Iron, Zinc and Copper from Cereal Food Sources and Cognitive Performance in Older Adults in China
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Yibing Wang
,
Xun Sun
,
Hui Ma
,
Xueling Qu
,
Haitao Wang
Abstract
Background: We aimed to determine the risk factors associated with cognitive performance in older adults in China.
Methods: A longitudinal study was conducted in a group of 1,898 adults aged 60 yr and over in China, Cognitive score was determined by a modified Telephone Interview for Cognitive Status (TICSM). The dietary intake of iron (Fe), zinc (Zn) and copper (Cu) from cereal source foods (CSF) were calculated by using Food Frequency Questionnaire (FFQ) and Chinese Food Composition Tables. Descriptive statistics and multivariate mixed regression models were utilized to explore the association between the intake of these elements and cognitive function.
Results: The mean dietary intakes of Fe, Zn and Cu from CSF were 12.01, 6.90 and 1.30 mg/d respectively. Compared with participants in the high-cognitive group, those in the low-cognitive group had lower total dietary intakes of Fe, Zn and Cu. However, with respect to ratios of CSF-Zn, CSF-Fe and CSF-Cu to their respective total values, participants in the low-cognitive group had significantly higher ratios than those in the high-cognitive group. The results of multivariate mixed regression model revealed that although total dietary Zn intake was positively linked with cognitive function, the CSF-Zn/Zn ratio was negatively associated with cognitive performance.
Conclusion: Excessive intake of Zn from a specific food source, such as CSF, was found to be negatively associated with cognitive status. Avoiding over-intake of Zn from CSF foods and diversifying intake of Zn from different food sources seemed to protect individuals from cognitive decline.
2. Bao CZ, Ma YL, Ye ZH, et al (2015). Fore-casting and analyzing the disease burden of aged population in China, based on the 2010 Global Burden of Disease Study. Int J Environ Res Public Health, 12(7):7172-84.
3. Salthouse TA (2009). When does age-related cognitive decline begin? Neurobiol Aging, 30(4): 507–514.
4. Xu JF, Wang J, Wimo A, et al (2017). The economic burden of dementia in China, 1990-2030: implications for health policy. Bull World Health Organ, 95(1): 18-26.
5. Barnett JH, Hachinski V, Blackwell AD (2013). Cognitive health begins at con-ception: addressing dementia as a lifelong and preventable condition. BMC Medicine. 11(1):246.
6. Kelly ME, Duff H, Kelly S, et al (2017). The impact of social activities, social networks, social support and social relationships on the cognitive functioning of healthy older adults: a systematic review. Syst Rev, 6(1):259.
7. Blondell SJ, Hammersley-Mather R, Veer-man JL (2014). Does physical activity prevent cognitive decline and dementia? A systematic review and meta-analysis of longitudinal studies. BMC Public Health. 14: 510.
8. Wengreen HJ, Neilson C, Munger R, et al (2009). Diet quality is associated with bet-ter cognitive test performance among ag-ing men and women. J Nutr, 139(10): 1944-9.
9. Dong L, Xiao R, Cai C, et al (2016). Diet, lifestyle and cognitive function in old Chinese adults. Arch Gerontol Geriatr, 63: 36-42.
10. Sayre LM, Perry G, Atwood CS, et al (2000). The role of metals in neurodegener ative diseases. Cell Mol Biol (Noisy-le-grand), 46(4):731-41.
11. DeFries R, Fanzo J, Remans R, et al (2015). Metrics for land-scarce agriculture. Science, 349:238-240.
12. He Z, Xia X, Peng S, et al (2014). Meeting demands for increased cereal production in China. Journal of Cereal Science, 59(3): 235-244.
13. Wang YQ, Gao FL, Gao GY, et al (2019). Production and Cultivated Area Variation in Cereal, Rice, Wheat and Maize in China (1998-2016). Agronomy, 9(5): 1-13.
14. Woo J, Woo KS, Leung SS, et al (2001). The Mediterranean score of dietary habits in Chinese populations in four different ge-ographical areas. Eur J Clin Nutr, 55(3):215-20.
15. Smorgon C, Mari E, Atti AR; et al (2004). Trace elements and cognitive impairment: an elderly cohort study. Arch Gerontol Ger-iatr Suppl, (9):393-402.
