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碳纳米材料的环境行为及其对环境中污染物迁移归趋的影响 总被引:3,自引:0,他引:3
碳纳米材料具有广阔的应用前景,近年来已成为一大研究热点.工程碳纳米材料的大量生产和使用将不可避免地造成这些材料向环境中的释放,可能带来环境和生态风险.一方面,碳纳米材料本身具有环境毒性,另一方面碳纳米材料对环境中有毒有害污染物有较强的吸附性能,因此会影响污染物迁移转化等环境行为.目前,对碳纳米材料生态风险的研究主要集中于碳纳米材料对生物体可能的毒性,而对其自身环境行为以及影响污染物迁移归趋等方面的研究较少.本文简要概述了碳纳米材料的来源、暴露途径、环境行为以及对污染物迁移归趋的影响,阐述了这些研究对于评估碳纳米材料的环境和生态风险所具有的重要意义. 相似文献
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以四氧化三铁为代表的医用磁性纳米材料具有独特的磁学性能、表面易功能化、良好的生物学相容性等特点,在纳米医学相关领域展现出巨大的应用前景,特别是近年来它作为可介导外场的智能材料,在材料设计和生物医学应用方面均取得了突破性的进展.鉴于此,本文围绕磁性氧化铁纳米材料的生物医学应用,着重介绍近年来其在磁共振影像探针、磁热和磁力效应的生物医学应用、诊疗一体化以及纳米酶催化等领域的研究进展,并对磁性纳米材料在生物医学领域未来的发展方向进行了展望. 相似文献
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《中国科学:生命科学》2020,(7)
纳米生物催化领域包括:(ⅰ)利用纳米技术或纳米材料调控生物催化剂的效率;(ⅱ)直接利用纳米材料或技术实现生物催化功能,并拓展生物催化在非友好环境及疾病诊疗中的应用.纳米生物催化已成为纳米生物学重要的研究领域,主要涉及纳米载体固定化酶和纳米材料人工模拟酶(纳米酶).一方面,可以借助纳米技术或材料所具有的特殊纳米效应来增强生物催化剂的效率和稳定性.另一方面,从模拟酶的理念出发,借助纳米材料自身所具有的催化能力,直接实现对生化反应的催化,这类具有酶学特性的纳米酶被视为新一代人工模拟酶.近年来,基于纳米载体固定化酶和纳米酶技术的纳米生物催化已在疾病诊断和治疗、化工制药、环境处理等领域得到了广泛研究,并展示了其具有重要的应用价值.本文简要综述了纳米载体固定化酶和纳米酶的发展历程及应用进展. 相似文献
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磷烯,即单层黑磷(BP),由于具有直接带隙、显著的结构和功能各向异性、高电荷载流子迁移率等,已经在生物医学、药物输送、生物传感、疾病的诊断和治疗等领域取得了很大的进展。和其他纳米材料相比,磷烯具有更优异的生物相容性和生物可降解性,在生物医药领域有很好的应用前景。虽然已有大量磷烯生物学效应的报道,但磷烯与生物大分子,如核酸、脂质、蛋白质之间相互作用的过程细节仍缺乏系统的研究。目前实验上无法观测磷烯与生物分子相互作用的动力学过程,分子模拟在获取精确动态结构方面具有独特的优势,被广泛应用于纳米材料和生物学领域。本文综述了近年来国内外利用计算机仿真和实验方法在磷烯纳米材料与蛋白质、脂质膜和DNA等生物大分子相互作用方面取得的最新研究进展,对磷烯生物毒性目前的研究进行了评述,并对未来需要解决的问题作了分析。本文将促进磷烯生物学效应的基础研究,也将推动磷烯纳米材料在生物医药领域的应用。 相似文献
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磁性纳米材料,由于其独特的磁学性能、小尺寸效应,被广泛应用于生物医学领域.本文总结了磁性纳米材料的化学设计与合成、表面功能化方法,及其在核磁共振成像、磁控治疗、磁热疗和生物分离等生物医学领域的应用进展. 相似文献
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卫涛涛 《生物化学与生物物理进展》2021,48(1):5-5
纳米科学技术是20世纪80年代末期诞生并蓬勃发展的新兴科学技术,以多学科交叉融合为特色,为物理、化学、材料和生命科学等提供新的技术手段和研究视角.纳米材料的结构及表面物理化学性质直接决定了其与生物分子、细胞、组织、器官及个体的相互作用方式,并由此产生独特的生物效应——纳米生物效应.纳米生物学是从个体、细胞及分子水平深入研究纳米生物效应、阐明其精确机制的交叉科学,现已成为极具挑战性的热点前沿领域.中国科学家在纳米生物学领域已取得一系列令国际同行瞩目的重要进展,其中纳米酶(nanozyme)的开发及应用研究是极具代表性的原创发现之一. 相似文献
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近40年来,金属纳米材料发展迅猛,因其不同于宏观晶体的特殊性质,逐渐在各行业中起到了不可或缺的作用。当下人类面临资源、环境等日益严重的生态问题,因此金属纳米材料与生物学结合的绿色生态模式是大势所趋。本文重点综述了利用各种植物提取物、微生物以及蛋白质等生物材料作为还原剂,制备金属以及金属氧化物纳米材料的生物化学绿色合成方法。这些方法操作简单,制备的材料形貌尺寸不会产生太大变化。除此之外,生物材料的特定结构与金属纳米材料结合,通常会表现出协同或者新的理化和生理性能,以至于这些金属纳米材料在光热治疗及生物成像、抑菌及康复治愈和生物传感器及检测等生物医学领域产生了重大影响。金属纳米材料的生物化学制备会给未来纳米材料和生物学领域带来更多的交叉,会有更多跨学科工作者对其现存挑战来进行努力工作,并且在未来的医疗领域定会有金属纳米材料不可或缺的身影。 相似文献
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Due to their many advantageous properties, nanomaterials(NMs) have been utilized in diverse consumer goods, industrial products, and for therapeutic purposes. This situation leads to a constant risk of exposure and uptake by the human body, which are highly dependent on nanomaterial size. Consequently, an improved understanding of the interactions between different sizes of nanomaterials and biological systems is needed to design safer and more clinically relevant nano systems. We discuss the sizedependent effects of nanomaterials in living organisms. Upon entry into biological systems, nanomaterials can translocate biological barriers, distribute to various tissues and elicit different toxic effects on organs, based on their size and location. The association of nanomaterial size with physiological structures within organs determines the site of accumulation of nanoparticles.In general, nanomaterials smaller than 20 nm tend to accumulate in the kidney while nanomaterials between 20 and 100 nm preferentially deposit in the liver. After accumulating in organs, nanomaterials can induce inflammation, damage structural integrity and ultimately result in organ dysfunction, which helps better understand the size-dependent dynamic processes and toxicity of nanomaterials in organisms. The enhanced permeability and retention effect of nanomaterials and the utility of this phenomenon in tumor therapy are also highlighted. 相似文献
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Nanotechnology is set to impact a vast range of fields, including computer science, materials technology, engineering/manufacturing
and medicine. As nanotechnology grows so does exposure to nanostructured materials, thus investigation of the effects of nanomaterials
on biological systems is paramount. Computational techniques can allow investigation of these systems at the nanoscale, providing
insight into otherwise unexaminable properties, related to both the intentional and unintentional effects of nanomaterials.
Herein, we review the current literature involving computational modelling of nanoparticles and biological systems. This literature
has highlighted the common modes in which nanostructured materials interact with biological molecules such as membranes, peptides/proteins
and DNA. Hydrophobic interactions are the most favoured, with π-stacking of the aromatic side-chains common when binding to
