磁性纳米材料的生物医学应用进展

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.     

医用金属及金属氧化物纳米材料的毒性研究

随着纳米科技的发展,纳米材料在各领域的应用日益增多。金属及金属氧化物纳米材料因其独特的物化性质,为多种疾病的诊治提供了崭新的解决途径。其中,贵金属金、银及应用最为广泛的铁所形成的纳米材料在医学领域应用甚广。纳米金及纳米银具有优异的抗菌效能,广泛用于伤口敷料、化妆品、食品等的制造中。除此之外,纳米金、纳米银及含铁的磁性纳米颗粒也用于疾病诊治方面,如肿瘤的诊断和治疗、生物传感器、生物成像等。但是,大部分金属纳米材料可对机体产生不良作用,因而了解金属纳米材料的毒性显得非常重要。为了在医学应用中更有效地利用金属纳米材料,必须探究其大小、表面化学、特殊性质及毒性。本文总结了这几种金属纳米材料的医学用途,概述了它们的体内外毒性,并分析了可能的毒性作用机制。     

涡旋磁纳米颗粒——崭新的生物医用磁性纳米平台

相比于超顺磁性纳米颗粒,具有涡旋磁畴的磁性纳米颗粒,由于独特的磁化闭合分布、较大的粒径尺寸及外加磁场中的磁化翻转特性,使得其兼具弱的颗粒间磁相互作用和更优异的磁学性能,在生物医学领域展现出了更好的应用优势和潜力.本综述结合近年来国内外对涡旋磁畴的研究及涡旋磁纳米颗粒在生物医学领域的报道,提出了一类新型的生物医用涡旋磁溶胶体系,并以涡旋磁氧化铁纳米盘和纳米环为例,介绍了涡旋磁纳米颗粒的化学合成,并着重论述了这类具有独特涡旋畴结构的纳米颗粒在磁共振成像、抗肿瘤治疗等生物医学应用上的最新研究进展.     

调制磁性纳米颗粒提高磁热性能的研究

磁性纳米颗粒具有独特的磁学性质,即在外加交变磁场下因产生磁滞释放热量,使其在生物医学领域,特别是肿瘤磁热疗,获得了广泛应用.到目前为止,磁性纳米颗粒介导的磁热疗成为一种治疗癌症的有效手段,已进入临床三期实验.因此,针对磁性纳米颗粒本身,优化设计尺寸、形貌、组分和表面修饰来提高其磁热性能,进而减小临床应用中的颗粒浓度来最小化毒副作用的研究,对肿瘤治疗及生物医药研究具有十分重要的意义.本综述详述如何优化调制磁性纳米颗粒以提高其磁热性能,为高效、低毒的磁性纳米颗粒的设计提供了指导性的研究方向.     

磁小体的生物合成及用于肿瘤靶向治疗的研究进展

趋磁细菌产生的磁小体是生物膜包被的磁性纳米颗粒,具有优良的纳米磁特性;相比化学合成的磁性纳米材料,其生物来源赋予磁小体更好的生物相容性和遗传可操作性.在生物医学领域,除了用于磁热疗进行肿瘤治疗外,最近几年其作为靶向药物载体、可能参与肿瘤微环境调控的性质得到研究者的广泛关注;同时DNA重组技术的发展解决了磁小体的产率低而趋磁细菌难培养的问题.本文综述了磁小体的生物合成及其相关研究进展,并对其应用前景进行了展望.     

磁场下铁基氧化物纳米材料的生物医学应用

在过去的几年中,磁性纳米材料的快速发展对生物医学变革产生了巨大的影响。作为磁性纳米材料家族重要的一大分类,纳米级铁基氧化物由于其良好的生物相容性、表面易功能化、独特的磁学性质等特点,在生物医学相关领域展现出巨大的应用前景。本综述围绕磁场下铁基氧化物纳米材料的生物医学应用,介绍了近年来其在磁分离、磁性药物靶向(magnetic drug targeting, MDT)、磁共振成像(magnetic resonance imaging, MRI)、磁性粒子成像(magnetic particle imaging, MPI)、磁响应药物释放、磁流体热疗(magnetic fluid hyperthermia, MFH)等领域的研究进展,并对铁基氧化物纳米材料在生物医学领域未来的发展方向进行了展望。     

