Preparation of the thienopyridine derivatives loaded liposomes and study on the effect of compound-lipid interaction on release behavior

The article describes characterization of two liposome formulations containing thienopyridine derivatives, namely TP-58 and TP-67. By preparing the liposomes, the concentration of the two compounds in ultrapure water was increased up to three orders of magnitude. After i.v. administration of the liposomes in rats, the initial compound plasma concentrations were enhanced more than fifty times relative to that after i.g. administration of the compound suspensions. It was found out that the release rate of TP-67 from the liposome both in vitro and in vivo was not significantly different from that of TP-58. TP-58 was more lipophilic than TP-67 according to partition coefficiency, and TP-67 had greater polarity than TP-58 based on polar surface area (PSA). With DSC, it was found out that the interaction magnitude between TP-67 and the lipid bilayer was not significantly different from that between TP-58 and the lipid bilayer, which accounted for the similarity of the two compounds in release rate both in vitro and in vivo. It indicated liposome can be used as a potential carrier for broading the application of TP-58 and TP-67. Interaction between the thienopyridine derivatives and the lipid bilayer is probably the decisive factor for compound release from the liposomes.     

修饰脂质体的可断裂聚乙二醇脂质衍生物的研究进展

聚乙二醇脂质衍生物可增加脂质体的稳定性，延长其体内循环时间。传统的长循环材料由于连接聚乙二醇与脂质的化学键太稳定，导致脂质体内容物释放延迟而影响药效。近年来提出可断裂聚乙二醇脂质衍生物的概念，该类衍生物具有可以在人的生理或病理条件下断裂的性质，能够延长脂质体体内循环时间，在到达靶部位后由于聚乙二醇已经从脂质体表面脱落，脂质体可以与病变细胞结合，从而将药物送入细胞。本文综述了可断裂聚乙二醇脂质衍生物的种类、断裂类型、在脂质体中的应用概况及在应用中的优势和局限。     

Improving solubility and chemical stability of natural compounds for medicinal use by incorporation into liposomes

Natural bioactive compounds have been studied for a long time for their chemopreventive and therapeutic potential in several chronic inflammatory diseases, including cancer. However, their physicochemical properties generally result in poor chemical stability and lack of in vivo bioavailability. Very few human clinical trials have addressed absorption, distribution, metabolism, and excretion of these compounds in relation to efficacy. This limits the use of these valuable natural compounds in the clinic.In this study, we examined caffeic acid (derivatives), carvacrol (derivatives), thymol, pterostilbene (derivatives), and N-(3-oxo-dodecanoyl)-l-homoserine lactone. These are natural compounds with strong anti-inflammatory properties derived from plants and bacteria. However, these compounds have poor water solubility or are chemically unstable. To overcome these limitations we have prepared liposomal formulations. Our results show that lipophilic 3-oxo-C₁₂-homoserine lactone and stilbene derivatives can be loaded into liposomal lipid bilayer with efficiencies of 50-70%. Thereby, the liposomes solubilize these compounds, allowing intravenous administration without use of solvents. When compounds could not be loaded into the lipid bilayer (carvacrol and thymol) or are rapidly extracted from the liposomes in the presence of serum albumin (3-oxo-C₁₂-homoserine lactone and pterostilbene derivatives), derivatization of the compound into a water-soluble prodrug was shown to improve loading efficiency and encapsulation stability. The phosphate forms of carvacrol and pterostilbene were loaded into the aqueous interior of the liposomes and encapsulation was unaffected by the presence of serum albumin. Chemical instability of resveratrol was improved by liposome-encapsulation, preventing inactivating cis-trans isomerization. For caffeic acid, liposomal encapsulation did not prevent oxidation into a variety of products. Still, by derivatization into a phenyl ester, the compound could be stably encapsulated without chemical degradation.Despite the instability of liposome-association of 3-oxo-C₁₂-homoserine lactone and resveratrol, intravenous administration of these compounds inhibited tumor growth for approximately 70% in a murine tumor model, showing that simple solubilization can have important therapeutic benefits.     

