University of North Texas, Departments of Chemistry and Biological Sciences, Denton, TX 76203, United States.
University of North Texas, Departments of Chemistry and Biological Sciences, Denton, TX 76203, United States.
J Colloid Interface Sci. 2017 Dec 1;507:437-452. doi: 10.1016/j.jcis.2017.08.009. Epub 2017 Aug 4.
A facile, single-step, non-seeded photochemical protocol for producing a new type of anisotropic silver nanostructure, "nanoworms", with curved longer dimensions and smooth, rounded edges. The nanoworms exhibit surface plasmon resonance (SPR) absorption in the near-infrared window (NIRW) region and are stabilized using biocompatible polymer chitosan, rendering biocompatibility and amplified safety for biological utility of the composition. Both NIRW-absorbing nanoworms and visible-absorbing nanospheres herein are attained exclusively by employing green chemistry principles. Contrary to seed-mediated or polyol techniques, the protocol demonstrates the feasibility to selectively synthesize NIRW-absorbing silver nanostructures in a single step and in complete absence of any known reducing agent. The effect of irradiation, pH, and concentration of starting materials on the formation of nanoworms vs nanospheres is investigated in detail and analyzed by optical spectroscopy and electron microscopy. The dominant SPR obtained in the NIRW region of the nanoworms results from anisotropic AgNPs, as opposed to agglomeration. From TEM images, it is also very clear that a strong correlation exists between the SPR peak maximum and the size distribution of the anisotropic nanoworm structures, with SPR peak maximum exhibiting red shift with the increase in the size of the nanoworm population. Although there is significant size variation of different nanoworms of a given population, all samples exhibit remarkable stability. The nanoworms retained their NIRW-absorbing features even at physiological pH and at a constant ionic strength. The nanodispersions also retained their SPR features in King's B medium. Antipathogenic assays reveal that the anisotropic NIRW-absorbing nanoworms exhibit the highest growth inhibition compared to other spherical nanosilver and molecular silver forms on Gram-negative pathogenic bacteria, Pseudomonas syringae pv. maculicola ES4326 and P. syringae pv. tomato DC3000. These results underscore shape effects of AgNPs and suggest that nanoworms favor the adhesion to (curved) rod-shaped Gram-negative bacteria, resulting in the highest inhibition compared to isotropic AgNPs (smaller spheres), sulfa antibiotics (silver sulfadiazine), and silver ions (AgNO).
一种简便的、单步的、无种子的光化学方法,用于制备新型各向异性银纳米结构“纳米蠕虫”,其具有弯曲的较长尺寸和光滑、圆形的边缘。纳米蠕虫在近红外窗口(NIRW)区域表现出表面等离子体共振(SPR)吸收,并用生物相容性聚合物壳聚糖稳定,从而赋予组合物生物相容性和增强的安全性,可用于生物应用。本文中的近红外吸收纳米蠕虫和可见吸收纳米球都是通过采用绿色化学原理获得的。与种子介导或多元醇技术相反,该方案证明了在无任何已知还原剂的情况下,以一步法选择性合成近红外吸收银纳米结构的可行性。通过光学光谱和电子显微镜详细研究了辐照、pH 值和起始材料浓度对纳米蠕虫与纳米球形成的影响,并进行了分析。纳米蠕虫在近红外区域获得的主导 SPR 源于各向异性 AgNPs,而不是团聚。从 TEM 图像中也可以清楚地看出,SPR 峰最大值与各向异性纳米蠕虫结构的尺寸分布之间存在很强的相关性,随着纳米蠕虫群体尺寸的增加,SPR 峰最大值发生红移。尽管给定群体的不同纳米蠕虫的尺寸变化很大,但所有样品都表现出显著的稳定性。纳米蠕虫在生理 pH 值和恒定离子强度下仍保留其近红外吸收特性。纳米分散体在 King's B 培养基中也保留了它们的 SPR 特征。抗病原体测定表明,与其他球形纳米银和分子银形式相比,各向异性近红外吸收纳米蠕虫对革兰氏阴性致病菌丁香假单胞菌 pv. 青枯菌 ES4326 和丁香假单胞菌 pv. 番茄 DC3000 表现出最高的生长抑制。这些结果强调了 AgNPs 的形状效应,并表明纳米蠕虫有利于与(弯曲)杆状革兰氏阴性细菌粘附,从而与各向同性 AgNPs(较小的球体)、磺胺类抗生素(磺胺嘧啶银)和银离子(AgNO)相比,表现出最高的抑制作用。