纳米材料在生物医学检测中的应用

纳米技术的兴起,对生物医学领域的变革产生了深远的影响。纳米材料是纳米技术发展的重要基础,它具有许多传统材料所不具备的独特的理化性质,因此在生物医学、传感器等重要技术领域有着广泛的应用前景。对几类常见的纳米材料包括纳米金、量子点、磁性纳米粒子、碳纳米管和硅纳米线在蛋白质、DNA、金属离子以及生物相关分子检测方面的应用进行综述。     

磁性纳米颗粒作为载体在基因转染中的研究进展

磁性纳米颗粒具有很强的结合、浓缩与保护DNA的作用,具有超顺磁性、较高的安全性和低的免疫原性,可以结合大片段DNA,在外加磁场的作用下可实现安全、高效的基因靶向性运输,提高外源基因的转染效率。由于磁性纳米颗粒的独特性质,使得其作为非病毒载体在基因治疗中的应用进展迅速。我们简要介绍磁性纳米材料的特点、种类及结构,磁性纳米基因载体的特点,以及磁性纳米颗粒作为载体在基因转染中的应用情况。     

磁性纳米粒子作用于肝癌细胞的生物学效应的研究进展

磁性纳米粒子,是一类智能型的纳米材料,因其特有的性质,被广泛应用于生物医学领域,在肝癌的治疗方面也有大量的实验性研究和成果。研究和探索磁性纳米粒子治疗肝癌的新方法和途径,有着很大的现实意义。本文就磁性纳米粒子作用于肝癌细胞的生物学效应的研究现状和进展进行总结整理,从三个方面进行了综述:磁性纳米粒子直接作用于肝癌细胞,探索磁性纳米粒子的生物相容性、在肝癌细胞的分布方式以及磁性纳米粒子本身对肝癌细胞的生物学效应的影响;磁性纳米粒子协同外加磁场(稳恒磁场、极低频交变磁场和高频交变磁场)作用于肝癌细胞;磁性纳米粒子外加修饰(磁性白蛋白纳米颗粒、纳米磁流体、磁性脂质体等),作为药物载体作用于肝癌细胞。     

综述——新型纳米生物材料的研发：磁性纳米材料：化学合成、功能化与生物医学应用

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．     

Non-toxic nanoparticles from phytochemicals: preparation and biomedical application

Nanoparticles (NPs) have various applications in biomedicine and drug delivery carriers and also are widely used in cosmetics. However, the preparation of biocompatible and non-toxic nanomaterials is a very important issue as most of the starting materials are synthesized using toxic chemical reagents. This review introduces the preparation of biocompatible NPs in a range of their concentrations using phytochemicals for biomedicine and biotechnology. Phytochemicals are natural products that are extracted from plants, vegetables, and fruits. Phytochemicals serve as reducing agents and stabilizers during NP synthesis to convert metal ions to metal NPs in water. Possible applications of such nanomaterials in biomedical sciences are also described in this review.     

Sustainable approaches towards green synthesis of TiO2 nanomaterials and their applications in photocatalysis-mediated sensing to monitor environmental pollution

Nanomaterials are gaining enormous interests due to their novel applications that have been explored nearly in every field of our contemporary society. In this scenario, preparations of nanomaterials following green routes have attracted widespread attention in terms of sustainable, reliable, and environmentally friendly practices to produce diverse nanostructures. In this review, we summarize the fundamental processes and mechanisms of green synthesis approaches of TiO₂ nanoparticles (NPs). We explore the role of plants and microbes as natural bioresources to prepare TiO₂ NPs. Particularly, focus has been made to explore the potential of TiO₂-based nanomaterials to design a variety of sensing platforms by exploiting the photocatalysis efficiency under the influence of a light source. These types of sensing are of massive importance for monitoring environmental pollution and therefore for inventing advanced strategies to remediate hazardous pollutants and offer a clean environment.     