Physical and biological characterization of antigen presenting liposome formulations: relative efficacy for the treatment of recurrent genital HSV-2 in guinea pigs

Antigen presenting liposomes (APLs) containing both liposome encapsulated (44%) and free (56%) recombinant glycoprotein D of herpes simplex virus type-2 (rgD-2) were characterized with respect to the interaction of the antigen with the lipid bilayer and the biological activities provided by each form of rgD-2. We found that free rgD-2 added externally to empty liposomes exhibited some biological activities both in vitro and in vivo, although we could not detect any significant adsorption and/or insertion of this form of rgD-2 into the lipid bilayer. Compared to APLs containing both forms of rgD-2, purified liposomes containing only encapsulated rgD-2 gave only 50% of the relative activity in vitro as measured by their ability to stimulate rgD-2 specific lymphocyte proliferation, and 67% of the relative activity in vivo as measured by their immunotherapeutic effect on recurrent genital HSV-2 disease in guinea pigs (P less than 0.05). These data indicate that while liposome encapsulated rgD-2 is essential for the elicitation of immunogenic responses, the free soluble rgD-2 in the APL formulation also acts in concert to generate an optimum immunotherapeutic efficacy.     

Liposomal diclofenac eye drop formulations targeting the retina: Formulation stability improvement using surface modification of liposomes

An efficient liposomal formulation for targeting the retina was produced as an optimal means of distributing therapeutic agents to the retina. Diclofenac was used as a model compound for liposome encapsulation, and the release rate and distribution to the retina were investigated. The calcium acetate gradient method was found to be the optimal method for encapsulating diclofenac into liposomes. Entrapment efficiency using this method was greater than 97%, whereas conventional hydration method achieved 51.3%. The resultant formulation obtained with the gradient method caused aggregation and/or fusion of liposomes. To avoid inhibition of retinal delivery due to the aggregation of the carrier, surface modification was performed simultaneously with the gradient method. The increase in particle size of the liposomal formulation clearly was inhibited for a long time in the presence of polyvinyl alcohol or its derivative. This observation may be explained by surface modification of the liposomes by physisorption or anchoring effect of polymers on the surface of the lipid bilayer. Furthermore, the sustained release profile of the diclofenac formulation was retained after modification. An in vivo animal study revealed that concentration of the accumulated diclofenac in the retina-choroid was enhanced 1.8-fold by surface-modified liposome entrapment compared to that of the unaltered diclofenac solution.     

Steric stabilization of liposomes by pH-responsive N-isopropylacrylamide copolymer

The aim of this study was to characterize a pH-sensitive liposome formulation bearing a terminally alkylated N-isopropylacrylamide (NIPAM) copolymer with regard to its pH responsiveness, surface properties, and pharmacokinetics. The interacting forces between two lipid bilayers bearing the anchored NIPAM copolymer were measured with a surface force apparatus. The pH-triggered content release was evaluated in buffer before and after incubation in human serum. The pharmacokinetics was determined in rats following the intravenous injection of 67Ga-loaded liposomes with or without the polymer coating. The force measurements between lipid bilayers showed that NIPAM copolymers provide a steric barrier that was dependent on pH. The pH-sensitive liposomes maintained their pH sensitivity after incubation in serum. In vivo, the polymer-coated liposomes exhibited a prolonged circulation time in rats, with an area under the blood concentration-time curve that is 1.6-fold higher than the control formulation. This study showed that liposomes can be rendered pH sensitive by anchoring a terminally alkylated NIPAM copolymer at their surface. At neutral pH, the polymer provides a steric barrier that increases the liposome circulation time in vivo.     

Effect of antimicrobial apomyoglobin 56-131 peptide on liposomes and planar lipid bilayer membrane

The horse apomyoglobin 56-131 peptide is a convenient object for studies on the recently discovered antimicrobial activities of haem-binding protein fragments called haemocidins. The purpose of this study was to determine the effect of this peptide on planar lipid bilayer membranes and on liposomes of different lipid compositions. Micromolar concentrations of the apomyoglobin 56-131 fragment disrupt phosphatidylserine/phosphatidylethanolamine planar lipid bilayers without discrete conductance changes. The observed detergent-like action is dependent on peptide concentration; the lower amount of peptide resulted in longer bilayer lifetime. The cholesterol has an inhibitory effect on peptide-induced liposome lysis as shown by calcein release from liposomes. Additionally, there was considerable lytic activity on liposomes formed from anionic lipids of the sort found in bacterial membranes. Circular dichroism (CD) experiments showed that the peptide had a disordered structure in aqueous solutions and folds gradually to form helices in both membrane-mimetic trifluoroethanol solutions as well as in liposome suspensions. The features of the apomyoglobin 56-131 fragment that are similar to the cationic antimicrobial peptides acting in a 'carpet-like' manner are discussed.     

