This study introduces a virtual life-sized perceptual-cognitive training paradigm that combines three-dimensional multiple object tracking (3D-MOT) with motor (Experiment 1) or perceptual (Experiment 2) sport decision-making tasks. We sought to assess the impact of training on task performance and determine optimal training conditions for improvement and learning. Fifty-seven participants were randomly assigned to one of four training conditions (isolated 3D-MOT, 3D-MOT combined with a decision-making task, consolidated 3D-MOT later combined with a decision-making task, and isolated decision-making task). We evaluated task performance using speed thresholds, success rate (%), and reaction time (s). Findings were that the dual-task paradigm was associated with performance beyond chance level on both 3D-MOT and decision-making tasks despite an important dual-task cost. Interestingly, the results seemed to favor consolidated 3D-MOT training over simultaneous 3D-MOT training when combined with a motor decision-making task but not when combined with a perceptual decision-making task. The number of shared attentional resources in the nature of the additional task (i.e., perceptual or motor decision-making) seems to be key in interpreting the dual-task interference. These findings must be considered when designing representative multitask perceptual-cognitive training.
AbernethyB.ParkerS. (1989) Perceiving joint kinematics and segment interactions as a basis for skilled anticipation in squash. In: GiamC. K.ChookK. K.TehK. C. (eds) Proceedings of the 7th World Congress in Sport Psychology, Singapore: International Society of Sport Psychology, pp. 56–58.
2.
AllenR.McGeorgeP.PearsonD. G.MilneA. (2006) Multiple-target tracking: A role for working memory?Quarterly Journal of Experimental Psychology59: 1101–1116.
3.
AlvarezG. A.HorowitzT. S.ArsenioH. C.DimaseJ. S.WolfeJ. M. (2005) Do multielement visual tracking and visual search draw continuously on the same visual attention resources?Journal of Experimental Psychology: Human Perception and Performance31: 643–667.
4.
AlvesH.VossM. W.BootW. R.DeslandesA.CossichV.SallesJ. I.KramerA. F. (2013) Perceptual-cognitive expertise in elite volleyball players. Frontiers in Psychology4: 36.
5.
ArrighiR.LunardiR.BurrD. (2011) Vision and audition do not share attentional resources in sustained tasks. Frontiers in Psychology2: 56.
6.
BhererL.KramerA. F.PetersonM. S.ColcombeS.EricksonK.BecicE. (2008) Transfer effects in task-set cost and dual-task cost after dual-task training in older and younger adults: Further evidence for cognitive plasticity in attentional control in late adulthood. Experimental Aging Research34: 188–219.
7.
BideauB.KulpaR.VignaisN.BraultS.MultonF.CraigC. (2010) Using virtual reality to analyze sports performance. IEEE Computer Graphics and Applications30: 14–21.
8.
BroadbentD. P.CauserJ.WilliamsA. M.FordP. R. (2015) Perceptual-cognitive skill training and its transfer to expert performance in the field: Future research directions. European Journal of Sport Science15: 322–331.
9.
Canal-BrulandR.MannD. L. (2015) Time to broaden the scope of research on anticipatory behavior: A case for the role of probabilistic information. Frontiers in Psychology6: 1518.
10.
ChaddockL.NeiderM. B.VossM. W.GasparJ. G.KramerA. F. (2011) Do athletes excel at everyday tasks?Medicine & Science in Sports & Exercise43: 1920–1926.
11.
CulhamJ. C.BrandtS. A.CavanaghP.KanwisherN. G.DaleA. M.TootellR. B. (1998) Cortical fMRI activation produced by attentive tracking of moving targets. Journal of Neurophysiology80: 2657–2670.
12.
de OliveiraR. F.LobingerB. H.RaabM. (2014) An adaptive toolbox approach to the route to expertise in sport. Frontiers in Psychology5: 709.
13.
EricksonK. I.ColcombeS. J.WadhwaR.BhererL.PetersonM. S.ScalfP. E.KramerA. F. (2007) Training-induced functional activation changes in dual-task processing: An FMRI study. Cerebral Cortex17: 192–204.
14.
FaubertJ. (2013) Professional athletes have extraordinary skills for rapidly learning complex and neutral dynamic visual scenes. Scientific Reports3: 1154.
15.
FaubertJ.SidebottomL. (2012) Perceptual-cognitive training of athletes. Journal of Clinical Sports Psychology6: 85–102.
16.
GabbettT.WakeM.AbernethyB. (2011) Use of dual-task methodology for skill assessment and development: Examples from rugby league. Journal of Sports Sciences29: 7–18.
17.
HarenbergS.McCaffreyR.ButzM.PostD.HowlettJ.DorschK. D.LysterK. (2016) Can multiple object tracking predict laparoscopic surgical skills?Journal of Surgical Education73: 386–390.
18.
Hoke, J., Reuter, C., Romeas, T., & Mantariol, M. (2017, Nov–Dec). Perceptual-cognitive and physiological assessment of training effectiveness. In Proceedings of the Interservice/Industry Training, Simulation and Education Conference, Orlando, FL.
19.
HoweP. D.HorowitzT. S.MoroczI. A.WolfeJ.LivingstoneM. S. (2009) Using fMRI to distinguish components of the multiple object tracking task. Journal of Vision9: 10.1–10.11.
20.
JohanssonG. (1973) Visual perception of biological motion and a model for its analysis. Attention, Perception, & Psychophysics14: 201–211.
