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Cognitive reserve

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Cognitive reserve is the mind's and brain's resistance to damage of the brain. The mind's resilience is evaluated behaviorally, whereas the neuropathological damage is evaluated histologically, although damage may be estimated using blood-based markers and imaging methods. There are two models that can be used when exploring the concept of "reserve": brain reserve and cognitive reserve. These terms, albeit often used interchangeably in the literature, provide a useful way of discussing the models. Using a computer analogy, brain reserve can be seen as hardware and cognitive reserve as software. All these factors are currently believed to contribute to global reserve. Cognitive reserve is commonly used to refer to both brain and cognitive reserves in the literature.

In 1988 a study published in Annals of Neurology reporting findings from post-mortem examinations on 137 elderly persons unexpectedly revealed that there was a discrepancy between the degree of Alzheimer's disease neuropathology and the clinical manifestations of the disease:[1] some participants whose brains had extensive Alzheimer's disease pathology, had no or very few clinical manifestations of the disease. Furthermore, the study showed that these persons had higher brain weights and greater number of neurons as compared to age-matched controls. The investigators speculated with two possible explanations for this phenomenon: these people may have had incipient Alzheimer's disease but somehow avoided the loss of large numbers of neurons, or alternatively, started with larger brains and more neurons and thus might be said to have had a greater "reserve". This is the first time this term has been used in the literature in this context.

The study sparked off interest in this area, and to try to confirm these initial findings further studies were done. Higher reserve was found to provide a greater threshold before clinical deficit appears.[2][3][4] Furthermore, those with higher capacity showed more rapid decline once becoming clinically impaired, probably indicating a failure of all compensatory systems and strategies put in place by the individual with greater reserve to cope with the increasing neuropathological damage.[5]

Brain reserve

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Brain reserve may be defined as the brain's resilience, its ability to cope with increasing damage while still functioning adequately. This passive, threshold model presumes the existence of a fixed cut-off which, once reached, would inevitably lead to clinical manifestations of dementia.

Brain size

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A 1997 study found that Alzheimer's disease pathology in large brains did not necessarily result in clinical dementia.[6] Another study reported head circumference to be independently associated with a reduced risk of clinical Alzheimer's disease.[7]

While some studies, like those mentioned, find an association, others do not. This is thought to be because head circumference and other approximations are indirect measures.

Number of neuronal connections

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The amount of synapse loss is greater in early onset dementia than in late onset dementia.[8] This might indicate a vulnerability to the manifestation of clinical cognitive impairment, although there may be other explanations.

Structures like the cerebellum contribute to brain reserve.[9] The cerebellum contains the majority of neurons in the brain and participates in both cognitive and motor operations.[10] Cerebellar circuitry is a site of multiple forms of neuronal plasticity, a factor playing a major role in terms of brain reserve.[11]

Genetic component of cognitive reserve

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Evidence from a twin study indicates a genetic contribution to cognitive functions.[12] Heritability estimates have been found to be high for general cognitive functions but low for memory itself.[13] Adjusting for the effects of education 79% of executive function can be explained by genetic contribution.[14] A study combining twin and adoption studies found all cognitive functions to be heritable. Speed of processing had the highest heritability in this particular study.[15]

Cognitive reserve

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Cognitive reserve also indicates a resilience to neuropathological damage, but the emphasis here is in the way the brain uses its damaged resources. It could be defined as the ability to optimize or maximize performance through differential recruitment of brain networks and/or alternative cognitive strategies. This is an efficiency model, rather than a threshold model, and it implies that the task is processed using less resources or using neural resources more efficiently, resulting in better cognitive performance. Studies use factors like education, occupation, and lifestyle as proxies for cognitive reserve because they tend to positively correlate with higher cognitive reserve.

