Abstract
Neutral buoyancy facilities are used to prepare astronauts and cosmonauts for extra vehicular activities e.g. on-board of the International Space Station. While previous studies indicated a decrease in cognitive performance in an under water setting, they have only provided behavioural data. This study aimed to review whether recording of electro cortical activity by the use of electroencephalography (EEG) is possible in an under water setting and if so, to identify the influence of water immersion at a depth of 4 m on neurocognitive markers. Ten male subjects performed a cognitive choice-reaction times (RT) task that progressed through five levels of increasing difficulty on land and when submerged 4 m under water. N200 latency and amplitude in the occipital and frontal areas were measured, and baseline cortical activity was measured during rest in both conditions. Neither RT nor amplitude or latency of the N200 showed any significant changes between the land and the under water conditions. Also theta, alpha and beta frequencies showed no differences between the two conditions. The data provided in this study demonstrate the possibility of recording EEG even under the extreme conditions of full body water immersion. The lack of cognitive impairment in RT and N200 in the under water condition may be explained by the fact that only experienced divers participated in the study. As a proof of principle, this study generates many new experimental possibilities that will improve our understanding of cognitive processes under water.
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References
Bolender H, Stevenin H, Bessone L, Torres A (2006) Preparing for space. EVA training at the European Astronaut Centre. ESA Bull 128:32–40
Brummer V, Schneider S, Vogt T, Struder H, Carnahan H, Askew CD, Csuhaj R (2011) Coherence between brain cortical function and neurocognitive performance during changed gravity conditions. J Vis Exp (51), pii 2670. doi:10.3791/2670
Ceballos NA, Giuliano RJ, Wicha NY, Graham R (2012) Acute stress and event-related potential correlates of attention to alcohol images in social drinkers. J Stud Alcohol Drugs 73:761–771
Dalecki M, Bock O, Schulze B (2012) Cognitive impairment during 5 m water immersion. J Appl Physiol (1985) 113:1075–1081
Dalecki M, Bock O, Hoffmann U (2013) Inverse relationship between task complexity and performance deficit in 5 m water immersion. Exp Brain Res 227:243–248
Ellemberg D, Lavoie K, Lewis TL, Maurer D, Lepore F, Guillemot JP (2003) Longer VEP latencies and slower reaction times to the onset of second-order motion than to the onset of first-order motion. Vision Res 43:651–658
Folstein JR, Van Petten C (2008) Influence of cognitive control and mismatch on the N2 component of the ERP: a review. Psychophysiology 45:152–170
Katuntsev VP, Osipov YY, Barer AS, Gnoevaya NK, Tarasenkov GG (2004) The main results of EVA medical support on the Mir Space Station. Acta Astronaut 54:577–583
Kuba M, Kubova Z, Kremlacek J, Langrova J (2007) Motion-onset VEPs: characteristics, methods, and diagnostic use. Vis Res 47:189–202
Ross HE (1970) Adaption of divers to curvature distortion under water. Ergonomics 13(4):489–499
Schneider S, Brummer V, Carnahan H, Dubrowski A, Askew CD, Struder HK (2008) What happens to the brain in weightlessness? A first approach by EEG tomography. Neuroimage 42:1316–1323
Schneider S, Rouffet DM, Billaut F, Struder HK (2013) Cortical current density oscillations in the motor cortex are correlated with muscular activity during pedaling exercise. Neuroscience 228:309–314
Wendel K, Narra NG, Hannula M, Kauppinen P, Malmivuo J (2008) The influence of CSF on EEG sensitivity distributions of multilayered head models. IEEE Trans Biomed Eng 55:1454–1456
York DH, Pulliam MW, Rosenfeld JG, Watts C (1981) Relationship between visual evoked potentials and intracranial pressure. J Neurosurg 55:909–916
Acknowledgments
We would like to thank two unknown reviewers for their valuable input. Our thank goes also to all participants spending their time to contribute to this study. This study was made possible by a grant from German Space Agency (DLR): 50WB1161.
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Schneider, S., Cheung, J.J.H., Frick, H. et al. When neuroscience gets wet and hardcore: neurocognitive markers obtained during whole body water immersion. Exp Brain Res 232, 3325–3331 (2014). https://doi.org/10.1007/s00221-014-4019-5
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DOI: https://doi.org/10.1007/s00221-014-4019-5