全部 标题 作者
关键词 摘要

OALib Journal期刊
ISSN: 2333-9721
费用:99美元
投递稿件

查看量下载量

相关文章

更多...
PLOS ONE  2014 

Intersegmental Eye-Head-Body Interactions during Complex Whole Body Movements

DOI: 10.1371/journal.pone.0095450

Full-Text   Cite this paper   Add to My Lib

Abstract:

Using state-of-the-art technology, interactions of eye, head and intersegmental body movements were analyzed for the first time during multiple twisting somersaults of high-level gymnasts. With this aim, we used a unique combination of a 16-channel infrared kinemetric system; a three-dimensional video kinemetric system; wireless electromyography; and a specialized wireless sport-video-oculography system, which was able to capture and calculate precise oculomotor data under conditions of rapid multiaxial acceleration. All data were synchronized and integrated in a multimodal software tool for three-dimensional analysis. During specific phases of the recorded movements, a previously unknown eye-head-body interaction was observed. The phenomenon was marked by a prolonged and complete suppression of gaze-stabilizing eye movements, in favor of a tight coupling with the head, spine and joint movements of the gymnasts. Potential reasons for these observations are discussed with regard to earlier findings and integrated within a functional model.

 References

[1]  Becker W, Fuchs AF (1985) Prediction in the oculomotor system: smooth pursuit during transient disappearance of a visual target. Exp Brain Res 57: 562–575.
[2]  Carl J, Gellmann R (1987) Human smooth pursuit: stimulus-dependent responses. J Neurophysiol 57: 1446–1463.
[3]  Gauthier G, Hofferer JM (1976) Eye tracking of self moved targets in the absence of vision. Exp Brain Res 26: 121–139.
[4]  Kelders WP, Kleinrensink GJ, van der Geest JN, Feenstra L, de Zeeuw CI, Frens MA (2003) Compensatory increase of the cervico-ocular reflex with age in healthy humans. J Physiol 553: 311–317.
[5]  Barnes GR, Forbat LN (1979) Cervical and vestibular afferent control of oculomotor response in man. Acta Otolaryngol (Stockh) 88: 79–87.
[6]  Barlow D, Freedman W (1980) Cervico-ocular reflex in the normal adult. Acta Otolaryngol 89 ((5–6)) 487–496.
[7]  Mergner T, Schweigart G, Botti F, Lehmann A (1998) Eye movements evoked by proprioceptive stimulation along the body axis in humans. Exp Brain Res 120: 450–460.
[8]  Warabi T (1978) Trunk-ocular reflex in man. Neurosci Lett 9 ((2–3)) 267–270.
[9]  Bronstein AM, Mossman S, Luxon LM (1991) The neck-eye reflex in patients with reduced vestibular and optokinetic function. Brain 114: 1–11.
[10]  Kasai T, Zee DS (1978) Eye-head coordination in labyrinthine-defective human beings. Brain Res 144: 123–141.
[11]  Lackner JR, DiZio P (1984) Some efferent and somatosensory influences on body orientation and oculomotor control. In: Spillmann L, Wooten BR, editors. Sensory Experience, Adaptation and Perception. Hillsdale, NJ: Erlbaum; pp: 281–301.
[12]  Brandt TW, Büchele FA, Arnold F (1977) Arthrokinetic nystagmus and ego-motion sensation. Exp Brain Res 30: 331–338.
[13]  Bizzi E (1981) Eye-head coordination. In: Brooks VB, editor. Handbook of Physiology. The Nervous System. Section 1, Volume 2, Part 2. Bethesda MD: American Physiological Society, pp. 1321–1336.
[14]  Tweed DB, Haslwanter T (1998) Optimizing gaze control in three dimensions. Science 281 ((5381)) 1363–1366.
[15]  Zupan LH, Merfeld DM (2005) An internal model of head kinematics predicts the influence of head orientation on reflexive eye movements. J Neural Eng 2 ((3)) 180–197.
[16]  Hollands MA, Ziavra NV, Bronstein AM (2004) A new paradigm to investigate the roles of head and eye movements in the coordination of whole-body movements. Exp Brain Res 154: 261–266.
[17]  Anastasopoulos D, Ziavra NV, Hollands M, Bronstein A (2009) Gaze displacement and inter-segmental coordination during large whole body voluntary rotations. Exp Brain Res 193: 323–336.