Education and occupation

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More education and cognitively complex occupation are some of the factors that predict higher cognitive abilities in old age.[16] Therefore, two most commonly used proxies to study cognitive reserve are education and occupation. Education is known to play a role in cognitive decline in normal aging, as well as in degenerative diseases or traumatic brain injuries.[17] A higher prevalence of dementia in individuals with fewer years of education has suggested that education may protect against Alzheimer's disease.[18] Moreover, the level of education has a strong impact on adult's lifestyle. Level of education is measured by the number of years an individual spends in school or alternatively, the degree of literacy.[17] Possibly, the level of education itself provides a set of cognitive tools that allow the individual to compensate for the pathological changes.[18] Cognitive Reserve Index Questionnaire (CRIq), devised to assess the level of cognitive reserve in order to provide better diagnosis and treatment, takes into account years of education and possible training courses lasting at least six months to assess the education load on cognitive reserve.[17] Clinically, education is negatively correlated with dementia severity,[19] but positively correlated with grey matter atrophy, intracranial volume, and overall global cognition.[20][21] Neurologically, education is correlated to greater functional connectivity between fronto-parietal regions[22] and greater cortical thickness in the left inferior temporal gyrus.[23] In addition to the level of education, it has been shown that bilingualism enhances attention and cognitive control in both children and older adults and delays the onset of dementia. It allows the brain to better tolerate the underlying pathologies and can be considered as a protective factor contributing positively to the cognitive reserve.[24] Another proxy for cognitive reserve is the occupation. Studies suggest that occupation may provide additive and independent source of cognitive reserve throughout person's life. The last or the longest job is usually taken into account. Occupation values may vary in terms of cognitive load involved. Some other common indices, such as prestige or salary can also be considered. Working activity measured by CRIq assesses adulthood professions. There are five different levels of working activities available, differing in the degree of intellectual involvement and personal responsibility. Working activity was recorded as the number of years in each profession over the lifespan.[17] Occupation as a proxy for cognitive reserve is positively correlated with local efficiency and functional connectivity in the right medial temporal lobe.[23] More cognitively stimulating occupations are weakly associated with greater memory, but are more strongly correlated with greater executive functioning.[21] These two proxies are typically measured together and are typically highly correlated with each other.[21] A genetic study using Mendelian randomization analysis demonstrated that high occupation levels were associated with reduced risk for Alzheimer’s disease. In addition, this study confirmed that occupational attainment had an independent effect on the risk for Alzheimer’s disease even after taking educational attainment into account.[25]

Premorbid intelligence

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Intellectual quotients derived from psychometric testing have been identified as valuable proxy measures of cognitive reserve, with higher scores relative to the mean being associated with slower rates of cognitive decline.[26] However, the rate of decline in some cognitive subdomains, such as processing speed, may be less affected by premorbid IQ.[27] The degree of association between IQ and cognitive reserve may vary between different types of dementia.[28]

Lifestyle

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For any given level of clinical impairment, there is a higher degree of neuropathological change in the brains of those Alzheimer's disease sufferers who are involved in greater number of activities. This is true even when education and IQ are controlled for. This suggests that differences in lifestyle may increase cognitive reserve by making the individual more resilient.[29] In other words, everyday experience affecting cognition is analogous to physical exercise influencing musculoskeletal and cardiovascular functions.[30] Using cerebral blood flow as an indirect measure of neuropathological damage, lower CBF indicating more damage, it was found that at a given level of clinical impairment leisure activity score was negatively correlated with CBF.[30] In other words, individuals with greater activity score were able to withstand more brain damage and therefore can be said to have more reserve. Mortimer et al. performed cognitive testing on a population of 678 nuns in 1997, in which they showed that different levels of cognitive activity and performance were possible in patients diagnosed with Alzheimer's. One subject showing reduced neocortical plaques survived with mild deficits, despite (or due to) low brain weight.

Lifestyle factors

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More recent studies distinguish four modifiable lifestyle factors which influence cognitive health in later life and offer potential to reduce the risk of cognitive decline and dementia.[31] Between 2011 and 2013 the Cognitive Function and Aging Study Wales (CFAS-Wales) collected data from a cohort of 2,315 cognitively healthy participants aged 65 years and over, not only confirming the theory of impacting lifestyle factors but also detecting a mediating effect of cognitive reserve on the cross-sectional association between lifestyle factors and cognitive function in later life.

Findings
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Cognitive and social activity: People with high leisure activity of intellectual (reading magazines or newspapers or books, playing cards, games or bingo, going to classes etc.), social (visiting or being visited by friends or relatives, etc.), engaging (helping others with daily tasks, paid work and volunteer work) nature have a significant smaller risk of developing dementia.[30]

Physical activity: Has a strong impact on developing cognitive decline or dementia.[31]

Healthy diet: Research on healthy diets emphasizes the benefits of adhering to the Mediterranean-style diet as protection of cognitive health.[31]

Alcohol consumption: Studies suggest that light-to-moderate alcohol intake is associated with lower risk (once or twice a week or three or four times a week), as were frequent drinking in earlier life is identified as a risk factor for cognitive decline in later life.[31]

Due to the variety of the four lifestyle factors, a lot of different self-report-scales are used to specify the severity of each proxy.

