than for the explicit motor learning condition during the retention test, implying that implicit motor learners used less verbal-analytic control to support motor performance than explicit motor learners. No differences were evident for EEG T4-Fz coherence, however, suggesting that visuospatial processing was essential for performance of the task and thus was little reduced by training. The same argument has been made for other visuomotor tasks [16–18].
Taken together, our data suggest that implicit motor learning allowed learners to achieve the same level of technical proficiency as explicit motor learning but with greater neural efficiency. Our findings are consistent with functional Magnetic Resonance Imaging (fMRI) studies showing that repetition of a motor task (practice) results in adaptations of neural activation that do not match accompanying improvements in the speed or accuracy of motor performance [41].
Proficiency levels for standardized laparoscopy tasks are extrapolated from the performance of highly experienced surgeons. Trainees generally reach proficiency levels on the standardized tasks within as few as 6–80 repetitions [42, 43] but fall short of the “true” expertise of the master surgeon. For example, contemporary research has identified multitasking as a key surgical stressor, demonstrating that the technical proficiency of inexperienced surgeons (let alone trainees [28]) is disrupted when verbal-analytic resources are demanded by concurrent tasks [44–46]. The main advantage of implicit motor learning, therefore, is not that novices will be quicker to attain movement proficiency, but rather that greater neural efficiency (i.e., more expert-like mapping of neural resources to task demands) allows them to deploy resources more easily to other nontechnical aspects of surgical performance. Indeed, preliminary research has shown that implicit motor learning interventions facilitate effective multitasking during the completion of a surgical knot-tying procedure [47].
The EEG technique clearly offers many benefits for researchers seeking to examine the neural substrate underpinning surgical performance and learning. It has excellent temporal resolution; it is relatively cheap and unobtrusive (compared with fMRI or positron emission topography); and its utility is supported by decades of research in other dynamic visuomotor task environments [8–10, 14]. However, research adopting a variety of methods and protocols (e.g., functional near-infrared spectroscopy [2]) is needed if we are to support surgical training fully with objective data based on changes in cortical activation. Nevertheless, our findings provide support for the efficacy of implicit motor learning in laparoscopy training. Reduced verbal-analytic involvement in movement seems likely to promote neural efficiency during performance, freeing up resources to deal with other nontechnical aspects of surgical performance when they arise.
Notes
Manipulation checks at the end of the experiment showed that no participant in the implicit condition was aware of the repeating segment.
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Acknowledgments
Dr. Jon Maxwell passed away on Sunday, 25 January 2009, during the preparation of this study. Jonny Max inspired us and challenged our thinking always. We were privileged to have the opportunity to work with him. This work was supported by a bilateral research grant from the Economic and Social Research Council, UK, and the Research Grants Council, Hong Kong (RES-000-22-3016), awarded to the third and last authors. Dr Wilson’s involvement was facilitated by a 6-month fellowship in Hong Kong funded by the Department of Business, Innovation and Skills, UK.
Disclosures
Frank F. Zhu, Jamie M. Poolton, Mark R. Wilson, Yong Hu, Jon P. Maxwell, and Rich S. W. Masters have no conflicts of interest or financial ties to disclose.
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Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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Zhu, F.F., Poolton, J.M., Wilson, M.R. et al. Implicit motor learning promotes neural efficiency during laparoscopy. Surg Endosc 25, 2950–2955 (2011). https://doi.org/10.1007/s00464-011-1647-8
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DOI: https://doi.org/10.1007/s00464-011-1647-8