http://research.usc.edu.au/vital/access/manager/Index ${session.getAttribute("locale")} 5 EEG activity and mood in health orientated runners after different exercise intensities http://research.usc.edu.au/vital/access/manager/Repository/usc:4313 18 Hz showed persisting decreases post-exercise we concluded that this might be a sign of outlasting effects of exercise on brain cortical activity which may have influences on general well-being. We could also show that there is a clear relationship between EEG activity and mood reflecting a basic principle of cortical excitation.]]> Wed 27 Nov 2019 14:30:38 AEST ]]> Coherence between brain cortical function and neurocognitive performance during changed gravity conditions http://research.usc.edu.au/vital/access/manager/Repository/usc:10241 Wed 13 May 2015 14:44:38 AEST ]]> What happens to the brain in weightlessness? - A first approach by EEG tomography http://research.usc.edu.au/vital/access/manager/Repository/usc:2365 Mon 25 Jan 2016 14:35:09 AEST ]]> What Happens to the Brain in Weightlessness? - A First Tomographical Approach http://research.usc.edu.au/vital/access/manager/Repository/usc:4712 Fri 27 May 2016 16:37:20 AEST ]]> Stress hormone stability: Processing of blood samples collected during parabolic flight A pre-flight comparison of different protocols http://research.usc.edu.au/vital/access/manager/Repository/usc:1608 Fri 13 Mar 2015 15:15:44 AEST ]]> Alteration of electro-cortical activity in microgravity http://research.usc.edu.au/vital/access/manager/Repository/usc:10176 12Hz during phases of microgravity compared to normal gravity. We conclude that the inhibition of high frequency frontal activity during microgravity may serve as a marker of emotional anxiety and/or indisposition associated with weightlessness. This puts a new light on the debate as to whether cognitive and sensorimotor impairments are attributable to primary physiological effects or secondary psychological effects of a weightless environment.]]> Fri 07 Nov 2014 12:25:30 AEST ]]>