Active uptake of drugs into photosensitive liposomes and rapid release on UV photolysis

Liposomes containing high concentrations of the anticancer drug doxorubicin, prepared by active-loading techniques, have been intensively investigated as potential agents for chemotherapy. The present study investigates the possibility of active uptake and photoinduced release of such solutes from liposomes incorporating a photoisomerizable lipid. The active loading of acridine orange and doxorubicin was investigated using liposomes containing entrapped ammonium sulfate. The liposomes were prepared with dipalmitoyl-L-alpha-phosphatidyl choline (DPPC) and a photochromic lipid, (1,2-(4'-n-butylphenyl)azo-4'-(gamma-phenylbutyroyl))-glycero-3- phosphocholine (Bis-Azo PC), which isomerizes on exposure to near-UV light with resulting changes in membrane permeability to solutes. The rate of loading of the vesicles below the phase transition temperature of DPPC was investigated as a function of Bis-Azo PC and cholesterol concentrations in the liposome. The rate of doxorubicin uptake was found to be greatly decreased in the presence of cholesterol, while below 30 degrees C the rate of acridine orange uptake was increased in the presence of cholesterol. On exposure to a single UV laser pulse, actively loaded acridine orange was rapidly released from liposomes containing Bis-Azo PC at a rate similar to that found for the indicator dye calcein. However while cholesterol had previously been shown to greatly enhance the rate of photo-induced calcein leakage, it had no significant effect on the rate of acridine orange release. After active loading into DPPC vesicles containing Bis-Azo PC, doxorubicin was also released after exposure to a single laser pulse, but at a rate slower than for acridine orange and calcein. The difference in behavior between these systems is ascribed to the interactions of acridine orange and doxorubicin with the liposome bilayer. Photoinduced release of pharmacologically active materials from sensitized liposomes might provide a useful adjunct or alternative to conventional photodynamic therapy.     

Controlling liposomal drug release with low frequency ultrasound: mechanism and feasibility

The ability of low-frequency ultrasound (LFUS) to release encapsulated drugs from sterically stabilized liposomes in a controlled manner was demonstrated. Three liposomal formulations having identical lipid bilayer compositions and a similar size ( approximately 100 nm) but differing in their encapsulated drugs and methods of drug loading have been tested. Two of the drugs, doxorubicin and methylpredinisolone hemisuccinate, were remote loaded by transmembrane gradients (ammonium sulfate and calcium acetate, respectively). The third drug, cisplatin, was loaded passively into the liposomes. For all three formulations, a short exposure to LFUS (<3 min) released nearly 80% of the drug. The magnitude of drug release was a function of LFUS amplitude and actual exposure time, irrespective of whether irradiation was pulsed or continuous. Furthermore, no change in liposome size distribution or in the chemical properties of the lipids or of the released drugs occurred due to exposure to LFUS. Based on our results, we propose that the mechanism of release is a transient introduction of porelike defects in the liposome membrane, which occurs only during exposure to LFUS, after which the membrane reseals. This explains the observed uptake of the membrane-impermeable fluorophore pyranine from the extraliposomal medium during exposure to LFUS. The implications of these findings for clinical applications of controlled drug release from liposomes are discussed.     

Liposomes‐Camouflaged Redox‐Responsive Nanogels to Resolve the Dilemma between Extracellular Stability and Intracellular Drug Release

Liposomes have shown great promises for pharmaceutical applications, but still suffer from the poor storage stability, undesirable drug leakage, and uncontrolled drug release. Herein, liposomes‐camouflaged redox‐responsive nanogels platform (denoted as “R‐lipogels”) is prepared to integrate the desirable features of sensitive nanogels into liposomes to circumvent their intrinsic issues. The results indicate that drug‐loaded R‐lipogels with controlled size and high stability not only can achieve a very high doxorubicin (DOX)‐loading capacity (12.9%) and encapsulation efficiency (97.3%) by ammonium sulfate gradient method and very low premature leakage at physiological condition, but also can quickly release DOX in the reducing microenvironment of tumor cells, resulting in effective growth inhibition of tumor cells. In summary, the strategy given here provides a facile approach to develop liposomes–nanogels hybrid system with combined beneficial features of stealthy liposomes and responsive nanogels, which potentially resolves the dilemma between systemic stability and intracellular rapid drug release.     

