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Age Moderates the Association of Aerobic Exercise with Initial Learning of an Online Task Requiring Cognitive Control

Published online by Cambridge University Press:  19 November 2015

Patrick J. O’Connor*
Affiliation:
Department of Kinesiology, University of Georgia, Athens, Georgia
Phillip D. Tomporowski
Affiliation:
Department of Kinesiology, University of Georgia, Athens, Georgia
Rodney K. Dishman
Affiliation:
Department of Kinesiology, University of Georgia, Athens, Georgia
*
Correspondence and reprint requests to: Patrick O’Connor, Department of Kinesiology, University of Georgia, Athens, GA 30602-6554. E-mail: [email protected]

Abstract

The aim of this study was to examine whether people differed in change in performance across the first five blocks of an online flanker task and whether those trajectories of change were associated with self-reported aerobic or resistance exercise frequency according to age. A total of 8752 men and women aged 13–89 completed a lifestyle survey and five 45-s games (each game was a block of ~46 trials) of an online flanker task. Accuracy of the congruent and incongruent flanker stimuli was analyzed using latent class and growth curve modeling adjusting for time between blocks, whether the blocks occurred on the same or different days, education, smoking, sleep, caffeinated coffee and tea use, and Lumosity training status (“free play” or part of a “daily brain workout”). Aerobic and resistance exercise were unrelated to first block accuracies. For the more cognitively demanding incongruent flanker stimuli, aerobic activity was positively related to the linear increase in accuracy [B=0.577%, 95% confidence interval (CI), 0.112 to 1.25 per day above the weekly mean of 2.8 days] and inversely related to the quadratic deceleration of accuracy gains (B=−0.619% CI, −1.117 to −0.121 per day). An interaction of aerobic activity with age indicated that active participants younger than age 45 had a larger linear increase and a smaller quadratic deceleration compared to other participants. Age moderates the association between self-reported aerobic, but not self-reported resistance, exercise and changes in cognitive control that occur with practice during incongruent presentations across five blocks of a 45-s online, flanker task. (JINS, 2015, 21, 802–815)

Type
Research Article
Copyright
Copyright © The International Neuropsychological Society 2015 

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References

Agaku, I.T., King, B.A., & Dube, S.R. (2014). Current cigarette smoking among adults — United States, 2005–2012. MMWR: Morbidity and Mortality Weekly Report, 63(2), 2946.Google Scholar
Aiken, L.S., & West, S.G. (1991). Multiple regression: Testing and interpreting interactions. Thousand Oaks, CA: Sage.Google Scholar
Angevaren, M., Aufdemkampe, G., Verhaar, H.J.J., Aleman, A., & Vanhees, L. (2008). Physical activity and enhanced fitness to improve cognitive function in older people without known cognitive impairment. Cochrane Database of Systematic Reviews, 3, CD005381.Google Scholar
Anstey, K.J., von Sanden, C., Salim, A., & O’Kearney, R. (2007). Smoking as a risk factor for dementia and cognitive decline: A meta-analysis of prospective studies. American Journal of Epidemiology, 166(4), 367378.Google Scholar
Baddeley, A. (2003). Working memory: Looking back and looking forward. Nature Reviews Neuroscience, 4(10), 829839.Google Scholar
Bauermeister, S., & Bunce, D. (2014). Aerobic fitness and intraindividual reaction time variability in middle and old age. The Journals of Gerontology. Series B, Psychological Sciences and Social Sciences, doi:10.1093/geronb/gbu1152 Google ScholarPubMed
Beydoun, M.A., Gamaldo, A.A., Beydoun, H.A., Tanaka, T., Tucker, K.L., Talegawkar, S.A., & Zonderman, A.B. (2014). Caffeine and alcohol intakes and overall nutrient adequacy are associated with longitudinal cognitive performance among U.S. adults. The Journal of Nutrition, 144(6), 890901. doi:10.3945/jn.3113.189027 Google Scholar
