References: Chapter 9

THE STIMULATED MIND: Future-Proof Your Brain from Dementia and Stay Sharp at Any Age

Mark, G., Attention Span: A Groundbreaking Way to Restore Balance, Happiness and Productivity. 2023, Hanover Square Press.

Divangahi, M., et al., Trained Immunity, Tolerance, Priming and Differentiation: Distinct Immunological Processes. Nature Immunology, 2021. 22(1): pp. 2–6.

Zanger, U.M. and M. Schwab, Cytochrome P450 Enzymes in Drug Metabolism: Regulation of Gene Expression, Enzyme Activities, and Impact of Genetic Variation. Pharmacology & Therapeutics, 2013. 138(1): pp. 103–41.

Turknett, J. and T.R. Wood, Demand Coupling Drives Neurodegeneration: A Model of Age-Related Cognitive Decline and Dementia. Cells, 2022. 11(18): 2789.

Rabinovitch, A., What a Decades-long Study Teaches Us About Brain Health and Aging. UW Medicine. Available↗

Schaie, K.W., Midlife Influences Upon Intellectual Functioning in Old Age. International Journal of Behavioral Development, 1984. 7(4): pp. 463–78.

Rabinovitch, A. What a Decades-long Study Teaches Us About Brain Health and Aging. UW Medicine. Available↗

Hertzog, C., K.W. Schaie, and K. Gribbin, Cardiovascular Disease and Changes in Intellectual Functioning from Middle to Old Age. Journal of Gerontology, 1978. 33(6): pp. 872–83.

10.

Willis, S.L. and K.W. Schaie, Cognitive Training and Plasticity: Theoretical Perspective and Methodological Consequences. Restorative Neurology and Neuroscience, 2009. 27(5): pp. 375–89.

11.

Hultsch, D.F., et al., Use It or Lose It: Engaged Lifestyle as a Buffer of Cognitive Decline in Aging? Psychology and Aging, 1999. 14(2): pp. 245–63.

Gribbin, K., K.W. Schaie, and I.A. Parham, Complexity of Life Style and Maintenance of Intellectual Abilities. Journal of Social Issues, 1980. 36(2): pp. 47–61.

12.

Szasz, T., “Words to the Wise: A Medical-Philosophical Dictionary”. 2004, Transaction Publishers.

13.

Bahl, E., et al., Using Deep Learning to Quantify Neuronal Activation from Single-Cell and Spatial Transcriptomic Data. Nature Communications, 2024. 15(1): 779.

Coronel-Oliveros, C., et al., Creative experiences and brain clocks. Nature Communications, 2025. 16, 8336.

14.

Flavell, S.W. and M.E. Greenberg, Signaling Mechanisms Linking Neuronal Activity to Gene Expression and Plasticity of the Nervous System. Annual Review of Neuroscience, 2008. 31: pp. 563–90.

Valencia, M., et al., Neuronal Autophagy: Characteristic Features and Roles in Neuronal Pathophysiology. Biomolecules & Therapeutics (Seoul), 2021. 29(6): pp. 605–14.

15.

Draganski, B., et al., Changes in Grey Matter Induced by Training. Nature, 2004. 427(6972): pp. 311–12.

16.

Livingston, G., et al., Dementia Prevention, Intervention, and Care: 2024 Report of the Lancet Standing Commission. The Lancet, 2024. 404(10452): pp. 572–628.

17.

Mekonnen, T., et al., Mediators of Educational Differences in Dementia Risk Later in Life: Evidence from the HUNT Study. BMC Public Health, 2025. 25(1): 1336.

Maccora, J., R. Peters, and K.J. Anstey, What Does (Low) Education Mean in Terms of Dementia Risk? A Systematic Review and Meta-Analysis Highlighting Inconsistency in Measuring and Operationalising Education. SSM—Population Health, 2020. 12: 100654.

Jin, J., A. Sommerlad, and N. Mukadam, Association Between Adult Education, Brain Volume and Dementia Risk: Longitudinal Cohort Study of UK Biobank Participants. Geroscience, 2025. 47(1): pp. 903–13.

Lövdén, M., et al., Education and Cognitive Functioning Across the Life Span. Popular Science in the Public Interest, 2020. 21(1): pp. 6–41.

18.

Lövdén et al., Education and Cognitive Functioning Across the Life Span. Popular Science in the Public Interest, 2020. 21(1): pp. 6–41.

19.

Guerra-Carrillo, B., K. Katovich, and S.A. Bunge, Does Higher Education Hone Cognitive Functioning and Learning Efficacy? Findings from a Large and Diverse Sample. PLoS One, 2017. 12(8): e0182276.

20.

Meng, X. and C. D’Arcy, Education and Dementia in the Context of the Cognitive Reserve Hypothesis: A Systematic Review with Meta-Analyses and Qualitative Analyses. PLoS One, 2012. 7(6): e38268.

Nelson, M.E., et al., Cognitive Reserve, Alzheimer’s Neuropathology, and Risk of Dementia: A Systematic Review and Meta-Analysis. Neuropsychology Review, 2021. 31(2): pp. 233–50.

