基于氧化铁纳米材料特性的生物分离和生物检测

氧化铁纳米粒子是一种新型的磁功能材料,被广泛应用于生物、材料以及环境等众多领域.本文介绍了超顺磁氧化铁纳米粒子的制备方法,比较了各种方法的优缺点;评述了磁性氧化铁纳米粒子在细胞、蛋白质和核酸分离及生物检测中的应用,对多功能复合磁性氧化铁纳米粒子的构建, 在生物医学领域中的应用具有的指导意义.     

磁性铁氧化物纳米粒子制备及其体内应用研究

磁性铁氧化物纳米粒子由于其生物相容性和低毒性而广泛的应用于生物医学领域。本文总结了近年来制备各种磁性铁氧化物纳米粒子的方法,比较了它们在粒径、结晶度以及制备条件等方面的优缺点,概括了对其进行表面修饰改性材料的种类,阐述近年来磁性铁氧化物纳米粒子在体内应用中药物运输、磁共振成像、磁热疗方面的进展,并指出当前应用中的主要方向和亟待解决的问题。     

羧甲基壳聚糖磁性纳米粒子的合成及应用

通过合成油酸修饰的Fe3O4纳米粒子和羧甲基壳聚糖直接包埋油酸修饰的Fe3O4纳米粒子的两步合成法制备了羧甲基壳聚糖磁性纳米粒子。采用透射电子显微镜、傅里叶变换红外光谱、振动样品磁强计和同步热分析测试技术对制备的羧甲基壳聚糖磁性纳米粒子进行了表征。所得磁性纳米粒子呈规则球形,粒径约为10 nm;表面含羧基,且具有很好的顺磁性和稳定性。考察了羧甲基壳聚糖磁性纳米粒子对阿霉素的载药量和对阿霉素在磷酸盐缓冲溶液中的缓释性能。结果表明,磁性纳米粒子对阿霉素展示了较高的载药量(91.8 mg/g),结合了阿霉素的磁性复合物对阿霉素的缓释作用明显,说明制备的羧甲基壳聚糖磁性纳米粒子有望作为治疗肿瘤的纳米磁靶向药物输送载体。     

深冷状态下纳米镝铁氧体磁粒子磁性能的研究

采用湿化学法制备出稀土Dy3+掺杂的纳米Fe3O4磁粒子,用月桂酸进行了表面修饰,研究了磁粒子在室温和深冷(200.2～56.5 K)状态下的磁性能.经X射线衍射分析发现,适量的Dy3+掺杂不会改变纳米Fe3O4磁粒子的晶型结构.透射电镜(TEM)照片表明,制备出的纳米磁粒子成球性好,且大部分磁粒子的粒径在14 nm左右.通过磁性测量仪、振动样品磁强计(VSM)对磁性能进行了表征.磁化曲线表明掺杂引起磁性能发生变化,磁粒子室温下无剩磁和矫顽力,具有超顺磁性;深冷状态下出现剩磁和矫顽力,且随温度的降低,剩磁和矫顽力增大,不具有超顺磁性,饱和磁化强度略高于室温值.     

磁性铁氧化物纳米粒子表面功能化及其应用

表面功能化的磁性铁氧化物纳米粒子是一种新型功能材料,可应用于各种生物活性物质如蛋白质、DNA等的富集和分离,药物的磁靶向,以及疾病的诊断和治疗等许多领域.本文在总结近年来国内外有关功能化磁性铁氧化物纳米粒子研究成果的基础上,阐述了功能化磁性铁氧化物纳米粒子的结构类型、特点、目前的各种功能化制备方法以及相关应用最新研究进展,指出了当前研究中的主要发展方向和仍需要解决的问题.     

水滑石型磁性纳米载药粒子的制备及其体外药物释放性能研究

通过调变镁铁尖晶石的含量, 采用一步共沉淀法制备了一系列具有核壳结构的水滑石型磁性纳米载药粒子, 对其微结构、热稳定性、磁性和药物释放性能进行了系统的研究. 结果表明这种磁性纳米载药粒子是一种具有以镁铁尖晶石为核层、双氯酚酸(Diclofenac, DIC)插层水滑石(DIC-LDH)为壳层的复合纳米粒子, 粒径在90～180 nm之间. 其中壳层DIC-LDH的晶粒尺寸D₁₁₀和层板电荷密度随磁核含量的增大而逐渐减小. 磁性纳米载药粒子的载药量随磁核含量的增大而逐渐减小, 而其比饱和磁化强度则随着磁核含量的增大逐渐增大. 体外释放实验表明, 无外加磁场时, 磁核含量增大, 壳层DIC-LDH粒径减小, 磁性纳米载药粒子药物释放速率逐渐增大|外加1500 G磁场时, 磁核含量增大, 磁致团聚程度增大, 其药物释放速率逐渐减小.     

