Zn/Al/Tyr摩尔比对Tyr/Zn-Al-LDH纳米复合物的影响

The intercalation of amphoteric amino acid tyrosine （Tyr） into LDH by co-precipitation method was systematically studied. The influence of initial molar ratios （R） of LDH to Tyr has also been examined. Powder X-ray diffraction, Fourier transform infrared spectroscopy, specific surface areas and pore size distributions, and thermal analysis have been employed for the characterization of the nanocomposites. The nanohybrids were found to have an expanded layered structure except the samples prepared with low R values, indicating that the biomolecules were intercalated into the gallery as anions. The intercalation of amino acids resulted in the increase of the surface areas and pore volumes, and the value of surface areas and pore volumes increased with enhancement of biomolecules intercalated. TEM analysis revealed that with increasing biomolecules into the gallery, the nanohybrids were changed from hexagonal particles to spherical ones. Moreover, the configuration of Tyr anions was varied under different R values, changed from monolayer to bilayers with more biomolecules intercalating into the gallery.     

The dynamic process in the formation of Tyr/LDH nanohybrids

The dynamic intercalation process of tyrosine (Tyr) into layered double hydroxide (LDHs) by co-precipitation method was investigated by powder X-ray diffractometry, Fourier transform infrared spectroscopy, specific surface area measurements, pore size distributions as well as thermal analysis. The nanohybrids were found to have an expanded layered structure indicating that amino acid anions were intercalated into the gallery space. Two kinds of arrangements such as mono- or bilayers of the tyrosinate anions could be deduced from the XRD patterns. The arrangement changed from monolayer to bilayer, then again to monolayer with increasing aging time of the synthesis solution. The diffraction intensity increased then decreased with aging time, because of the variation in the orientation and ordering of the particles. TG analysis and the varying M²⁺/M³⁺ results revealed that the amount of tyrosinate anions in the gallery first decreased then increased with the increase of aging time. In addition, the morphology results showed that the degree of ordering also increased then decreased with aging time. On all accounts, the intercalation of the tyrosinate anions was a typical dynamic process. At the beginning numerous biomolecules entered the gallery space, giving rise to increased basal spacings and BET surface areas. Later the increase of aging time led to the escape of amino acid anions from the gallery space, hence to the decrease of basal spacing and surface areas.     

氟尿苷-层状双金属氢氧化物纳米杂化物制备及表征

采用共沉淀法将抗癌药物氟尿苷插入Mg-Al层状双金属氢氧化物(LDHs)的层间,合成了氟尿苷-LDHs纳米杂化物。依据氟尿苷分子大小和杂化物通道高度推测,氟尿苷分子是以长轴垂直或略倾斜于LDHs层片在LDHs层间呈双层排列。分别在pH=4.8和7.2的介质中研究了药物释放动力学,表明符合准二级动力学方程;释放速率随载药量增大而降低;氟尿苷-LDHs纳米杂化物具有良好的缓释效果。     

合成温度对Tyr/LDH纳米复合物性质的影响

研究了合成温度对Tyr(酪氨酸)/LDH(层状双氢氧化物)纳米复合物性质的影响. 结果表明: 随着合成温度的升高, 纳米复合材料的层间距和比表面积逐渐降低; 随着温度的升高, 合成粒子的形状由球形到三角形最后变为无定形. 进一步的研究表明, 这些规律性的变化与插入层间的生物分子数量有关.     

喜树碱插层的镁铝型层状双金属氢氧化物的合成及表征

采用共沉淀法把抗癌药物喜树碱（Camptothecin, CPT）插入层状双金属氢氧化物(layered double hydroxide, LDH)层间, 合成了CPT-LDH纳米杂化物。结果表明,在CPT-LDH纳米杂化物中,CPT在层间的排布方式有两种,即平行于层板的单层排列和垂直于层板的双层排列;缓释研究表明,CPT-LDH在pH 7.5的磷酸缓冲液中具有明显的缓释效果,其释放速率较相同pH值时CPT和LDH物理混合物的释放速率明显降低;考察了CPT-LDH的药物释放机理,在 pH 7.5的缓冲溶液中,释放过程受粒内扩散过程控制;CPT-LDH纳米杂化物的释放动力学符合准一级动力学过程。     