Chapko, D., et al., Life-Course Determinants of Cognitive Reserve (CR) in Cognitive Aging and Dementia—A Systematic Literature Review. Aging & Mental Health, 2018. 22(8): pp. 915–26.

21.

Leon, A., et al., Mast Cells Synthesize, Store, and Release Nerve Growth Factor. Proceedings of the National Academy of Sciences of the U.S., 1994. 91(9): pp. 3739–43.

Rita Levi-Montalcini—Nobel Prize in Physiology or Medicine 1986. Available↗

22.

Lövdén et al., Education and Cognitive Functioning Across the Life Span. Popular Science in the Public Interest, 2020. 21(1): pp. 6–41.

23.

Kivimäki, M., et al., Cognitive Stimulation in the Workplace, Plasma Proteins, and Risk of Dementia: Three Analyses of Population Cohort Studies. The BMJ, 2021. 374: n1804.

24.

Edwin, T.H., et al., Trajectories of Occupational Cognitive Demands and Risk of Mild Cognitive Impairment and Dementia in Later Life. Neurology, 2024. 102(9): e209353.

25.

Hughes, T.F., et al., Engagement in Reading and Hobbies and Risk of Incident Dementia: The Movies Project. American Journal of Alzheimer’s Disease and Other Dementias, 2010. 25(5): pp. 432–38.

Iwasa, H., et al., Leisure Activities and Cognitive Function in Elderly Community-Dwelling Individuals in Japan: A 5-Year Prospective Cohort Study. Journal of Psychosomatic Research, 2012. 72(2): pp. 159–64.

Matsumura, T., et al., Hobby Engagement and Risk of Disabling Dementia. Journal of Epidemiology, 2023. 33(9): pp. 456–63.

Zammit, A.R., et al., Associations of Lifetime Cognitive Enrichment With Incident Alzheimer Disease Dementia, Cognitive Aging, and Cognitive Resilience. Neurology. 2026 Mar 10;106(5):e214677.

26.

Boyke, J., et al., Training-Induced Brain Structure Changes in the Elderly. The Journal of Neuroscience, 2008. 28(28): pp. 7031–35.

27.

von Bastian, C.C., et al., Mechanisms Underlying Training-Induced Cognitive Change. Nature Reviews, Psychology, 2022. 1(1): pp. 30–41.

28.

Anderson, J.A.E., K. Hawrylewicz, and J.G. Grundy, Does Bilingualism Protect Against Dementia? A Meta-Analysis. Psychonomic Bulletin & Review, 2020. 27(5): pp. 952–65.

Venugopal, A., et al., Protective Effect of Bilingualism on Aging, MCI, and Dementia: A Community-Based Study. Alzheimers & Dementia. 2024 Apr;20(4):2620-2631.

29.

Adesope, O.O., et al., A Systematic Review and Meta-Analysis of the Cognitive Correlates of Bilingualism. Review of Educational Research, 2010. 80(2): pp. 207–45.

Grundy, J.G. and K. Timmer, Bilingualism and Working Memory Capacity: A Comprehensive Meta-Analysis. Second Language Research, 2017. 33(3): pp. 325–40.

Stocco, A., et al., Bilingual Brain Training: A Neurobiological Framework of How Bilingual Experience Improves Executive Function. International Journal of Bilingualism, 2014. 18(1): pp. 67–92.

30.

Stocco et al., Bilingual Brain Training: A Neurobiological Framework of How Bilingual Experience Improves Executive Function. International Journal of Bilingualism, 2014. 18(1): pp. 67–92.

31.

Bice, K., B.L. Yamasaki, and C.S. Prat, Bilingual Language Experience Shapes Resting-State Brain Rhythms. Neurobiology of Language, 2020. 1(3): pp. 288–318.

32.

Bubbico, G., et al., Effects of Second Language Learning on the Plastic Aging Brain: Functional Connectivity, Cognitive Decline, and Reorganization. Frontiers in Neuroscience, 2019. 13: 423.

Ware, C., et al., Does Second Language Learning Promote Neuroplasticity in Aging? A Systematic Review of Cognitive and Neuroimaging Studies. Frontiers in Aging Neuroscience, 2021. 13: 706672.

33.

Ware et al., Does Second Language Learning Promote Neuroplasticity in Aging? A Systematic Review of Cognitive and Neuroimaging Studies. Frontiers in Aging Neuroscience, 2021. 13: 706672.

Grossmann, J.A., et al., Foreign Language Learning Can Improve Response Inhibition in Individuals with Lower Baseline Cognition: Results from a Randomized Controlled Superiority Trial. Frontiers in Aging Neuroscience, 2023. 15: 1123185.

Meltzer, J.A., et al., Improvement in Executive Function for Older Adults Through Smartphone Apps: A Randomized Clinical Trial Comparing Language Learning and Brain Training. Neuropsychology, Development, and Cognition, Section B: Aging, Neuropsychology and Cognition, 2023. 30(2): pp. 150–71.