a carbonaceous nanoparticle or surface. van der Waals forces are found to dominate in the insertion process of DNA molecules
into carbon nanotubes. Generally, nanoparticles have been observed to disrupt the tertiary structure of proteins due to the
curvature and atomic arrangement of the particle surface. Many hydrophobic nanoparticles are found to be able to transverse
a lipid membrane, with some nanoparticles even causing mechanical damage to the membrane, thus potentially leading to cytotoxic
effects. Current computational techniques have revealed how some nanoparticles interact with biological systems. However,
further research is required to determine both useful applications and possible cytotoxic effects that nanoparticles may have
on DNA, protein and membrane structure and function within biosystems. 相似文献
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Kunos G Járai Z Varga K Liu J Wang L Wagner JA 《Prostaglandins & other lipid mediators》2000,61(1-2):71-84
Cannabinoids, the bioactive ingredients of the marijuana plant, are best known for their psychoactive properties, but they also influence other physiological processes, such as cardiovascular variables. Endocannabinoids are recently identified lipid mediators that act as natural ligands at cannabinoid receptors and mimic most of the biological effects, including the cardiovascular actions, of plant-derived cannabinoids. In experimental animals, the most prominent component of the cardiovascular effects of cannabinoids is prolonged hypotension and bradycardia. This review focuses on the possible mechanisms underlying these effects. The emerging evidence suggesting that endocannabinoids may be involved in the peripheral regulation of vascular tone under certain conditions is also discussed. 相似文献
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Biotechnological synthesis of functional nanomaterials 总被引:1,自引:0,他引:1
Biological systems, especially those using microorganisms, have the potential to offer cheap, scalable and highly tunable green synthetic routes for the production of the latest generation of nanomaterials. Recent advances in the biotechnological synthesis of functional nano-scale materials are described. These nanomaterials range from catalysts to novel inorganic antimicrobials, nanomagnets, remediation agents and quantum dots for electronic and optical devices. Where possible, the roles of key biological macromolecules in controlling production of the nanomaterials are highlighted, and also technological limitations that must be addressed for widespread implementation are discussed. 相似文献
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Engineered nanomaterials are commonly defined as materials with at least one dimension of 100 nanometers or less. Such materials typically possess nanostructure-dependent properties (e.g., chemical, mechanical, electrical, optical, magnetic, biological), which make them desiderable for commercial or medical application. However, these same properties may potentially lead to nanostructure-dependent biological activity that differs from and is not directly predicted by the bulk properties of the constitutive chemicals and compounds. Nanoparticles and nanomaterials can be on the same scale of living cells components, including proteins, nucleic acids, lipids and cellular organelles. When considering nanoparticles it must be asked how man-made nanostructures can interact with or influence biological systems. Carbon nanotubes (CNTs) are an example of carbon-based nanomaterial, which has won a huge spreading in nanotechnology. The incorporation of CNTs in living systems has raised many concerns because of their hydrophobicity and tendency to aggregate and accumulate into cells, organs, and tissues with dangerous effects. 相似文献
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A decade of aggressive researches on carbon nanotubes (CNTs) has paved way for extending these unique nanomaterials into a wide range of applications. In the relatively new arena of nanobiotechnology, a vast majority of applications are based on CNTs, ranging from miniaturized biosensors to organ regeneration. Nevertheless, the complexity of biological systems poses a significant challenge in developing CNT‐based tissue engineering applications. This review focuses on the recent developments of CNT‐based tissue engineering, where the interaction between living cells/tissues and the nanotubes have been transformed into a variety of novel techniques. This integration has already resulted in a revaluation of tissue engineering and organ regeneration techniques. Some of the new treatments that were not possible previously become reachable now. Because of the advent of surface chemistry, the CNT's biocompatibility has been significantly improved, making it possible to serve as tissue scaffolding