A new procedure for the Antioxidant capacity dpph assessment in small samples.

M. Gombert, Alvaro Carrasco Garcia, J. Luna, P. C. Franch
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Abstract

The antioxidant capacity of a substance is its ability to prevent or slow down oxidation. This reaction is a transfer of electrons. The molecule catching electrons is the oxidative agent and the molecule giving electrons is the reducing agent. Oxidative stress is toxic for the cells, and it can be limited by different pathways: the inhibition of enzymes responsible of the production of oxidative species, the synthesis, activation or stabilization of antioxidant enzymes, and finally by direct scavenging of radical species. In living organisms, especially in association to the respiration process, free radicals are commonly produced. Antioxidant are naturally present to prevent damages, and therefore the antioxidant capacity of a substance is a key element to evaluate. Several methods can be employed to assess total antioxidant capacity in a liquid, one of the most famous requires the use of Di-phenyl-picryl-hydrazyl (DPPH). Brand & Williams developed in 1995 the method of assessment of antioxidant capacity based on the color change of DPPH according to its oxidation status. The oxidized DPPH is a radical, with dark purple color and in contact with antioxidant species, it is reduced and turns to yellow-green color. The amount of oxidized DPPH can be quantified at 517nm spectrophotometrically. Using a known dose of antioxidant molecule, such as Trolox, a standard curve of antioxidant can be built. The antioxidant capacity of any sample can be assessed measuring the oxidized DPPH, in Trolox equivalents. The main limitation of this method are (i) the important volume of sample required and (ii) the interference of molecules of fat present in biological fluids. A new protocol with adaptations has been developed in order to obtain efficient and reproducible antioxidant capacity measurement in very small biological samples, with a required volume 20 times smaller than in the original method. We used it for antioxidant determination of colostrum, which available quantity is very limited, and contains fat. We insist on the importance of the sonication of DPPH prior to use to obtain a good solubility of the product. We added a complementary centrifugation to get rid of the interferences caused by fat, and on the measurement of absorbance at 517 nm with a nanodrop, so that the volume required is importantly reduced. This technique could be used for the following purpose: antioxidant capacity assessment in small samples such breast milk and colostrum, but it could also be applied to the industry to assess the antioxidant capacity of dairy products, using reduced volumes. Finally, for medical use, this technique could be adopted to assess antioxidant capacity in body fluids which sample volume is very limited, such as tears for example, which determination was impossible with the previous method.
小样本抗氧化能力dpph评估的新方法。
物质的抗氧化能力是指它防止或减缓氧化的能力。这个反应是电子的转移。捕获电子的分子是氧化剂,给出电子的分子是还原剂。氧化应激对细胞是有毒的,它可以通过不同的途径受到限制:抑制负责氧化物质产生的酶,合成、激活或稳定抗氧化酶,最后直接清除自由基。在生物体中,特别是在呼吸过程中,自由基通常会产生。抗氧化剂是自然存在的,以防止损害,因此抗氧化能力的物质是一个关键因素来评估。有几种方法可以用来评估液体中的总抗氧化能力,其中最著名的一种需要使用二苯基-苦基-肼(DPPH)。Brand & Williams于1995年开发了基于DPPH根据氧化状态的颜色变化来评估抗氧化能力的方法。氧化后的DPPH为自由基,呈深紫色,与抗氧化物质接触后被还原为黄绿色。在517nm分光光度下可测定氧化DPPH的量。使用已知剂量的抗氧化剂分子,如Trolox,可以建立抗氧化剂的标准曲线。任何样品的抗氧化能力可以评估测量氧化DPPH,在Trolox当量。这种方法的主要限制是(i)需要大量的样品和(ii)存在于生物液体中的脂肪分子的干扰。为了在非常小的生物样品中获得高效和可重复的抗氧化能力测量,已经开发了一种具有适应性的新方案,所需体积比原始方法小20倍。我们用它来测定初乳的抗氧化性,因为初乳的可用量非常有限,而且含有脂肪。我们坚持在使用前对DPPH进行超声处理的重要性,以获得产品的良好溶解度。我们增加了补充离心,以消除脂肪造成的干扰,并在517 nm处用纳米滴测量吸光度,使所需体积大大减少。该技术可用于以下目的:在母乳和初乳等小样本中评估抗氧化能力,但也可应用于工业中,以减少体积来评估乳制品的抗氧化能力。最后,对于医疗用途,该技术可用于评估样品体积非常有限的体液中的抗氧化能力,例如泪液,用以前的方法无法测定。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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