TaggedAPTARAEnd244                                                                             X.R. Tan et al.
         TaggedAPTARAListItemTaggedAPTARAListLabel40TaggedAPTARAEnd. Dai TH, Liu JZ, Sahgal V, Brown RW, Yue GH. Relationship between  TaggedAPTARAListItemTaggedAPTARAListLabel52TaggedAPTARAEnd. Flouris AD. Functional architecture of behavioural thermoregulation. Eur
            muscle output and functional MRI-measured brain activation. Exp Brain  J Appl Physiol 2011;111:1–8TaggedAPTARAEnd.
            Res 2001;140:290–300TaggedAPTARAEnd.               TaggedAPTARAListItemTaggedAPTARAListLabel53TaggedAPTARAEnd. Chan RC, Shum D, Toulopoulou T, Chen EY. Assessment of executive
         TaggedAPTARAListItemTaggedAPTARAListLabel41TaggedAPTARAEnd. Jiang T, Wu W, Wang X, Weng C, Wang Q, Guo Y. Activation of brain  functions: Review of instruments and identification of critical issues. Arch
            areas following ankle dorsiflexion versus plantar flexion: Functional  Clin Neuropsychol 2008;23:201–16TaggedAPTARAEnd.
            magnetic resonance imaging verification. Neural Regen Res 2012;7:501–5TaggedAPTARAEnd.  TaggedAPTARAListItemTaggedAPTARAListLabel54TaggedAPTARAEnd. Bennett AF. Thermal dependence of muscle function. Am J Physiol
         TaggedAPTARAListItemTaggedAPTARAListLabel42TaggedAPTARAEnd. Iacoboni M. Visuo-motor integration and control in the human posterior  1984;247:R217–29TaggedAPTARAEnd.
            parietal cortex: Evidence from TMS and fMRI. Neuropsychologia  TaggedAPTARAListItemTaggedAPTARAListLabel55TaggedAPTARAEnd. Tomporowski PD. Effects of acute bouts of exercise on cognition. Acta
            2006;44:2691–9TaggedAPTARAEnd.                        Psychol (Amst) 2003;112:297–324TaggedAPTARAEnd.
         TaggedAPTARAListItemTaggedAPTARAListLabel43TaggedAPTARAEnd. Solopchuk O, Alamia A, Z enon A. The role of the dorsal premotor cortex  TaggedAPTARAListItemTaggedAPTARAListLabel56TaggedAPTARAEnd. Shibasaki M, Namba M, Oshiro M, Kakigi R, Nakata H. Suppression
            in skilled action sequences. J Neurosci 2016;36:6599–601TaggedAPTARAEnd.  of cognitive function in hyperthermia; from the viewpoint of executive
         TaggedAPTARAListItemTaggedAPTARAListLabel44TaggedAPTARAEnd. Martino J, Gabarr os A, Deus J, et al. Intrasurgical mapping of complex motor  and inhibitive cognitive processing. Sci Rep 2017;7:43528. doi:10.1038/
            function in the superior frontal gyrus. Neuroscience 2011;179:131–42TaggedAPTARAEnd.  srep43528TaggedAPTARAEnd.
         TaggedAPTARAListItemTaggedAPTARAListLabel45TaggedAPTARAEnd. Robertson CV, Marino FE. A role for the prefrontal cortex in exercise  TaggedAPTARAListItemTaggedAPTARAListLabel57TaggedAPTARAEnd. Parris BA, Wadsley MG, Hasshim N, Benattayallah A, Augustinova M,
            tolerance and termination. J Appl Physiol (1985) 2016;120:464–6TaggedAPTARAEnd.  Ferrand L. An fMRI study of response and semantic conflict in the Stroop
         TaggedAPTARAListItemTaggedAPTARAListLabel46TaggedAPTARAEnd. Kiyatkin EA, Brown PL, Wise RA. Brain temperature fluctuation: A  task. Front Psychol 2019;10:2426. doi:10.3389/fpsyg.2019.02426TaggedAPTARAEnd.
            reflection of functional neural activation. Eur J Neurosci 2002;16:164–8TaggedAPTARAEnd.  TaggedAPTARAListItemTaggedAPTARAListLabel58TaggedAPTARAEnd. Song Y, Hakoda Y. An fMRI study of the functional mechanisms of
         TaggedAPTARAListItemTaggedAPTARAListLabel47TaggedAPTARAEnd. Yang M, Li Z, Zhao Y, et al. Outcome and risk factors associated with  Stroop/reverse-Stroop effects. Behav Brain Res 2015;290:187–96TaggedAPTARAEnd.
            extent of central nervous system injury due to exertional heat stroke. Medi-  TaggedAPTARAListItemTaggedAPTARAListLabel59TaggedAPTARAEnd. Tanaka M, Sadato N, Okada T, et al. Reduced responsiveness is an essen-
            cine (Baltimore) 2017;96:e8417. doi:10.1097/MD.0000000000008417TaggedAPTARAEnd.  tial feature of chronic fatigue syndrome: A fMRI study. BMC Neurol
         TaggedAPTARAListItemTaggedAPTARAListLabel48TaggedAPTARAEnd. Nybo L, Nielsen B. Middle cerebral artery blood velocity is reduced with  2006;6:9. doi:10.1186/1471-2377-6-9TaggedAPTARAEnd.
            hyperthermia during prolonged exercise in humans. J Physiol 2001;  TaggedAPTARAListItemTaggedAPTARAListLabel60TaggedAPTARAEnd. Xin J, Zhang Y, Tang Y, Yang Y. Brain differences between men and
            534:279–86TaggedAPTARAEnd.                            women: Evidence from deep learning. Front Neurosci 2019;13:185.
         TaggedAPTARAListItemTaggedAPTARAListLabel49TaggedAPTARAEnd. Nybo L, Møller K, Volianitis S, Nielsen B, Secher NH. Effects of hyper-  doi:10.3389/fnins.2019.00185TaggedAPTARAEnd.
            thermia on cerebral blood flow and metabolism during prolonged exercise  TaggedAPTARAListItemTaggedAPTARAListLabel61TaggedAPTARAEnd. Cosgrove KP, Mazure CM, Staley JK. Evolving knowledge of sex
            in humans. J Appl Physiol (1985) 2002;93:58–64TaggedAPTARAEnd.  differences in brain structure, function, and chemistry. Biol Psychiatry
         TaggedAPTARAListItemTaggedAPTARAListLabel50TaggedAPTARAEnd. Lassen NA, Christensen MS. Physiology of cerebral blood flow. Br J  2007;62:847–55TaggedAPTARAEnd.
            Anaesth 1976;48:719–34TaggedAPTARAEnd.             TaggedAPTARAListItemTaggedAPTARAListLabel62TaggedAPTARAEnd. Morren G, Wolf M, Lemmerling P, et al. Detection of fast neuronal
         TaggedAPTARAListItemTaggedAPTARAListLabel51TaggedAPTARAEnd. Nelson MD, Haykowsky MJ, Stickland MK, et al. Reductions in cerebral  signals in the motor cortex from functional near infrared spectroscopy
            blood flow during passive heat stress in humans: Partitioning the mecha-  measurements using independent component analysis. Med Biol Eng
            nisms. J Physiol 2011;589:4053–64TaggedAPTARAEnd.     Comput 2004;42:92–9TaggedAPTARAEnd.