Bherer, L., Erickson, K.I., & Liu-Ambrose, T. (2013). A review of the effects of physical activity and exercise on cognitive and brain functions in older adults. Journal of Aging Research, 2013, 657508.Google Scholar
Birnbaum, M.H. (2004). Human research and data collection via the internet. Annual Review of Psychology, 55(1), 803832.Google Scholar
Bollen, K.A., & Curran, P.J. (2006). Latent curve models. New York, NY: John Wiley & Sons, Inc.Google Scholar
Boraud, T., Bezard, E., Bioulac, B., & Gross, C.E. (2002). From single extracellular unit recording in experimental and human parkinsonism to the development of a functional concept of the role played by the basal ganglia in motor control. Progress in Neurobiology, 66(4), 265283.Google Scholar
Botvinick, M., & Braver, T. (2015). Motivation and cognitive control: From behavior to neural mechanism. Annual Review of Psychology, 66(1), 83113.Google Scholar
Botvinick, M.M., Braver, T.S., Barch, D.M., Carter, C.S., & Cohen, J.D. (2001). Conflict monitoring and cognitive control. Psychological Review, 108(3), 624652.Google Scholar
Britton, A., Singh-Manoux, A., & Marmot, M. (2004). Alcohol consumption and cognitive function in the Whitehall II study. American Journal of Epidemiology, 160(3), 240247.CrossRefGoogle ScholarPubMed
Brown, A.D., McMorris, C.A., Longman, R.S., Leigh, R., Hill, M.D., Friedenreich, C.M., & Poulin, M.J. (2010). Effects of cardiorespiratory fitness and cerebral blood flow on cognitive outcomes in older women. Neurobiology of Aging, 31(12), 20472057.Google Scholar
Brunyé, T.T., Mahoney, C.R., Lieberman, H.R., & Taylor, H.A. (2010). Caffeine modulates attention network function. Brain and Cognition, 72(2), 181188.CrossRefGoogle ScholarPubMed
Busse, A.L., Filho, W.J., Magaldi, R.M., Coelho, V.A., Melo, A.C., Betoni, R.A., &Santarem, J.M. (2008). Effects of resistance training exercise on cognitive performance in elderely individuals with memory impairment: Results of a controlled trial. Einstein, 6(4), 402407.Google Scholar
Calamia, M., Markon, K., & Tranel, D. (2012). Scoring higher the second time around: Meta-analyses of practice effects in neuropsychological assessment. The Clinical Neuropsychologist, 26(4), 543570.Google Scholar
Carroll, D.D., Courtney-Long, E.A., Stevens, A.C., Sloan, M.L., Lullo, C., Visser, S.N., & Dorn, J.M. (2014). Vital signs: Disability and physical activity — United States, 2009–2012. MMWR: Morbidity and Mortality Weekly Report, 63(18), 407413.Google Scholar
Cassilhas, R.C., Viana, V.A.R., Grassmann, V., Santos, R.R., Santos, R.F., Tufik, S., &Mello, M.T. (2007). The impact of resistance exercise on the cognitive function of the elderly. Medicine & Science in Sports & Exercise, 39(8), 14011407.CrossRefGoogle ScholarPubMed
Centers for Disease Control. (2013). Adult participation in aerobic and muscle-strengthening physical activities — United States, 2011. MMWR: Morbidity and Mortality Weekly Report, 62(17), 326–330.Google Scholar
Chaddock-Heyman, L., Erickson, K.I., Voss, M.W., Knecht, A.M., Pontifex, M.B., Castelli, D.M., & Kramer, A.F. (2013). The effects of physical activity on functional mri activation associated with cognitive control in children: A randomized controlled intervention. Frontiers in Human Neuroscience, 7, 7279.Google Scholar
Chaddock, L., Erickson, K.I., Prakash, R.S., Vanpatter, M., Voss, M.W., Pontifex, M.B., & Kramer, A.F. (2010). Basal ganglia volume is associated with aerobic fitness in preadolescent children. Developmental Neuroscience, 32(3), 249256.Google Scholar
Chaddock, L., Erickson, K.I., Prakash, R.S., Voss, M.W., VanPatter, M., Pontifex, M.B., & Kramer, A.F. (2012). A functional mri investigation of the association between childhood aerobic fitness and neurocognitive control. Biological Psychology, 89(1), 260268.Google Scholar
Chodzko-Zajko, W.J. (1991). Physical fitness, cognitive performance, and aging. Medicine & Science in Sports & Exercise, 23(7), 868872.Google Scholar
Churilla, J.R., Magyari, P.M., Ford, E.S., Fitzhugh, E.C., & Johnson, T.M. (2012). Muscular strengthening activity patterns and metabolic health risk among us adults. Journal of Diabetes, 4(1), 7784.Google Scholar