Active loading and tunable release of doxorubicin from block copolymer vesicles

Vesicles are spherical bilayers that offer a hydrophilic reservoir, suitable for the incorporation of water-soluble molecules, as well as a hydrophobic wall that protects the loaded molecules from the external solution. The permeability of a vesicle wall made from polystyrene can be enhanced by adding a plasticizer such as dioxane. Tuning the wall permeability allows loading and release of molecules from vesicles to be controlled. In this study, vesicles are prepared from polystyrene(310)-b-poly(acrylic acid)(36) and used as model carriers for doxorubicin (DXR), a weak amine and a widely used anticancer drug. To increase the wall permeability, different amounts of dioxane are added to the vesicle solution. A pH gradient is created across the vesicle wall (inside acidic) and used as an active loading method to concentrate the drug inside the vesicles. The results show that a pH gradient of ca. 3.8 units can enhance the loading level up to 10-fold relative to loading in the absence of the gradient. After loading, the release of DXR from vesicles is followed as a function of the wall permeability. The diffusion coefficient of doxorubicin through polystyrene (D) is evaluated from the initial slope of the release curves; the value of D ranges from 8 x 10(-17) to 6 x 10(-16) cm(2)/s, depending on the degree of plasticization of the vesicle wall.     

葡聚糖分子量和接枝度对阿霉素/白蛋白-葡聚糖纳米粒子体外抗肿瘤效果的影响

以Maillard反应制备的牛血清白蛋白-葡聚糖共价接枝物作为载体, 通过调节混合溶液的pH值和温度制备负载阿霉素的白蛋白-葡聚糖纳米粒子. 利用分子量为5×10³, 10×10³和62×10³的葡聚糖制备了多种共价接枝物, 研究了共价接枝物分子量对载药纳米粒子的粒径和稳定性及载药量的影响. 用短链葡聚糖(分子量5×10³和10×10³)制备的纳米粒子粒径为60 nm左右, 用长链葡聚糖(分子量62×10³)制备的纳米粒子粒径约为200 nm; 阿霉素的包埋效率为81%~98%, 包埋量为7.4%~16.9%. 细胞实验结果表明, 共价接枝物具有很好的生物相容性; 与自由阿霉素相比, 纳米粒子可以促进阿霉素进入人口腔上皮癌细胞; 受缓释性质的影响, 纳米粒子在低浓度时的细胞毒性要小于自由阿霉素. 与长链葡聚糖纳米粒子相比, 接枝度高的短链葡聚糖纳米粒子由于具有较小的粒径、 密集的葡聚糖分子刷表面、 一定的自由阿霉素浓度和较快的阿霉素释放速率, 因而更容易进入细胞并具有更好的体外抗肿瘤活性.     

Intercalation of Polyaniline in Montmorillonite and Zeolite

The anilinium ion was encapsulated into the interlayer space of montmorillonite and the intrachannel space of NaY zeolite by the ion exchange method. After addition of ammonium peroxodisulfate, the loaded anilinium ions were polymerized to polyaniline (PAN). The structures of PAN in NaM and CsM are compared with that in NaY by means of UV-Vis, FTIR and EPR spectroscopies. The structures of PAN in NaY zeolite and montmorillonite hosts were shown to have the typical spectral features of emeraldine base and emeraldine salt respectively. Intercalation of polyaniline in montmorillonite was confirmed by the variation of the basal spacing, the resonances in EPR and the reduction of bulk conductivity.     