16. Gao S, Jin Y, Unverzagt FW, et al (2008). Trace element levels and cognitive func-tion in rural elderly Chinese. J Gerontol A Biol Sci Med Sci, 63(6):635-41.
17. Houston DK, Nicklas BJ, Ding J, et al (2008). Dietary protein intake is associat-ed with lean mass change in older, com-munity dwelling adults: the health, aging, and body composition (Health ABC) study. Am J Clin Nutr, 87(1): 150–5.
18. Qin B, Adair LS, Plassman BL, et al (2015). Dietary patterns and cognitive decline among Chinese older adults. Epidemiology, 26(5):758-68.
19. Lei X, Hu Y, McArdle JJ, et al (2012). Gen-der Differences in Cognition among Older Adults in China. J Hum Resour, 47(4): 951–971.
20. Seo EH, Lee DY, Kim SG, et al (2011). Va-lidity of the telephone interview for cog-nitive status (TICS) and modified TICS (TICSm) for mild cognitive impairment (MCI) and dementia screening. Arch Ger-ontol Geriatr, 52(1):e26-30.
21. Xu X, Byles J, Shi Z, et al (2016). Dietary pattern transitions, and the associations with BMI, waist circumference, weight and hypertension in a 7-year follow-up among the older Chinese population: a longitudinal study. BMC Public Health, 16:743.
22. Yang YX, Wang GY, Pan XC (2002). Chinese Food Composition Table, Peking University Medical Press: Beijing, China, ISBN 978-7-81071-180-6.
23. Yang YX (2004). Chinese Food Composition Ta-ble, Peking University Medical Press: Bei-jing, China, ISBN 978-7-81071-678-6.
24. Xu X, Hall J, Byles J, Shi Z (2015). Do older Chinese people's diets meet the Chinese Food Pagoda guidelines? Results from the China Health and Nutrition Survey 2009. Public Health Nutr, 18(16):3020-30.
25. Tian X, Huang Y, Wang H (2017). Deviation of Chinese adults' diet from the Chinese Food Pagoda 2016 and its association with adiposity. Nutrients, 9(9):995.
26. Otsuka R, Kato Y, Nishita Y, et al (2014). Cereal intake increases and dairy products decrease risk of cognitive decline among elderly female Japanese. J Prev Alzheimers Dis, 1(3):160-167.
27. Zhu J, Xiang YB, Cai H, et al (2018). A pro-spective investigation of dietary intake and functional impairments among the elderly. Am J Epidemiol, 187(11):2372-2386.
28. Andriollo-Sanchez M, Hininger-Favier I, Meunier N, et al (2005). Zinc intake and status in middle-aged and older Europe-an subjects: the ZENITH study. Eur J Clin Nutr, 2:S37-41.
29. Cuajungco MP, Faget KY (2003). Zinc takes the center stage: its paradoxical role in Alzheimer's disease. Brain Res Brain Res Rev, 41(1):44-56.
30. Takeda A (2000). Movement of zinc and its functional significance in the brain. Brain Res Brain Res Rev, 34(3):137-48.
31. Plum LM, Rink L, Haase H (2010). The es-sential toxin: impact of zinc on human health. Int J Environ Res Public Health, 7(4): 1342–1365.
32. Dineley KE, Votyakova TV, Reynolds IJ (2003). Zinc inhibition of cellular energy production: implications for mitochon-dria and neurodegeneration. J Neurochem, 85(3):563-70.
33. Huang M, Zhou S, Sun B, et al (2008). Heavy metal in wheat grain: assessment of potential health risk for inhabitants in Kunshan China. Sci Total Environ, 405(1-3):54-61.
34. Yin Z, Fei Z, Qiu C, et al (2017). Dietary di-versity and cognitive function among el-derly people: a population-based study. J Nutr Health Aging, 21(10):1089-1094.
| Files | ||
| Issue | Vol 50 No 12 (2021) | |
| Section | Original Article(s) | |
| DOI | https://doi.org/10.18502/ijph.v50i12.7937 | |
| Keywords | ||
| Iron Zinc Copper Cognitive Cereal Diet China | ||
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