Cohen-Kdoshay, O., & Meiran, N. (2009). The representation of instructions operates like a prepared reflex. Experimental Psychology (formerly Zeitschrift für Experimentelle Psychologie), 56(2), 128133.Google Scholar
Colcombe, S., & Kramer, A.F. (2003). Fitness effects on the cognitive function of older adults: A meta-analytic study. Psychological Science, 14(2), 125130.Google Scholar
Colcombe, S.J., Erickson, K.I., Raz, N., Webb, A.G., Cohen, N.J., McAuley, E., & Kramer, A.F. (2003). Aerobic fitness reduces brain tissue loss in aging humans. The Journals of Gerontology. Series A, Biological Sciences and Medical Sciences, 58(2), M176M180.Google Scholar
Colcombe, S.J., Kramer, A.F., Erickson, K.I., Scalf, P., McAuley, E., Cohen, N.J., & Elavsky, S. (2004). Cardiovascular fitness, cortical plasticity, and aging. Proceedings of the National Academy of Sciences of the United States of America, 101(9), 33163321.Google Scholar
Davis, C.L., & Cooper, S. (2011). Fitness, fatness, cognition, behavior, and academic achievement among overweight children: Do cross-sectional associations correspond to exercise trial outcomes? Preventive Medicine, 52(Suppl. 1), S65S69.Google Scholar
Denckla, M.B. (1996). A theory and model of executive function: A neuropsychological perspective. In G.R. Lyon & N.A. Krasnegor (Eds.), Attention, memory, and executive function (pp. 263278). Baltimore, MD: Paul H Brookes Publishing.Google Scholar
Duff, K., Beglinger, L.J., Moser, D.J., Paulsen, J.S., Schultz, S.K., & Arndt, S. (2010). Predicting cognitive change in older adults: The relative contribution of practice effects. Archives of Clinical Neuropsychology, 25(2), 8188.Google Scholar
Duff, K., Beglinger, L.J., Schultz, S.K., Moser, D.J., McCaffrey, R.J., Haase, R.F., & Paulsen, J.S. (2007). Practice effects in the prediction of long-term cognitive outcome in three patient samples: A novel prognostic index. Archives of Clinical Neuropsychology, 22(1), 1524.Google Scholar
Duff, K., Lyketsos, C.G., Beglinger, L.J., Chelune, G., Moser, D.J., Arndt, S., & McCaffrey, R.J. (2011). Practice effects predict cognitive outcome in amnestic mild cognitive impairment. The American Journal of Geriatric Psychiatry, 19(11), 932939.CrossRefGoogle ScholarPubMed
Elsayed, M., Ismail, A.H., & Young, R.J. (1980). Intellectual differences of adult men related to age and physical fitness before and after an exercise program. Journal of Gerontology, 35(3), 383387.Google Scholar
Enders, C.K., & Bandalos, D.L. (2001). The relative performance of full information maximum likelihood estimation for missing data in structural equation models. Structural Equation Modeling: A Multidisciplinary Journal, 8(3), 430457.CrossRefGoogle Scholar
Erickson, K.I., Milham, M.P., Colcombe, S.J., Kramer, A.F., Banich, M.T., Webb, A., & Cohen, N.J. (2004). Behavioral conflict, anterior cingulate cortex, and experiment duration: Implications of diverging data. Human Brain Mapping, 21(2), 98107.Google Scholar
Erickson, K.I., Prakash, R.S., Voss, M.W., Chaddock, L., Hu, L., Morris, K.S., & Kramer, A.F. (2009). Aerobic fitness is associated with hippocampal volume in elderly humans. Hippocampus, 19(10), 10301039.Google Scholar
Erickson, K.I., Raji, C.A., Lopez, O.L., Becker, J.T., Rosano, C., Newman, A.B., & Kuller, L.H. (2010). Physical activity predicts gray matter volume in late adulthood: The cardiovascular health study. Neurology, 75(16), 14151422.Google Scholar
Erickson, K.I., Voss, M.W., Prakash, R.S., Basak, C., Szabo, A., Chaddock, L., & Kramer, A.F. (2011). Exercise training increases size of hippocampus and improves memory. Proceedings of the National Academy of Sciences of the United States of America, 108(7), 30173022.Google Scholar
Erickson, K.I., Weinstein, A.M., Sutton, B.P., Prakash, R.S., Voss, M.W., Chaddock, L., Szabo, A.N., … Kramer, A.F. (2012). Beyond vascularization: Aerobic fitness is associated with N-acetylaspartate and working memory. Brain and Behavior, 2(1), 3241.Google Scholar
Eriksen, B.A., & Eriksen, C.W. (1974). Effects of noise letters upon the identification of a target letter in a non-search task. Perception and Psychophysics, 16, 143149.Google Scholar
