Interactions of variously coated gold and silver nanoparticles with a bis(triarylborane) photodyanmic therapy (PDT)-dye; their cellular uptake, cytotoxicity and photo-activity

Pub Date : 2023-10-25 DOI:10.18054/pb.v125i1-2.23726
Isabela Drašković, Ivana Fabijanić, Matthias Ferger, Todd B. Marder, Dragomira Majhen, Ivo Piantanida
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Abstract

Background and purpose: Diethynylarene-linked bis(triarylborane) tetracations can be used as probes for fluorimetric and Raman sensing of biomacromolecules, as well as promising theragnostic agents. Among them, bis(triarylborane) fluorophore (TAB3), when bonded to Ag nanoparticles (NP), stood out with specific properties such as Raman signal enhancemen of the TAB3 dye in a cuvette. However, TAB3 dye - nanoparticle composites have not been studied in biological systems. For this reason, questions arose as to whether different types of metal nanoparticles (Au or Ag-based) with different coatings (negatively charged citrate or neutral PVP) could be efficiently stained with the TAB3 dye in a cuvette. The aim of this research was to examine Au and Ag nanoparticles of similar size (20-25 nm) with different stabilizers for their cellular uptake, cytotoxicity in the dark and under visible light radiation, to characterize the interactions of nanoparticles with the TAB3 fluorophore, and to study NP-TAB3 composites in cells, evaluate their intracellular staining, as well as possible photoinduced release and biological activity. Materials and methods: The binding constants of Au- and Ag- based nanoparticles with TAB3 were determined by fluorimetric titrations. The cytotoxic effect of NPs was determined by the survival of A549 cells (MTT assay). Cellular uptake of both NP and NP-TAB3 composites were performed by live cell imaging experiments. Results: The Au- or Ag-based NPs with different coatings bind to the TAB3 with high affinity. These NPs, as well as TAB3-NP complexes, efficiently enter living human cells, accumulating in cytoplasm with no apparent selectivity for a particular organelle. Even prolonged 3-day treatment with the NPs studied did not show any toxic effect on the cells. Bioimaging studies in cells revealed that the TAB3-NP complex does not intracellularly dissociate; the previously reported photo-bioactivity of TAB3 is completely inhibited by binding to NPs. Conclusion: Au- and Ag NPs were non-covalently stained by TAB3, irrespective of the different coatings, with similar binding affinities. Emission from TAB3 is strongly quenched by the NPs, but not completely. Experiments on living human cells revealed that neither free NPs, nor their composites with TAB3, were toxic. Bioimaging studies by confocal microscopy revealed that all NPs efficiently enter living cells within 90 min. Colocalization experiment with simultaneous collection of data in the reflection and fluorescence modes demonstrated that the TAB3 dye remained bound to NPs inside cells. Strong irradiation of TAB3-NP inside cells with a 457 nm laser did not yield any damage to the cells, at variance with our previously shown very strong photo-bioactivity of the TAB3 dye alone. Thus, binding of a chromophore to a nanoparticle can inhibit the chromophore’s ability to undergo photo-induced singlet oxygen production, consequently blocking its photo-bioactivity.
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不同包覆金、银纳米粒子与双(三芳基硼烷)光动力治疗(PDT)染料的相互作用它们的细胞摄取、细胞毒性和光活性
背景与目的:二乙烯烯连接的双(三芳基硼烷)聚物可作为生物大分子荧光和拉曼传感探针,也是很有前景的治疗药物。其中,二(三芳基硼烷)荧光团(TAB3)与银纳米颗粒(NP)结合后,在试管中表现出TAB3染料的拉曼信号增强等特性。然而,TAB3染料-纳米颗粒复合材料尚未在生物系统中得到研究。因此,不同类型的金属纳米颗粒(金或银基)和不同的涂层(带负电荷的柠檬酸盐或中性PVP)是否可以在试管中有效地用TAB3染料染色就产生了问题。本研究的目的是研究大小相近(20-25 nm)的金和银纳米颗粒(含不同稳定剂)在黑暗和可见光辐射下的细胞摄取和细胞毒性,表征纳米颗粒与TAB3荧光团的相互作用,研究细胞内NP-TAB3复合物,评估其细胞内染色,以及可能的光诱导释放和生物活性。材料与方法:采用荧光滴定法测定了金基和银基纳米颗粒与TAB3的结合常数。NPs的细胞毒作用通过A549细胞的存活(MTT法)来确定。通过活细胞成像实验观察NP和NP- tab3复合材料的细胞摄取情况。结果:不同涂层的金基或银基NPs与TAB3具有较高的亲和力。这些np,以及TAB3-NP复合物,有效地进入活的人类细胞,在细胞质中积累,对特定细胞器没有明显的选择性。即使用所研究的NPs延长治疗3天,也没有显示出对细胞的任何毒性作用。细胞生物成像研究显示,TAB3-NP复合物不会在细胞内游离;先前报道的TAB3的光生物活性被与NPs的结合完全抑制。结论:无论采用不同的涂层,Au-和Ag - NPs均可通过TAB3进行非共价染色,具有相似的结合亲和力。TAB3的辐射被NPs强烈猝灭,但不是完全猝灭。对活细胞的实验表明,游离的NPs及其与TAB3的复合物都没有毒性。共聚焦显微镜的生物成像研究显示,所有NPs在90分钟内有效进入活细胞。在反射和荧光模式下同时收集数据的共定位实验表明,TAB3染料仍然与细胞内的NPs结合。用457nm激光对细胞内的TAB3- np进行强照射不会对细胞产生任何损伤,这与我们之前显示的TAB3染料单独具有很强的光生物活性不同。因此,将发色团与纳米颗粒结合可以抑制发色团进行光诱导单线态氧产生的能力,从而阻断其光生物活性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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