大黄素/Mg-Al-LDHs纳米杂化物的制备及缓释性能研究

以Mg-Al型层状双金属氢氧化物(Mg-Al-LDHs)为载体,将大黄素分子通过二次组装法成功插入其层间,得到大黄素/Mg-Al-LDHs纳米杂化物。XRD结果显示,Mg-Al-LDHs粒子层间距由0.48 nm增大到3.35 nm。差热曲线(DTA曲线)分析结果表明,该纳米杂化物分子中大黄素的分解温度比纯大黄素的分解温度高50℃。分别在pH 4.8和pH 7.5的缓冲溶液中测定了大黄素/LDHs的缓释性能,结果表明大黄素/LDHs的药品释放速率明显低于二者的物理混合物,并探讨了释放机理。     

Fabrication,controlled release,and kinetic studies of indomethacin—layered zinc hydroxide nanohybrid and its effect on the viability of HFFF2

The intercalation of indomethacin into the interlayer gallery of layered zinc hydroxide (LZH) has been successfully executed using the simple ion exchange approaches. The synthesized intercalation compound, indomethacin-LZH nanohybrid, was characterized using PXRD, FTIR, SEM, BET, and STA. From the PXRD results, the intercalation of indomethacin anions into the interlayer gallery of LZH was successful; showing the formation of a new peak at lower 2θ with a basal spacing of 21.96?Å. FTIR analysis of the nanohybrid further supported the presence of indomethacin in the interlayer of the indomethacin-LZH nanohybrid. STA analysis confirms that the nanohybrid has higher thermal stability than pure indomethacin. The in vitro release mechanism of the indomethacin anions from the indomethacin-LZH nanohybrid showed slow release, with 95% and 78% release in phosphate buffer saline (PBS) solution at pH 4.8 and 7.4, respectively. The release behavior of indomethacin from its intercalation compounds in PBS solution at pH 4.8 and 7.4 follows the Higuchi model. In addition, the nanohybrid treated with normal fibroblast cell line shows that it reduces cell viability in a dose and time-dependent manner. This study shows that the high potential of the nanohybrid as an encapsulated material for the controlled release formulation of nonsteroidal anti-inflammatory (NASID) anions.     

Synthesis and characterization of 10-hydroxycamptothecin – sebacate – layered double hydroxide nanocomposites

10-Hydroxycamptothecin (HCPT) as a hydrophobic anticancer drug brings many challenges in the clinical applications due to its poor water solubility and the presence of a chemically unstable lactone ring. In this work, the nanocomposites of HCPT intercalated layered double hydroxide (LDH) were prepared by a secondary intercalation method, and the encapsulated HCPT could keep the biologically active lactone form. A Zn–Al–NO₃ LDH was pillared with sebacate anions by a co-precipitation method in an aqueous medium, and then HCPT was intercalated into the LDH's gallery via hydrophobic interaction in an ethanol medium. The parallel alkyl chains of perpendicularly arranged sebacate anions in the LDH gallery provide a hydrophobic space for the drug intercalation. The in vitro release kinetics of HCPT from the nanocomposites could be fitted with the pseudo-second-order kinetic model, and the diffusion of HCPT through the LDH particles played an important role in controlling the drug release. The nanocomposites can be considered as a potential drug delivery system.     

利用有机改性的类水滑石缓释阿维菌素

采用蒸发溶剂促进插层(evaporating solvent enhanced intercalation)的方法把农药阿维菌素(Avermectin, AVM)插层到十二烷基硫酸钠(SDS)改性的类水滑石(Hydrotalcite-like compound, HTlc)层间，合成了AVM-SDS-HTlc纳米杂化物。研究发现其能够很好的控制阿维菌素的释放，表明AVM-SDS-HTlc纳米杂化物是一种很有潜力的农药控释剂型。AVM-SDS-HTlc纳米杂化物的释放受pH、温度和电解质的影响，酸性介质、较高温度以及有电解质存在会提高其缓释速率。释放过程符合准一级释放动力学，释放的活化能为279 kJ/mol。     

Synthesis and Characterization of Imidacloprid/Hydrotalcite-like Compound Nanohybrids