Etnier, J.L., Nowell, P.M., Landers, D.M., & Sibley, B.A. (2006). A meta-regression to examine the relationship between aerobic fitness and cognitive performance. Brain Research Reviews, 52(1), 119130.CrossRefGoogle ScholarPubMed
Fedewa, A.L., & Ahn, S. (2011). The effects of physical activity and physical fitness on children’s achievement and cognitive outcomes. Research Quarterly for Exercise and Sport, 82(3), 521535.Google Scholar
Festl, R., Scharkow, M., & Quandt, T. (2013). Problematic computer game use among adolescents, younger and older adults. Addiction, 108(3), 592599.Google Scholar
Flicker, L., Almeida, O.P., Acres, J., Le, M.T.Q., Tuohy, R.J., Jamrozik, K., & Norman, P. (2005). Predictors of impaired cognitive function in men over the age of 80 years: Results from the health in men study. Age and Ageing, 34(1), 7780.Google Scholar
Fortier-Brochu, É., Beaulieu-Bonneau, S., Ivers, H., & Morin, C.M. (2012). Insomnia and daytime cognitive performance: A meta-analysis. Sleep Medicine Reviews, 16(1), 8394.Google Scholar
Frary, C.D., Johnson, R.K., & Wang, M.Q. (2005). Food sources and intakes of caffeine in the diets of persons in the united states. Journal of the American Dietetic Association, 105(1), 110113.CrossRefGoogle ScholarPubMed
Friedman, N.P., Miyake, A., Young, S.E., DeFries, J.C., Corley, R.P., & Hewitt, J.K. (2008). Individual differences in executive functions are almost entirely genetic in origin. Journal of Experimental Psychology: General, 137(2), 201225.Google Scholar
Geda, Y.E., Roberts, R.O., Knopman, D.S., Christianson, T.J., Pankratz, V.S., Ivnik, R.J., & Rocca, W.A. (2010). Physical exercise, aging, and mild cognitive impairment: A population-based study. Archives of Neurology, 67(1), 8086.Google Scholar
Gorber, S.C., Tremblay, M., Moher, D., & Gorber, B. (2007). A comparison of direct vs. self-report measures for assessing height, weight and body mass index: A systematic review. Obesity Reviews, 8(4), 307326.Google Scholar
Gothe, N.P., Fanning, J., Awick, E., Chung, D., Wójcicki, T.R., Olson, E.A., & McAuley, E. (2014). Executive function processes predict mobility outcomes in older adults. Journal of the American Geriatrics Society, 62(2), 285290.Google Scholar
Granholm, E., Link, P., Fish, S., Kraemer, H., & Jeste, D. (2010). Age-related practice effects across longitudinal neuropsychological assessments in older people with schizophrenia. Neuropsychology, 24(5), 616624.Google Scholar
Hamer, M., & Chida, Y. (2009). Physical activity and risk of neurodegenerative disease: A systematic review of prospective evidence. Psychological Medicine, 39(01), 311.Google Scholar
Haskell, W. (2008). Physical activity guidelines advisory committee report, 2008. Washington, DC: US Department of Health and Human Services.Google Scholar
Herman, H., de Kort, Y.A.W., & Ijsselsteijn, W.A. (2009). Senior gamers: Preferences, motivations and needs. Gerotechnology, 8(4), 247262.Google Scholar
Herting, M.M., & Nagel, B.J. (2012). Aerobic fitness relates to learning on a virtual morris water task and hippocampal volume in adolescents. Behavioural Brain Research, 233(2), 517525.Google Scholar
Hillman, C.H., Belopolsky, A.V., Snook, E.M., Kramer, A.F., & McAuley, E. (2004). Physical activity and executive control: Implications for increased cognitive health during older adulthood. Research Quarterly for Exercise and Sport, 75(2), 176185.CrossRefGoogle ScholarPubMed
Hillman, C.H., Buck, S.M., Themanson, J.R., Pontifex, M.B., & Castelli, D.M. (2009). Aerobic fitness and cognitive development: Event-related brain potential and task performance indices of executive control in preadolescent children. Developmental Psychology, 45(1), 114129.Google Scholar
Hillman, C.H., Castelli, D.M., & Buck, S.M. (2005). Aerobic fitness and neurocognitive function in healthy preadolescent children. Medicine & Science in Sports & Exercise, 37(11), 19671974.Google Scholar