Parkinson's disease

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Parkinson's disease is an example for a condition which is associated with the role of cognitive reserve and cognitive impairment. Previous investigation into Parkinson's disease implicated a possible influence of cognitive reserve in the human brain.

According to some studies[32] the so-called Cognitive Lifestyle is seen as a general protective factor that can be mediated though several different mechanisms.

A study from 2015[33] included the effects of (cognitive) lifestyle on cross-sectional and longitudinal measures. 525 participants with Parkinson’s disease completed different baseline assessments of cognition and provided clinical, social and demographic data. After 4 years 323 participated in a cognition assessment in the follow-up. The researchers therefore used the measures of global cognition dementia severity. It has been shown, that next to the educational level and the socio-economic status a higher level of recent social engagement was also associated with a decreased risk of dementia.  On the other hand, increasing age and low levels of social engagement may increase the risk of dementia in Parkinson’s disease.

Global reserve

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In spite of the differences in approach between the models of brain reserve and cognitive reserve, there is evidence that both might be interdependent and related. This is where the computer analogy ends, as with the brain it seems that hardware can be changed by software.

Neurotrophic effect of knowledge

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Exposure to an enriched environment, defined as a combination of more opportunities for physical activity, learning and social interaction, may produce structural and functional changes in the brain and influence the rate of neurogenesis in adult and senescent animal model hippocampi.[34] Many of these changes can be effected merely by introducing a physical exercise regimen rather than requiring cognitive activity per se.[35]

In humans, the posterior hippocampi of licensed London taxi drivers was famously found to be larger than that of matched controls, while the anterior hippocampi were smaller.[36] This study shows that people choosing taxi driving as a career (one which has as a barrier to entry—the ability to memorize London's streets—described as "the world's most demanding test (of street knowledge)") have larger hippocampi, but does not demonstrate change in volume as a result of driving. Similarly, while acquiring a second language requires extensive and sustained cognitive activity, it does not appear to reduce dementia risk compared to those who have not learned another language,[37] although lifelong bilingualism is associated with delayed onset of Alzheimer's disease.[38]

Clinical implications

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The clinical diagnosis of dementia is not perfectly linked to levels of underlying neuropathology. The severity of pathologies and the deficit in cognitive performance could not have direct relationship. The theory of cognitive reserve explains this phenomenon. Katzman et al. (1998) conducted a study on the autopsy results of 10 people and found a pathology related to Alzheimer's disease.[1] However, the same patients showed no symptoms of Alzheimer's disease during their life time. So, when pathology emerges in the brain, cognitive reserve helps to cope with cognitive decline. Thus, individuals with high cognitive reserve cope better than those with low cognitive reserve even if they have the same pathology.[39] This causes people with high cognitive reserve to go un-diagnosed until damage becomes severe.

Cognitive reserve, which can be estimated clinically, is affected by many variables. The Cognitive Reserve Index questionnaire (CRIq) measures cognitive reserve under three main sources, namely the education, work activities and leisure time activities throughout the individual's lifespan.[40]

It is important to note that cognitive reserve (and the variables associated with it) do not "protect" from Alzheimer's disease as a disease process—the definition of cognitive reserve is based exactly on the presence of disease pathology. This means that the traditional idea that education protects from Alzheimer's disease is false, albeit that cognitive reserve is protective of the clinical manifestations of disease.[34] As of 2010, there was insufficient evidence to recommend any way to increase cognitive reserve to prevent dementia or Alzheimer's.[35] On the other hand, cognitive reserve has a very important impact on neurodegenerative diseases. Patients with high cognitive reserve showed a delay in cognitive decline when compared to patients with low cognitive reserve. However, when the symptoms of cognitive decline become symptomatic, patients with high cognitive reserve show rapid cognitive decline.[41]

The presence of cognitive reserve implies that people with greater reserve who already are suffering neuropathological changes in the brain will not be picked up by standard clinical cognitive testing. Conversely anyone who has used these instruments clinically knows that they can yield false positives in people with very low reserve. From this point of view the concept of "adequate level of challenge" easily emerges. Conceivably one could measure cognitive reserve and then offer specifically tailored tests that would pose enough level of challenge to accurately detect early cognitive impairment both in individuals with high and low reserve. This has implications for treatment and care.

