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Timing and Mechanisms of Nanodiamond Uptake in Colon Cancer Cells 结肠癌细胞吸收纳米金刚石的时间和机制
Pub Date : 2024-07-01 DOI: 10.2147/nsa.s464075
A. Sigaeva, Runrun Li, Jan Jelle van Laar, Leon Wierenga, R. Schirhagl
Introduction: As nanodiamonds become more and more widely used for intracellular labelling and measurements, the task of delivering these nanoparticles inside cells becomes more and more important. Certain cell types easily take up nanodiamonds, while others require special procedures. Methods: In previous research, we found that HT-29 cells (a colon cancer cell line), which are notoriously difficult in the context of nanodiamond internalization, show increased uptake rates, when pre-treated with trypsin-ethylenediaminetetraacetic acid (trypsin-EDTA). However, the uptake mechanism has not been studied before. This article focuses on a more detailed investigation of the reasons underlying this phenomenon. We start by identifying the timing of fluorescent nanodiamond (FND) uptake in trypsin-EDTA pre-treated cells. We then use a combination of chemical inhibitors and Immunocytochemistry to identify the main pathways employed by HT-29 cells in the internalization process. Results and Discussion: We investigate how these pathways are affected by the trypsin-EDTA pre-treatment and conclude by offering possible explanations for this phenomenon. We found that nanodiamonds are internalized via different pathways. Clathrin-mediated endocytosis proves to be the dominating mechanism. Trypsin-EDTA treatment increases particle uptake and affects the uptake mechanism.
导言:随着纳米金刚石越来越广泛地用于细胞内标记和测量,将这些纳米颗粒送入细胞内的任务也变得越来越重要。某些类型的细胞容易吸收纳米金刚石,而其他类型的细胞则需要特殊的程序。方法在以前的研究中,我们发现 HT-29 细胞(结肠癌细胞系)在纳米金刚石内化方面是出了名的困难,但在用胰蛋白酶-乙二胺四乙酸(胰蛋白酶-EDTA)预处理后,其吸收率会增加。然而,有关纳米金刚石的吸收机制还没有被研究过。本文将重点对这一现象的原因进行更详细的研究。我们首先确定了胰蛋白酶-EDTA 预处理细胞摄取荧光纳米金刚石(FND)的时间。然后,我们使用化学抑制剂和免疫细胞化学相结合的方法来确定 HT-29 细胞在内化过程中采用的主要途径。结果与讨论:我们研究了这些途径如何受到胰蛋白酶-EDTA 预处理的影响,最后提出了这一现象的可能解释。我们发现纳米金刚石是通过不同途径内化的。Clathrin 介导的内吞被证明是主要的机制。胰蛋白酶-EDTA处理增加了颗粒的吸收并影响了吸收机制。
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引用次数: 0
Farnesol and Selected Nanoparticles (Silver, Gold, Copper, and Zinc Oxide) as Effective Agents Against Biofilms Formed by Pathogenic Microorganisms 法尼醇和精选纳米粒子(银、金、铜和氧化锌)作为抗病原微生物形成的生物膜的有效药物
Pub Date : 2024-04-01 DOI: 10.2147/NSA.S457124
A. Lange, A. Matuszewski, Marta Kutwin, Agnieszka Ostrowska, S. Jaworski
Purpose Biofilms, which are created by most microorganisms, are known for their widely developed drug resistance, even more than planktonic forms of microorganisms. The aim of the study was to assess the effectiveness of agents composed of farnesol and nanoparticles (silver, gold, copper, and zinc oxide) in the degradation of biofilms produced by pathogenic microorganisms. Methods Escherichia coli, Enterococcus faecalis, Staphylococcus aureus, Pseudomonas aeruginosa, and Candida albicans were used to create the biofilm structure. Colloidal suspensions of silver, gold, copper, and zinc oxide (Ag, Au, Cu, ZnO) with the addition of farnesol (F) were used as the treatment factor. The size distribution of those composites was analyzed, their zeta potential was measured, and their structure was visualized by transmission electron microscopy. The viability of the microorganism strains was assessed by an XTT assay, the ability to form biofilms was analyzed by confocal microscopy, and the changes in biofilm structure were evaluated by scanning electron microscopy. The general toxicity toward the HFFF2 cell line was determined by a neutral red assay and a human inflammation antibody array. Results The link between the two components (farnesol and nanoparticles) caused mutual stability of both components. Planktonic forms of the microorganisms were the most sensitive when exposed to AgF and CuF; however, the biofilm structure of all microorganism strains was the most disrupted (both inhibition of formation and changes within the structure) after AgF treatment. Composites were not toxic toward the HFFF2 cell line, although the expression of several cytokines was higher than in the not-treated group. Conclusion The in vitro studies demonstrated antibiofilm properties of composites based on farnesol and nanoparticles. The greatest changes in biofilm structure were triggered by AgF, causing an alteration in the biofilm formation process as well as in the biofilm structure.