布洛芬在阴离子交换树脂上的负载及其缓释

将布洛芬通过静电和疏水作用的共同作用负载于聚苯乙烯型大孔弱碱性阴离子交换树脂D301R和D301T上,最佳负载条件为:布洛芬悬浮于5~10%的乙醇水溶液中,加入树脂后在60℃下搅拌12h,负载量可达到0.49g/g树脂。研究了负载的布洛芬在模拟胃肠道的条件下(pH2下2h、pH 7.4下4h和pH 6.7下18h)的释放动力学,在前12h的释放接近于线性释放,释放率为58~60%。后12h的释放量较小,释放率为13~17%。如果每12h服药1次,第2次服药后的24h的累加释放率接近于线性释放。与聚苯乙烯骨架的大孔弱碱性阴离子交换树脂相比,聚甲基丙烯酸酯骨架的弱碱性阴离子交换树脂(甲基丙烯酸正丁酯/甲基丙烯酸N,N-二甲胺基乙酯/双甲基丙烯酸乙二醇酯共聚物)负载的布洛芬在相同释放条件下突释明显,表明布洛芬与苯乙烯型弱碱性阴离子交换树脂之间的π-π作用在布洛芬的缓释中起关键的作用。     

盐溶液调控海藻酸钙微球中的自由羧酸根及其对阿霉素的装载和释放行为研究

采用膜乳化-凝胶化法制备了粒径窄分布的海藻酸钙微球.用不同浓度的氯化钠溶液处理微球来调控微球中的自由羧酸根的含量.用原子吸收光谱和红外光谱表征了微球中钙、钠离子以及化学基团的变化,证明盐处理后海藻酸钙微球内发生了钠离子置换钙离子的过程,海藻酸中的羧酸根由螯合态转变为自由态.用盐处理后的微球吸附带正电荷的小分子抗癌药物阿霉素的能力大大提高,其中用浓度1.8%的氯化钠溶液处理后的微球载药量达到1310μg/mg,是未处理微球的10倍.负载药物的微球具有pH敏感的释放行为,在pH5.5的PBS溶液中的释放速率和释放量显著大于在pH 7.4的PBS溶液中.     

pH‐sensitive carbon quantum dots−doxorubicin nanoparticles for tumor cellular targeted drug delivery

A kind of pH‐responsive carbon quantum dots?doxorubicin nanoparticles drug delivery platform (D‐Biotin/DOX‐loaded mPEG‐OAL/N‐CQDs) was designed and synthesized. The system consists of fluorescent carbon dots as cross‐linkers, and D‐Biotin worked as targeting groups, which made the system have a pH correspondence, doxorubicin hydrochloride (DOX) as the target drug, oxidized sodium alginate (OAL) as carrier materials. Ultraviolet (UV)‐Vis spectrum showed that the drug‐loading rate of DOX is 10.5%, and the drug release in vitro suggested that the system had a pH response and tumor cellular targeted, the drug release rate is 65.6% at the value of pH is 5.0, which is much higher than that at the value of pH is 7.4. The cytotoxicity test and laser confocal fluorescence imaging showed that the synthesized drug delivery system has high cytotoxicity to cancer cells, and the drug‐loaded nanoparticles could enter the cells through endocytosis.     

Study on anion electrochemical recognition based on a novel ferrocenyl compound with multiple binding sites

A novel ferrocenyl anion receptor N, N, N, N-(dimethyl, ethyl, ferrocenecarboxylic amidodimethylene) ammonium fluoborate 2 with multiple binding sites was synthesized. Its anion recognition behaviors were investigated by CV, 1H NMR and UV-vis spectrum. It was found that the combination of two interactions enforced the anion binding ability and the binding selectivity of 2 to phosphate anion. The effects of scan rate on the CV curves of 2 with phosphate were also investigated. In different scan rate, the CV curves kept stable which indicated the strong binding between 2 and phosphate. According to relationships of peak potential, peak currents and scan rate of 2 binding with phosphate, the kinetic parameters of electrode process such as diffusion coefficient Dapp, surface transfer coefficient alphan alpha, and standard rate constant k0 were calculated.     

Near-infrared light (NIR)-responsive nanoliposomes combining photodynamic therapy and chemotherapy for breast tumor control

