Novel multimodal nanocomposite carriers for diagnostic and therapy (Conference Presentation)

M. Novoselova, D. Bratashov, D. Nedosekin, B. Khlebtsov, E. Galanzha, V. Zharov, D. Gorin
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Abstract

At the present time a new direction of theranostics associated with using of nanostructured multifunctional carriers is developed rapidly. Appreciative examples of such carriers are core-shell nanoparticles, liposomes, polymer micelles, capsules produced by Layer by Layer assembly (LbL) method. Every type of nanostructured carriers has its own advantages and disadvantages. Undoubted advantages of LbL capsules are high loading capacity, wide range of possible internal payloads and wide possibilities of controlling physical and chemical properties of nanostructured carriers by variation of shell structure, thickness and its chemical composition [М.Delcea, et al, Adv. drug delivery reviews, 2011, 63(9), 730, A.S.Timin, et al, Adv. Mater. Interfaces,2016, 4, 1600338]. Application of nanostructured carriers is limited by absence of methods for its in vivo visualization with sufficient spatial resolution and significant tissue penetration depth [A.S.Timin, et al, Adv. Mater. Interfaces, 2016, 4,1600338]. One of the method that allows to visualize and to detect the nanostructured carriers efficiently is a photoacoustic (PA) method. PA approach allows to use the photoacoustic cytometry in vivo [E.I. Galanzha et al, Cancer Res. 2009, 69, 7926]. It is also very important for detection and killing of free circulating cancer cells required for early cancer diagnostics and decreasing the metastases probability [E.I. Galanzha, et al, J. Biophotonics, 2009, 2, 725]. Unique combination of photoacoustic cytometry and nanostructured carriers prepared by LbL assembly approach gives clinicians and researchers significant advantages in the developing of new therapy method based on delivery of nanostructured carriers loaded by bioactive substances into lesion focus and also their visualization and remote controlled release of encapsulated bioactive substances using PA approach. Visualization of two types of nanostructured carriers produced by LbL assembly method was demonstrated recently in diluted and undiluted blood [E.I. Galanzha, et al, J. Biophotonics, 2009, 2, 725]. It was established that hollow microcapsules exhibited greater photoacoustic signal comparing to core-shell type of microparticles with the same composition of polymeric shell [E.I. Galanzha, et al, J. Biophotonics, 2009, 2, 725]. Nevertheless, there are no known examples of in vivo photoacoustic detection of LbL nanostructured carriers, therefore the main goal of present study is formation of biocompatible nanostructured carriers (BNCs) that will exhibit giant photoacoustic signal allowing in vivo detection of such structures. It was demonstrated for the first time, the super (giant) PA contrast of BNCs both in vitro and in vivo. It was verified the unique PA characteristics of these advanced contrast agents using PA flow cytometry diagnostic platform. The obtained data suggest the high PA contrast of BNCs that can be associated with synergistic plasmonic, thermal and acoustic effects, especially in nonlinear mode with nanobubble formation in overheated absorbing layers, in particular gold nanoclusters between two light transparent shells. This work was partly supported by RFBR (project №18-29-08046), the Government of the Russian Federation (grant no. 14.Z50.31.0044 to support scientific research projects implemented under the supervision of leading scientists at Russian institutions and Russian institutions of higher education) and Saratov State University.
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用于诊断和治疗的新型多模态纳米复合载体(会议报告)
目前,利用纳米结构的多功能载体是治疗医学的一个新的发展方向。这种载体的典型例子有核壳纳米粒子、脂质体、聚合物胶束、通过层接层组装(LbL)方法生产的胶囊。每一种纳米结构载体都有其自身的优缺点。毫无疑问,LbL胶囊的优点是高负载能力,广泛的内部有效载荷范围,以及通过改变外壳结构、厚度及其化学成分来控制纳米结构载体的物理和化学性质的广泛可能性[М]。陈晓明,陈晓明,陈晓明,等。药物给药评价,2011,63(9),730。接口,2016,4,1600338]。由于缺乏具有足够空间分辨率和显著组织穿透深度的体内可视化方法,纳米结构载体的应用受到限制蒂姆等人,马特博士。接口,2016,4,1600338]。光声(PA)方法是一种可视化和有效检测纳米结构载流子的方法。PA方法允许在体内使用光声细胞术[j].中华肿瘤杂志,2009,26(2):726 - 726。它对于检测和杀死早期癌症诊断所需的自由循环癌细胞和降低转移概率也非常重要张建军,等。生物光子学研究进展[j].光子学报,2009,27(2):555 - 557。光声细胞术与LbL组装方法制备的纳米结构载体的独特结合,为临床医生和研究人员开发基于负载生物活性物质的纳米结构载体进入病变病灶的新治疗方法以及利用PA方法可视化和远程控制胶囊化生物活性物质的释放提供了显著的优势。最近在稀释和未稀释的血液中展示了两种由LbL组装方法产生的纳米结构载体的可视化[ei]张建军,等。生物光子学研究进展[j].光子学报,2009,27(2):555 - 557。结果表明,空心微胶囊比核壳型微粒子具有更强的光声信号张建军,等。生物光子学研究进展[j].光子学报,2009,27(2):555 - 557。然而,目前还没有已知的在体内光声检测LbL纳米结构载体的例子,因此本研究的主要目标是形成生物相容性纳米结构载体(bnc),这种载体将表现出巨大的光声信号,从而允许在体内检测这种结构。首次在体外和体内证实了bnc的超(巨)PA对比。利用PA流式细胞术诊断平台验证了这些高级造影剂独特的PA特性。所得数据表明,bnc的高PA对比度可能与协同等离子体,热和声学效应有关,特别是在非线性模式下,过热吸收层中的纳米气泡形成,特别是两个轻透明壳之间的金纳米团簇。这项工作得到了俄罗斯联邦政府RFBR(项目№18-29-08046)的部分支持。(14.Z50.31.0044)以支持在俄罗斯机构(俄罗斯高等教育机构)和萨拉托夫国立大学的主要科学家监督下实施的科学研究项目。
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