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    Wallace, Taylor C. 2018. A Comprehensive Review of Eggs, Choline, and Lutein on Cognition Across the Life-span. Journal of the American College of Nutrition, Vol. 37, Issue. 4, p. 269.
    Mohn, Emily S. and Johnson, Elizabeth J. 2017. Lutein and Cognition Across the Lifespan. Nutrition Today, Vol. 52, Issue. 4, p. 183.
    Zielińska, Monika Wesołowska, Aleksandra Pawlus, Beata and Hamułka, Jadwiga 2017. Health Effects of Carotenoids during Pregnancy and Lactation. Nutrients, Vol. 9, Issue. 8, p. 838.
    Barnett, Sasha M. Khan, Naiman A. Walk, Anne M. Raine, Lauren B. Moulton, Christopher Cohen, Neal J. Kramer, Arthur F. Hammond, Billy R. Renzi-Hammond, Lisa and Hillman, Charles H. 2017. Macular pigment optical density is positively associated with academic performance among preadolescent children. Nutritional Neuroscience, p. 1.
    Walk, Anne M. Khan, Naiman A. Barnett, Sasha M. Raine, Lauren B. Kramer, Arthur F. Cohen, Neal J. Moulton, Christopher J. Renzi-Hammond, Lisa M. Hammond, Billy R. and Hillman, Charles H. 2017. From neuro-pigments to neural efficiency: The relationship between retinal carotenoids and behavioral and neuroelectric indices of cognitive control in childhood. International Journal of Psychophysiology, Vol. 118, Issue. , p. 1.
    Leermakers, Elisabeth T. M. Kiefte-de Jong, Jessica C. Hofman, Albert Jaddoe, Vincent W. V. and Franco, Oscar H. 2015. Lutein intake at the age of 1 year and cardiometabolic health at the age of 6 years: the Generation R Study. British Journal of Nutrition, Vol. 114, Issue. 06, p. 970.
    McCorkle, Sasha Raine, Lauren Hammond, Billy Renzi-Hammond, Lisa Hillman, Charles and Khan, Naiman 2015. Reliability of Heterochromatic Flicker Photometry in Measuring Macular Pigment Optical Density among Preadolescent Children. Foods, Vol. 4, Issue. 4, p. 594.
    Cheatham, Carol and Sheppard, Kelly 2015. Synergistic Effects of Human Milk Nutrients in the Support of Infant Recognition Memory: An Observational Study. Nutrients, Vol. 7, Issue. 11, p. 9079.
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Plasma lutein concentrations are related to dietary intake, but unrelated to dietary saturated fat or cognition in young children

  • Kelly A. Mulder (a1), Sheila M. Innis (a1), Betina F. Rasmussen (a1), Brian T. Wu (a1), Kelly J. Richardson (a1) and David Hasman (a1)...
Abstract

Lutein and zeaxanthin are xanthophyll carotenoids present in highly pigmented vegetables and fruits. Lutein is selectively accumulated in the brain relative to other carotenoids. Recent evidence has linked lutein to cognition in older adults, but little is known about lutein in young children, despite structural brain development. We determined lutein intake using FFQ, one 24 h recall and three 24 h recalls, plasma lutein concentrations and their association with cognition in 160 children 5·6–5·9 years of age, at low risk for neurodevelopmental delay. Plasma lutein was skewed, with a median of 0·23 (2·5th to 95th percentile range 0·11–0·53) µmol/l. Plasma lutein showed a higher correlation with lutein intake estimated as the average of three 24 h recalls (r 0·479; P = 0·001), rather than one 24 h recall (r 0·242; P = 0·003) or FFQ (r 0·316; P = 0·001). The median lutein intake was 697 (2·5th to 95th percentile range 178–5287) µg/d based on three 24 h recalls. Lutein intake was inversely associated with SFA intake, but dietary fat or SFA intakes were not associated with plasma lutein. No associations were found between plasma lutein or lutein intake and any measure of cognition. While subtle independent effects of lutein on child cognition are possible, separating these effects from covariates making an impact on both child diet and cognition may be difficult.

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Copyright
COPYRIGHT: © The Author(s) 2014
The online version of this article is published within an Open Access environment subject to the conditions of the Creative Commons Attribution license .
Corresponding author
* Corresponding author: Dr S. M. Innis, fax +1 604 875 3597, email sinnis@mail.ubc.ca
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