Hillman, C.H., Kramer, A.F., Belopolsky, A.V., & Smith, D.P. (2006). A cross-sectional examination of age and physical activity on performance and event-related brain potentials in a task switching paradigm. International Journal of Psychophysiology, 59(1), 3039.Google Scholar
Hillman, C.H., Motl, R.W., Pontifex, M.B., Posthuma, D., Stubbe, J.H., Boomsma, D.I., & de Geus, E.J.C. (2006). Physical activity and cognitive function in a cross-section of younger and older community-dwelling individuals. Health Psychology, 25(6), 678687.Google Scholar
Houx, P.J., Shepherd, J., Blauw, G.-J., Murphy, M.B., Ford, I., Bollen, E.L., & Westendorp, R.G. (2002). Testing cognitive function in elderly populations: The prosper study. Journal of Neurology, Neurosurgery, & Psychiatry, 73(4), 385389.Google Scholar
Howieson, D.B., Carlson, N.E., Moore, M.M., Wasserman, D., Abendroth, C.D., Payne-Murphy, J., & Kaye, J.A. (2008). Trajectory of mild cognitive impairment onset. Journal of the International Neuropsychological Society, 14(02), 192198.Google Scholar
Hu, L.T., & Bentler, P.M. (1999). Cutoff criteria for fit indexes in covariance structure analysis: Conventional criteria versus new alternatives. Structural Equation Modeling: A Multidisciplinary Journal, 6(1), 155.Google Scholar
Jaeggi, S.M., Buschkuehl, M., Jonides, J., & Shah, P. (2011). Short- and long-term benefits of cognitive training. Proceedings of the National Academy of Sciences of the United States of America, 108(25), 1008110086.CrossRefGoogle Scholar
Kann, L., Kinchen, S., Shanklin, S.L., Flint, K.H., Hakins, J., & Harris, W.A. (2014). Youth risk behavior surveillance — United States, 2013. MMWR: Morbidity and Mortality Weekly Report, 4(63), 3537.Google Scholar
Kim, B., Park, H., & Baek, Y. (2009). Not just fun, but serious strategies: Using meta-cognitive strategies in game-based learning. Computers & Education, 52(4), 800810.Google Scholar
Kimura, K., Obuchi, S., Arai, T., Nagasawa, H., Shiba, Y., Watanabe, S., & Kojima, M. (2010). The influence of short-term strength training on health-related quality of life and executive cognitive function. Journal of Physiological Anthropology, 29(3), 95101.Google Scholar
Kohl, H.W., Blair, S.N., Paffenbarger, R.S., Macera, C.A., & Kronenfeld, J.J. (1988). A mail survey of physical activity habits as related to measured physical fitness. American Journal of Epidemiology, 127(6), 12281239.Google Scholar
Krafft, C.E., Schwarz, N.F., Chi, L., Weinberger, A.L., Schaeffer, D.J., Pierce, J.E., & McDowell, J.E. (2014). An 8-month randomized controlled exercise trial alters brain activation during cognitive tasks in overweight children. Obesity, 22(1), 232242.Google Scholar
Kramer, A.F., Erickson, K.I., & Colcombe, S.J. (2006). Exercise, cognition, and the aging brain. Journal of Applied Physiology, 101(4), 12371242.Google Scholar
Kripke, D.F., Garfinkel, L., Wingard, D.L., Klauber, M.R., & Marler, M.R. (2002). Mortality associated with sleep duration and insomnia. Archives of General Psychiatry, 59(2), 131136.Google Scholar
Lachman, M.E., Neupert, S.D., Bertrand, R., & Jette, A.M. (2006). The effects of strength training on memory in older adults. Journal of Aging and Physical Activity, 14(1), 5973.Google Scholar
Lee, H., Baniqued, P.L., Cosman, J., Mullen, S., McAuley, E., Severson, J., & Kramer, A.F. (2012). Examining cognitive function across the lifespan using a mobile application. Computers in Human Behavior, 28(5), 19341946.Google Scholar
Lees, C., & Hopkins, J. (2013). Effect of aerobic exercise on cognition, academic achievement, and psychosocial function in children: A systematic review of randomized control trials. Preventing Chronic Disease, 10, E174.CrossRefGoogle ScholarPubMed
Liu-Ambrose, T., & Donaldson, M.G. (2009). Exercise and cognition in older adults: Is there a role for resistance training programmes? British Journal of Sports Medicine, 43(1), 2527.Google Scholar
Liu-Ambrose, T., Nagamatsu, L.S., Voss, M.W., Khan, K.M., & Handy, T.C. (2012). Resistance training and functional plasticity of the aging brain: A 12-month randomized controlled trial. Neurobiology of Aging, 33(8), 16901698.Google Scholar
