Institute of Organic Chemistry with Centre of Phytochemistry, Bulgarian Academy of Sciences, Sofia, Bulgaria.
Biochimie. 2012 Feb;94(2):403-15. doi: 10.1016/j.biochi.2011.08.008. Epub 2011 Aug 25.
Antioxidants could be promising agents for management of oxidative stress-related diseases. New biologically active compounds, belonging to a rare class of natural lignans with antiangiogenic, antitumoral and DNA intercalating properties, have been recently synthesized. These compounds are benzo[kl]xanthene lignans (1,2) and dihydrobenzofuran neolignans (3,4). The radical scavenging and chain-breaking antioxidant activities of compounds 1-4 were studied by applying different methods: radical scavenging activity by DPPH rapid test, chain-breaking antioxidant activity and quantum chemical calculations. All studied compounds were found to be active as DPPH scavengers but reaction time with DPPH and compounds' concentrations influenced deeply the evaluation. The highest values of radical scavenging activity (%RSAmax) and largest rate constants for reaction with DPPH were obtained for compounds 2 and 3. Comparison of %RSAmax with that of standard antioxidants DL-α-tocopherol (TOH), caffeic acid (CA) and butylated hydroxyl toluene (BHT) give the following new order of %RSA max: TOH (61.1%) > CA (58.6%) > 3 (36.3%) > 2 (28.1%) > 4 (6.7%) > 1 (3.6%) = BHT (3.6%). Chain-breaking antioxidant activities of individual compounds (0.1-1.0 mM) and of their equimolar binary mixtures (0.1 mM) with TOH were determined from the kinetic curves of lipid autoxidation at 80 °C. On the basis of a comparable kinetic analysis with standard antioxidants a new order of the antioxidant efficiency (i.e., protection factor, PF) of compounds 1-4 were obtained: 2 (7.2) ≥ TOH (7.0) ≥ CA (6.7) > 1 (3.1) > 3 (2.2) > ferulic acid FA (1.5) > 4 (0.6); and of the antioxidant reactivity (i.e. inhibition degree, ID): 2 (44.0) >> TOH (18.7) >> CA (9.3) >> 1 (8.4) > 3 (2.8) > FA (1.0) > 4 (0.9). The important role of the catecholic structure in these compounds, which is responsible for the high chain-breaking antioxidant activity, is discussed and a reaction mechanism is proposed. Higher oxidation stability of the lipid substrate was found in the presence of equimolar binary mixtures 2 + TOH, 3 + TOH and 4 + TOH. However, an actual synergism was only obtained for the binary mixtures with compounds 3 and 4. The geometries of compounds and all possible phenoxyl radicals were optimized using density functional theory. For description of the scavenging activity bond dissociation enthalpies (BDE), HOMO energies and spin densities were employed. The best correlation between theoretical and experimental data was obtained for compound 2, with the highest activity, and for compound 4 with the lowest activity. The BDE is the most important theoretical descriptor, which correlates with the experimentally obtained antioxidant activity of the studied benzo[kl]xanthene lignans and dihydrobenzofuran neolignans.
抗氧化剂可能是管理与氧化应激相关疾病的有前途的药物。最近合成了新的具有生物活性的化合物,属于具有抗血管生成、抗肿瘤和 DNA 插入特性的罕见天然木脂素类。这些化合物是苯并[k]薁木脂素(1、2)和二氢苯并呋喃新木脂素(3、4)。通过应用不同的方法研究了化合物 1-4 的自由基清除和链断裂抗氧化活性:通过 DPPH 快速测试研究自由基清除活性、链断裂抗氧化活性和量子化学计算。研究发现所有研究的化合物都是有效的 DPPH 清除剂,但与 DPPH 的反应时间和化合物的浓度对评价有很大影响。化合物 2 和 3 获得了最高的自由基清除活性(%RSAmax)和与 DPPH 反应的最大速率常数。与标准抗氧化剂 DL-α-生育酚(TOH)、咖啡酸(CA)和丁基羟基甲苯(BHT)的%RSAmax 比较,给出了以下新的%RSA max 顺序:TOH(61.1%)>CA(58.6%)>3(36.3%)>2(28.1%)>4(6.7%)>1(3.6%)=BHT(3.6%)。在 80°C 下从脂质自动氧化的动力学曲线中确定了各个化合物(0.1-1.0 mM)和它们等摩尔二元混合物(0.1 mM)的链断裂抗氧化活性。基于与标准抗氧化剂的可比动力学分析,获得了化合物 1-4 的抗氧化效率(即保护因子,PF)的新顺序:2(7.2)≥TOH(7.0)≥CA(6.7)>1(3.1)>3(2.2)>3(2.2)> 阿魏酸(FA)(1.5)>4(0.6);以及抗氧化反应性(即抑制程度,ID):2(44.0)>>TOH(18.7)>>CA(9.3)>1(8.4)>3(2.8)>FA(1.0)>4(0.9)。讨论了这些化合物中儿茶酚结构的重要作用,这是其具有高链断裂抗氧化活性的原因,并提出了一种反应机制。在存在等摩尔二元混合物 2+TOH、3+TOH 和 4+TOH 的情况下,发现脂质底物的氧化稳定性更高。然而,仅在混合物 3 和 4 中获得了实际协同作用。使用密度泛函理论优化了化合物和所有可能的苯氧自由基的几何形状。为了描述清除活性键离解焓(BDE)、HOMO 能量和自旋密度,采用了 HOMO 能量和自旋密度。对于具有最高活性的化合物 2 和具有最低活性的化合物 4,理论和实验数据之间获得了最佳相关性。BDE 是最重要的理论描述符,与研究的苯并[k]薁木脂素和二氢苯并呋喃新木脂素的实验抗氧化活性相关。