Light-responsive carriers have been used for the controlled release of antitumor drugs in recent years. However, most light-responsive vectors require high-energy ultraviolet or visible light to achieve local drug release, and ultraviolet light would cause cellular damage. Near-infrared light has a deeper tissue-penetration depths and minimal harm to tissues, but it is difficult to cleave the chemical bond directly. The aim of this study is to develop a novel near-infrared light-responsive carrier for local release of antitumor drugs. Unsaturated phospholipids can be oxidized by singlet oxygen to achieve liposomal drug release, and singlet oxygen can be produced by photosensitizer under light irradiation. A new near-infrared light-responsive nanoliposome was designed that imparts light-triggered local drug release. Nanoliposomes, which were composed of matrix phospholipids and unsaturated phospholipids, were prepared by ammonium sulfate gradient method, and loaded with antitumor drug doxorubicin (DOX) and photosensitizer 1,4,8,11,15,18,22,25-octabutoxypalladium phthalocyanine. Under near-infrared light, photosensitizers could produce singlet oxygen and damage tumor cells by photodynamic therapy. Simultaneously, the unsaturated phospholipids were oxidized by singlet oxygen and result in DOX release, causing sustained cell damage by chemotherapy. Near-infrared light-responsive nanoliposomes exhibit enhanced anticancer activity owing to combined treatment of photodynamic therapy and chemotherapy. A new platform is thus offered for designing effective intracellular drug-release systems, holding great promise for future cancer therapy.     

Design and Synthesis of Lipidic Organoalkoxysilanes for the Self‐Assembly of Liposomal Nanohybrid Cerasomes with Controlled Drug Release Properties

This paper reports the facile design and synthesis of a series of lipidic organoalkoxysilanes with different numbers of triethoxysilane headgroups and hydrophobic alkyl chains linked by glycerol and pentaerythritol for the construction of cerasomes with regulated surface siloxane density and controlled release behavior. It was found that the number of triethoxysilane headgroups affected the properties of the cerasomes for encapsulation efficiency, drug loading capacity, and release behavior. For both water‐soluble doxorubicin (DOX) and water‐insoluble paclitaxel (PTX), the release rate from the cerasomes decreased as the number of triethoxysilane headgroups increased. The slower release rate from the cerasomes was attributed to the higher density of the siloxane network on the surface of the cerasomes, which blocks the drug release channels. In contrast to the release results with DOX, the introduction of one more hydrophobic alkyl chain into the cerasome‐forming lipid resulted in a slower release rate of PTX from the cerasomes due to the formation of a more compact cerasome bilayer. An MTT viability assay showed that all of these drug‐loaded cerasomes inhibited proliferation of the HepG2 cancer cell line. The fine tuning of the chemical structure of the cerasome‐forming lipids would foster a new strategy to precisely regulate the release rate of drugs from cerasomes.     

DNA binding during expanded bed adsorption and factors affecting adsorbent aggregation

DNA-induced aggregation and contraction of expanded bed adsorption chromatography beds have been examined using strong anion exchanger Q HyperZ and calf thymus DNA in buffers containing added NaCl. Two batches of adsorbent with different ionic capacities were used allowing the effects of different ligand densities to be examined. Very high dynamic binding capacities at 10% breakthrough were found in the absence of added salt. However, the highest binding capacities ( approximately 10 and approximately 19mgDNAml(-1) gel) were found in buffers containing added salt at concentrations of either 0.25 or 0.35M, for the low and high ligand density adsorbents, respectively. Bed contraction was observed, but did not correlate with dynamic binding capacity or with the amount of DNA loaded. No differences in bed contraction were seen by varying the concentration of DNA loaded in the range of 20-80mugml(-1) even though the dynamic binding capacity was reduced as DNA concentration was increased. The extent of bed contraction during DNA loading was found to be a function of added salt concentration and ligand density of the adsorbent. The results imply that ligand density significantly affects the salt tolerance of anion exchangers when binding DNA. However, more importantly, with the adsorbents examined here, attempts to reduce bed aggregation by feedstock conditioning with added salt may increase DNA binding leading to a reduction in expanded bed adsorption performance compromising protein capture in real feedstocks.     

