介孔二氧化硅和氧化锌纳米颗粒与大肠杆菌的相互作用

Meena Ls
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引用次数: 1

摘要

纳米技术创造了大量不同的方法,这些方法正被用于量子电子学、传感、催化、非线性光学、生物医学、治疗学等领域的各种应用。纳米材料,如纳米颗粒,由于其独特的物理化学性质,已经被世界各地的研究人员广泛研究。认识NP在生物系统中的相互作用,为其更好、更多样化的应用提供了新的研究方向。近年来,介孔材料的合成及其作用机理引起了研究者的广泛关注[1-6]。介孔材料具有大量可达孔、高比表面积和周期性纳米级孔间距形成空腔的可控性和单分散性,广泛应用于多相催化、环境、传感和电子介质中。氧化锌是另一种独特的纳米材料,具有优异的化学和光电子性能,这决定了它在科学和技术领域的重要作用,如紫外激光器和二极管、医学和生物学中的荧光标记、储氢、场发射体、压电器件和光催化剂[7-11]。纳米粒子与生物系统的相互作用是非常有吸引力的。许多研究表明,它们在治疗结核病和癌症等致命疾病方面具有有效作用[12]。小尺寸和在循环中的保留能力使它们在医学领域非常有用和具有革命性[9,13 -18]。纳米颗粒可以被细胞吞没;研究人员利用纳米颗粒的这一特性将其用于靶向药物输送。载药的纳米颗粒被细胞包裹,然后纳米颗粒降解并按要求释放药物。本文报道了化学法制备氧化锌和十六烷基三甲基溴化铵(CTAB)模板碱催化缩合法制备介孔二氧化硅纳米颗粒(MSN)及其与大肠杆菌细胞的相互作用。精心选择不同尺寸、形态和表面活性的材料,研究它们与大肠杆菌细胞的相互作用。采用XRD和孔隙率测试对纳米晶材料进行了表征。并用高分辨透射电镜对其形貌进行了研究。通过光致发光(PL)研究了它们与大肠杆菌细胞的相互作用。摘要
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Interactions of Mesoporous Silica and Zno Nanoparticles with Escherichia Coli
Nanotechnology has created a plethora of diverse approaches that are being exploited for various applications in quantum electronics, sensing, catalysis, non-linear optics, biomedicines, therapeutics and many more. Nanoscale materials like Nanoparticles (NP’s) have already been widely studied by the researchers throughout the world, because of their exclusive physicochemical properties. Understanding the interaction of NP’s in biological system gives new dimensions to the researchers for their better and diversified use. Recently, mesoporous materials have attracted a lot of attention of researchers for their synthesis and functional mechanism [1-6]. Mesoporous materials are widely used in heterogeneous catalytic, environmental, sensory and electronic media due to their controllable and monodispersive nature of large number of accessible pores, high surface area and periodic nano-scale pore spacing forming cavities all around. Zinc oxide is another unique nanomaterial having excellent chemical and optoelectronic properties that define its significant role in areas of science and technology such as ultraviolet lasers and diodes, fluorescent labels in medicine and biology, hydrogen storage, field emitters, piezoelectric devices and photocatalysts [7-11]. The interactions of nanoparticles with biological systems are very attractive. Many studies have shown their effective role in treatment of deadly diseases like Tuberculosis and Cancer [12]. Small size and their ability to be retained in the circulation makes them very useful and revolutionary in field of medicine [9, 13-18]. Nanoparticles can be engulfed by a cell; researchers exploited this property of nanoparticles to use them in targeted drug delivery. Drug loaded nanoparticles get encapsulated by the cell and then nanoparticle degrades to release drug as per requirements. Here, we have reported results for zinc oxide prepared by chemical method and Mesoporous Silica Nanoparticles (MSN) that are prepared by Cetyltrimethylammonium bromide (CTAB) template base catalyzed condensation technique and their interaction with E. coli cells. The materials of different sizes, morphologies and surface activities were deliberately chosen to study their interactions with E. coli bacterial cells. The nanocrystalline materials were characterized by XRD and porosity measurements. Their morphology was also studied by high resolution TEM. Their interactions with the E. coli cells were studied by Photoluminescence (PL). Abstract
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