目的 大多数微生物都会产生生物膜,众所周知,生物膜具有广泛的抗药性,其抗药性甚至超过了浮游形态的微生物。本研究旨在评估由法尼醇和纳米粒子(银、金、铜和氧化锌)组成的制剂在降解病原微生物产生的生物膜方面的效果。方法 使用大肠杆菌、粪肠球菌、金黄色葡萄球菌、铜绿假单胞菌和白色念珠菌创建生物膜结构。银、金、铜和氧化锌(Ag、Au、Cu、ZnO)的胶体悬浮液添加了法尼醇(F)作为处理因子。分析了这些复合材料的粒度分布,测量了它们的 zeta 电位,并用透射电子显微镜观察了它们的结构。微生物菌株的活力通过 XTT 试验进行评估,形成生物膜的能力通过共聚焦显微镜进行分析,生物膜结构的变化通过扫描电子显微镜进行评估。对 HFFF2 细胞系的一般毒性是通过中性红检测法和人类炎症抗体阵列来确定的。结果 两种成分(法呢醇和纳米颗粒)之间的联系导致了两种成分的相互稳定性。在暴露于 AgF 和 CuF 时,微生物的浮游形式最为敏感;然而,所有微生物菌株的生物膜结构在 AgF 处理后受到的破坏最大(既抑制了形成,又改变了结构)。复合材料对 HFFF2 细胞系无毒性,但几种细胞因子的表达量高于未处理组。结论 体外研究表明,基于法呢醇和纳米颗粒的复合材料具有抗生物膜特性。AgF 引发了生物膜结构的最大变化,改变了生物膜的形成过程和生物膜结构。
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引用次数: 0
Spectroscopic Assessment of Doxorubicin (DOX)-Gemcitabine (GEM) Gold Complex Nanovector as Diagnostic Tool of Galectin-1 Biomarker 将多柔比星(DOX)-吉西他滨(GEM)金复合物纳米载体作为加列汀-1 生物标记物诊断工具的光谱学评估
Pub Date : 2024-03-01 DOI: 10.2147/NSA.S448883
Memona Khan, Khaoula Cherni, Rawdha Dekhili, J. Spadavecchia
Introduction The aim of this study is focused on the development of theranostic hybrid nanovectors based on gold-doxorubicin (DOX)-gemcitabine (GEM) complexes and their active targeting with Galectin-1 (Gal-1) as a promising therapeutic and prognostic marker in cancer. Methods For this purpose, a gold salt (HAuCl4) interacts with antitumor drugs (DOX; GEM) by chelation and then stabilizes with dicarboxylic acid-terminated polyethylene glycol (PEG) as a biocompatible surfactant. The proposed methodology is fast and reproducible, and leads to the formation of a hybrid nanovector named GEM@DOX IN PEG-AuNPs, in which the chemo-biological stability was improved. All synthetic chemical products were evaluated using various spectroscopic techniques (Raman and UV–Vis spectroscopy) and transmission electron microscopy (TEM). Results To conceive a therapeutic application, our hybrid nanovector (GEM@DOX IN PEG-AuNPs) was conjugated with the Galectin-1 protein (Gal-1) at different concentrations to predict and specifically recognize cancer cells. Gal-1 interacts with GEM@DOX in PEG-AuNPs, as shown by SPR and Raman measurements. We observed both dynamic variation in the plasmon position (SPR) and Raman band with Gal-1 concentration. Discussion We identified that GEM grafted electrostatically onto DOX IN PEG-AuNPs assumes a better chemical conformation, in which the amino group (NH3+) reacts with the carboxylic (COO−) group of PEG diacide, whereas the ciclopenthanol group at position C-5’ reacts with NH3+ of DOX. Conclusion This study opens further way in order to built “smart nanomedical devices” that could have a dual application as therapeutic and diagnostic in the field of nanomedicine and preclinical studies associated.
引言 本研究的目的是开发基于金-多柔比星(DOX)-吉西他滨(GEM)复合物的治疗杂交纳米载体,并将其与作为癌症治疗和预后标志物的Galectin-1(Gal-1)积极靶向。为此,金盐(HAuCl4)通过螯合作用与抗肿瘤药物(DOX;GEM)相互作用,然后用二羧酸封端聚乙二醇(PEG)作为生物相容性表面活性剂使其稳定。所提出的方法快速、可重复,并形成了一种名为 GEM@DOX IN PEG-AuNPs 的混合纳米载体,其化学生物稳定性得到了提高。使用各种光谱技术(拉曼光谱和紫外可见光谱)和透射电子显微镜(TEM)对所有合成化学产品进行了评估。结果 为了设想治疗应用,我们的混合纳米载体(GEM@DOX IN PEG-AuNPs)与不同浓度的 Galectin-1 蛋白(Gal-1)共轭,以预测和特异性识别癌细胞。SPR 和拉曼测量结果表明,Gal-1 与 PEG-AuNPs 中的 GEM@DOX 相互作用。我们观察到等离子体位置(SPR)和拉曼光谱带随 Gal-1 浓度的动态变化。讨论 我们发现,静电接枝到 DOX IN PEG-AuNPs 上的 GEM 具有更好的化学构象,其中氨基(NH3+)与 PEG 二酰羧基(COO-)反应,而 C-5' 位的环戊醇基则与 DOX 的 NH3+ 反应。结论 这项研究为制造 "智能纳米医疗设备 "开辟了新的道路,这种设备可以在纳米医学领域和临床前研究中发挥治疗和诊断的双重作用。
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引用次数: 0
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Nanotechnology, Science and Applications
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