聚电解质包覆的铕(Ⅲ)配合物@SiO2荧光纳米粒的合成与性质

以二苯甲酰甲烷(DBM)、邻菲罗琳(phen)和丙烯酸(AA)为配体,制备了铕的配合物Eu(Ⅲ)(DBM)2-(phen)(AA).利用St(o)ber法合成了SiO2纳米粒.通过超声辅助,将脂溶性的强荧光铕配合物吸附到SiO2纳米粒上,再包覆阳离子聚电解质聚二烯丙基二甲基氯化铵(PDAC)和阴离子聚电解质聚丙烯酸(P...     

丹酰氯SiO2纳米发光标记物的制备

通过合成丹酰氯的荧光单体硅酯前驱物,采用油包水的反相微乳液法,以丹酰氯的荧光单体硅酯前驱物为核材料,成功地制备了丹酰氯的荧光纳米颗粒,克服了传统方法制备核壳荧光纳米颗粒中存在的荧光染料泄漏问题.通过透射电子显微镜表征该纳米粒子呈球形,大小均匀,直径为40nm左右.所制得纳米颗粒荧光性质稳定,受外界环境的影响小,且潜在生物亲和性,是一种新型的荧光标记物.     

SiO2包覆共轭聚合物CN-PPV纳米探针的制备与荧光性质

采用纳米沉淀法制备了半导体聚合物CN-PPV纳米粒子,并用改进的Stber方法对纳米粒子进行包覆,获得了发光稳定的SiO2/CN-PPV纳米粒子。用动态光散射(DLS)及透射电镜(TEM)方法对粒子尺寸进行了表征,结果表明包覆前的CN-PPV纳米粒子平均粒径约为30 nm,包覆获得SiO2/CN-PPV纳米粒子的平均粒径约为60 nm。通过紫外-可见吸收光谱及荧光光谱对包覆前后纳米粒子的发光性质进行了比较,发现共轭聚合物CN-PPV包覆后的发射光谱与包覆前相比发生了小的蓝移,表明共轭聚合物的分子构型可能发生了微小变化。SiO2包覆可以提高聚合物发光分子的光稳定性,并且提供用于生物分子耦联的表面,这类材料有望在生物医学成像中获得应用。     

Functionalized Ultrabright Fluorescent Mesoporous Silica Nanoparticles

The problem of functionalization of recently reported ultrabright fluorescent mesoporous silica nanoparticles while preserving their fluorescent brightness is solved. This is a serious issue because of the open geometry of mesoporous channels and physical encapsulation of fluorescent dye inside those channels. Amine modification of mesoporous nanoparticles is described to preserve the brightness comparable to that of earlier reported ultrabright silica nanoparticles. Scaling to 40 nm sized particles, amine‐functionalized nanoparticle have fluorescent brightness equivalent to the one of 630 free rhodamine 6G (R6G) dye molecules in water. To demonstrate further most challenging functionalization, which relies on using organic‐solvent‐based chemistry, folic acid conjugation is developed. Two different methods are used to conjugate folites to the amine functionalities. Both methods result in a decrease of fluorescence intensity, which can nonetheless still be called ultrabright. The brightness can drop to either 310 or 80 R6G dye molecules per particle of nominal diameter of 40 nm.     

Engineering the Internal Structure of Magnetic Silica Nanoparticles by Thermal Control

Calcination of hydrated iron salts in the pores of both spherical and rod‐shaped mesoporous silica nanoparticles (NPs) changes the internal structure from an ordered 2D hexagonal structure into a smaller number of large voids in the particles with sizes ranging from large hollow cores down to ten nanometer voids. The voids only form when the heating rate is rapid at a rate of 30 °C min^?1. The sizes of the voids are controlled reproducibly by the final calcination temperature; as the temperature is decreased the number of voids decreases as their size increases. The phase of the iron oxide NPs is α‐Fe₂O₃ when annealed at 500 °C, and Fe₃O₄ when annealed at lower temperatures. The water molecules in the hydrated iron (III) chloride precursor salts appear to play important roles by hydrolyzing Si? O? Si bonding, and the resulting silanol is mobile enough to affect the reconstruction into the framed hollow structures at high temperature. Along with hexahydrates, trivalent Fe³⁺ ions are assumed to contribute to the structure disruption of mesoporous silica by replacing tetrahedral Si⁴⁺ ions and making Fe? O? Si bonding. Volume fraction tomography images generated from transmission electron microscopy (TEM) images enable precise visualization of the structures. These results provide a controllable method of engineering the internal shapes in silica matrices containing superparamagnetic NPs.     

