The potential neuroprotective effects of regular physical activity on brain structure are unclear, despite links between activity and reduced dementia risk.
Objective:
To investigate the relationships between regular moderate to vigorous physical activity and quantified brain volumes on magnetic resonance neuroimaging.
Methods:
A total of 10,125 healthy participants underwent whole-body MRI scans, with brain sequences including isotropic MP-RAGE. Three deep learning models analyzed axial, sagittal, and coronal views from the scans. Moderate to vigorous physical activity, defined by activities increasing respiration and pulse rate for at least 10 continuous minutes, was modeled with brain volumes via partial correlations. Analyses adjusted for age, sex, and total intracranial volume, and a 5% Benjamini-Hochberg False Discovery Rate addressed multiple comparisons.
Results:
Participant average age was 52.98±13.04 years (range 18–97) and 52.3% were biologically male. Of these, 7,606 (75.1%) reported engaging in moderate or vigorous physical activity approximately 4.05±3.43 days per week. Those with vigorous activity were slightly younger (p < 0.00001), and fewer women compared to men engaged in such activities (p = 3.76e-15). Adjusting for age, sex, body mass index, and multiple comparisons, increased days of moderate to vigorous activity correlated with larger normalized brain volumes in multiple regions including: total gray matter (Partial R = 0.05, p = 1.22e-7), white matter (Partial R = 0.06, p = 9.34e-11), hippocampus (Partial R = 0.05, p = 5.96e-7), and frontal, parietal, and occipital lobes (Partial R = 0.04, p≤1.06e-5).
Conclusions:
Exercise-related physical activity is associated with increased brain volumes, indicating potential neuroprotective effects.
del Pozo CruzB, AhmadiM, NaismithSL, StamatakisE (2022) Association of daily step count and intensity with incident dementia in 78 430 adults living in the UK. JAMA Neurol79, 1059.
2.
Iso-MarkkuP, KujalaUM, KnittleK, PoletJ, VuoksimaaE, WallerK (2022) Physical activity as a protective factor for dementia and Alzheimer’s disease: Systematic review, meta-analysis and quality assessment of cohort and case–control studies. Br J Sports Med56, 701–709.
3.
YoonH, MyungW, LimSW, KangHS, KimS, WonHH, CarrollBJ, KimDK (2015) Association of the choline acetyltransferase gene with responsiveness to acetylcholinesterase inhibitors in Alzheimer’s disease. Pharmacopsychiatry48, 111–117.
KennedyG, HardmanRJ, MacphersonH, ScholeyAB, PipingasA (2016) How does exercise reduce the rate of age-associated cognitive decline? A review of potential mechanisms. J Alzheimers Dis55, 1–18.
6.
PereiraAC, HuddlestonDE, BrickmanAM, SosunovAA, HenR, McKhannGM, SloanR, GageFH, BrownTR, SmallSA (2007) Ancorrelate of exercise-induced neurogenesis in the adult dentate gyrus. Proc Natl Acad Sci U S A104, 5638–5643.
7.
Melo NevesL, Ritti-DiasR, JudayV, MarquesiniR, Mendes GerageA, Cândido LaurentinoG, Hoffmann NunesR, StubbsB, UgrinowitschC (2023) Objective physical activity accumulation and brain volume in older adults: An MRI and whole-brain volume study. J Gerontol A Biol Sci Med Sci78, 902–910.
8.
DomingosC, Picó-PérezM, MagalhãesR, MoreiraM, SousaN, PêgoJM, SantosNC (2021) Free-living physical activity measured with a wearable device is associated with larger hippocampus volume and greater functional connectivity in healthy older adults: An observational, cross-sectional study in Northern Portugal. Front Aging Neurosci13, 729060.
9.
PiercyKL, TroianoRP, BallardRM, CarlsonSA, FultonJE, GaluskaDA, GeorgeSM, OlsonRD (2018) The physical activity guidelines for Americans. JAMA320, 2020.
10.
BlackwellDL, ClarkeTC (2018) State variation in meeting the 2008 Federal Guidelines for both aerobic and muscle-strengthening activities through leisure-time physical activity among adults aged 18-64: United States, 2010-2015. Natl Health Stat Report, . pp. 1–22.
11.