Hydrotalcite‐like compounds (HTlc) were first modified by sodium dodecyl sulfate (SDS), then the intercalation of imidacloprid (IM) into modified HTlc was carried out in mixed solvent of toluene/ethanol by an evaporating solvent enhanced intercalation method, obtaining IM‐SDS‐HTlc nanohybrids. It was found that the nanohybrids could well control the release of imidacloprid, demonstrating that the nanohybrids are a potential pesticide controlled‐release formulation. The release of imidacloprid from IM‐SDS‐HTlc nanohybrids is dependent on the pH and the presence of electrolyte in release medium. Acidic medium and the presence of electrolytes induce the higher release rate of imidacloprid. The release process of imidacloprid from IM‐SDS‐HTlc nanohybrids can be described by pseudo‐second‐order release kinetics.     

Benzocarbazole anions intercalated layered double hydroxide and its tunable fluorescence

Luminescent benzocarbazole anions (BCZC) intercalated into the interlayer region of Mg-Al-layered double hydroxides (BCZC/LDH) with different layered charge densities (LCD) were prepared. The structure and chemical composition of the composites were characterized by X-ray diffraction, elemental analysis, thermogravimetry and differential thermal analysis (TG-DTA), infrared spectra (FT-IR), UV-vis absorption and fluorescence spectroscopy. The photoemission behavior of BCZC in the LDH matrix with high (Mg/Al ratio = 1.801) and low (Mg/Al ratio = 3.132) LCD is similar to that of BCZC solid and aqueous solution states respectively, indicating that the luminescence performances of the intercalated dye anions can be tuned by adjusting the LCD of the LDH layer. Moreover, the thermal stability and stacking order of BCZC are largely improved upon intercalation, and the BCZC/LDH thin film exhibits well polarized luminescence with the luminescent anisotropy of 0.15-0.20. In addition, molecular dynamics (MD) simulation was employed to calculate the basal spacing and molecular arrangement of the intercalated BCZC within the LDH matrix. The simulation results show that the distribution of BCZC anions is much broader in the gallery of Mg-Al-LDH with high LCD, while BCZC anions exhibit a more ordered arrangement in LDH with low LCD. Furthermore, the radial distribution functions of interlayer water molecules were also studied. Based on the combination of experiment and theoretical simulation, this work provides a detailed understanding of the tunable photoluminescence, orientation and diffusion behavior of the luminescent molecules confined within the gallery of a 2D inorganic matrix.     

三氧化钼/苯胺层状复合材料的制备

以三氧化钼为无机主体, 用十二烷基胺对三氧化钼层间进行改性, 成功地制备了三氧化钼/苯胺层状复合材料. X射线衍射、元素分析、扫描电子显微镜、红外光谱测试及差热分析结果表明, 苯胺分子已成功地插入三氧化钼层间, 所得复合物化学式为[ANI]0.4MoO3. 插层后, 三氧化钼仍保持规则有序的层状结构, 其层间距扩大至1.318 nm. 讨论了无机主体与有机客体之间的相互作用、苯胺在层间的可能排布形式以及苯胺插入层间的反应机理.     

10-羟基喜树碱-癸二酸-LDH杂化物的制备及性能

采用二次插层法成功制备了10-羟基喜树碱(HCPT)-癸二酸(SC)插层的层状双金属氢氧化物(LDH). 先采用共沉淀法制备SC柱撑LDH杂化物(SC-LDH), 再在乙醇介质中将HCPT插入LDH层间形成HCPT-SC-LDH纳米杂化物. 依据SC和HCPT的分子尺寸和纳米杂化物的通道高度, 推测SC分子在层间可能为双层排列, SC分子两端的羧基同时键合在同一个LDH层片表面上; HCPT分子插入(或溶入)SC分子碳氢链形成的疏水区中. 所制备的纳米杂化物既可稳定HCPT的内酯环, 又可明显提高HCPT的溶解度, 还具有明显的药物缓释效果, 其释放动力学过程符合准二级动力学方程.     