34.

Verstynen, T.D., et al., Caudate Nucleus Volume Mediates the Link Between Cardiorespiratory Fitness and Cognitive Flexibility in Older Adults. Journal of Aging Research, 2012. 2012(1): 939285.

35.

von Bastian, C.C., et al., Mechanisms Underlying Training-Induced Cognitive Change. Nature Reviews, Psychology, 2022. 1(1): pp. 30–41.

36.

Drachman, D.A., Aging of the Brain, Entropy, and Alzheimer’s Disease. Neurology, 2006. 67(8): pp. 1340–52.

Yao, Y., et al., The Increase of the Functional Entropy of the Human Brain with Age. Scientific Reports, 2013. 3(1): 2853.

Cieri, F., et al., Brain Entropy During Aging Through a Free Energy Principle Approach. Frontiers in Human Neuroscience, 2021 Mar 22:15:647513.

Coronel-Oliveros, C., et al., Creative experiences and brain clocks. Nature Communications, 2025. 16, 8336.

37.

Frank, M.J., B.S. Woroch, and T. Curran, Error-Related Negativity Predicts Reinforcement Learning and Conflict Biases. Neuron, 2005. 47(4): pp. 495–501.

Walsh, M.M. and J.R. Anderson, Modulation of the Feedback-Related Negativity by Instruction and Experience. Proceedings of the National Academy of Sciences, 2011. 108(47): pp. 19048–53.

Gehring, W.J., et al., The Error-Related Negativity (ERN/Ne), in the Oxford Handbook of Event-Related Potential Components, E.S. Kappenman and S.J. Luck, editors (Oxford University Press, 2011).

38.

O’Donnell, J., et al., Norepinephrine: A Neuromodulator That Boosts the Function of Multiple Cell Types to Optimize CNS Performance. Neurochemical Research, 2012. 37(11): pp. 2496–512.

Eldar, E., J.D. Cohen, and Y. Niv, The Effects of Neural Gain on Attention and Learning. Nature Neuroscience, 2013. 16(8): pp. 1146–53.

Basu, A., et al., Frontal Norepinephrine Represents a Threat Prediction Error Under Uncertainty. Biological Psychiatry, 2024. 96(4): pp. 256–67.

39.

Mera, Y., G. Rodríguez, and E. Marin-Garcia, Unraveling the Benefits of Experiencing Errors During Learning: Definition, Modulating Factors, and Explanatory Theories. Psychonomic Bulletin & Review, 2022. 29(3): pp. 753–65.

40.

Touroutoglou, A., et al., The Tenacious Brain: How the Anterior Mid-Cingulate Contributes to Achieving Goals. Cortex, 2020. 123: pp. 12–19.

Touroutoglou, A., et al., Motivation in the Service of Allostasis: The Role of Anterior Mid Cingulate Cortex. Advances in Motivational Science, 2019. 6: pp. 1–5.

Smith, R., G.L. Ahern, and R.D. Lane, The Role of Anterior and Midcingulate Cortex in Emotional Awareness: A Domain-General Processing Perspective. Handbook of Clinical Neurology, 2019. 166: pp. 89–101.

41.

Marseglia, A., et al., Biological Brain Age and Resilience in Cognitively Unimpaired 70-Year-Old Individuals. Alzheimer’s & Dementia, 2025. 21(2): e14435.

42.

Franke, K. and C. Gaser, Ten Years of BrainAGE as a Neuroimaging Biomarker of Brain Aging: What Insights Have We Gained? Frontiers in Neurology, 2019 Aug 14;10:789.

Zwilling, C.E., J. Wu, and A.K. Barbey, Investigating Nutrient Biomarkers of Healthy Brain Aging: A Multimodal Brain Imaging Study. npj Aging, 2024. 10(1): 27.

Tan, W.Y., et al., Role of Brain Age Gap as a Mediator in the Relationship Between Cognitive Impairment Risk Factors and Cognition. Neurology. 2025 Jul 22;105(2):e213815.

Whitman, E.T., et al., DunedinPACNI Estimates the Longitudinal Pace of Aging From a Single Brain Image to Track Health and Disease. Nature Aging. 2025 Aug;5(8):1619-1636.

Oh, H.S., et al., Plasma Proteomics Links Brain and Immune System Aging with Healthspan and Longevity. Nature Medicine. 2025 Aug;31(8):2703-2711.

43.

Rogenmoser, L., et al., Keeping Brains Young with Making Music. Brain Structure and Function, 2018. 223(1): pp. 297–305.

44.

Román-Caballero, R., et al., Musical Practice as an Enhancer of Cognitive Function in Healthy Aging—A Systematic Review and Meta-Analysis. PLoS One, 2018. 13(11): e0207957.

45.

Frischen, U., G. Schwarzer, and F. Degé, Music Lessons Enhance Executive Functions in 6- to 7-Year-Old Children. Learning and Instruction, 2021. 74: 101442.