materials to enhance the organ regeneration. The superior mechanic strength and chemical inert also makes it ideal for blood compatible applications, especially for cardiopulmonary bypass surgery. The applications of CNTs in these cardiovascular surgeries led to a remarkable improvement in mechanical strength of implanted catheters and reduced thrombogenecity after surgery. Moreover, the functionalized CNTs have been extensively explored for in vivo targeted drug or gene delivery, which could potentially improve the efficiency of many cancer treatments. However, just like other nanomaterials, the cytotoxicity of CNTs has not been well established. Hence, more extensive cytotoxic studies are warranted while converting the hydrophobic CNTs into biocompatible nanomaterials. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009 相似文献
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Yi Cao Yu Gong Wenzhen Liao Yunfeng Luo Chaohua Wu Maolin Wang Qianyu Yang 《Biometals》2018,31(4):457-476
To ensure the safe use of nanoparticles (NPs) in modern society, it is necessary and urgent to assess the potential toxicity of NPs. Cardiovascular system is required for the systemic distribution of NPs entering circulation. Therefore, the adverse cardiovascular effects of NPs have gained extensive research interests. Metal based NPs, such as TiO2, ZnO and Ag NPs, are among the most popular NPs found in commercially available products. They may also have potential applications in biomedicine, which could increase their contact with cardiovascular systems. This review aimed at providing an overview about the adverse cardiovascular effects of TiO2, ZnO and Ag NPs. We discussed about the bio-distribution of NPs following different exposure routes. We also discussed about the cardiovascular toxicity of TiO2, ZnO and Ag NPs as assessed by in vivo and in vitro models. The possible mechanisms and contribution of physicochemical properties of metal based NPs were also discussed. 相似文献
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Nanotechnologies, defined as techniques aimed to conceive, characterize and produce material at the nanometer scale, represent a fully expanding domain, and one can predict without risk that production and utilization of nanomaterials will increase exponentially in the coming years. Applications of nanotechnologies are numerous, in constant development, and their potential use in the medical field as diagnosis and therapeutics tools is very attractive. The size particularity of these nanomaterials gives them novel properties, allowing them to adopt new comportments because of the laws of quantum physics that exist at this scale. However, worries are expressed regarding the exact properties that make these nanomaterials attractive, and questions are raised regarding their potential toxicity, their long-term secondary effects or their biodegradability, particularly when thinking of their use in the (nano)medical field. These questions are justified by the knowledge of the toxic effects of atmospheric pollution micrometric particles on health, and the fear to get an amplification of these effects because of the size of the materials blamed. In this paper, we first expose the sensed medical applications of nanomaterials, and the physicochemical and molecular determinants potentially responsible for nanomaterials biological effects. Finally, we present a synthesis of the actual knowledge regarding toxicological effects of nanomaterials. It is clear that, in regard to the almost empty field of what is known on the subject, there's an urge to better understand biological effects of nanomaterials, which will allow their safe use, in particular in the nanomedicine field. 相似文献
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Pawel Mroz George P Tegos Hariprasad Gali Tim Wharton Tadeusz Sarna Michael R Hamblin 《Photochemical & photobiological sciences》2007,6(11):1139-1149
Fullerenes are a class of closed-cage nanomaterials made exclusively from carbon atoms. A great deal of attention has been focused on developing medical uses of these unique molecules especially when they are derivatized with functional groups to make them soluble and therefore able to interact with biological systems. Due to their extended pi-conjugation they absorb visible light, have a high triplet yield and can generate reactive oxygen species upon illumination, suggesting a possible role of fullerenes in photodynamic therapy. Depending on the functional groups introduced into the molecule, fullerenes can effectively photoinactivate either or both pathogenic microbial cells and malignant cancer cells. The mechanism appears to involve superoxide anion as well as singlet oxygen, and under the right conditions fullerenes may have advantages over clinically applied photosensitizers for mediating photodynamic therapy of certain diseases. 相似文献