荧光性胱氨酸聚集纳米团簇的制备及其应用研究

基于碱性胱氨酸水溶液在恒温水浴条件下可形成荧光性分子聚集体的特性,发展一种荧光光谱直接检测胱氨酸含量的新方法。实验结果表明,将pH 9.0的0.01 mol·L-1的胱氨酸溶液,于90 ℃恒温水浴热处理12 h后,胱氨酸分子可形成大小为12.5nm粒径的荧光分子聚集纳米团簇（FANC）结构,并发射蓝绿色荧光。采用荧光光谱（FL）、透射扫描电镜（TEM）和质谱（MS）对FANC的荧光性能和结构进行表征,并初步探讨光致发光机理。FANC在410 nm最佳激发波长条件下,于508 nm处具有最佳的荧光发射信号,体系的平均荧光寿命为6.028 ns,荧光量子产率为8.48%。FANC在水溶液中具有稳定的光漂白性、酸碱稳定性和光谱不依赖性质,粒子的Zeta电位为-57 mV,结合150 nm的水合粒径结果,表明形成的团簇表面亲水且带负电荷。质谱结果显示体系中存在多种胱氨酸分子间脱水形成的分子碎片,因此推测FANC是胱氨酸分子在水溶液环境中因分子间作用力形成分子聚集体。基于FANC的荧光强度和原料胱氨酸的浓度在1.0×10-5～6.0×10-4 mol·L-1范围内呈良好的线性关系,可将该方法用于胱氨酸片中含量的测定,结果与中国药典中记载的滴定比色法相吻合。相比于其他检测方法,该方法具有操作简便,检测限低,精确度高等优点。     

Cytotoxicity and Cellular Uptake of Amorphous Silica Nanoparticles in Human Cancer Cells

The cytotoxic effects of silica nanoparticles (SNPs) on different human cancer cells, as well as the uptake kinetics and pathways of SNPs have been studied here. SNPs with the diameter of ≈20 nm induced a dose‐dependent cytotoxicity in both gastric cancer cells (MGC80–3) and cervical adenocarcinoma epithelial cells (HeLa), but MGC80–3 cells were more susceptible to the cytotoxic effect induced by SNPs. Changes in the nuclear morphology and flow cytometric analysis with annexin V/PI double staining show that SNPs induced a higher degree of apoptosis in MGC80–3 cells. Accordingly, more remarkable reactive oxygen species (ROS) burst is detected in SNP‐treated MGC80–3 cells. Using fluorescein isothiocyanate (FITC)‐labeled SNPs and flow cytometry, it is found that the uptake of SNPs is more efficient in MGC80–3 than in HeLa cells. SNPs are internalized into both cancer cells through energy‐dependent pathway. Inhibitor studies with dynasore and methyl‐β‐cyclodextrin show that these cancer cells took up 20 nm SNPs mainly through the caveolin‐mediated endocytosis, while in HeLa cells SNPs internalization was also via dynamin‐dependent clathrin‐mediated pathway. These findings indicate that SNPs cause differential cytotoxic effects in different human cancer cells, which might be related to the uptake process and efficiency toward these cancer cells.     

Reciprocal Response of Human Oral Epithelial Cells to Internalized Silica Nanoparticles

Silica nanoparticles (SiO₂ NPs) are one of the most widely used engineered nanoparticles and can been found in a wide range of consumer products. Despite their massive global production scale, little is known about their potential effects in the context of unintended exposure or ingestion. Using TR146 cells as an in vitro model of the human oral buccal mucosa, the uptake, spatial intracellular distribution, reactive oxygen species (ROS) production, inflammatory response, and cytotoxic effects of commercial SiO₂ NPs are examined. SiO₂ NPs are shown to dock and cross the cellular membrane barrier in a dose–time‐dependent manner. Confocal sectioning reveals translocation of SiO₂ NPs into the cell nucleus after 12 h of exposure. A concentration threshold of more than 500 × 10^?6 m is observed, above which SiO₂ NPs are shown to exert significant oxidative stress with concomitant upregulation of inflammatory genes IL6 and TNFA. Further analysis of the p53 pathway and a series of apoptotic and cell cycle biomarkers reveals intracellular accumulation of SiO₂ NPs exert marginal nanotoxicity. Collectively, this study provides important information regarding the uptake, intracellular distribution, and potential adverse cellular effects of SiO₂ NPs commonly found in consumer products in the human oral epithelium.     

