Drug delivery and anticancer activity of biosynthesised mesoporous Fe2O3 nanoparticles

IF 3.8 4区 工程技术 Q1 BIOCHEMICAL RESEARCH METHODS IET nanobiotechnology Pub Date : 2022-03-16 DOI:10.1049/nbt2.12080
Firoozeh Abolhasani Zadeh, Saade Abdalkareem Jasim, Nigora E. Atakhanova, Hasan Sh. Majdi, Mohammed Abed Jawad, Mohammed Khudair Hasan, Fariba Borhani, Mehrdad Khatami
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引用次数: 8

Abstract

Mesoporous magnetic nanoparticles of haematite were synthesised using plant extracts according to bioethics principles. The structural, physical and chemical properties of mesoporous Fe2O3 nanoparticles synthesised with the green chemistry approach were evaluated by XRD, SEM, EDAX, BET, VSM and HRTEM analysis. Then, their toxicity against normal HUVECs and MCF7 cancer cells was evaluated by MTT assay for 48 h. These biogenic mesoporous magnetic nanoparticles have over 71% of doxorubicin loading efficiency, resulting in a 50% reduction of cancer cells at a 0.5 μg.ml−1 concentration. Therefore, it is suggested that mesoporous magnetic nanoparticles be used as a multifunctional agent in medicine (therapeutic-diagnostic). The produced mesoporous magnetic nanoparticles with its inherent structural properties such as polygonal structure (increasing surface area to particle volume) and porosity with large pore volume became a suitable substrate for loading the anti-cancer drug doxorubicin.

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生物合成介孔Fe2O3纳米颗粒的药物传递和抗癌活性
摘要根据生物伦理学原理,利用植物提取物合成了赤铁矿介孔磁性纳米粒子。通过XRD、SEM、EDAX、BET、VSM和HRTEM分析,对采用绿色化学方法合成的介孔Fe2O3纳米粒子的结构、物理和化学性能进行了评价。然后,通过MTT测定48小时来评估其对正常HUVEC和MCF7癌症细胞的毒性。这些生物介孔磁性纳米颗粒具有超过71%的阿霉素负载效率,在0.5μg.ml−1浓度下可使癌症细胞减少50%。因此,建议将介孔磁性纳米颗粒作为一种多功能药物用于医学(治疗-诊断)。所制备的中孔磁性纳米颗粒具有多边形结构(增加颗粒体积的表面积)和大孔体积的孔隙率等固有结构特性,成为负载抗癌症药物阿霉素的合适基质。
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来源期刊
IET nanobiotechnology
IET nanobiotechnology 工程技术-纳米科技
CiteScore
6.20
自引率
4.30%
发文量
34
审稿时长
1 months
期刊介绍: Electrical and electronic engineers have a long and illustrious history of contributing new theories and technologies to the biomedical sciences. This includes the cable theory for understanding the transmission of electrical signals in nerve axons and muscle fibres; dielectric techniques that advanced the understanding of cell membrane structures and membrane ion channels; electron and atomic force microscopy for investigating cells at the molecular level. Other engineering disciplines, along with contributions from the biological, chemical, materials and physical sciences, continue to provide groundbreaking contributions to this subject at the molecular and submolecular level. Our subject now extends from single molecule measurements using scanning probe techniques, through to interactions between cells and microstructures, micro- and nano-fluidics, and aspects of lab-on-chip technologies. The primary aim of IET Nanobiotechnology is to provide a vital resource for academic and industrial researchers operating in this exciting cross-disciplinary activity. We can only achieve this by publishing cutting edge research papers and expert review articles from the international engineering and scientific community. To attract such contributions we will exercise a commitment to our authors by ensuring that their manuscripts receive rapid constructive peer opinions and feedback across interdisciplinary boundaries. IET Nanobiotechnology covers all aspects of research and emerging technologies including, but not limited to: Fundamental theories and concepts applied to biomedical-related devices and methods at the micro- and nano-scale (including methods that employ electrokinetic, electrohydrodynamic, and optical trapping techniques) Micromachining and microfabrication tools and techniques applied to the top-down approach to nanobiotechnology Nanomachining and nanofabrication tools and techniques directed towards biomedical and biotechnological applications (e.g. applications of atomic force microscopy, scanning probe microscopy and related tools) Colloid chemistry applied to nanobiotechnology (e.g. cosmetics, suntan lotions, bio-active nanoparticles) Biosynthesis (also known as green synthesis) of nanoparticles; to be considered for publication, research papers in this area must be directed principally towards biomedical research and especially if they encompass in vivo models or proofs of concept. We welcome papers that are application-orientated or offer new concepts of substantial biomedical importance Techniques for probing cell physiology, cell adhesion sites and cell-cell communication Molecular self-assembly, including concepts of supramolecular chemistry, molecular recognition, and DNA nanotechnology Societal issues such as health and the environment Special issues. Call for papers: Smart Nanobiosensors for Next-generation Biomedical Applications - https://digital-library.theiet.org/files/IET_NBT_CFP_SNNBA.pdf Selected extended papers from the International conference of the 19th Asian BioCeramic Symposium - https://digital-library.theiet.org/files/IET_NBT_CFP_ABS.pdf
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