剥离-共组装法制备葫芦素插层类水滑石纳米杂化物

采用剥离-共组装法制备了电中性疏水药物葫芦素(CA)插层类水滑石(HTlc)纳米杂化物. 先用胆酸钠(Ch)包覆修饰葫芦素, 再与剥离的HTlc薄片共组装, 形成CA-Ch-HTlc纳米杂化物. 采用小角X射线散射、 傅里叶变换红外吸收光谱、 透射和扫描电子显微镜、 Zeta电位和元素分析等技术对样品进行了表征. 所制备纳米杂化物的载药量达到7.06%, 表明该方法可以实现电中性疏水药物在HTlc上的有效负载. 依据胆酸离子和葫芦素尺寸及纳米杂化物通道高度推测, 胆酸离子在HTlc层间为双层排列, 其长轴几乎垂直于HTlc层板; 葫芦素分子插入(或“溶入”)胆酸离子双层中. CA-Ch-HTlc纳米杂化物具有良好的药物缓释效果, 其药物释放过程符合准二级动力学方程.     

Synthesis and characterization of 5-fluorocytosine intercalated Zn-Al layered double hydroxide

In this paper, the intercalation of 5-fluorocytosine (5-FC) into a layered inorganic host, Zn-Al layered double hydroxide (LDH), has been carried out using coprecipitation method to obtain 5-FC/LDH nanohybrids. The intercalated amount (A_In) of 5-FC into the LDH is remarkably dependent on the molar ratio (R_F/M) of 5-FC to metal ions and the pH of coprecipitation system. The morphology of 5-FC molecules in 5-FC/LDH nanohybrids is dependent on the A_In. It is interestingly found that the morphology of the nanohybrid particles may be changed with the increase of R_F/M from hexagonal plate particles to threadlike particles. The in vitro drug release from the nanohybrids is remarkably lower than that from the corresponding physical mixture and pristine 5-FC at either pH 4.8 or pH 7.5. In addition, the release rate of 5-FC from the nanohybrid at pH 7.5 is remarkably lower than that at pH 4.8, this is due to a possible difference in the release mechanism. The obtained results show these drug-inorganic nanohybrids can be used as a potential drug delivery system.     

Porous film fabricated by a thermoresponsive polymer poly(N-isopropylacrylamide-co-butylmethacrylate) with enhanced hydrophobicity

In this paper, two charge-neutral and poorly water-soluble bactericides (BC), hexaconazole and triadimenol, were first encapsulated in micelles derived from anionic surfactant, calcium dodecylbenzenesulfonate (DBS), and then were successfully intercalated into the gallery of Mg–Al layered double hydroxides (LDHs) by using ion exchange, coprecipitation and reconstruction methods, respectively, to obtain BC–LDHs nanohybrids. The loading amounts of hexaconazole-LDHs nanohybrids are obviously higher than those of triadimenol-LDHs nanohybrids. The release kinetics of bactericides from the nanohybrids was investigated. It was found that the bactericide release kinetic processes of the nanohybrids can be described with pseudo-second-order model. The initial release rates and equilibrium percent releases of the nanohybrids are obviously dependent of synthesis methods. The nanohybrids can well control the release of bactericides, showing they are a potential pesticide controlled-release formulation.     

氨基硅烷偶联剂对蒙脱石的修饰改性研究

研究了氨基硅烷偶联剂对蒙脱石的修饰改性,并和长链烷基硅烷偶联剂作对比.通过改性前后蒙脱石的傅立叶红外光谱(FT-IR),广角X射线衍射(WAXD),热失重分析(TGA)研究发现,在冰醋酸的处理下,氨基硅烷偶联剂不但能够对蒙脱石进行表面偶联修饰而且能够以插层剂的形式进入蒙脱石的层间.初步的浸润/分散性实验结果表明:氨基硅烷插层/表面修饰改性的蒙脱石在弱极性乙醇溶剂中的分散性能明显提高.     

