Henan Engineering Technology Research Center of Food Processing and Circulation Safety Control, College of Food Science and Technology, Henan Agricultural University, Nongye Road, Zhengzhou, Henan, 450002, PR China.
Henan Engineering Technology Research Center of Food Processing and Circulation Safety Control, College of Food Science and Technology, Henan Agricultural University, Nongye Road, Zhengzhou, Henan, 450002, PR China.
Talanta. 2022 Sep 1;247:123532. doi: 10.1016/j.talanta.2022.123532. Epub 2022 May 10.
In peptide amphiphile, The positively charged amino acid arginine can inspire the ordered self-assembly of gold nanocomposites (AuNPs), transfer positive charge to AuNPs, and weaken the aggregation of AuNPs by electrostatic repulsion, whereas hydrophobic fatty acid chains regulate the self-assembly of AuNPs through hydrophobic interaction, which may be a novel strategy to overcome disordered arrangement and aggregation of AuNPs to obtain an ultra-sensitive electrochemical immunosensor for determining the total aflatoxin amount. In this study, a peptide amphiphile (C14R5), composed of five arginine residues as the hydrophilic chain and myristic acid as the hydrophobic chain, inspired AuNPs to form monodispersed hollow raspberry-like AuNPs (rasAuNPs). rasAuNPs could captured and immobilized large amounts of aflatoxin antigens via the Au-S bonds, resulting in binding to more anti-aflatoxin antibodies. In the absence of aflatoxins, the enriched antigens bound to abundant antibodies, resulting in a low blank signal current. By contrast, in the presence of aflatoxins, enough antibodies could bind to the targets and less antibodies could recognize the antigens, increasing the detection signal intensity. Under the optimal conditions, the developed sensor demonstrated a wide linear range (0.13-29.06 pg mL) and a low limit of detection for total aflatoxins (0.05 pg mL) using a mixed standard (AFB1: AFB2: AFG1: AFG2 with a weight ratio of 1:1:1:1) in peanut, peanut milk, and maize powder samples. Hence, this novel strategy improves the sensitivity of electrochemical sensors and can be easily applied to detect other small molecule compound for the purpose of food safety.
在肽两亲分子中,带正电荷的氨基酸精氨酸可以激发金纳米复合材料 (AuNPs) 的有序自组装,将正电荷转移到 AuNPs 上,并通过静电排斥减弱 AuNPs 的聚集,而疏水性脂肪酸链通过疏水相互作用调节 AuNPs 的自组装,这可能是克服 AuNPs 无序排列和聚集以获得超灵敏电化学免疫传感器来测定总黄曲霉毒素含量的一种新策略。在这项研究中,一种由五个精氨酸残基作为亲水链和肉豆蔻酸作为疏水链组成的肽两亲分子(C14R5)激发 AuNPs 形成单分散空心覆盆子状 AuNPs(rasAuNPs)。rasAuNPs 可以通过 Au-S 键捕获和固定大量黄曲霉毒素抗原,从而结合更多的抗黄曲霉毒素抗体。在不存在黄曲霉毒素的情况下,富集的抗原与大量抗体结合,导致空白信号电流低。相比之下,在存在黄曲霉毒素的情况下,足够的抗体可以与靶标结合,而较少的抗体可以识别抗原,从而增加检测信号强度。在最佳条件下,该开发的传感器在花生、花生奶和玉米粉样品中使用混合标准(AFB1:AFB2:AFG1:AFG2 重量比为 1:1:1:1)时,对总黄曲霉毒素表现出较宽的线性范围(0.13-29.06 pg mL)和较低的检测限(0.05 pg mL)。因此,这种新策略提高了电化学传感器的灵敏度,并且可以很容易地应用于检测其他小分子化合物,以确保食品安全。