Loprinzi, P.D., Loenneke, J.P., & Abe, T. (2015). The association between muscle strengthening activities and red blood cell distribution width among a national sample of U.S. adults. Preventive Medicine, 73(0), 130132.Google Scholar
Lumme, V., Aalto, S., Ilonen, T., Någren, K., & Hietala, J. (2007). Dopamine D2/D3 receptor binding in the anterior cingulate cortex and executive functioning. Psychiatry Research: Neuroimaging, 156(1), 6974.Google Scholar
Machulda, M.M., Pankratz, V.S., Christianson, T.J., Ivnik, R.J., Mielke, M.M., Roberts, R.O., & Petersen, R.C. (2013). Practice effects and longitudinal cognitive change in normal aging vs. Incident mild cognitive impairment and dementia in the mayo clinic study of aging. The Clinical Neuropsychologist, 27(8), 12471264.CrossRefGoogle ScholarPubMed
Mahncke, H.W., Connor, B.B., Appelman, J., Ahsanuddin, O.N., Hardy, J.L., Wood, R.A., & Merzenich, M.M. (2006). Memory enhancement in healthy older adults using a brain plasticity-based training program: A randomized, controlled study. Proceedings of the National Academy of Sciences of the United States of America, 103(33), 1252312528.Google Scholar
Mayr, U., Awh, E., & Laurey, P. (2003). Conflict adaptation effects in the absence of executive control. Nature Neuroscience, 6(5), 450452.Google Scholar
McAuley, E., Mullen, S.P., Szabo, A.N., White, S.M., Wójcicki, T.R., Mailey, E.L., & Kramer, A.F. (2011). Self-regulatory processes and exercise adherence in older adults: Executive function and self-efficacy effects. American Journal of Preventive Medicine, 41(3), 284290.Google Scholar
McAuley, E., Szabo, A.N., Mailey, E.L., Erickson, K.I., Voss, M., White, S.M., & Kramer, A.F. (2011). Non-exercise estimated cardiorespiratory fitness: Associations with brain structure, cognition, and memory complaints in older adults. Mental Health and Physical Activity, 4(1), 511.Google Scholar
McNab, F., Varrone, A., Farde, L., Jucaite, A., Bystritsky, P., Forssberg, H., & Klingberg, T. (2009). Changes in cortical dopamine d1 receptor binding associated with cognitive training. Science, 323(5915), 800802.Google Scholar
Middleton, L.E., Barnes, D.E., Lui, L.-Y., & Yaffe, K. (2010). Physical activity over the life course and its association with cognitive performance and impairment in old age. Journal of the American Geriatrics Society, 58(7), 13221326.Google Scholar
Milton, K., Bull, F.C., & Bauman, A. (2010). Reliability and validity testing of a single-item physical activity measure. British Journal of Sports Medicine, 45(3), 203208.Google Scholar
Mink, J.W. (1996). The basal ganglia: Focused selection and inhibition of competing motor programs. Progress in Neurobiology, 50(4), 381425.Google Scholar
Moul, J.L., Goldman, B., & Warren, B. (1995). Physical activity and cognitive performance in the older population. Journal of Aging Physical Activity, 3(2), 135145.Google Scholar
Muthén, L.K., & Muthén, B.O. (1998–2012). Mplus user's guide (7th ed.). Los Angeles, CA: Muthén & Muthén.Google Scholar
Nagamatsu, L.S., Chan, A., Davis, J.C., Beattie, B.L., Graf, P., Voss, M.W., & Liu-Ambrose, T. (2013). Physical activity improves verbal and spatial memory in older adults with probable mild cognitive impairment: A 6-month randomized controlled trial. Journal of Aging Research, 2013, 10.Google Scholar
Newman, M.F., Kirchner, J.L., Phillips-Bute, B., Gaver, V., Grocott, H., Jones, R.H., & Blumenthal, J.A. (2001). Longitudinal assessment of neurocognitive function after coronary-artery bypass surgery. New England Journal of Medicine, 344(6), 395402.Google Scholar
Niemann, C., Godde, B., Staudinger, U.M., & Voelcker-Rehage, C. (2014). Exercise-induced changes in basal ganglia volume and cognition in older adults. Neuroscience, 281C, 147163.Google Scholar
Padilla, C., Pérez, L., & Andrés, P. (2014). Chronic exercise keeps working memory and inhibitory capacities fit. Frontiers in Behavioral Neuroscience, 8, 49.Google Scholar
Peig-Chiello, P., Perrig, W.J., Ehrsam, R., Staehelin, H.B., & Krings, F. (1998). The effects of resistance training on well-being and memory in elderly volunteers. Age and Ageing, 27(4), 469475.Google Scholar