Optical Properties of Ag and Au Nanoparticles Dispersed within the Pores of Monolithic Mesoporous Silica

The optical absorption of silver and gold nanoparticles dispersed within the pores of monolithic mesoporous silica upon annealing at elevated temperatures has been investigated. With decreasing particle size, the surface plasmon resonance position of the particles blue-shifts first and then red-shifts for silver/silica samples, but only red-shifts for gold/silica samples. This size evolution of the resonance position is completely different from that previously reported for fully embedded particles. We assume a local porosity at the particle/matrix interface, such that free surface of particles within the pores may be in contact with ambient air, and present a two-layer core/shell model to calculate the optical properties. These calculations also consider deviations from the optical constants of bulk matter to account for corresponding effects below about 10 nm particle size. From the good agreement between experimental results and model calculations, we conclude a peculiar particle/ambience interaction dominating the size evolution of the resonance. Because of the difference of core electron structure, the relative importance of the effects of local porosity and free surface, respectively, are different for silver and gold. For silver, the effect of the local porosity is stronger, but for gold the opposite is found.     

新型高分子蓝色荧光材料的制备及性能

以吡唑啉为发光功能基团,设计并合成了4种新的聚酰胺类高分子化合物,采用核磁共振氢谱(H 1NMR)和凝胶色谱(GPC)对其结构进行了确证。进而测定了高分子化合物的液体及固体荧光激发、发射光谱,高分子J1,J2和J3具有良好的液体及固体荧光发光能力。所制备的高分子材料具有良好的成膜能力、成本低廉、热稳定性好,有望在电致发光器件中广泛应用。     

The Internalization,Distribution, and Ultrastructure Damage of Silica Nanoparticles in Human Hepatic L‐02 Cells

Nowadays, due to the wide use of amorphous silica nanoparticles (SiNPs), their adverse effects on human beings are attracting more attention. Understanding the interaction between SiNPs and cells is a fundamental step for toxicity assessment. Therefore, the current study is aimed at elaborating the internalization process, subcellular distribution, ultrastructure damage, and cytotoxicity of two different sizes of SiNPs (Nano‐Si64 and Nano‐Si46) in L‐02 cells. The results indicate that the smaller‐sized SiNPs, Nano‐Si46, accumulate in cells more efficiently and produce a stronger cytotoxic effect than Nano‐Si64. Both types of nanoparticles can accumulate in L‐02 cells through the active endocytotic pathway and passive diffusion, and distribute within endocytotic vesicles or freely in cytoplasma and organelles. Microvillus fracture, membrane injury, mitochondria damage, degranulation of the rough endoplasmic reticulum, lamellar‐like structure, lysosome destruction, autophagosomes, and autophagy‐lysosomes are found in L‐02 cells. Oxidative damage and direct interaction between SiNPs and subcellular structure are responsible for the toxicity.     

掺杂香豆素6的杂化纳米颗粒的制备及荧光性能研究(英文)

采用一种再沉淀-封装法制备了掺杂香豆素6(C6)的杂化荧光纳米颗粒,并通过SEM和DLS对其进行了形貌和粒径大小表征。在450 nm光激发下,制备的C6掺杂纳米颗粒表现出绿色荧光。通过比较光致发光光谱随掺杂浓度的变化,得出C6掺杂纳米颗粒的浓度猝灭是因为分子间能量转移而非C6分子聚集所致。另外,由于所选聚合物基质材料PS和PMMA分子结构的区别,导致PS-基质和PMMA-基质的纳米颗粒的光谱形状不同。C 6分子在PS-基质的纳米颗粒中处于两种不同的微环境,所以发射峰较宽;PMMA是线性分子,PMMA-基质的纳米颗粒中只存在一种局域环境,所以发射峰较窄。高的掺杂浓度会超过纳米颗粒对C6分子的负载能力,从而导致C6分子在水溶液中聚集。     

Coassembled Nanoparticles Composed of Functionalized Mesoporous Silica and Pillar[5]arene-Appended Gold Nanoparticles as Mitochondrial-Selective Dual-Drug Carriers

Coassembled nanoparticles composed of functionalized mesoporous silica and pillar[5]arene-appended Au nanoparticles obtained through the formation of a host–guest complex are designed and synthesized as a mitochondrial-selective dual-drug delivery system. A pyridinium-based ligand and fluorescein isothiocyanate are immobilized onto mesoporous silica to act as the mitochondria-targeting ligand and fluorescence tracker, respectively, of a material dubbed NP-3. Carboxylated pillar[5]arene-capped Au nanoparticles (CP-AuNPs) are fabricated by the templated reduction of Au³⁺. Interestingly, coassembled nanoparticles (NP-1) composed of doxorubicin (DOX) loaded NP-3 and CP-AuNPs are then prepared via the formation of a host–guest complex between the pyridinium-based ligand of NP-3 and the pillar[5]arene of CP-AuNPs. To demonstrate the effectiveness of NP-2 and NP-1 as mitochondrial targeting drug delivery systems, DOX and F16 are employed as model drugs. These drugs loaded onto NP-2 and CP-AuNPs, respectively, are selectively delivered to mitochondria, indicating the usefulness of NP-2 and CP-AuNPs as mitochondrial-specific drug-delivery carriers in cancer cells. More interestingly, the use of NP-1 is also associated with the selective accumulation of DOX and F16 in mitochondria. The selective mitochondrial-targeting of NP-1 is possible by NP-2 and F16 exposed to the cytoplasm, allowing the codelivery of the two drugs to the mitochondria.     

