ABTS在氧化剂作用下被氧化为稳定的蓝绿色阳离子ABTS自由基,在405 nm或734 nm处具有特征吸收峰,抗氧化物存在时会抑制ABTS自由基的生成使反应体系褪色,405 nm处吸光值随之下降,在一定范围内吸光值的变化与自由基被清除的程度成正比,通过吸光值的下降程度即可表征样本的ABTS自由基清除能力,并提供Trolox作为阳性对照量化抗氧化物质的清除能力。
标准物质: Trolox①样品提取过程建议在冰上完成操作,且提取后应当天完成测定;
②若待测样本ABTS自由基清除率(DS%)大于90%,建议将待测样本使用提取液稀释后再进行测定;若待测样本ABTS自由基清除率(DS%)小于5%,建议适当增加烘干样本质量或液体样本体积重新提取后再进行测定,计算时相应修改;
③试剂四应用液和试剂五应用液配制时,建议最少取10 μL进行配制;
④不同样本ABTS自由基清除能力可能相差较大,若需要比较不同样本的ABTS自由基清除能力,建议对于同一批植物样本加入等量的样本,液体样本加入相同体积,提取物或者药物配制为相同浓度;将样本根据预实验结果进行适当调整,比较同样浓度(相同稀释倍数)的清除率大小;
⑤试剂三配制后有效期短,为便于试验安排,附赠2支试剂三作为备用;
[1] Wu L, Wang Y, Zhao X, et al. A self-adhesive hierarchical nanofiber patch for dynamic and multistage management of full-thickness cutaneous wounds[J]. Journal of Nanobiotechnology, 2025, 23(1): 448. (IF 12.6)
[2] Chen H, Yang Q, Li M, et al. Polyphenol-Based Self-Assembled Nanoparticles Treating Uveitis by Inflammation-Oxidative Stress Suppression[J]. Materials Today Bio, 2025: 102052. (IF 10.2)
[3] Zhou D, Hu Y, Zhou T, et al. Deep eutectic solvent extraction of polysaccharides from Gastrodiae elata with ultrasonic and enzymes assistance: Process optimization, structure, and antioxidant activity[J]. Ultrasonics Sonochemistry, 2025: 107383. (IF 8.7)
[4] Yang Y, Guan M, Fang M, et al. Simultaneous extraction and selective separation of catechins, caffeine and theanine from waste tea residue facilitated by citric acid-based deep eutectic solvent[J]. Separation and Purification Technology, 2024: 130918. (IF 8.1)
[5] Li M, Jia L, Wang X, et al. Study on network cross-linked hydrogel with cationic Bletilla striata polysaccharide/carbopol as a drug delivery system[J]. International Journal of Biological Macromolecules, 2025: 140778. (IF 7.7)
[6] Li K, Xu R, Cao J, et al. Nordihydroguaiaretic acid (NDGA) maintains the postharvest quality of fresh daylily flower buds (Hemerocallis citrina) by enhancing antioxidant metabolism and regulating phytohormone equilibrium[J]. Postharvest Biology and Technology, 2023, 200: 112326.(IF 7)
[7] Zhou D, Hu Y, He X, et al. Quality analysis and characteristic difference identification of organic tea and conventional planting tea based on ICP, HPLC and machine algorithm[J]. Food Chemistry: X, 2025: 102299. (IF 6.5)
[8] Xing S, Tian Q, Zheng Y, et al. Sulfur dioxide enhances the resistance of postharvest grape berries to gray mold through hydrogen peroxide signaling[J]. Postharvest Biology and Technology, 2025, 221: 113325. (IF 6.4)
[9] Peng C, Deng L, Tan H, et al. Transcriptome and metabolome analysis of preharvest internal browning in Nane plum fruit caused by high temperatures[J]. Horticultural Plant Journal, 2024. (IF 5.7)
[10] Ma Y N, Xu X, Chen L F, et al. Process optimization and evaluation of quality properties of natto with co-culture of Bacillus subtilis natto and Limosilactobacillus fermentum[J]. Current Research in Microbial Sciences, 2025: 100347. (IF 4.8)
[11] Wan B, Tian T, Xiong Y, et al. Isolation and Evaluation of Rhizopus arrhizus Strains from Traditional Rice Wine Starters (Jiuqu): Enzyme Activities, Antioxidant Capacity, and Flavour Compounds[J]. Foods, 2025, 14(2): 312. (IF 4.7)
[12] Yi X, Zhang S, Meng D, et al. Optimization of Rosa roxburghii Tratt pomace fermentation process and the effects of mono-and mixed culture fermentation on its chemical composition[J]. Frontiers in Nutrition, 2024, 11: 1494678. (IF 4.0)