46.

Sala, G. and F. Gobet, When the Music’s Over. Does Music Skill Transfer to Children’s and Young Adolescents’ Cognitive and Academic Skills? A Meta-Analysis. Educational Research Review, 2017. 20: pp. 55–67.

47.

Marie, D., et al., Music Interventions in 132 Healthy Older Adults Enhance Cerebellar Grey Matter and Auditory Working Memory, Despite General Brain Atrophy. Neuroimage: Reports, 2023. 3(2): 100166.

48.

Olszewska, A.M., et al., How Musical Training Shapes the Adult Brain: Predispositions and Neuroplasticity. Frontiers in Neuroscience, 2021. 15: 630829.

Wan, C.Y. and G. Schlaug, Music Making as a Tool for Promoting Brain Plasticity Across the Life Span. Neuroscientist, 2010. 16(5): pp. 566–77.

49.

Lappe, C., et al., Cortical Plasticity Induced by Short-Term Unimodal and Multimodal Musical Training. The Journal of Neuroscience, 2008. 28(39): pp. 9632–39.

Li, Q., et al., Musical Training Induces Functional and Structural Auditory-Motor Network Plasticity in Young Adults. Human Brain Mapping, 2018. 39(5): pp. 2098–110.

50.

Verghese, J., et al., Leisure Activities and the Risk of Dementia in the Elderly. The New England Journal of Medicine, 2003. 348(25): pp. 2508–16.

51.

Blumen, H.M., et al., Randomized Controlled Trial of Social Ballroom Dancing and Treadmill Walking: Preliminary Findings on Executive Function and Neuroplasticity from Dementia-at-Risk Older Adults. Journal of Aging and Physical Activity, 2023. 31(4): pp. 589–99.

Rehfeld, K., et al., Dancing or Fitness Sport? the Effects of Two Training Programs on Hippocampal Plasticity and Balance Abilities in Healthy Seniors. Frontiers in Human Neuroscience, 2017 Jun 15:11:305.

Predovan, D., et al., Effects of Dancing on Cognition in Healthy Older Adults: a Systematic Review. Journal of Cognitive Enhancement. 2019;3(2):161-167.

52.

Huang, C., et al., Effects of Dance Therapy on Cognitive and Mental Health in Adults Aged 55 Years and Older with Mild Cognitive Impairment: A Systematic Review and Meta-Analysis. BMC Geriatricsics, 2023. 23(1): 695.

53.

Noetel, M., et al., Effect of Exercise for Depression: Systematic Review and Network Meta-Analysis of Randomised Controlled Trials. The BMJ, 2024. 384: e075847.

54.

Karpati, F.J., et al., Dance and the Brain: a Review. Annals of the New Yorak Academy of Sciences. 2015 Mar;1337:140-6.

55.

Davis, E., et al., Dance for Multiple Sclerosis: A Systematic Review. International Journal of MS Care, 2023. 25(4): pp. 176–85.

Cheng, W.H., Y. Quan, and W.F. Thompson, The Effect of Dance on Mental Health and Quality of Life of People with Parkinson’s Disease: A Systematic Review and Three-Level Meta-Analysis. Archives of Gerontology and Geriatrics, 2024. 120: 105326.

Tao, D., et al., The Effectiveness of Dance Movement Interventions for Older Adults with Mild Cognitive Impairment, Alzheimer’s Disease, and Dementia: A Systematic Scoping Review and Meta-Analysis. Ageing Research Reviews, 2023. 92: 102120.

56.

Higgins, E.S. and M.S. George, The Neuroscience of Clinical Psychiatry: The Pathophysiology of Behavior and Mental Illness, 3e (Lippincott Williams & Wilkins, 2019).

57.

Stieger, M. and M.E. Lachman, Increases in Cognitive Activity Reduce Aging-Related Declines in Executive Functioning. Frontiers in Psychiatry, 2021 Jul 29:12:708974.

Lachman, M.E., et al., Frequent Cognitive Activity Compensates for Education Differences in Episodic Memory. American Journal of Geriatriatric Psychiatry, 2010. 18(1): pp. 4–10.

58.

Verghese, J., et al., Leisure Activities and the Risk of Dementia in the Elderly. The New England Journal of Medicine, 2003. 348(25): pp. 2508–16.

59.

Sparrow, B., J. Liu, and D.M. Wegner, Google Effects on Memory: Cognitive Consequences of Having Information at Our Fingertips. Science, 2011. 333(6043): pp. 776–78.

60.

Prat, C.S., et al., Relating Natural Language Aptitude to Individual Differences in Learning Programming Languages. Scientific Reports, 2020. 10(1): 3817.

61.

Owen, A.M., et al., Putting brain training to the test. Nature, 2010. 465(7299): pp. 775–78.

62.

Willis, S.L., et al., Long-Term Effects of Cognitive Training on Everyday Functional Outcomes in Older Adults. JAMA, 2006. 296(23): pp. 2805–14.