In people with high reserve, deterioration occurs rapidly once the threshold is reached.[36] In these individuals and their careers early diagnosis might provide an opportunity to plan future care and to adjust to the diagnosis while they are still able to make decisions. A cognitive rehabilitation study, conducted with dementia patients, showed that patients with low cognitive reserve had better outcomes from cognitive training rehabilitation when compared to high cognitive reserve. This is due to the fact that the patients with high cognitive reserve had delayed cognitive symptoms and therefore the disease could no longer resist the pathology. Furthermore, the improvement seen in the patients with low cognitive reserve indicates that these patients can build their cognitive reserve as a life-long process.[42]

References

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  1. ^ a b Katzman R, Terry R, DeTeresa R, Brown T, Davies P, Fuld P, Renbing X, Peck A (February 1988). "Clinical, pathological, and neurochemical changes in dementia: a subgroup with preserved mental status and numerous neocortical plaques". Annals of Neurology. 23 (2): 138–44. doi:10.1002/ana.410230206. PMID 2897823. S2CID 31389744.
  2. ^ Katzman R (January 1993). "Education and the prevalence of dementia and Alzheimer's disease". Neurology. 43 (1): 13–20. doi:10.1212/wnl.43.1_part_1.13. PMID 8423876. S2CID 42469859.
  3. ^ Stern Y, Gurland B, Tatemichi TK, Tang MX, Wilder D, Mayeux R (April 1994). "Influence of education and occupation on the incidence of Alzheimer's disease". JAMA. 271 (13): 1004–10. doi:10.1001/jama.1994.03510370056032. PMID 8139057.
  4. ^ Satz P, Morgenstern H, Miller EN, Selnes OA, McArthur JC, Cohen BA, Wesch J, Becker JT, Jacobson L, D'Elia LF (May 1993). "Low education as a possible risk factor for cognitive abnormalities in HIV-1: findings from the multicenter AIDS Cohort Study (MACS)". Journal of Acquired Immune Deficiency Syndromes. 6 (5): 503–11. doi:10.1097/00126334-199305000-00011. PMID 8483113.
  5. ^ Wilson RS, Bennett DA, Gilley DW, Beckett LA, Barnes LL, Evans DA (December 2000). "Premorbid reading activity and patterns of cognitive decline in Alzheimer disease". Archives of Neurology. 57 (12): 1718–23. doi:10.1001/archneur.57.12.1718. PMID 11115237.
  6. ^ Mori E, Hirono N, Yamashita H, Imamura T, Ikejiri Y, Ikeda M, Kitagaki H, Shimomura T, Yoneda Y (January 1997). "Premorbid brain size as a determinant of reserve capacity against intellectual decline in Alzheimer's disease". The American Journal of Psychiatry. 154 (1): 18–24. doi:10.1176/ajp.154.1.18. PMID 8988953.
  7. ^ Mortimer JA, Snowdon DA, Markesbery WR (August 2003). "Head circumference, education and risk of dementia: findings from the Nun Study". Journal of Clinical and Experimental Neuropsychology. 25 (5): 671–9. doi:10.1076/jcen.25.5.671.14584. PMID 12815504. S2CID 20727671.
  8. ^ Bigio EH, Hynan LS, Sontag E, Satumtira S, White CL (June 2002). "Synapse loss is greater in presenile than senile onset Alzheimer disease: implications for the cognitive reserve hypothesis". Neuropathology and Applied Neurobiology. 28 (3): 218–27. doi:10.1046/j.1365-2990.2002.00385.x. PMID 12060346. S2CID 25125923.