AbildsoCG, DailySM, Umstattd MeyerMR, PerryCK, EylerA (2023) Prevalence of meeting aerobic, muscle-strengthening, and combined physical activity guidelines during leisure time among adults, by rural-urban classification and region — United States, 2020. MMWR Morb Mortal Wkly Rep72, 85–89.
12.
EricksonKI, RajiCA, LopezOL, BeckerJT, RosanoC, NewmanAB, GachHM, ThompsonPM, HoAJ, KullerLH (2010) Physical activity predicts gray matter volume in late adulthood: The Cardiovascular Health Study. Neurology75, 1415–1422.
13.
BoyleCP, RajiCA, EricksonKI, LopezOL, BeckerJT, GachHM, LongstrethWTJr, TeverovskiyL, KullerLH, CarmichaelOT, ThompsonPM (2015) Physical activity, body mass index, and brain atrophy in Alzheimer’s disease.S. Neurobiol Aging36 Suppl 1, 194–202.
14.
RajiCA, MerrillDA, EyreH, MallamS, TorosyanN, EricksonKI, LopezOL, BeckerJT, CarmichaelOT, GachHM, ThompsonPM, LongstrethWT, KullerLH (2016) Longitudinal relationships between caloric expenditure and gray matter in the Cardiovascular Health Study. J Alzheimers Dis52, 719–729.
15.
BrownBM, De Frutos LucasJ, PorterT, FrostN, VacherM, PeifferJJ, LawsSM (2022) Non-modifiable factors as moderators of the relationship between physical activity and brain volume: A cross-sectional UK Biobank Study. J Alzheimers Dis88, 1091–1101.
16.
PetraliaG, KohD-M, AttariwalaR, BuschJJ, EelesR, KarowD, LoGG, MessiouC, SalaE, VargasHA, ZugniF, PadhaniAR (2021) Oncologically Relevant Findings Reporting and Data System (ONCO-RADS): Guidelines for the acquisition, interpretation, and reporting of whole-body MRI for cancer screening. Radiology299, 494–507.
HenschelL, ConjetiS, EstradaS, DiersK, FischlB, ReuterM (2020) FastSurfer –A fast and accurate deep learning based neuroimaging pipeline. Neuroimage219, 117012.
20.
FischlB (2012) FreeSurfer. Neuroimage62, 774–781.
21.
IsenseeF, JaegerPF, KohlSAA, PetersenJ, Maier-HeinKH (2021) nnU-Net: A self-configuring method for deep learning-based biomedical image segmentation. Nat Methods18, 203–211.
22.
NoldenM, ZelzerS, SeitelA, WaldD, MüllerM, FranzAM, MaleikeD, FangerauM, BaumhauerM, Maier-HeinL, Maier-HeinKH, MeinzerH-P, WolfI (2013) The Medical Imaging Interaction Toolkit: Challenges and advances: 10 years of open-source development. Int J Comput Assist Radiol Surg8, 607–620.
BenjaminiY, HochbergY (1995) Controlling the false discovery rate: A practical and powerful approach to multiple testing. J R Stat Soc Series B Methodol57, 289–300.
25.
GenoveseCR, LazarNA, NicholsTE (2002) Thresholding of statistical maps in functional neuroimaging using the false discovery rate. Neuroimage15, 870–878.
26.
BennettCM, WolfordGL, MillerMB (2009) The principled control of false positives in neuroimaging. Soc Cogn Affect Neurosci4, 417–422.
SpartanoNL, Davis-PlourdeKL, HimaliJJ, AnderssonC, PaseMP, MaillardP, DeCarliC, MurabitoJM, BeiserAS, VasanRS, SeshadriS (2019) Association of accelerometer-measured light-intensity physical activity with brain volume: The Framingham Heart Study. JAMA Netw Open2, e192745.
29.
CarmichaelOT, KullerLH, LopezOL, ThompsonPM, DuttonRA, LuA, LeeJY, AizensteinHJ, MeltzerCC, LiuY, TogaAW, BeckerJT (2007) Cerebral ventricular changes associated with transitions between normal cognitive function, mild cognitive impairment, and dementia. Alzheimer Dis Relat Disord21, 14–24.
30.
