Free Radical Formation in Novel Carotenoid Metal Ion Complexes of Astaxanthin

Polyakov, Nikolay E.; Focsan, A. Ligia; Bowman, Michael K.; Kispert, Lowell D.

doi:10.1021/jp109039v

Cited by 64 publications

(98 citation statements)

References 49 publications

(121 reference statements)

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“…both pathways will form carotenoid neutral radicals (b-CAR Å and HO-b-CAR-H Å ) (Scheme 3). Recently, Kispert et al [24,[46][47][48][49][50] have extensively investigated the stabilities of different carotenoid neutral radicals formed via proton loss from various positions. For example; based on theoretical calculations and experimental results, the most energetically favorable positions for proton loss from b-CAR-H Å+ , to form b-CAR Å , are 4, 4 0 and methyl groups at 5 and 5 0 positions ( Fig.…”

Section: Resultsmentioning

confidence: 99%

Influence of pH on the decay of β-carotene radical cation in aqueous Triton X-100: A laser flash photolysis study

El‐Agamey

El-Hagrasy

Suenobu

et al. 2015

Journal of Photochemistry and Photobiology B: Biology

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Section: Resultsmentioning

confidence: 99%

Influence of pH on the decay of β-carotene radical cation in aqueous Triton X-100: A laser flash photolysis study

El‐Agamey

El-Hagrasy

Suenobu

et al. 2015

Journal of Photochemistry and Photobiology B: Biology

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“…The antioxidant mechanism of carotenoids is through quenching of singlet oxygen and subsequently interacting with free radicals. (22) The limitations of this study are firstly, that the sampling was done in stages, since not all of the mice were found to be pregnant. Secondly, that several oxidative stress parameters were not measured, e.g.…”

Section: Discussionmentioning

confidence: 98%

Red fruit oil increases trophoblast cells and decreases caspase-9 expression in placenta of lead exposed mice

Sumarsono

Widjiati

Susilowati

2016

UnivMed

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BACKGROUND Lead is able to pass through the placental barrier and interfere with fetal development. Red fruit has high antioxidant activity, due to carotenoids (pro-vitamin A), tocopherols (vitamin E) and unsaturated fatty acids. This study aims to examine the effect of red fruit oil towards placenta in pregnant mice before lead exposure. METHODS This was a laboratory experimental post test only study, using 20 pregnant mice (Mus musculus) that were randomized into five groups. The negative control group was not exposed to lead; intervention group 0 (P0) was exposed to lead at 0.011 mg/20 g BW/day on days 6-15 of gestation. The intervention groups P1-P3 were given red fruit orally at 0.3 mL/20 g BW/day, 0.8 mL/20 g BW/day, 0.9 mL/20 g BW/day, respectively, before lead exposure. Normal trophoblast cell count and caspase-9 expression of trophoblasts were calculated. One-way ANOVA, Kruskal-Wallis and Mann Whitney tests were used to analyze the data. RESULTS The intervention groups P2 and P3 given red fruit at 0.8 mL/20 g BW/day and 0.9 mL/20 g BW/day showed a significant increase in normal trophoblast cell count of 88.2% (p=0.024) and a decrease in caspase-9 expression of 70.8% compared with P0 to which was not given red fruit (p=0.020). CONCLUSION Red fruit increased normal trophoblast cell count by 88.2% and decreased caspase-9 expression by 70.8% in pregnant mice before lead exposure. It should be noted that red fuit may prevent oxidative damage to cells.

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“…Recently, Polyakov et al (2010) showed that ASTA and its mono-and dication forms can chelate Ca 2+ , Zn 2+ , and Fe 2+ ions, although the lifetime of the radical ions formed electrochemically decreased in comparison to uncomplexed ASTA. Moreover, due to its spatial orientation perpendicular to the plane of lipid bilayers, ASTA increases the hydrophobicity in the central core of biological membranes, with several proposed biochemical/physiological consequences (Gabrielska & Gruszecki, 1996).…”

Section: Biosynthesis and Biological Properties Of Astaxanthinmentioning

confidence: 99%

Putative benefits of microalgal astaxanthin on exercise and human health

Barros¹,

Poppe²,

Souza³

2011

Rev. bras. farmacogn.

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Astaxanthin (ASTA) is a pinkish-orange carotenoid produced by microalgae, but also commonly found in shrimp, lobster and salmon, which accumulate ASTA from the aquatic food chain. Numerous studies have addressed the benefits of ASTA for human health, including the inhibition of LDL oxidation, UVphotoprotection and prophylaxis of bacterial stomach ulcers. ASTA is recognized as a powerful scavenger of reactive oxygen species (ROS), especially those involved in lipid peroxidation. Both aerobic and anaerobic exercise are closely related to overproduction of ROS in muscle tissue. Post-exercise inflammatory processes can even exacerbate the oxidative stress imposed by exercise. Thus, ASTA is suggested here as a putative nutritional alternative/coadjutant for antioxidant therapy to afford additional protection to muscle tissues against oxidative damage induced by exercise, as well as for an (overall) integrative redox re-balance and general human health.

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Free Radical Formation in Novel Carotenoid Metal Ion Complexes of Astaxanthin

Cited by 64 publications

References 49 publications

Influence of pH on the decay of β-carotene radical cation in aqueous Triton X-100: A laser flash photolysis study

Influence of pH on the decay of β-carotene radical cation in aqueous Triton X-100: A laser flash photolysis study

Red fruit oil increases trophoblast cells and decreases caspase-9 expression in placenta of lead exposed mice

Putative benefits of microalgal astaxanthin on exercise and human health

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