Catalytic Nanomedicine: Coated bionanocatalysts for Catalytic Antineoplastic activity

IF 3 4区 工程技术 Q3 CHEMISTRY, PHYSICAL Adsorption Pub Date : 2024-06-16 DOI:10.1007/s10450-024-00497-0
Tessy López-Goerne, Emma Ortiz-Islas, Francisco Rodríguez-Reinoso, Hugo Monroy, Esteban Gómez-López, Francisco J. Padilla-Godínez
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Abstract

Glioma tumors are the most common form of central nervous system tumors, and there is a pressing need for innovative methods that can precisely target cancer cells while leaving healthy tissues unharmed. In this study, progressing in the field of Catalytic Nanomedicine, we investigated the cytotoxic effects of a novel class of bionanocatalysts on glioma cancer cells. These bionanocatalysts were constructed from a catalytic matrix of oxides with evenly dispersed superficial copper-coating nanoparticles. This design optimizes both the inherent catalytic characteristics of the matrix and instills cytotoxic properties. The bionanocatalysts coated with copper demonstrated a significant reduction in cancer cell viability when compared to reference bionanocatalysts without the transition metal. We also observed structural damage to the cytoskeleton and alterations in mitochondrial activity. These findings suggest that these pathways are integral to the mechanisms through which these nanostructures execute their bionanocatalytic activities, particularly in breaking chemical bonds. Importantly, our physicochemical analyses verified that the coating with copper species, primarily CuO, did not disrupt the individual structure of the bionanocatalysts: instead, it enhanced their catalytic cytotoxic potential. This research aims to deepen our understanding of the mechanisms underlying this promising antineoplastic treatment and underscore the effectiveness of superficial copper-coating nanoparticles as agents for amplifying the inherent properties of bionanocatalysts through nanocatalysis.

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催化纳米医学:具有催化抗肿瘤活性的涂层仿生催化剂
胶质瘤是中枢神经系统肿瘤中最常见的一种,因此迫切需要一种既能精确靶向癌细胞,又能使健康组织不受损伤的创新方法。本研究在催化纳米医学领域取得了进展,我们研究了一类新型仿生纳米催化剂对胶质瘤癌细胞的细胞毒性作用。这些仿生纳米催化剂由氧化物催化基质与均匀分布的表层铜涂层纳米颗粒构建而成。这种设计既优化了基质固有的催化特性,又注入了细胞毒性特性。与不含过渡金属的参考仿生催化剂相比,涂铜的仿生催化剂显著降低了癌细胞的存活率。我们还观察到细胞骨架的结构损伤和线粒体活性的改变。这些发现表明,这些途径是这些纳米结构执行其仿生催化活性(尤其是破坏化学键)的不可或缺的机制。重要的是,我们的理化分析验证了铜物种(主要是氧化铜)涂层并没有破坏仿生催化剂的个体结构:相反,它增强了它们的催化细胞毒性潜力。这项研究旨在加深我们对这一前景广阔的抗肿瘤疗法的机制的理解,并强调表层铜涂层纳米粒子作为通过纳米催化放大仿生催化剂固有特性的制剂的有效性。
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来源期刊
Adsorption
Adsorption 工程技术-工程:化工
CiteScore
8.10
自引率
3.00%
发文量
18
审稿时长
2.4 months
期刊介绍: The journal Adsorption provides authoritative information on adsorption and allied fields to scientists, engineers, and technologists throughout the world. The information takes the form of peer-reviewed articles, R&D notes, topical review papers, tutorial papers, book reviews, meeting announcements, and news. Coverage includes fundamental and practical aspects of adsorption: mathematics, thermodynamics, chemistry, and physics, as well as processes, applications, models engineering, and equipment design. Among the topics are Adsorbents: new materials, new synthesis techniques, characterization of structure and properties, and applications; Equilibria: novel theories or semi-empirical models, experimental data, and new measurement methods; Kinetics: new models, experimental data, and measurement methods. Processes: chemical, biochemical, environmental, and other applications, purification or bulk separation, fixed bed or moving bed systems, simulations, experiments, and design procedures.
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