银/聚合物纳米复合材料

银/聚合物纳米复合材料是一种典型的聚合物基复合材料, 其结构和性能依赖于合成方法,因此开发材料的优异性能必须以深入研究纳米材料的先进合成技术为前提。本文综述了纳米银粒子及其与聚合物形成的纳米复合材料的最新合成进展, 重点介绍了基于液相化学还原方法合成纳米银粒子的新方法, 如溶胶-凝胶法、沉淀法、微乳液法和离子液体法, 以及纳米银粒子的分散技术和原位法合成银/聚合物纳米复合材料的新技术, 并介绍了纳米银复合材料的电绝缘性、表面增强拉曼散射性能、抗菌性及其在生物医学等领域中的应用。     

Fe3O4纳米材料的低温溶剂控制合成及其磁性质

报道了一种低温（60℃～100℃）溶剂控制合成立方相Fe3O4及正交相FeOOH等纳米材料的简易方法,即采用氯化亚铁为铁源,六亚甲基四胺为弱碱源,借助回流装置,通过改变反应温度、溶剂（分别以水、水与乙醇、水与乙二醇为溶剂）、时间等实验条件,合成出正交相的FeOOH、正交相FeOOH与立方相Fe3O4的混合物以及立方相Fe3O4磁性纳米粒子.利用X射线衍射仪（XRD）、透射电子显微镜（TEM）、物性磁测量系统以及穆斯堡尔光谱仪对产物进行了表征和分析.结果显示,所制备的混合相磁性纳米粒子为片状和棒状,而立方相的的Fe3O4磁性纳米粒子呈颗粒状.磁测量表明立方相的Fe3O4比混合相磁性纳米粒子有更大的磁饱和强度,对立方相的Fe3O4纳米粒子进行穆斯堡尔谱分析可以明确判断所合成的样品是Fe3O4,而不是γ-Fe2O3.此外,通过对实验过程、现象及表征结果等的分析;对不同条件下Fe3O4磁性纳米粒子的形成机理做了初步探讨.     

Fe3O4表面原位引发可控/“活性”聚合制备磁性聚苯乙烯纳米粒子

采用化学共沉淀方法合成了Fe3O4纳米粒子, 用3-甲基丙烯酰氧基丙基三甲氧基硅烷(3-MPS)对其进行表面接枝修饰, 然后以苯乙烯(St)为单体, 过氧化苯甲酰(BPO)为引发剂, 4-羟基-2,2,6,6-四甲基哌啶-1-氧化物自由基(HTEMPO·)为稳定自由基介质, 采用可控/“活性”自由基聚合技术在修饰后的Fe3O4纳米粒子表面原位引发聚合, 制备了粒径小、分布窄、磁含量高的磁性聚苯乙烯（PS）纳米粒子. X射线衍射(XRD)研究表明, 所合成的Fe3O4粒子为尖晶石结构. 凝胶渗透色谱(GPC)分析表明, 聚苯乙烯的分子量与反应时间呈较好的线性关系. 透射电镜(TEM)观察表明, 所制备的磁性聚苯乙烯纳米粒子的粒径在20-30 nm之间. 热重(TG)分析得到磁性聚苯乙烯纳米粒子的磁含量为62.6%. 振动样品磁强计(VSM)测试结果表明, 磁性聚苯乙烯纳米粒子的比饱和磁化强度为31.7 emu·g-1, 呈现单磁畴结构.     