High entrapment of insulin and bovine serum albumin into neutral and positively-charged liposomes by the remote loading method

Remote loading of insulin and bovine serum albumin (BSA) into neutral or positively-charged liposomes by incubation under a transmembrane pH gradient or non-pH gradient was investigated. Trapping efficiencies in several incubation conditions were compared with those of the conventional reverse-phase evaporation vesicle method (c-REV method). For neutral liposomes, insulin could not be effectively loaded into the liposomes by incubation, regardless of the incubation conditions. The trapping efficiency of insulin into positively-charged liposomes was higher than that of neutral liposomes, especially by the pH-gradient method. Insulin could be loaded into positively-charged liposomes about twofold more efficiently than by the pH-gradient method, compared with the c-REV method. Insulin distributed more on the surface of liposomes by the pH-gradient method than by the c-REV method. BSA showed significantly higher affinity to positively-charged liposomes than to neutral ones by various methods. However, the transmembrane pH-gradient method did not increase BSA loading into liposomes, compared with the c-REV and the non-pH-gradient methods. Our results suggest that the pH-gradient method, combining electrostatic interactions, may be useful for preparation of liposomal insulin and that the high hydrophobicity of BSA may not increase the remote loading of BSA into liposomes by the pH-gradient method.     

Dual drug delivery system with flexible and controllable drug ratios for synergistic chemotherapy

Determination of whether multidrug nanocarriers can deliver and release loaded drugs at a predefined synergistic ratio to target cancer cells is crucial. Although there are many successful applications for delivery of multiple drugs, most current carriers are unable to achieve coordinated loading and release, leading to a drug release ratio that disagrees with the predefined loading ratio.In this work, a simple dual-drug delivery system with a flexible and controllable drug release ratio was constructed to deliver two anticancer drugs, doxorubicin(DOX) and curcumin(CUR). The drug ratio of DOX and CUR can be easily tuned for an enhanced synergistic effect, and the drugs can be released at predesigned ratios due to synchronous drug activation and nanoparticle collapse. Drug release at predefined ratios for synergistic anticancer therapy was demonstrated via in vitro and in vivo experiments. Therefore, the dual drug delivery system developed here provides a simple and efficient strategy for combination chemotherapy.     

A versatile prodrug approach for liposomal core-loading of water-insoluble camptothecin anticancer drugs

We describe a versatile prodrug strategy for loading the liposomal lumen with water-insoluble camptothecins. The procedure involves conversion of an active camptothecin analogue to a 20-OR omega-aminoalkanoanic ester prodrug in which R = CO[CH(2)](n)()NH(2) and n = 1-3. The basic amino group of the prodrug serves three roles. First, at pH ranges of 3-5, the amine enhances aqueous solubility. Second, it enhances responsiveness to a transmembrane ammonium sulfate gradient across the liposomal bilayer, thereby facilitating active loading of the agent into the liposomal aqueous core. Third, at a physiological pH of 7 or above (the pH to be encountered following drug release at the tumor site), the nucleophilicity of the amine manifests itself and cyclization to the C-21 carbonyl carbon occurs. This cyclization triggers a rapid and convenient nonenzymatic decomposition process that releases active camptothecin. Accordingly, this novel liposomal approach offers a potential system for tumor-targeting prodrugs of many water-insoluble camptothecins, including the highly lipophilic and clinically attractive analogues SN-38, 9-nitrocamptothecin and DB-67. The rate of formation of the active agent at the tumor site can be controlled through the selection of n (the length of the alkyl spacer group).     

Cyclic voltammetric detection of chemical DNA damage induced by styrene oxide in natural dsDNA layer-by-layer films using methylene blue as electroactive probe

In this work, an electrochemical sensor for detecting damage of natural double-stranded DNA (dsDNA) was constructed based on PSS/{PDDA/dsDNA}₃ layer-by-layer films, where PSS was poly(styrene sulfonate) and PDDA was poly(diallyldimethyl ammonium). When the PSS/{PDDA/dsDNA}₃ films assembled on pyrolytic graphite (PG) electrodes were immersed into methylene blue (MB) solution and loaded MB into the films, the formed PSS/{PDDA/dsDNA}₃-MB films in blank buffers at pH 7.0 showed a reversible cyclic voltammetric (CV) peak pair at −0.23 V vs. SCE for MB redox couple. In blank solutions, the MB loaded into the films was released gradually from the films, but the complete reloading of MB into the films could be realized by immersing the films into MB solution again, indicating the good reversibility of MB incorporation. However, after incubation in the solution of known genotoxic agent styrene oxide (SO), the damaged PSS/{PDDA/dsDNA}₃-MB films could not return to their original and fully-loaded state with reloading of MB, and showed smaller CV peak currents than those of intact PSS/{PDDA/dsDNA}₃-MB films. The relative peak current ratio, I_p,I/I_p,III, where I_p,I was the anodic peak current of intact DNA films in blank buffers after fully loading with MB and I_p,III was that of SO-damaged DNA films after reloading with MB, increased linearly with the incubation time with SO in the range of 5–40 min with a damage rate of 0.0099 min⁻¹. While the formation of SO adducts with dsDNA had no substantial effect on the dsDNA conformation, the steric hindrance of SO adducts with guanine or adenine blocked the intercalation of MB into the base pairs of dsDNA, resulting in the decrease of CV peak currents of loaded MB. The specific intercalation of MB into dsDNA base pairs and the sensitive electrochemical response of MB, combined with the unique feature of loading reversibility of MB in the DNA layer-by-layer films, make the difference in CV response between the intact and damaged dsDNA films become pronounced in the “loading/release/reloading” procedure. This may provide a new and general approach for constructing a biosensor for screening genetoxic chemicals in vitro.     