[18]  Vickers JN (2007) Perception, Cognition and Decision Training. The Quiet Eye in Action. Human Kinetics, Champaign, IL.
[19]  Land MF, McLeod P (2000) From eye movements to actions: how batsmen hit the ball. Nat Neurosci 3: 1340–1345.
[20]  Ahn SC (2003) Short-term vestibular responses to repeated rotations in pilots. Aviat Space Environ Med 74 ((3)): 285–287.
[21]  Lee MY, Kim MS, Park BR (2004) Adaptation of the horizontal vestibulo-ocular reflex in pilots. Laryngoskope 114 ((5)): 897–902.
[22]  Schwarz U, Henn V (1989) Vestibular habituation in student pilots. Aviat Space Environ Med 60 ((8)): 755–761.
[23]  Alpini D, Botta M, Mattei V, Tornese D (2009) Figure ice skating induces vestibulo-ocular adaptation specific to required athletic skills. Sport Sci Health 5 ((3)) 129–134.
[24]  Tanguy S, Quarck G, Etard O, Gauthier A, Denise P (2008) Vestibulo-ocular reflex and motion sickness in figure skaters. Eur J Appl Physiol 104 ((6)) 1031–1037.
[25]  Krug J, von Laβberg C, Muehlbauer T (2002) Load effects of fast longitudinal rotations. In: Gianikellis KE, editor. Proceedings of XXth International Society of Biomechanics in Sports.Cáceres, Spain. ISBS – Conference Proceedings Archive, pp. 535–538.
[26]  von Laβberg C, Mühlbauer T, Krug J (2003) Differences in postrotatory response in differing sports associated rotation requirements. In: Sch?llhorn WI, Bohn C, J?ger JM, Schaper H, Alichmann M, editors. European Workshop on Movement Science: Mechanics - Physiology - Psychology. K?ln, Germany: Verlag Sport und Buch Strauβ, pp. 108–109.
[27]  Baloh RW, Henn V, J?ger J (1982) Habituation of the human vestibulo-ocular reflex with low-frequency harmonic acceleration. Am J Otolaryngol 3 ((4)): 235–241.
[28]  Clement G, Tilikete C, Courjon JH (2008) Retention of habituation of vestibulo-ocular reflex and sensation of rotation in humans. Exp Brain Res 190: 307–315.
[29]  Davlin CD, Sands WA, Shultz BB (2001) The role of vision in control of orientation in a back tuck somersault. Mot Control 5 ((4)) 337–346.
[30]  Heinen T (2011) Evidence for the spotting hypothesis in gymnasts. Mot Control 15 ((2)) 267–284.
[31]  Hondzinski JM, Darling WG (2001) Aerial somersault performance under three visual conditions. Mot Control 5 ((3)) 281–300.
[32]  Lee DN, Young DS, Rewt D (1992) How do somersaulters land on their feet? J Exp Psychol Hum Percept Perform 18 ((4)) 1195–1202.
[33]  Luis M, Tremblay L (2008) Visual feedback use during a back tuck somersault: evidence for optimal visual feedback utilization. Mot Control 12 ((3)) 210–218.
[34]  von Laβberg C, Beykirch K, Campos JL, Krug J (2012) Smooth pursuit eye movement adaptation in high level gymnasts. Mot Control 16 ((2)) 176–194.
[35]  von Laβberg C (2007) Okulomotorische Orientierungsregulation bei multiaxialen Ganzk?rperrotationen (Oculomotor control during multiaxial whole body rotations). K?ln, Germany: Sportverlag Strauβ, pp 192–197.
[36]  von Laβberg C, Reimann M, Krug J (2009) Vismo - a prototype software solution for integration of vestibular, oculomotor, spinalmotor and 3D-kinemetric data in sports. In Loland S, B? K, Fasting K, Hallèn J, Ommundsen Y, et al., eds. Proceedings of the 14th Annual Congress of European College of Sport Science. Oslo, Norway: Norwegian School of Sport Sciences, p. 402.
[37]  Merletti R (1999) Standards for reporting EMG data. J Electromyogr Kines 9 ((1)) III–IV.
[38]  von Laβberg C, Rapp W, Mohler B, Krug J (2013) Neuromuscular Onset Succession of High Level Gymnasts during dynamic Leg Acceleration Phases on High Bar. J Electromyogr Kines 23: 1124–30.
[39]  Leigh RJ, Zee DS (2006) The Neurology of Eye Movements. Oxford University Press, Oxford, New York.
[40]  Kandel ER, Schwartz JH, Jessel TM (2000) Principles of Neural Science, 4th ed. McGraw-Hill, New York.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133