  9. ^ Mitoma H, Manto M, Hampe CS (2017). "Immune-mediated cerebellar ataxias: from bench to bedside". Cerebellum & Ataxias. 4: 16. doi:10.1186/s40673-017-0073-7. PMC 5609024. PMID 28944066.
  10. ^ Bodranghien F, Bastian A, Casali C, Hallett M, Louis ED, Manto M, Mariën P, Nowak DA, Schmahmann JD, Serrao M, Steiner KM, Strupp M, Tilikete C, Timmann D, van Dun K (June 2016). "Consensus Paper: Revisiting the Symptoms and Signs of Cerebellar Syndrome". Cerebellum. 15 (3): 369–91. doi:10.1007/s12311-015-0687-3. PMC 5565264. PMID 26105056.
  11. ^ Mitoma, H.; Buffo, A.; Gelfo, F.; Guell, X.; Fucà, E.; Kakei, S.; Lee, J.; Manto, M.; Petrosini, L.; Shaikh, A. G.; Schmahmann, J. D. (February 2020). "Consensus Paper. Cerebellar Reserve: From Cerebellar Physiology to Cerebellar Disorders". Cerebellum (London, England). 19 (1): 131–153. doi:10.1007/s12311-019-01091-9. ISSN 1473-4230. PMC 6978437. PMID 31879843.
  12. ^ Ando J, Ono Y, Wright MJ (2001). "Genetic structure of spatial and verbal working memory". Behavioral Genetics. 31 (6): 615–24. doi:10.1023/A:1013353613591. PMID 11838538. S2CID 39136550.
  13. ^ Swan GE, Carmelli D, Reed T, Harshfield GA, Fabsitz RR, Eslinger PJ (March 1990). "Heritability of cognitive performance in aging twins. The National Heart, Lung, and Blood Institute Twin Study". Archives of Neurology. 47 (3): 259–62. doi:10.1001/archneur.1990.00530030025010. PMID 2310310.
  14. ^ Swan GE, Carmelli D (2002). Evidence for genetic mediation of executive control: a study of aging male twins. Journals of Gerontology Series B: Psychological Sciences and Social Sciences. 57(2):P133-43
  15. ^ Plomin R, Pedersen NL, Lichtenstein P, McClearn GE (May 1994). "Variability and stability in cognitive abilities are largely genetic later in life". Behavior Genetics. 24 (3): 207–15. doi:10.1007/bf01067188. PMID 7945151. S2CID 6503298.
  16. ^ Staff, Roger T.; Murray, Alison D.; Deary, Ian J.; Whalley, Lawrence J. (2004). "What provides cerebral reserve?". Brain. 127 (Pt 5): 1191–1199. doi:10.1093/brain/awh144. ISSN 0006-8950. PMID 15047587.
  17. ^ a b c d Nucci, Massimo; Mapelli, Daniela; Mondini, Sara (2012-06-01). "Cognitive Reserve Index questionnaire (CRIq): a new instrument for measuring cognitive reserve". Aging Clinical and Experimental Research. 24 (3): 218–26. doi:10.3275/7800. PMID 21691143. S2CID 7306499.
  18. ^ a b Mayeux, Richard; Prohovnik, Isak; Alexander, Gene E.; Stern, Yaakov (1992-09-01). "Inverse relationship between education and parietotemporal perfusion deficit in Alzheimer's disease". Annals of Neurology. 32 (3): 371–5. doi:10.1002/ana.410320311. PMID 1416806. S2CID 20777087.
  19. ^ Groot C, van Loenhoud AC, Barkhof F, van Berckel BN, Koene T, Teunissen CC, Scheltens P, van der Flier WM, Ossenkoppele R (January 2018). "Differential effects of cognitive reserve and brain reserve on cognition in Alzheimer disease". Neurology. 90 (2): e149–e156. doi:10.1212/WNL.0000000000004802. PMID 29237798. S2CID 10750586.
  20. ^ Mungas D, Gavett B, Fletcher E, Farias ST, DeCarli C, Reed B (August 2018). "Education amplifies brain atrophy effect on cognitive decline: implications for cognitive reserve". Neurobiology of Aging. 68: 142–150. doi:10.1016/j.neurobiolaging.2018.04.002. PMC 5993638. PMID 29798764.