Tennstedt, S.L. and F.W. Unverzagt, The ACTIVE Study: Study Overview and Major Findings. Journal of Aging and Health, 2013. 25(8 Suppl): pp. 3s–20s.

Wolinsky, F.D., et al., The ACTIVE cognitive training trial and health-related quality of life: protection that lasts for 5 years. Journals of Gerontololgy: Series. 2006 Dec;61(12):1324-9.

Coe, N.B., et al., Impact of cognitive training on claims-based diagnosed dementia over 20 years: evidence from the ACTIVE study. Alzheimer’s and Dementia. 2026 Feb 9;12(1):e70197.

Edwards, J.D., et al., Speed of processing training results in lower risk of dementia. Alzheimer’s & Dementia. 2017 Nov 7;3(4):603-611.

63.

Ball, K., et al., Cognitive Training Decreases Motor Vehicle Collision Involvement of Older Drivers. Journal of the American Geriatrics Society, 2010. 58(11): pp. 2107–13.

Edwards, J.D., P.B. Delahunt, and H.W. Mahncke, Cognitive Speed of Processing Training Delays Driving Cessation. The Journals of Gerontology: Series A, Biological Sciences and Medical Sciences, 2009. 64(12): pp. 1262–67.

64.

The ACTIVE Study. BrainHQ. Available↗

65.

Hundreds of Published Studies. BrainHQ. Available↗

Attarha, M., et al., Effects of Computerized Cognitive Training on Vesicular Acetylcholine Transporter Levels using [18F]Fluoroethoxybenzovesamicol Positron Emission Tomography in Healthy Older Adults: Results from the Improving Neurological Health in Aging via Neuroplasticity-based Computerized Exercise (INHANCE) Randomized Clinical Trial. JMIR Serious Games. 2025 Oct 13;13:e75161.

66.

Hao, Y., et al., Comparative Effectiveness of Different Dual Task Mode Interventions on Cognitive Function in Older Adults with Mild Cognitive Impairment or Dementia: A Systematic Review and Network Meta-Analysis. Aging Clinical and Experimental Research, 2025. 37(1): 139.

Tait, J.L., et al., Influence of Sequential vs. Simultaneous Dual-Task Exercise Training on Cognitive Function in Older Adults. Frontiers in Aging Neuroscience, 2017. 9: 368.

Szczepocka, E., et al., Virtual Reality-Based Training May Improve Visual Memory and Some Aspects of Sustained Attention Among Healthy Older Adults — Preliminary Results of a Randomized Controlled Study. BMC Psychiatry. 2024 May 8;24(1):347.

Raichlen, D.A., and Alexander, G.E., Adaptive Capacity: An Evolutionary Neuroscience Model Linking Exercise, Cognition, and Brain Health. Trends in Neuroscies. 2017 Jul;40(7):408-421.

67.

Khan, A., et al., Virtual reality in stroke recovery: a meta-review of systematic reviews. Bioelectronic Medicine, 2024. 10(1): 23.

Calderone, A., et al., Use of Virtual Reality in Patients with Acquired Brain Injury: A Systematic Review. Journal of Clinical Medicine, 2023 Dec 14;12(24):7680.

Anguera, J.A., et al., Assessing the Impact of a Virtual Reality Cognitive Intervention on Tennis Performance in Junior Tennis Players: Pilot Study. JMIR Formative Research. 2025 Feb 7;9:e66979.

Richlan, F., et al., Virtual training, real effects: a narrative review on sports performance enhancement through interventions in virtual reality. Frontiers in Psychology. 2023 Oct 19;14:1240790.

68.

Jordan, T. and M. Dhamala, Video game Players Have Improved Decision-Making Abilities and Enhanced Brain Activities. Neuroimage: Reports, 2022. 2(3): 100112.

69.

Clemenson, G.D., et al., Enriching Hippocampal Memory Function in Older Adults Through Video Games. Behavioural Brain Research, 2020. 390: 112667.

70.

Clemenson, G.D. and C.E. Stark, Virtual Environmental Enrichment Through Video Games Improves Hippocampal-Associated Memory. The Journal of Neuroscience, 2015. 35(49): pp. 16116–25.

71.

West, G.L., et al., Playing Super Mario 64 increases hippocampal grey matter in older adults. PLoS One, 2017. 12(12): e0187779.

Bergmann, M., et al., Effects of a video Game Intervention on Symptoms, Training Motivation, and Visuo-Spatial Memory in Depression. Frontiers in Psychiatry, 2023 Aug 24:14:1173652.

72.

Stark, C.E.L., et al., Playing Minecraft Improves Hippocampal-Associated Memory for Details in Middle Aged Adults. Frontiers in Sports and Active Living, 2021 Jul 5:3:685286.

Bediou, B., et al., Effects of Action Video Game Play on Cognitive Skills: A Meta-Analysis. Technology, Mind, and Behavior, 2023. 4(1).

73.

Ali, Z., J. Janarthanan, and Mohan, Understanding Digital Dementia and Cognitive Impact in the Current Era of the Internet: A Review. Cureus, 2024. 16(9): e70029.