Use of ZnO:Tb down‐conversion phosphor for Ag nanoparticle plasmon absorption using a He–Cd ultraviolet laser

Although noble metal nanoparticles (NPs) have attracted some attention for potentially enhancing the luminescence of rare earth ions for phosphor lighting applications, the absorption of energy by NPs can also be beneficial in biological and polymer applications where local heating is desired, e.g. photothermal applications. Strong interaction between incident laser light and NPs occurs only when the laser wavelength matches the NP plasmon resonance. Although lasers with different wavelengths are available and the NP plasmon resonance can be tuned by changing its size and shape or the dielectric medium (host material), in this work, we consider exciting the plasmon resonance of Ag NPs indirectly with a He–Cd UV laser using the down‐conversion properties of Tb³⁺ ions in ZnO. The formation of Ag NPs was confirmed by X‐ray diffraction, transmission electron microscopy and UV–vis diffuse reflectance measurements. Radiative energy transfer from the Tb³⁺ ions to the Ag NPs resulted in quenching of the green luminescence of ZnO:Tb and was studied by means of spectral overlap and lifetime measurements. The use of a down‐converting phosphor, possibly with other rare earth ions, to indirectly couple a laser to the plasmon resonance wavelength of metal NPs is therefore successfully demonstrated and adds to the flexibility of such systems. Copyright © 2016 John Wiley & Sons, Ltd.     

Bioengineered silver nanoparticles using Curvularia pallescens and its fungicidal activity against Cladosporium fulvum

Microorganisms based biosynthesis of nanomaterials has triggered significant attention, due to their great potential as vast source of the production of biocompatible nanoparticles (NPs). Such biosynthesized functional nanomaterials can be used for various biomedical applications. The present study investigates the green synthesis of silver nanoparticles (Ag NPs) using the fungus Curvularia pallescens (C. pallescens) which is isolated from cereals. The C. pallescens cell filtrate was used for the reduction of AgNO₃ to Ag NPs. To the best of our knowledge C. pallescens is utilized first time for the preparation of Ag NPs. Several alkaloids and proteins present in the phytopathogenic fungus C. pallescens were mainly responsible for the formation of highly crystalline Ag NPs. The as-synthesized Ag NPs were characterized by using UV–Visible spectroscopy, X-ray diffraction and transmission electron microscopy (TEM). The TEM micrographs have revealed that spherical shaped Ag NPs with polydisperse in size were obtained. These results have clearly suggested that the biomolecules secreted by C. pallescens are mainly responsible for the formation and stabilization of nanoparticles. Furthermore, the antifungal activity of the as-prepared Ag NPs was tested against Cladosporium fulvum, which is the major cause of a serious plant disease, known as tomato leaf mold. The synthesized Ag NPs displayed excellent fungicidal activity against the tested fungal pathogen. The extreme zone of reduction occurred at 50 μL, whereas, an increase in the reduction activity is observed with increasing the concentration of Ag NPs. These encouraging results can be further exploited by employing the as synthesized Ag NPs against various pathogenic fungi in order to ascertain their spectrum of fungicidal activity.     

A review of cardiovascular toxicity of TiO<Subscript>2</Subscript>, ZnO and Ag nanoparticles (NPs)

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.     

Double-Layer Magnetic Nanoparticle-Embedded Silica Particles for Efficient Bio-Separation

Superparamagnetic Fe₃O₄ nanoparticles (NPs) based nanomaterials have been exploited in various biotechnology fields including biomolecule separation. However, slow accumulation of Fe₃O₄ NPs by magnets may limit broad applications of Fe₃O₄ NP-based nanomaterials. In this study, we report fabrication of Fe₃O₄ NPs double-layered silica nanoparticles (DL MNPs) with a silica core and highly packed Fe₃O₄ NPs layers. The DL MNPs had a superparamagnetic property and efficient accumulation kinetics under an external magnetic field. Moreover, the magnetic field-exposed DL MNPs show quantitative accumulation, whereas Fe₃O₄ NPs single-layered silica nanoparticles (SL MNPs) and silica-coated Fe₃O₄ NPs produced a saturated plateau under full recovery of the NPs. DL MNPs are promising nanomaterials with great potential to separate and analyze biomolecules.     