21.
LandM. F.McLeodP. (2000) From eye movements to actions: How batsmen hit the ball. Nature Neuroscience3: 1340–1345.
22.
LapierreM. D.CropperS. J.HoweP. D. L. (2017) Shared processing in multiple object tracking and visual working memory in the absence of response order and task order confounds. PLoS One12: e0175736.
23.
LauferY. (2008) Effect of cognitive demand during training on acquisition, retention and transfer of a postural skill. Human Movement Science27: 126–141.
24.
LegaultI.AllardR.FaubertJ. (2013) Healthy older observers show equivalent perceptual-cognitive training benefits to young adults for multiple object tracking. Frontiers in Psychology4: 323.
25.
LegaultI.FaubertJ. (2012) Perceptual-cognitive training improves biological motion perception: Evidence for transferability of training in healthy aging. Neuroreport23: 469–473.
26.
LevittH. (1971) Transformed up-down methods in psychoacoustics. The Journal of the Acoustical Society of America49(Suppl 2): 467.
27.
MangineG. T.HoffmanJ. R.WellsA. J.GonzalezA. M.RogowskiJ. P.TownsendJ. R.StoutJ. R. (2014) Visual tracking speed is related to basketball-specific measures of performance in NBA players. The Journal of Strength & Conditioning Research28: 2406–2414.
28.
MemmertD. (2009) Pay attention! A review of visual attentional expertise in sport. International Review of Sport and Exercise Psychology2: 119–138.
29.
MichaelsJ.ChaumillonR.Nguyen-TriD.WatanabeD.HirschP.BellavanceF.FaubertJ. (2017) Driving simulator scenarios and measures to faithfully evaluate risky driving behavior: A comparative study of different driver age groups. PLoS One12: e0185909.
30.
OberauerK.KlieglR. (2004) Simultaneous cognitive operations in working memory after dual-task practice. Journal of Experimental Psychology: Human Perception and Performance30: 689–707.
31.
OramM. W.PerrettD. I. (1994) Responses of anterior superior temporal polysensory (STPa) neurons to “biological motion” stimuli. Journal of Cognitive Neuroscience6: 99–116.
32.
ParsonsB.MagillT.BoucherA.ZhangM.ZogboK.BérubéS.FaubertJ. (2016) Enhancing cognitive function using perceptual-cognitive training. Clinical EEG and Neuroscience47: 37–47.
33.
Pothier, K., Benguigui, N., Kulpa, R., & Chavoix, C. (2015). Multiple Object Tracking While Walking: Similarities and Differences Between Young, Young-Old, and Old-Old Adults. The Journals of Gerontology Series B: Psychological Sciences and Social Sciences, 70, 840–849.
34.
PtitoM.FaubertJ.GjeddeA.KupersR. (2003) Separate neural pathways for contour and biological-motion cues in motion-defined animal shapes. NeuroImage19: 246–252.
35.
QuevedoL.BlázquezA. P.Solé i FortóJ.Cardona TorradeflotG. (2015) Perceptual-cognitive training with the Neurotracker 3D-MOT to improve performance in three different sports. Educació Física i Esports119: 97–108.
36.
RomeasT.FaubertJ. (2015) Soccer athletes are superior to non-athletes at perceiving soccer-specific and non-sport specific human biological motion. Frontiers in Psychology6: 1343.
37.
RomeasT.GuldnerA.FaubertJ. (2016) 3D-Multiple object tracking training task improves passing decision-making accuracy in soccer players. Psychology of Sport and Exercise22: ,1–9.
38.
ThomasL.SeiffertA. (2011) How many objects are you worth? Quantification of the self-motion load on multiple object tracking. Frontiers in Psychology2: 245.
39.
TulloD.GuyJ.FaubertJ.BertoneA. (2018) Training with a three-dimensional multiple object-tracking (3D-MOT) paradigm improves attention in students with a neurodevelopmental condition: A randomized controlled trial. Developmental Science21: e12670.
40.
VainaL. M.SolomonJ.ChowdhuryS.SinhaP.BelliveauJ. W. (2001) Functional neuroanatomy of biological motion perception in humans. Proceedings of the National Academy of Sciences of the United States of America98: 11656–11661.
41.
VartanianO.CoadyL.BlacklerK. (2016) 3D multiple object tracking boosts working memory span: Implications for cognitive training in military populations. Military Psychology28: 353–360.
42.
WahnB.KonigP. (2016) Attentional resource allocation in visuotactile processing depends on the task, but optimal visuotactile integration does not depend on attentional resources. Frontiers in Integrative Neuroscience10: 13.
43.
WahnB.KönigP. (2017) Is attentional resource allocation across sensory modalities task-dependent?Advances in Cognitive Psychology13: 83–96.
44.
WardP.WilliamsA. M.BennettS. J. (2002) Visual search and biological motion perception in tennis. Research Quarterly for Exercise and Sport73: 107–112.
45.
WrightM. J.BishopD. T.JacksonR. C.AbernethyB. (2011) Cortical fMRI activation to opponents’ body kinematics in sport-related anticipation: Expert-novice differences with normal and point-light video. Neuroscience Letters500: 216–221.
46.
ZhangH.XuanY. M.FuX. L.PylyshynZ. W. (2010) Do objects in working memory compete with objects in perception?Visual Cognition18: 617–640.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