74.

Benge, J.F. and M.K. Scullin, A Meta-Analysis of Technology Use and Cognitive Aging. Nature Human Behaviour, 2025 Jul;9(7):1405-1419.

75.

Vida, R.G., et al., Efficacy of Repetitive Transcranial Magnetic Stimulation (rTMS) Adjunctive Therapy for Major Depressive Disorder (MDD) After Two Antidepressant Treatment Failures: Meta-Analysis of Randomized Sham-Controlled Trials. BMC Psychiatry, 2023. 23(1): 545.

Zheng, W., et al., Adjunctive Transcranial Alternating Current Stimulation for Patients with Major Depressive Disorder: A Systematic Review and Meta-Analysis. Frontiers in Psychiatry, 2023. 14: 1154354.

Woodham, R.D., et al., Home-Based Transcranial Direct Current Stimulation Treatment for Major Depressive Disorder: a Fully Remote Phase 2 Randomized Sham-Controlled Trial. Nature Medicine. 2025 Jan;31(1):87-95.

Caumo, W., et al., Home-Based Transcranial Direct Current Stimulation vs Placebo for Fibromyalgia: A Randomized Clinical Trial. JAMA Network Open. 2025 Jun 2;8(6):e2514262.

Zheng, E.Z., et al., Evaluating the Effects of tDCS on Depressive and Anxiety Symptoms from a Transdiagnostic Perspective: A Systematic Review and Meta-Analysis of Randomized Controlled Trials. Translational Psychiatry, 2024. 14(1): 295.

Weiler, M., et al., Transcranial Magnetic Stimulation in Alzheimer’s Disease: Are We Ready? eNeuro, 2020. 7(1).

De Paolis, M.L., et al., Transcranial alternating Current Stimulation (Tacs) at Gamma Frequency: An Up-And-Coming Tool to Modify the Progression of Alzheimer’s Disease. Translational Neurodegeneration, 2024. 13(1): 33.

Saxena, V. and A. Pal, Role of Transcranial Direct Current Stimulation in the Management of Alzheimer’s Disease: A Meta-analysis of Effects, Adherence and Adverse Effects. Clinical Psychopharmacolgy and Neuroscience, 2021. 19(4): pp. 589–99.

Terney, D., et al., Increasing Human Brain Excitability by Transcranial High-Frequency Random Noise Stimulation. Journal of Neuroscience. 2008 Dec 24;28(52):14147-55.

Zacharopoulos, Get al., Functional Connectivity and GABAergic Signaling Modulate the Enhancement Effect of Neurostimulation on Mathematical Learning. PLoS Biology. 2025 Jul 1;23(7):e3003200.

Hajós, M., et al., Safety, tolerability, and efficacy estimate of evoked gamma oscillation in mild to moderate Alzheimer's disease. Frontiers in Neurolology. 2024 Mar 6;15:1343588.

Vargas-Caballero, M., et al., Vagus Nerve Stimulation as a Potential Therapy in Early Alzheimer's Disease: A Review. Frontiers in Human Neuroscience. 2022 Apr 29;16:866434.

Luo, S., et al., Vagus nerve and brain-gut communication in neurodegenerative diseases: Mechanism and therapeutic perspectives. Pharmacological Research. 2025 Nov;221:107974.

Wang, W., et al., Advances in VNS efficiency and mechanisms of action on cognitive functions. Frontiers in Physiology. 2024 Oct 9;15:1452490.

Zhang, S., et al., Transcutaneous Auricular Vagus Nerve Stimulation for Chronic Insomnia Disorder: A Randomized Clinical Trial. JAMA Network Open. 2024 Dec 2;7(12):e2451217.

Nizamutdinov, D., et al., Transcranial Near Infrared Light Stimulations Improve Cognition in Patients with Dementia. Aging and Disease. 2021 Jul 1;12(4):954-963.

Lindsey, H.M., et al., Transcranial Photobiomodulation Promotes Neurological Resilience in Current Collegiate American Football Players Exposed to Repetitive Head Acceleration Events. Journal of Neurotrauma. 2026;0(0).

Nizamutdinov, D., et al., Therapeutic Effects of Near Infrared Light Stimulation on Cognitive and Behaviour Symptoms of Dementia. The FASEB Journal, 2020, 34: 1-1.

Guo, R., et al., Effects of whole-head 810 nm near-infrared therapy on cognitive and neuropsychiatric symptoms in Alzheimer's disease: A pilot study. Journal of Alzheimers Disease. 2025 Mar;104(1):52-60.

Berman, M.H., et al., Photobiomodulation with Near Infrared Light Helmet in a Pilot, Placebo Controlled Clinical Trial in Dementia Patients Testing Memory and Cognition. Journal of Neurology and Neuroscience. 2017;8(1):176.

Jog, M.A., et al., Personalized High-Definition Transcranial Direct Current Stimulation for the Treatment of Depression: A Randomized Clinical Trial. JAMA Network Open. 2025 Sep 2;8(9):e2531189.