Pereira, A.C., Huddleston, D.E., Brickman, A.M., Sosunov, A.A., Hen, R., McKhann, G.M., & Small, S.A. (2007). An in vivo correlate of exercise-induced neurogenesis in the adult dentate gyrus. Proceedings of the National Academy of Sciences of the United States of America, 104(13), 56385643.Google Scholar
Pérez, L., Padilla, C., Parmentier, F.B.R., & Andrés, P. (2014). The effects of chronic exercise on attentional networks. PLoS One, 9(7), e101478.Google Scholar
Petzinger, G.M., Fisher, B.E., Van Leeuwen, J.-E., Vukovic, M., Akopian, G., Meshul, C.K., & Jakowec, M.W. (2010). Enhancing neuroplasticity in the basal ganglia: The role of exercise in parkinson’s disease. Movement Disorders, 25(Suppl. 1), S141S145.Google Scholar
Pontifex, M.B., Hillman, C.H., & Polich, J. (2009). Age, physical fitness, and attention: P3a and P3b. Psychophysiology, 46(2), 379387.Google Scholar
Pontifex, M.B., Kamijo, K., Scudder, M.R., Raine, L.B., Khan, N.A., Hemrick, B., & Hillman, C.H. (2014). The differential association of adiposity and fitness with cognitive control in preadolescent children. Monographs of the Society for Research in Child Development, 79(4), 7292.Google Scholar
Posner, M.I., & Rothbart, M.K. (2005). Influencing brain networks: Implications for education. Trends in Cognitive Sciences, 9(3), 99103.Google Scholar
Prakash, R.S., Voss, M.W., Erickson, K.I., & Kramer, A.F. (2015). Physical activity and cognitive vitality. Annual Review of Psychology, 66(1), 769797.Google Scholar
Rapport, L.J., Brines, D.B., Theisen, M.E., & Axelrod, B.N. (1997). Full scale iq as mediator of practice effects: The rich get richer. The Clinical Neuropsychologist, 11(4), 375380.Google Scholar
Ritchie, K., Artero, S., Portet, F., Brickman, A., Muraskin, J., Beanino, E., & Carrière, I. (2010). Caffeine, cognitive functioning, and white matter lesions in the elderly: Establishing causality from epidemiological evidence. Journal of Alzheimer's Disease, 20(Suppl 1), S161S166.Google Scholar
Rönnlund, M., Lövdén, M., & Nilsson, L.-G. (2007). Cross-sectional versus longitudinal age gradients of tower of hanoi performance: The role of practice effects and cohort differences in education. Aging, Neuropsychology, and Cognition, 15(1), 4067.Google Scholar
Rovio, S., Spulber, G., Nieminen, L.J., Niskanen, E., Winblad, B., Tuomilehto, J., & Kivipelto, M. (2010). The effect of midlife physical activity on structural brain changes in the elderly. Neurobiology of Aging, 31(11), 19271936.Google Scholar
Salthouse, T.A. (2010). Influence of age on practice effects in longitudinal neurocognitive change. Neuropsychology, 24(5), 563572.Google Scholar
Samitz, G., Egger, M., & Zwahlen, M. (2011). Domains of physical activity and all-cause mortality: Systematic review and dose–response meta-analysis of cohort studies. International Journal of Epidemiology, 40(5), 13821400.Google Scholar
Sanders, A.F., & Lamers, J.M. (2002). The eriksen flanker effect revisited. Acta Psychologica, 109(1), 4156.CrossRefGoogle ScholarPubMed
Schmidt, J.R., & De Houwer, J. (2011). Now you see it, now you don't: Controlling for contingencies and stimulus repetitions eliminates the gratton effect. Acta Psychologica, 138(1), 176186.Google Scholar
Shuttleworth-Edwards, A.B., Radloff, S.E., Whitefield-Alexander, V.J., Smith, I.P., & Horsman, M. (2014). Practice effects reveal visuomotor vulnerability in school and university rugby players. Archives of Clinical Neuropsychology, 29(1), 8699.Google Scholar
Sibley, B.A., & Etnier, J.L. (2003). The relationship between physical activity and cognition in children: A meta-analysis. Pediatric Exercise Science, 15(3), 243256.Google Scholar
Smith, A.M., Spiegler, K.M., Sauce, B., Wass, C.D., Sturzoiu, T., & Matzel, L.D. (2013). Voluntary aerobic exercise increases the cognitive enhancing effects of working memory training. Behavioural Brain Research, 256, 626635.Google Scholar
Smith, P.J., Blumenthal, J.A., Hoffman, B.M., Cooper, H., Strauman, T.A., Welsh-Bohmer, K., & Sherwood, A. (2010). Aerobic exercise and neurocognitive performance: A meta-analytic review of randomized controlled trials. Psychosomatic Medicine, 72(3), 239252.Google Scholar
