Uptake of luminescent colloidal Ag–In–S nanoprobes by BC cells differing in metastasis propensity

IF 4.7 3区化学 Q2 CHEMISTRY, PHYSICAL Journal of Photochemistry and Photobiology A-chemistry Pub Date : 2025-02-23 DOI:10.1016/j.jphotochem.2025.116359

E. Kontareva , E. Pershikova , A. Sizikov , A. Mutali , M. Pustovalova , S. Leonov , Y. Merkher

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Abstract

This study investigates the metastasis-dependent cellular uptake of luminescent colloidal silver–indium–sulfur (Ag–In–S) nanoprobes in breast cancer (BC) cells. We developed water-soluble fluorescent semiconductor nanocrystals (quantum dots, QDs) that exhibit exceptional brightness, remarkable photostability, and impressive resistance to photobleaching. The Ag–In–S quantum dots, coated with either mercaptopropionic acid (MPA–Ag–In–S) or branched polyethyleneimine (BPEI–Ag–In–S), demonstrate a broad emission spectrum ranging from deep red to bluish green, achieving photoluminescence quantum yields of up to 47 %. The absorption spectra revealed peaks ranging from 290 nm to 440 nm, with a persistent peak at 555 nm observed across all quantum dots. The size of MPA–Ag–In–S nanoparticles ranged from 2 to 5 nm, while BPEI-–Ag–In–S nanoparticles ranged from 150 to 200 nm.

We employed a scanning microplate fluorometer to accurately measure the cellular uptake of QDs, normalizing the fluorescence data based on DNA content quantified using Hoechst 33,342 dye. Our findings revealed that cells exhibiting high MP internalized significantly more QDs compared to those with low MP, showing an increase of 1.5–1.7 times. Toxicity assays demonstrated that MPA–Ag–In–S QDs exhibited no toxic effects on both high and low MP cells. In contrast, BPEI–Ag–In–S QDs caused substantial cell death within just one hour of exposure.

Comparative analysis with commercially available nanoparticles highlighted the superior concentration and fluorescence properties of our synthesized QDs. These results indicate that Ag–In–S nanoprobes may be a powerful tool for distinguishing the metastatic potential of cancer cells, presenting a promising avenue for enhanced targeted cancer diagnostics and treatment.

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不同转移倾向的BC细胞对发光胶体Ag-In-S纳米探针的摄取

本研究探讨了乳腺癌（BC）细胞中发光胶体银铟硫（Ag-In-S）纳米探针的转移依赖性细胞摄取。我们开发了水溶性荧光半导体纳米晶体（量子点，QDs），具有卓越的亮度，卓越的光稳定性和令人印象深刻的抗光漂白能力。用巯基丙酸（MPA-Ag-In-S）或支化聚乙烯亚胺（BPEI-Ag-In-S）包覆的Ag-In-S量子点显示出从深红色到蓝绿色的宽发射光谱，实现高达47%的光致发光量子产率。吸收光谱在290 ~ 440 nm范围内，在555 nm处有一个持久的峰。MPA-Ag-In-S纳米颗粒的尺寸在2 ~ 5 nm之间，BPEI- Ag-In-S纳米颗粒的尺寸在150 ~ 200 nm之间。我们使用扫描微孔板荧光仪精确测量量子点的细胞摄取，并根据Hoechst 33,342染料定量的DNA含量对荧光数据进行归一化。我们的研究结果显示，与低MP的细胞相比，高MP的细胞内化了更多的量子点，增加了1.5-1.7倍。毒性实验表明，MPA-Ag-In-S QDs对高、低MP细胞均无毒性作用。相比之下，BPEI-Ag-In-S量子点在暴露1小时内导致大量细胞死亡。与市售纳米粒子的对比分析表明，我们合成的量子点具有优异的浓度和荧光特性。这些结果表明，Ag-In-S纳米探针可能是区分癌细胞转移潜力的有力工具，为增强靶向癌症诊断和治疗提供了一条有希望的途径。

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来源期刊

Journal of Photochemistry and Photobiology A-chemistry 化学-物理化学

CiteScore

7.90

自引率

7.00%

发文量

580

审稿时长

48 days

期刊介绍： JPPA publishes the results of fundamental studies on all aspects of chemical phenomena induced by interactions between light and molecules/matter of all kinds. All systems capable of being described at the molecular or integrated multimolecular level are appropriate for the journal. This includes all molecular chemical species as well as biomolecular, supramolecular, polymer and other macromolecular systems, as well as solid state photochemistry. In addition, the journal publishes studies of semiconductor and other photoactive organic and inorganic materials, photocatalysis (organic, inorganic, supramolecular and superconductor). The scope includes condensed and gas phase photochemistry, as well as synchrotron radiation chemistry. A broad range of processes and techniques in photochemistry are covered such as light induced energy, electron and proton transfer; nonlinear photochemical behavior; mechanistic investigation of photochemical reactions and identification of the products of photochemical reactions; quantum yield determinations and measurements of rate constants for primary and secondary photochemical processes; steady-state and time-resolved emission, ultrafast spectroscopic methods, single molecule spectroscopy, time resolved X-ray diffraction, luminescence microscopy, and scattering spectroscopy applied to photochemistry. Papers in emerging and applied areas such as luminescent sensors, electroluminescence, solar energy conversion, atmospheric photochemistry, environmental remediation, and related photocatalytic chemistry are also welcome.