WanigatungaAA, WangH, AnY, SimonsickEM, TianQ, DavatzikosC, UrbanekJK, ZipunnikovV, SpiraAP, FerrucciL, ResnickSM, SchrackJA (2021) Association between brain volumes and patterns of physical activity in community-dwelling older adults. J Gerontol A Biol Sci Med Sci76, 1504–1511.
31.
HofmanA, Rodriguez-AyllonM, VernooijMW, CrollPH, LuikAI, NeumannA, NiessenWJ, IkramMA, VoortmanT, MuetzelRL (2023) Physical activity levels and brain structure in middle-aged and older adults: A bidirectional longitudinal population-based study. Neurobiol Aging121, 28–37.
32.
GregoryS, ParkerB, ThompsonP (2012) Physical activity, cognitive function, and brain health: What is the role of exercise training in the prevention of dementia?Brain Sci2, 684–708.
33.
FelisattiF, GonneaudJ, PalixC, Garnier-CrussardA, MézengeF, BrigitteL, ChocatA, QuillardA, Ferrand-DevougeE, De La SayetteV, VivienD, ChételatG, PoisnelG, on behalf of the Medit-Ageing Research Group (2022) Role of cardiovascular risk factors on the association between physical activity and brain integrity markers in older adults. Neurology98, e2023–e2035.
34.
AdlardPA, PerreauVM, PopV, CotmanCW (2005) Voluntary exercise decreases amyloid load in a transgenic model of Alzheimer’s disease. J Neurosci25, 4217–4221.
35.
LiuPZ, NusslockR (2018) Exercise-mediated neurogenesis in the hippocampus via BDNF. Front Neurosci12, 52.
36.
BraskieMN, BoyleCP, RajagopalanP, GutmanBA, TogaAW, RajiCA, TracyRP, KullerLH, BeckerJT, LopezOL, ThompsonPM (2014) Physical activity, inflammation, and volume of the aging brain. Neuroscience273, 199–209.
37.
SeoD-Y, HeoJ-W, KoJR, KwakH-B (2019) Exercise and neuroinflammation in health and disease. Int Neurourol J23, S82–92.
38.
RajaD, RavichandranS, ChandrasekaranB, KadavigereR, BabuMGR, AlmeshariM, AlyahyawiAR, AlzamilY, AbanomyA, SukumarS (2022) Association between physical activity levels and brain volumes in adults visiting radio-imaging center of tertiary care hospital. Int J Environ Res Public Health19, 17079.
39.
LiuY, YanT, ChuJM-T, ChenY, DunnettS, HoY-S, WongGT-C, ChangRC-C (2019) The beneficial effects of physical exercise in the brain and related pathophysiological mechanisms in neurodegenerative diseases. Lab Invest99, 943–957.
SaifN, HristovH, AkiyoshiK, NiotisK, ArizaIE, MalviyaN, LeeP, MelendezJ, SadekG, HackettK, RahmanA, Meléndez-CabreroJ, GreerCE, MosconiL, KrikorianR, IsaacsonRS (2022) Sex-driven differences in the effectiveness of individualized clinical management of Alzheimer’s disease risk. J Prev Alzheimers Dis9, 731–742.
47.
BassettDR, WyattHR, ThompsonH, PetersJC, HillJO (2010) Pedometer-measured physical activity and health behaviors in U.S. adults. Med Sci Sports Exerc42, 1819–1825.
48.
BerkoJ, GoetzelRZ, RoemerEC, KentK, MarchibrodaJ (2016) Results from the Bipartisan Policy Center’s CEO Council Physical Activity Challenge to American Business. J Occup Environ Med58, 1239–1244.
49.
PizarroR, AssemlalH-E, De NigrisD, ElliottC, AntelS, ArnoldD, ShmuelA (2019) Using deep learning algorithms to automatically identify the brain MRI contrast: Implications for managing large databases. Neuroinformatics17, 115–130.
50.
HuF, ChenAA, HorngH, BashyamV, DavatzikosC, Alexander-BlochA, LiM, ShouH, SatterthwaiteTD, YuM, ShinoharaRT (2023) Image harmonization: A review of statistical and deep learning methods for removing batch effects and evaluation metrics for effective harmonization. Neuroimage274, 120125.