Snowden, M., Steinman, L., Mochan, K., Grodstein, F., Prohaska, T.R., Thurman, D.J., & Anderson, L.A. (2011). Effect of exercise on cognitive performance in community-dwelling older adults: Review of intervention trials and recommendations for public health practice and research. Journal of the American Geriatrics Society, 59(4), 704716.Google Scholar
Sofi, F., Valecchi, D., Bacci, D., Abbate, R., Gensini, G.F., Casini, A., & Macchi, C. (2011). Physical activity and risk of cognitive decline: A meta-analysis of prospective studies. Journal of Internal Medicine, 269(1), 107117.Google Scholar
Spirduso, W.W. (1980). Physical fitness, aging, and psychomotor speed: A review. Journal of Gerontology, 35(6), 850865.Google Scholar
Spreng, R.N., Wojtowicz, M., & Grady, C.L. (2010). Reliable differences in brain activity between young and old adults: A quantitative meta-analysis across multiple cognitive domains. Neuroscience & Biobehavioral Reviews, 34(8), 11781194.Google Scholar
Sprenger, A.M., Atkins, S.M., Bolger, D.J., Harbison, J.I., Novick, J.M., Chrabaszcz, J.S., & Dougherty, M.R. (2013). Training working memory: Limits of transfer. Intelligence, 41(5), 638663.Google Scholar
Steinmo, S., Hagger-Johnson, G., & Shahab, L. (2014). Bidirectional association between mental health and physical activity in older adults: Whitehall II prospective cohort study. Preventive Medicine, 66, 7479.Google Scholar
Sternberg, D.A., Ballard, K., Hardy, J.L., Katz, B., Doraiswamy, P.M., & Scanlon, M. (2013). The largest human cognitive performance dataset reveals insights into the effects of lifestyle factors and aging. Frontiers in Human Neuroscience, 7, 292.Google Scholar
Suchy, Y., Kraybill, M.L., & Franchow, E. (2011). Practice effect and beyond: Reaction to novelty as an independent predictor of cognitive decline among older adults. Journal of the International Neuropsychological Society, 17(1), 101111.Google Scholar
ten Brinke, L.F., Bolandzadeh, N., Nagamatsu, L.S., Hsu, C.L., Davis, J.C., Miran-Khan, K., & Liu-Ambrose, T. (2014). Aerobic exercise increases hippocampal volume in older women with probable mild cognitive impairment: A 6-month randomised controlled trial. British Journal of Sports Medicine, 49, 248254.Google Scholar
Tomporowski, P., Davis, C., Miller, P., & Naglieri, J. (2008). Exercise and children’s intelligence, cognition, and academic achievement. Educational Psychology Review, 20(2), 111131.Google Scholar
Tsutsumi, T., Don, B.M., Zaichkowsky, L.D., & Delizonna, L.L. (1997). Physical fitness and psychological benefits of strength training in community dwelling older adults. Applied Human Science, 16(6), 257266.Google Scholar
Van Boxtel, P.J., Paas, F.G., Houx, P.J., Adam, J.J., Teeken, J.C., & Jolles, J. (1997). Aerobic capacity and cognitive performance in a cross-sectional aging study. Medicine & Science in Sports & Exercise, 29(10), 13571365.Google Scholar
Verstynen, T.D., Lynch, B., Miller, D.L., Voss, M.W., Prakash, R.S., Chaddock, L., & Erickson, K.I. (2012). Caudate nucleus volume mediates the link between cardiorespiratory fitness and cognitive flexibility in older adults. Journal of Aging Research, 2012, 11.Google Scholar
Volkers, K.M., & Scherder, E.J.A. (2014). Physical performance is associated with working memory in older people with mild to severe cognitive impairment. BioMed Research International, 2014, 762986.Google Scholar
Voss, M.W., Chaddock, L., Kim, J.S., VanPatter, M., Pontifex, M.B., Raine, L.B., & Kramer, A.F. (2011). Aerobic fitness is associated with greater efficiency of the network underlying cognitive control in preadolescent children. Neuroscience, 199, 166176.Google Scholar
Weuve, J., Kang, J., Manson, J.E., Breteler, M.B., Ware, J.H., & Grodstein, F. (2004). Physical activity, including walking, and cognitive function in older women. Journal of the American Medical Association, 292(12), 14541461.Google Scholar
Wilson, R.S., Leurgans, S.E., Boyle, P.A., & Bennett, D.A. (2011). Cognitive decline in prodromal alzheimer disease and mild cognitive impairment. Archives of Neurology, 68(3), 351356.Google Scholar