Rektorová, I., et al., Non-invasive brain stimulation: current and future applications in neurology. Nature Reviews Neurology, 2025. 21, 669–686.

76.

Ji, Z., et al., Survey of Hallucination in Natural Language Generation. ACM Computing Surveys, 2023. 55(12): 248.

Hicks, M.T., J. Humphries, and J. Slater, ChatGPT Is Bullshit. Ethics and Information Technology, 2024. 26(2): 38.

Ford, K.M., et al., Cognitive Orthoses: Towards Human-Centered AI. AI Magazine, 2015, 36(4), 5-8.

77.

Carr, D.C., et al., Alternative Retirement Paths and Cognitive Performance: Exploring the Role of Preretirement Job Complexity. Gerontologist, 2020. 60(3): pp. 460–71.

78.

Akbaraly, T.N., et al., Leisure Activities and the Risk of Dementia in the Elderly: Results from the Three-City Study. Neurology, 2009. 73(11): pp. 854–61.

79.

Ehlenbach, W.J., et al., Association Between Acute Care and Critical Illness Hospitalization and Cognitive Function in Older Adults. JAMA, 2010. 303(8): pp. 763–70.

80.

Balbim, G.M., et al., Exercise Counters the Negative Impact of Bed Rest on Executive Functions in Middle-Aged and Older Adults: A Proof-of-Concept Randomized Controlled Trial. Maturitas, 2024. 179: 107869.

81.

Brauns, K., et al., Effects of Two Months of Bed Rest and Antioxidant Supplementation on Attentional Processing. Cortex, 2021. 141: pp. 81–93.

82.

Cantuaria, M.L., et al., Hearing Loss, Hearing Aid Use, and Risk of Dementia in Older Adults. JAMA Otolaryngology–Head & Neck Surgery, 2024. 150(2): 157.

Ferguson, E.L., et al., Visual Impairment, Eye Conditions, and Diagnoses of Neurodegeneration and Dementia. JAMA Network Open, 2024. 7(7): e2424539.

Lin, F.R., et al., Hearing intervention Versus Health Education Control to Reduce Cognitive Decline in Older Adults with Hearing Loss in the USA (ACHIEVE): A Multicentre, Randomised Controlled Trial. The Lancet, 2023. 402(10404): pp. 786–97.

Francis,L., et al., Self-Reported Hearing Aid Use and Risk of Incident Dementia. JAMA Neurolology. 2025 Aug 18:e252713.

Cribb, L., et al., Treating Hearing Loss With Hearing Aids for the Prevention of Cognitive Decline and Dementia. Neurology. 2026 Feb 10;106(3):e214572.

83.

Lee, C.S., et al., Association Between Cataract Extraction and Development of Dementia. JAMA Internal Medicine, 2022. 182(2): 134.

84.

Makin, T.R. and J.W. Krakauer, Against Cortical Reorganisation. Neuroscience, 2023. 12: e84716.

85.

Karpel, H., Are Noise-Cancelling Headphones to Blame for Young People’s Hearing Problems? BBC News, February 15, 2025. Available↗

86.

Wingrove, J., et al., Aberrant olfactory Network Functional Connectivity in People with Olfactory Dysfunction Following COVID-19 Infection: An Exploratory, Observational Study. eClinicalMedicine, 2023. 58: 101883.

Kausel, L., et al., Patients Recovering from COVID-19 Who Presented with Anosmia During Their Acute Episode Have Behavioral, Functional, and Structural Brain Alterations. Scientific Reports, 2024. 14(1): 19049.

87.

Leon, M. and C. Woo, Environmental Enrichment and Successful Aging. Frontiers in Behavioral Neuroscience, 2018Jul 23;12:155.

88.

Scholz, J., et al., Training Induces Changes in White-Matter Architecture. Nature Neuroscience, 2009. 12(11): pp. 1370–71.

Malik, J., R. Stemplewski, and J. Maciaszek, The Effect of Juggling as Dual-Task Activity on Human Neuroplasticity: A Systematic Review. International Journal of Environmental Research and Public Health, 2022. 19(12): 7102.

Draganski, B., et al., Changes in Grey Matter Induced by Training. Nature, 2004. 427(6972): pp. 311–12.

89.

Ware, C. et al., Does Second Language Learning Promote Neuroplasticity in Aging? A Systematic Review of Cognitive and Neuroimaging Studies. Frontiers in Aging Neuroscience, 2021. 13: 706672.

90.

Meltzer, J.A., et al., Improvement in executive function for older adults through smartphone apps: A randomized clinical trial comparing language learning and brain training. Aging, Neuropsychology, and Cognition, 30(2), 150–171.

91.

Rogers, F. and C. Metzler-Baddeley, The Effects of Musical Instrument Training on Fluid Intelligence and Executive Functions in Healthy Older Adults: A Systematic Review and Meta-Analysis. Brain and Cognition, 2024. 175: 106137.

92.