Toxicity of gold nanoparticles (AuNPs): A review

Gold nanoparticles are a kind of nanomaterials that have received great interest in field of biomedicine due to their electrical, mechanical, thermal, chemical and optical properties. With these great potentials came the consequence of their interaction with biological tissues and molecules which presents the possibility of toxicity. This paper aims to consolidate and bring forward the studies performed that evaluate the toxicological aspect of AuNPs which were categorized into in vivo and in vitro studies. Both indicate to some extent oxidative damage to tissues and cell lines used in vivo and in vitro respectively with the liver, spleen and kidney most affected. The outcome of these review showed small controversy but however, the primary toxicity and its extent is collectively determined by the characteristics, preparations and physicochemical properties of the NPs. Some studies have shown that AuNPs are not toxic, though many other studies contradict this statement. In order to have a holistic inference, more studies are required that will focus on characterization of NPs and changes of physical properties before and after treatment with biological media. So also, they should incorporate controlled experiment which includes supernatant control Since most studies dwell on citrate or CTAB-capped AuNPs, there is the need to evaluate the toxicity and pharmacokinetics of functionalized AuNPs with their surface composition which in turn affects their toxicity. Functionalizing the NPs surface with more peculiar ligands would however help regulate and detoxify the uptake of these NPs.     

The futuristic applications of transition metal dichalcogenides for cancer therapy

The second-most common cause of death resulting from genetic mutations in DNA sequences is cancer. The difficulty in the field of anticancer research is the application of the traditional methods, which also affects normal cells. Mutations, genetic replication alterations, and chromosomal abnormalities have a direct impact on the effectiveness of anticancer drugs at different stages. Presently, therapeutic techniques utilize nanotechnology, transition metal dichalcogenides (TMDCs), and robotics. TMDCs are being increasingly employed in tumor therapy and biosensing applications due to their biocompatibility, adjustable bandgap, versatile functionality, exceptional photoelectric properties, and wide range of applications. This study reports the advancement of nanoplatforms based on TMDCs that are specifically engineered for responsive and intelligent cancer therapy. This article offers a thorough examination of the current challenges, future possibilities for theranostic applications using TMDCs, and recent progress in employing TMDCs for cancer therapy. Currently, there is significant interest in two-dimensional (2D) TMDCs nanomaterials as ultrathin unique physicochemical properties. These materials have attracted attention in various fields, including biomedicine. Due to their inherent ability to absorb near-infrared light and their exceptionally large surface area, significant efforts are being made to prepare multifunctional nanoplatforms based on 2D TMDCs.     

Dendrimer functionalized magnetic nanoparticles as a promising platform for localized hyperthermia and magnetic resonance imaging diagnosis

Magnetic iron oxide nanoparticles are a well-explored class of nanomaterials known for their high magnetization and biocompatibility. They have been used in various biomedical applications such as drug delivery, biosensors, hyperthermia, and magnetic resonance imaging (MRI) contrast agent. It is necessary to surface modify the nanoparticles with a biocompatible moiety to prevent their agglomeration and enable them to target to the defined area. Dendrimers have attracted considerable attention due to their small size, monodispersed, well-defined globular shape, and a relative ease incorporation of targeting ligands. In this study, superparamagnetic iron oxide nanoparticles were synthesized via a coprecipitation method. The magnetic nanoparticles (MNPs) had been modified with (3-aminopropyl) triethoxysilane, and then polyamidoamine functionalized MNPs had been synthesized cycling. Various characterization techniques had been used to reveal the morphology, size, and structure of the nanoparticles such as scanning electron microscopy, transmission electron microscope, X-ray diffraction analysis, and vibrating sample magnetometer, Fourier-transform infrared spectroscopy and zeta potential measurements. In addition, the cytotoxicity property of G3–dendrimer functionalized MNPs were evaluated using 3-[4,5-dimethylthiazol-2-yl]-2, 5-diphenyl tetrazolium bromide assay which confirmed the biocompatibility of the nanocomposites. Dendrimer functionalized MNPs are able to act as contrast agents for MRI and magnetic fluid hyperthermia mediators. A superior heat generation was achieved for the given concentration according to the hyperthermia results. MRI results show that the synthesized nanocomposites are a favorable option for MRI contrast agent. We believe that these dendrimer functionalized MNPs have the potential of integrating therapeutic and diagnostic functions in a single carrier.