Macular lutein and zeaxanthin are related to brain lutein and zeaxanthin in primates

Rohini Vishwanathan, Martha Neuringer, D Max Snodderly, Wolfgang Schalch, Elizabeth J Johnson, Rohini Vishwanathan, Martha Neuringer, D Max Snodderly, Wolfgang Schalch, Elizabeth J Johnson

Abstract

Objectives: Xanthophyll pigments lutein and zeaxanthin cross the blood-retina barrier to preferentially accumulate in the macular region of the neural retina. There they form macular pigment, protecting the retina from blue light damage and oxidative stress. Lutein and zeaxanthin also accumulate in brain tissue. The objective of the study was to evaluate the relationship between retinal and brain levels of these xanthophylls in non-human primates.

Methods: Study animals included rhesus monkeys reared on diets devoid of xanthophylls that were subsequently fed pure lutein or pure zeaxanthin (both at 3.9 µmol/kg per day, n = 6/group) and normal rhesus monkeys fed a stock diet (0.26 µmol/kg per day lutein and 0.24 µmol/kg per day zeaxanthin, n = 5). Retina (4 mm macular punch, 4-8 mm annulus, and periphery) and brain tissue (cerebellum, frontal cortex, occipital cortex, and pons) from the same animals were analyzed by reverse-phase high-performance liquid chromatography.

Results: Lutein in the macula and annulus was significantly related to lutein levels in the cerebellum, occipital cortex, and pons, both in bivariate analysis and after adjusting for age, sex and n-3 fatty acid status. In the frontal cortex the relationship was marginally significant. Macular zeaxanthin was significantly related to zeaxanthin in the cerebellum and frontal cortex, while the relationship was marginally significant in the occipital cortex and pons in a bivariate model.

Discussion: An integrated measure of total macular pigment optical density, which can be measured non-invasively, has the potential to be used as a biomarker to assess brain lutein and zeaxanthin status.

Figures

Figure 1
Figure 1
Mean (± SEM) concentrations of lutein and zeaxanthin in the cerebellum, frontal cortex, occipital cortex and pons. Columns labeled with different letters (a, b or c) represent means that are significantly different at P<0.05, while those labeled with the same letters represent means that are not significantly different from one another (evaluated independently for lutein and zeaxanthin). A. Xanthophyll-free monkeys fed pure lutein or pure zeaxanthin. Lutein was detected in the brain tissue of the lutein-fed monkeys only, and zeaxanthin was detected in the brain tissue of the zeaxanthin-fed monkeys only. B. Monkeys fed stock diet. Note that the y-axis scale is different from Figure 1A; lutein and zeaxanthin concentrations are 10-20 times lower for stock diet fed monkeys.
Figure 1
Figure 1
Mean (± SEM) concentrations of lutein and zeaxanthin in the cerebellum, frontal cortex, occipital cortex and pons. Columns labeled with different letters (a, b or c) represent means that are significantly different at P<0.05, while those labeled with the same letters represent means that are not significantly different from one another (evaluated independently for lutein and zeaxanthin). A. Xanthophyll-free monkeys fed pure lutein or pure zeaxanthin. Lutein was detected in the brain tissue of the lutein-fed monkeys only, and zeaxanthin was detected in the brain tissue of the zeaxanthin-fed monkeys only. B. Monkeys fed stock diet. Note that the y-axis scale is different from Figure 1A; lutein and zeaxanthin concentrations are 10-20 times lower for stock diet fed monkeys.
Figure 2
Figure 2
Mean (± SEM) concentrations of lutein and zeaxanthin in the retina (4 mm macular region, 4-8 mm annulus and periphery). Columns labeled with different letters (a, b or c) represent means that are significantly different at P<0.05, while those labeled with the same letters represent means that are not significantly different from one another (evaluated independently for lutein and zeaxanthin). A. Xanthophyll-free monkeys fed pure lutein or pure zeaxanthin. *Meso-zeaxanthin was detected only in the 4 mm macular region of lutein-fed monkeys. Lutein was detected in the retinal tissue of the lutein-fed monkeys only. Zeaxanthin was detected in the retinal tissue of the zeaxanthin-fed monkeys only. These data have been previously reported (3). B. Monkeys fed stock diet.
Figure 2
Figure 2
Mean (± SEM) concentrations of lutein and zeaxanthin in the retina (4 mm macular region, 4-8 mm annulus and periphery). Columns labeled with different letters (a, b or c) represent means that are significantly different at P<0.05, while those labeled with the same letters represent means that are not significantly different from one another (evaluated independently for lutein and zeaxanthin). A. Xanthophyll-free monkeys fed pure lutein or pure zeaxanthin. *Meso-zeaxanthin was detected only in the 4 mm macular region of lutein-fed monkeys. Lutein was detected in the retinal tissue of the lutein-fed monkeys only. Zeaxanthin was detected in the retinal tissue of the zeaxanthin-fed monkeys only. These data have been previously reported (3). B. Monkeys fed stock diet.

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