Polyelectrolyte microcapsules templated on poly(styrene sulfonate)-doped CaCO3 particles for loading and sustained release of daunorubicin and doxorubicin

A strategy to incorporate and release anti-cancer drugs of daunorubicin (DNR) and doxorubicin (DOX) in preformed microcapsules is introduced, which is based on charge interaction mechanism. Oppositely charged poly(allylamine hydrochloride) (PAH) and poly(styrene sulfonate) (PSS) were assembled onto PSS doped-CaCO₃ colloidal particles in a layer-by-layer manner to yield core-shell particles. After removal of the carbonate cores, hollow microcapsules with entrapped PSS were fabricated, which showed spontaneous loading ability of positively charged DNR and DOX. The drug loading was confirmed quantitatively by observations under confocal laser scanning microscopy, transmission electron microscopy and scanning force microscopy. Quantification of the drug loading was performed under different conditions, revealing that a larger amount of drugs could be incorporated at higher drug feeding concentrations and higher salt concentrations. However, putting additional polyelectrolyte layers on the microcapsules after core removal resulted in weaker drug loading efficiency. The drug release behaviors from the microcapsules with different layer numbers were studied too, revealing a diffusion controlled release mechanism at the initial stage (4 h).     

Core–Shell Hollow Microspheres of Magnetic Iron Oxide@Amorphous Calcium Phosphate: Synthesis Using Adenosine 5′‐Triphosphate and Application in pH‐Responsive Drug Delivery

Drug nanocarriers with magnetic targeting and pH‐responsive drug‐release behavior are promising for applications in controlled drug delivery. Magnetic iron oxides show excellent magnetism, but their application in drug delivery is limited by low drug‐loading capacity and poor control over drug release. Herein, core–shell hollow microspheres of magnetic iron oxide@amorphous calcium phosphate (MIO@ACP) were prepared and investigated as magnetic, pH‐responsive drug nanocarriers. Hollow microspheres of magnetic iron oxide (HMIOs) were prepared by etching solid MIO microspheres in hydrochloric acid/ethanol solution. After loading a drug into the HMIOs, the drug‐loaded HMIOs were coated with a protective layer of ACP by using adenosine 5′‐triphosphate (ATP) disodium salt (Na₂ATP) as stabilizer, and drug‐loaded core–shell hollow microspheres of MIO@ACP (HMIOs/drug/ACP) were obtained. The as‐prepared HMIOs/drug/ACP drug‐delivery system exhibits superparamagnetism and pH‐responsive drug‐release behavior. In a medium with pH 7.4, drug release was slow, but it was significantly accelerated at pH 4.5 due to dissolution of the ACP shell. Docetaxel‐loaded core–shell hollow microspheres of MIO@ACP exhibited high anticancer activity.     

质谱法分析季铵盐型阳离子表面活性剂

以电子轰击质谱法(EI/MS)与电喷雾质谱法(ESI/MS)相结合,分析季铵盐型表面活性剂。由于阳离子表面活性剂在水溶液中离解成正离子,可用电喷雾质谱的正离子模式(ESI /MS)对其结构及组成进行鉴定,同时可判别季铵盐所含的Cl-、Br-、NO3-等阴离子。