  21. ^ a b c Opdebeeck C, Martyr A, Clare L (2016-01-02). "Cognitive reserve and cognitive function in healthy older people: a meta-analysis" (PDF). Neuropsychology, Development, and Cognition. Section B, Aging, Neuropsychology and Cognition. 23 (1): 40–60. doi:10.1080/13825585.2015.1041450. PMID 25929288. S2CID 25058178.
  22. ^ Stern Y, Gazes Y, Razlighi Q, Steffener J, Habeck C (September 2018). "A task-invariant cognitive reserve network". NeuroImage. 178: 36–45. doi:10.1016/j.neuroimage.2018.05.033. PMC 6409097. PMID 29772378.
  23. ^ a b Lee DH, Lee P, Seo SW, Roh JH, Oh M, Oh JS, Oh SJ, Kim JS, Jeong Y (February 2019). "Neural substrates of cognitive reserve in Alzheimer's disease spectrum and normal aging". NeuroImage. 186: 690–702. doi:10.1016/j.neuroimage.2018.11.053. PMID 30503934. S2CID 53811225.
  24. ^ Craik, Fergus I. M.; Bialystok, Ellen; Freedman, Morris (2010-11-09). "Delaying the onset of Alzheimer disease: bilingualism as a form of cognitive reserve". Neurology. 75 (19): 1726–1729. doi:10.1212/WNL.0b013e3181fc2a1c. PMC 3033609. PMID 21060095.
  25. ^ Ko, H; Kim, S; Kim, K; Jung, SH; Shim, I; Cha, S; Lee, H; Kim, B; Yoon, J; Ha, TH; Kwak, S; Kang, JM; Lee, JY; Kim, J; Park, WY; Nho, K; Kim, DK; Myung, W; Won, HH (24 May 2022). "Genome-wide association study of occupational attainment as a proxy for cognitive reserve". Brain: A Journal of Neurology. 145 (4): 1436–1448. doi:10.1093/brain/awab351. PMID 34613391.
  26. ^ Boyle, R.; Knight, S. P.; De Looze, C.; Carey, D.; Scarlett, S.; Stern, Y.; Robertson, I. H.; Kenny, R. A.; Whelan, R. (2021-07-12). "Verbal intelligence is a more robust cross-sectional measure of cognitive reserve than level of education in healthy older adults". Alzheimer's Research & Therapy. 13 (1): 128. doi:10.1186/s13195-021-00870-z. ISSN 1758-9193. PMC 8276413. PMID 34253231.
  27. ^ Gazes, Yunglin; Lee, Seonjoo; Fang, Zhiqian; Mensing, Ashley; Noofoory, Diala; Nazario, Geneva Hidalgo; Babukutty, Reshma; Habeck, Christian; Stern, Yaakov (2021-02-23), IQ moderation of cognitive decline supports cognitive reserve and not brain maintenance, doi:10.1101/2021.02.19.21251920, retrieved 2024-08-17
  28. ^ Russ, Tom C. (2018-09-07). "Intelligence, Cognitive Reserve, and Dementia: Time for Intervention?". JAMA Network Open. 1 (5): e181724. doi:10.1001/jamanetworkopen.2018.1724. ISSN 2574-3805. PMID 30646136.
  29. ^ Scarmeas, Nikolaos; Zarahn, Eric; Anderson, Karen E.; Habeck, Christian G.; Hilton, John; Flynn, Joseph; Marder, Karen S.; Bell, Karen L.; Sackeim, Harold A.; Van Heertum, Ronald L.; Moeller, James R.; Stern, Yaakov (1 March 2003). "Association of Life Activities With Cerebral Blood Flow in Alzheimer Disease". Archives of Neurology. 60 (3): 359–65. doi:10.1001/archneur.60.3.359. PMC 3028534. PMID 12633147.
  30. ^ a b c Scarmeas, Nikolaos; Stern, Yaakov (2003). "Cognitive Reserve and Lifestyle". Journal of Clinical and Experimental Neuropsychology. 25 (5): 625–633. doi:10.1076/jcen.25.5.625.14576. ISSN 1380-3395. PMC 3024591. PMID 12815500.
  31. ^ a b c d Clare, Linda; Wu, Yu-Tzu; Teale, Julia C.; MacLeod, Catherine; Matthews, Fiona; Brayne, Carol; Woods, Bob (2017-03-21). "Potentially modifiable lifestyle factors, cognitive reserve, and cognitive function in later life: A cross-sectional study". PLOS Medicine. 14 (3): e1002259. doi:10.1371/journal.pmed.1002259. ISSN 1549-1676. PMC 5360216. PMID 28323829.