高性能、多功能化的磁性水凝胶材料的研究进展

以磁性纳米粒子为关键构件的磁性纳米复合水凝胶,拥有优良的机械性能、较好的生物相容性和丰富的磁性,因此在核磁成像、环境治理、热疗以及促进干细胞分化上有着显著的效果。基于目前的研究概况,本文简要介绍了纳米复合水凝胶的理化性质以及作为关键构件的磁性纳米粒子的特性以及制备方法,同时重点阐述了磁性水凝胶在应用及其设计策略方面的研究进展,并从应用角度出发提出了未来将会面临的挑战以及其发展趋势。     

过渡金属掺杂磁性纳米粒子在生物医学领域中的研究进展

在过去50多年中,磁性纳米粒子(MNPs)由于其可协调的磁性、非侵入性、易操控性和良好的生物相容性等优点得到了广泛的关注.从具有复合结构或不同形状的MNPs的合成方法到与MNPs相关的大量表征技术,其应用领域也与我们的生活紧密相关.然而,MNPs的复杂磁行为受到多种参量的影响,包括粒径、成分、形状和结构等.基于此,通过...     

Magnetofection: Magic magnetic nanoparticles for efficient gene delivery

Magnetic nanoparticles (MNPs) have become a research hotspot and widely used in the biomedical field in recent decades due to their unique magnetic properties. This minireview summarizes the specific gene transfection of magnetic particles (magnetofection) during eversy dynamic process of gene delivery (gene binding, cellular uptake, endosomal escape, intracellular trafficking and in vivo targeting). Meanwhile, the synergistic biomedical application of magnetofection and the effects of MNPs have also been discussed, including magnetic resonance imaging (MRI), magnetic mediated hyperthermia (MMH), Fenton reaction and autophagy. Finally, the clinical prospect of magnetofection was briefly expected.     

Magnetofection: Magic magnetic nanoparticles for efficient gene delivery

Magnetic nanoparticles (MNPs) have become a research hotspot and widely used in the biomedical field in recent decades due to their unique magnetic properties. This minireview summarizes the specific gene transfection of magnetic particles (magnetofection) during eversy dynamic process of gene delivery (gene binding, cellular uptake, endosomal escape, intracellular trafficking and in vivo targeting). Meanwhile, the synergistic biomedical application of magnetofection and the effects of MNPs have also been discussed, including magnetic resonance imaging (MRI), magnetic mediated hyperthermia (MMH), Fenton reaction and autophagy. Finally, the clinical prospect of magnetofection was briefly expected.     

Ultrasensitive detection and molecular imaging with magnetic nanoparticles

Recent advances in nanotechnology have produced a variety of nanoparticles ranging from semiconductor quantum dots (QDs), magnetic nanoparticles (MNPs), metallic nanoparticles, to polymeric nanoparticles. Their unique electronic, magnetic, and optical properties have enabled a broad spectrum of biomedical applications such as ultrasensitive detection, medical imaging, and specific therapeutics. MNPs made from iron oxide, in particular, have attracted extensive interest and have already been used in clinical studies owing to their capability of deep-tissue imaging, non-immunogenesis, and low toxicity. In this Research Highlight article, we attempt to highlight the recent breakthroughs in MNP synthesis based on a non-hydrolytic approach, nanoparticle (NP) surface engineering, their unique structural and magnetic properties, and current applications in ultrasensitive detection and imaging with a special focus on innovative bioassays. We will also discuss our perspectives on future research directions.     

功能化磁性纳米粒子在乳状液制备及破乳中的应用及作用机制

功能化磁性纳米粒子因其独特的理化性质,在乳状液制备与破乳领域的应用受到广泛关注。本文归纳了功能化磁性纳米粒子的制备方法、合成结构与特征性质,阐述了其在乳状液制备及破乳中的应用过程,重点分析了磁性纳米粒子在溶液中良好分散、稳定吸附于油水界面排布为膜结构的作用行为,尤其是磁性纳米粒子的磁响应特征对乳状液中界面性质、液滴形貌及运动状态的影响,并进一步总结出其表面性质及作用行为对稳定乳状液或使乳状液破乳的规律。针对磁性纳米粒子对乳状液稳定性影响规律的探究可为其在应用领域提供理论支持。最后本文就功能化磁性纳米粒子研究中亟待解决的新问题作出展望。     