Zhang, H., et al., Effects of Dance Interventions on Cognitive Function, Balance, Mobility, and Life Quality in Older Adults: A Systematic Review and Bayesian Network Meta-Analysis. Archives of Gerontology and Geriatrics, 2025. 131: 105775.

93.

94.

Tennstedt and Unverzagt, The ACTIVE Study: Study Overview and Major Findings. Journal of Aging and Health, 2013. 25(8 Suppl): pp. 3s–20s.

Bonnechère, B., C. Langley, and B.J. Sahakian, The Use of Commercial Computerised Cognitive Games in Older Adults: A Meta-Analysis. Scientific Reports, 2020. 10(1): 15276.

Wolinsky, F.D., et al., The ACTIVE cognitive training trial and health-related quality of life: protection that lasts for 5 years. Journals of Gerontololgy: Series. 2006 Dec;61(12):1324-9.

Coe, N.B., et al., Impact of cognitive training on claims-based diagnosed dementia over 20 years: evidence from the ACTIVE study. Alzheimer’s and Dementia. 2026 Feb 9;12(1):e70197.

95.

Sherman, D.S., et al., The Efficacy of Cognitive Intervention in Mild Cognitive Impairment (MCI): a Meta-Analysis of Outcomes on Neuropsychological Measures. Neuropsychology Review, 2017. 27(4): pp. 440–84.

96.

Smith, E.T. and C. Basak, A Game-Factors Approach to Cognitive Benefits from Video-Game Training: A Meta-Analysis. PLoS One, 2023. 18(8): e0285925.

Coronel-Oliveros, C., et al., Creative experiences and brain clocks. Nature Communications, 2025. 16, 8336.

97.

98.

Woo, C.C., et al., Overnight Olfactory Enrichment Using an Odorant Diffuser Improves Memory and Modifies the Uncinate Fasciculus in Older Adults. Frontiers in Neuroscience, 2023. 17: 1200448.

99.

Yakushina, A., et al., Chess Classes and Executive Function Skills in 5-6 Years old Children: Evidence From Cross-Sectional Study. Frontiers in Psychology. 2025 Jul 21;16:1564963.

Rosholm, M., et al., Your Move: The Effect of Chess on Mathematics Test Scores. PLoS One. 2017 May 11;12(5):e0177257.

Lillo-Crespo, M., et al., Chess Practice as a Protective Factor in Dementia. International Journal of Environmental Research and Public Health. 2019 Jun 14;16(12):2116.

100.

Hale, J.M., M.J. Bijlsma, and A. Lorenti, Does Postponing Retirement Affect Cognitive Function? A Counterfactual Experiment to Disentangle Life Course Risk Factors. SSM—Population Health, 2021. 15: 100855.

101.

Andel, R., et al., Retirement and Cognitive Aging in a Racially Diverse Sample of Older Americans. Journal of the American Geriatrics Society, 2023. 71(9): pp. 2769–78.

102.

Martela, F., Laitinen, E., and Hakulinen, C., Which Predicts Longevity Better: Satisfaction with Life or Purpose in Life? Psychology and Aging, 2024. 39 (6): pp. 589–98.

103.

Sutin, A.R., et al., Sense of Purpose in Life Is Associated with Lower Risk of Incident Dementia: A Meta-Analysis. Journal of Alzheimer’s Disease, 2021. 83(1): pp. 249–58.

104.

Chang, Y.H., I.C. Wu, and C.A. Hsiung, Reading Activity Prevents Long-Term Decline in Cognitive Function in Older People: Evidence from a 14-Year Longitudinal Study. International Psychogeriatrics, 2021. 33(1): pp. 63–74.

Carney, J., and Robertson, C., Five Studies Evaluating the Impact on Mental Health and Mood of Recalling, Reading, and Discussing Fiction. PLoS One. 2022 Apr 8;17(4):e0266323.

Wimmer, L., et al., Cognitive effects and correlates of reading fiction: Two preregistered multilevel meta-analyses. Journal of Experimental Psychology: General. 2024 Jun;153(6):1464-1488.

Hughes, T.F., et al., Engagement in reading and hobbies and risk of incident dementia: the MoVIES project. American Journal of Alzheimer’s Disease and Other Dementias. 2010 Aug;25(5):432-8.

105.

Levy, B.R., et al., Longevity Increased by Positive Self-Perceptions of Aging. Journal of Personality and Social Psychology, 2002. 83(2): pp. 261–70.

Tully-Wilson, C., et al., Self-perceptions of aging: A systematic review of longitudinal studies. Psychology and Aging. 2021 Nov;36(7):773-789.

Rodrigues, M., et al., Aging anxiety and epigenetic aging in a national sample of adult women in the United States. Psychoneuroendocrinology. 2026 Feb;184:107704.

106.

Lee, L.O., et al., Optimism Is Associated with Exceptional Longevity in 2 Epidemiologic Cohorts of Men and Women. Proceedings of the National Academy of Sciences, 2019. 116(37): pp. 18357–62.

Index