New layered double hydroxides containing intercalated manganese oxide species: synthesis and characterization

Manganese oxide species (MnO(x)) have been intercalated within the gallery spaces of Mg-Al layered double hydroxides (LDHs). Synthesis of these materials was achieved by ion-exchange of the LDH-nitrate precursor with permanganate anion followed by reduction with organic reagents, such as glucose, ethanol, and ascorbic acid. Elemental analysis, X-ray diffraction, FT-IR spectroscopy, Raman spectroscopy, HR-TEM, and N(2) sorption analyses have been used to characterize these materials. TEM micrographs of LDH-MnO(x) materials revealed platelike morphology, characteristic of hydrotalcite-like compounds. Chemical analysis results showed that permanganate anions exchanged with nitrate anions. FT-IR and Raman spectroscopy confirmed the reduction of the permanganate anions after treatment with the organic reagents. The XRD diffraction patterns of LDH-MnO(x) revealed that the layer structure is maintained after all synthetic steps. The observed basal spacings of intercalates varied depending on the reducing agent; the largest expansion was 9.93A, corresponding to the use of ascorbic acid. The specific surface areas were also affected according to the organic reagent used, indicating that the structural modifications in the interlayer domain observed by X-ray diffraction also influence the microtextural properties.     

Synthesis and characterization of new Mg(2)Al-paratungstate layered double hydroxides

Layered double hydroxides (LDHs, or hydrotalcites) with Mg(2+) and Al(3+) cations in the mixed metal hydroxide layer and paratungstate anions in the interlayer have been prepared. Different methods have been followed: anion exchange with Mg,Al LDHs originally containing nitrate or adipate, reconstruction of the LDH structure from a mildly calcined Mg(2)Al-CO(3) LDH, and coprecipitation. In all cases, the tungsten precursor salt was (NH(4))(10)H(2)W(12)O(42). The prepared solids have been characterized by elemental chemical analysis, powder X-ray diffraction (PXRD), FT-IR spectroscopy, thermogravimetric (TG) and differential thermal (DTA) analyses, scanning electron microscopy (SEM) with EDX (energy-dispersive X-ray analysis), and nitrogen adsorption at -196 degrees C for surface area and surface texture. Most of the synthesis methods used, especially anion exchange starting from a Mg(2)Al-NO(3) precursor at low temperature and short reaction times, lead to formation of a hydrotalcite with a gallery height of 9.8 A; increasing the reaction temperature to 70-100 degrees C and maintaining short contact times leads to a solid with a gallery height of 7.8 A. Both phases have been identified as a result of the intercalation of W(7)O(24)(6)(-) species in different orientations in the interlayer space. If the time of synthesis or the temperature is increased, a more stable phase, with a gallery height of 5.2 A corresponding to a solid with intercalated W(7)O(24)(6)(-), is formed, probably with grafting of the interlayer anion on the brucite-like layers. All systems are microporous. Calcination at 300 degrees C leads to amorphous species, and crystallized MgWO(4) is observed at 700 degrees C.     

Intercalation behavior of amino acids into Zn-Al-layered double hydroxide by calcination-rehydration reaction

The intercalation of amino acids for the Zn-Al-layered double hydroxide (LDH) has been investigated by the calcination-rehydration reaction at 298 K using mainly phenylalanine (Phe) as a guest amino acid. The Zn-Al oxide precursor prepared by the calcination of Zn-Al-carbonated LDH at 773 K for 2 h was used as the host material. The amount of Phe intercalated by the rehydration was remarkably influenced by the initial solution pH and reached ca. 2.7 times for anion exchange capacity (AEC) of the LDH at neutral and weak alkaline solutions, suggesting that Phe was intercalated as amphoteric ion form into the LDH interlayer. As Phe is intercalated for the LDH as monovalent anion in alkaline solution, the amount of Phe intercalated at pH 10.5 corresponded with AEC of the LDH. The solid products were found to have the expanded LDH structure, which confirmed that Phe was intercalated into the LDH interlayer as amphoteric ion or anion form. The basal spacing, d₀₀₃, of the Phe/LDH was 1.58 nm at pH 7.0 and 0.80 nm at pH 10.5; two kinds of expansion suggested for Phe in the interlayer space as vertical (pH 7.0) and horizontal (pH 10.5) orientations. The intercalation behavior of various amino acids for the LDH was also found to be greatly influenced by the feature of the amino acid side-chain, namely, its carbon-chain length, structure and physicochemical property. In particular, α-amino acids possessing a hydrophobic or negative-charged side-chain were preferentially intercalated for the LDH.