Magnetic nanosensor particles in luminescence upconversion capability

Nanoparticles (NPs) exhibit interesting size-dependent electrical, optical, magnetic, and chemical properties that cannot be observed in their bulk counterparts. The synthesis of NPs (i.e., crystalline particles ranging in size from 1 to 100 nm) has been intensely studied in the past decades. Magnetic nanoparticles (MNPs) form a particularly attractive class of NPs and have found numerous applications such as in magnetic resonance imaging to visualize cancer, cardiovascular, neurological and other diseases. Other uses include drug targeting, tissue imaging, magnetic immobilization, hyperthermia, and magnetic resonance imaging. MNPs, due to their magnetic properties, can be easily separated from (often complex) matrices and manipulated by applying external magnetic field. Near-infrared to visible upconversion luminescent nanoparticles (UCLNPs) form another type of unusual nanoparticles. They are capable of emitting visible light upon NIR light excitation. Lanthanide-doped (Yb, Er) hexagonal NaYF? UCLNPs are the most efficient upconversion phosphors known up to now. The use of UCLNPs for in vitro imaging of cancer cells and in vivo imaging in tissues has been demonstrated. UCLNPs show great potential as a new class of luminophores for biological, biomedical, and sensor applications. We are reporting here on our first results on the combination of MNP and UCLNP technology within an ongoing project supported by the DFG and the FWF (Austria).     

高性能磁性纳米粒子的有机相制备与生物应用的研究进展

磁性纳米粒子(MNPs)的合成开发在基础科学研究和技术应用方面得到了深入的发展。与大块的磁性材料不同,MNPs展现出了独特的磁性,并且可以通过系统的纳米尺寸工程调控它们的性能。本文首先简要介绍了MNPs的基本特征,总结了不同MNPs的制备方法,包括金属、合金、金属氧化物和多功能的MNPs;重点关注了可精确控制MNPs尺寸、形状、组成和结构的有机相合成方法;最后讨论了这些MNPs在生物方面的应用。     

Chemical design of nanoparticle probes for high-performance magnetic resonance imaging

Synthetic magnetic nanoparticles (MNPs) are emerging as versatile probes in biomedical applications, especially in the area of magnetic resonance imaging (MRI). Their size, which is comparable to biological functional units, and their unique magnetic properties allow their utilization as molecular imaging probes. Herein, we present an overview of recent breakthroughs in the development of new synthetic MNP probes with which the sensitive and target-specific observation of biological events at the molecular and cellular levels is possible.     

Separation/Concentration‐signal‐amplification in‐One Method Based on Electrochemical Conversion of Magnetic Nanoparticles for Electrochemical Biosensing

We propose a separation/concentration‐signal‐amplification in‐one method based on electrochemical conversion (ECC) of magnetic nanoparticles (MNPs) to develop a facile and sensitive electrochemical biosensor for chloramphenicol (CAP) detection. Briefly, aptamer‐modified magnetic nanoparticles (MNPs‐Apt) was designed to capture CAP in sample, then the MNPs‐Apt composite was conjugated to Au electrode through the DNA hybridization between the unoccupied aptamer and a strand of complementary DNA. The ECC method was applied to transfer MNPs labels to electrochemically active Prussian blue (PB). The anodic and cathodic currents of PB were taken for signal readout. Comparing with conventional methods that require electrochemically active labels and related sophisticated labelling procedures, this method explored and integrated the magnetic and electrochemical properties of MNPs into one system, in turn realized magnetic capturing of CAP and signal generation without any additional conventional labels. Taking advantages of the high abundance of iron content in MNPs and the refreshing effect deriving from ECC process, the method significantly promoted the signal amplification. Therefore, the proposed biosensors exhibited linear detection range from 1 to 1000 ng mL⁻¹ and a limit of detection down to 1 ng mL⁻¹, which was better than or comparable with those of most analogues, as well as satisfactory specificity, storage stability and feasibility for real samples. The developed method may lead to new concept for rapid and facile biosensing in food safety, clinic diagnose/therapy and environmental monitoring fields.     

多功能磁性纳米粒的合成、修饰及生物医学应用

多功能磁性纳米粒由于其独特的性质而受到广泛的关注。磁性纳米粒可以与荧光探针、生物靶向分子或抗肿瘤药物等相结合实现磁性纳米粒的多功能化,因此在多模式成像、癌症的靶向诊断与治疗中有较好的应用前景。本文介绍了磁性纳米粒的合成以及多功能磁性纳米粒的构建方法,重点介绍了核壳型、哑铃型和组合杂化型三种不同类型多功能磁性纳米粒的合成方法。多功能磁性纳米粒通常具有粒径小、超顺磁性以及荧光等独特性质,在此基础上对纳米粒表面进行稳定化和靶向性修饰后即可在多模式成像、特异性靶向药物输送、基因转染等生物医学领域得到应用。最后指出了当前研究中需要解决的问题。