  32. ^ Valenzuela, Michael J.; Matthews, Fiona E.; Brayne, Carol; Ince, Paul; Halliday, Glenda; Kril, Jillian J.; Dalton, Marshall A.; Richardson, Kathryn; Forster, Gill (2012). "Multiple Biological Pathways Link Cognitive Lifestyle to Protection from Dementia". Biological Psychiatry. 71 (9): 783–791. doi:10.1016/j.biopsych.2011.07.036. ISSN 0006-3223. PMID 22055015. S2CID 21944032.
  33. ^ Hindle, John V.; Hurt, Catherine S.; Burn, David J.; Brown, Richard G.; Samuel, Mike; Wilson, Kenneth C.; Clare, Linda (2015-03-17). "The effects of cognitive reserve and lifestyle on cognition and dementia in Parkinson's disease-a longitudinal cohort study" (PDF). International Journal of Geriatric Psychiatry. 31 (1): 13–23. doi:10.1002/gps.4284. ISSN 0885-6230. PMID 25781584. S2CID 1589655.
  34. ^ a b Brown J, Cooper-Kuhn CM, Kempermann G, Van Praag H, Winkler J, Gage FH, Kuhn HG (May 2003). "Enriched environment and physical activity stimulate hippocampal but not olfactory bulb neurogenesis". The European Journal of Neuroscience. 17 (10): 2042–6. doi:10.1046/j.1460-9568.2003.02647.x. PMID 12786970. S2CID 25304270.
  35. ^ a b van Praag H, Christie BR, Sejnowski TJ, Gage FH (November 1999). "Running enhances neurogenesis, learning, and long-term potentiation in mice". Proceedings of the National Academy of Sciences of the United States of America. 96 (23): 13427–31. Bibcode:1999PNAS...9613427V. doi:10.1073/pnas.96.23.13427. PMC 23964. PMID 10557337.
  36. ^ a b Maguire EA, Gadian DG, Johnsrude IS, Good CD, Ashburner J, Frackowiak RS, Frith CD (April 2000). "Navigation-related structural change in the hippocampi of taxi drivers". Proceedings of the National Academy of Sciences of the United States of America. 97 (8): 4398–403. Bibcode:2000PNAS...97.4398M. doi:10.1073/pnas.070039597. PMC 18253. PMID 10716738.
  37. ^ Crane PK, Gibbons LE, Arani K, Nguyen V, Rhoads K, McCurry SM, Launer L, Masaki K, White L (September 2009). "Midlife use of written Japanese and protection from late life dementia". Epidemiology. 20 (5): 766–74. doi:10.1097/EDE.0b013e3181b09332. PMC 3044600. PMID 19593152.
  38. ^ Craik FI, Bialystok E, Freedman M (November 2010). "Delaying the onset of Alzheimer disease: bilingualism as a form of cognitive reserve". Neurology. 75 (19): 1726–9. doi:10.1212/WNL.0b013e3181fc2a1c. PMC 3033609. PMID 21060095.
  39. ^ Stern, Yaakov (2012). "Cognitive reserve in ageing and Alzheimer's disease". The Lancet Neurology. 11 (11): 1006–1012. doi:10.1016/s1474-4422(12)70191-6. ISSN 1474-4422. PMC 3507991. PMID 23079557.
  40. ^ Nucci, Massimo; Mapelli, Daniela; Mondini, Sara (2011), Cognitive Reserve Index Questionnaire, American Psychological Association, doi:10.1037/t53917-000
  41. ^ Stern, Yaakov (2009). "Cognitive reserve". Neuropsychologia. 47 (10): 2015–2028. doi:10.1016/j.neuropsychologia.2009.03.004. ISSN 0028-3932. PMC 2739591. PMID 19467352.
  42. ^ Mondini, Sara; Madella, Ileana; Zangrossi, Andrea; Bigolin, Angela; Tomasi, Claudia; Michieletto, Marta; Villani, Daniele; Di Giovanni, Giuseppina; Mapelli, Daniela (2016-04-26). "Cognitive Reserve in Dementia: Implications for Cognitive Training". Frontiers in Aging Neuroscience. 8: 84. doi:10.3389/fnagi.2016.00084. ISSN 1663-4365. PMC 4844602. PMID 27199734.