A New Fluorescent Probe, ABM: Properties and Application in Clinical Diagnostics

Properties of benzanthrone aminoderivative ABM (conditional name) as a potential fluorescent probe were investigated. Spectral characteristics of the compound in different solvents as well as their binding to model lipid membranes (liposomes) and human peripheral blood mononuclear cells (lymphocytes; ly) were determined. The fluorescence was found to be sensitive polarity changes to the environment. Distinctions were observed in the spectral characteristics of the investigated compound when bounded to liposomes. It was established that spectral characteristics of ABM in cell suspension qualitatively characterize the structural and functional alterations of ly during pathological phenomena and correlate directly with the clinical view of disease. The ABM is shown to be a perspective in the screening for various pathologies.     

Preparation,Characterization and Application of Fluorescent Terbium Complex-Doped Zirconia Nanoparticles

Novel zirconia-based fluorescent terbium nanoparticles have been prepared as a fluorescent nanoprobe for time-resolved fluorescence bioassay. The nanoparticles were prepared in a water-in-oil (W/O) microemulsion consisting of a strongly fluorescent Tb³⁺ complex, N,N,N¹, N¹-[2,6-bis(3′-aminomethyl-1′-pyrazolyl)-phenylpyridine]tetrakis(acetate)-Tb³⁺(BPTA-Tb³⁺), Triton X-100, hexanol, and cyclohexane by controlling co-condensation of Zr(OCH₂CH₃)₄ and ZrOCl_2. The characterizations by transmission electron microscopy and fluorometric methods indicate that the nanoparticles are uniform in size, 33± 4 nm in diameter, and have a fluorescence quantum yield of 8.9% and a long fluorescence lifetime of 2.0 ms. The zirconia-based fluorescent terbium nanoparticles show high stability against basic dissolution in a high pH aqueous buffer compared to the silica-based nanoparticles. A surface modification and bioconjugation method for the fluorescent nanoparticles was developed, and the nanoparticle-conjugated streptavidin (SA) was used for time-resolved floroimmunoassy (TR-FIA) of human prostate specific antigen (PSA). The result shows that the zirconia-based fluorescent terbium nanoparticles are useful as a fluorescent nanoprobe for time-resolved fluorescence bioassay.     

Multidisciplinary Role of Mesoporous Silica Nanoparticles in Brain Regeneration and Cancers: From Crossing the Blood–Brain Barrier to Treatment

Mesoporous silica nanoparticles (MSNs) have gained wide attention for their role in biomedicine and as drug delivery vehicles. Their structural tunability, high surface area, and easy functionalization impart significant advantages over conventional materials. In this Review, recent advances in the synthesis, drug delivery, and therapeutic roles of MSNs in the treatment of various neurodegenerative and neuroinflammatory diseases are presented. The intention is to understand how MSN formulations that are capable of encapsulating drug molecules can enhance drug delivery by overcoming the blood–brain barrier (BBB) mediated by specific transport processes. The composition and characteristics of the BBB, and how alterations are observed in neurodegenerative diseases including Alzheimer's, epilepsy, and intracerebral hemorrhage are reviewed. Finally, the factors affecting efficient delivery of MSNs into the brain are summarized, and their most promising functional outcomes are discussed.     

电化学刻蚀制备的荧光碳纳米颗粒

以纯石墨作电极、乙二胺四乙酸二钠溶液作电解液制备了具有荧光性质的碳纳米颗粒。利用紫外-可见分光光度计和荧光分光光度计分析了碳纳米颗粒的光吸收和荧光发射特征,利用透射电镜和电子能谱分析了碳纳米颗粒的尺寸、晶体状态和成分。结果表明,碳纳米颗粒仅有几纳米,呈分散状态;在325 nm附近具有强的光吸收并表现出强的蓝光发射特征。研究了电解质溶液的种类、浓度等对碳纳米颗粒荧光发射的影响,讨论了碳纳米颗粒的荧光发射机理。