5-Fluorouracil in topical liposome gels for anticancer treatment--formulation and evaluation

Liposome gels bearing an antineoplastic agent, 5-fluorouracil, intended for topical application have been prepared and drug release properties in vitro have been evaluated. Different formulations of liposomes were prepared by the film hydration method by varying the lipid phase composition (PL 90H/cholesterol mass ratio) and hydration conditions of dry lipid film (drug/aqueous phase mass ratio). Topical liposome gels were prepared by incorporation of lyophilized liposomes into a structured vehicle (1%, m/m, chitosan gel base). Also, hydrogels containing different concentrations of 5-fluorouracil were prepared and drug release properties were investigated. The rate of drug release from liposome gels was found to be dependent on the bilayer composition and the dry lipid film hydration conditions. Also, liposomes embedded into a structured vehicle of chitosan showed significantly slower release than hydrogels. The drug release obeyed the Higuchi diffusion model, while liposomes acted as reservoir systems for continuous delivery of the encapsulated drug.     

多西他赛他莫昔芬脂质体体外释放研究

目的考察多西他赛他莫昔芬复方脂质体体外释放。方法薄膜分散法制备单方和复方脂质体样品,通过透析法进行脂质体体外释放,采用高效液相色谱法测定他莫昔芬和多西他赛药物浓度,并对体外释放曲线进行数学模型拟合。结果单方和复方脂质体中,他莫昔芬和多西他赛均无突释,多西他赛较他莫昔芬释放快,他莫昔芬和多西他赛释放模型符合一级释放方程,他莫昔芬和多西他赛的释放曲线相似。结论他莫昔芬和多西他赛在单方和复方脂质体体外释放并无显著差异。     

Effect of preparation method and cholesterol on drug encapsulation studies by phospholipid liposomes

Unilamellar liposomes, prepared from synthetic lipid mixture of DMPC and DMPG either by sonication or extrusion, were used to entrap water soluble and water insoluble molecules to investigate the efficacy of encapsulation by different liposome preparation methods. In the case of entrapment of hydrophilic protein cytochrome-C, the solutions were subjected to a series of ultrafiltration steps to eliminate any free protein outside the vesicles. It was observed that the protein could be encapsulated by the vesicles only if cholesterol was present in the bilayer. The release of cytochrome-C was observed spectrophotometrically upon vesicle-breakdown. The amount of protein encapsulated depended on the method of preparation and was found to be 10 times greater in extruded liposomes compared to those produced by sonication. Hydrophobic Vitamin E, on the other hand, could be encapsulated in the liposome bilayer, independently of the presence of cholesterol and the method of preparation. These fundamental results can be used to develop more efficient drug encapsulations and to have better understanding about their release.     

Incorporation of chlorpromazine into bilayer liposomes for protection against microsomal metabolism and liver absorption

Chlorpromazine (CPZ) was incorporated into bilayer liposomes carrying negative charges either from phosphatidic acid (PA) or from phosphatidyl inositol (PI). CPZ incorporation was dependent on the amount of negatively charged lipid present in the liposomes. At a concentration of 0.6 mol parts phosphatidic acid as referred to egg phosphatidyl choline (EPC) as matrix lipid, 80 micrograms CPZ/mg EPC were stably incorporated. At the saturation concentration a 1:1 molar complex between the phenothiazine drug and the negatively charged lipid is formed. This lipophilic complex retains the CPZ molecules firmly within the lipid bilayer. In vitro release of CPZ into the medium surrounding the liposomes was found to be a very slow process with release half-times of 30 to 99 hours depending on liposome composition. Microsomal metabolism of liposomally incorporated CPZ was slowed and reduced by 50% as determined by the formation of CPZ-sulfoxide. In single pass liver perfusion experiments it was shown that CPZ absorption is significantly reduced when CPZ is incorporated into liposomes. It is suggested that this protective effect of the liposomes might influence the pharmacological effects of CPZ and reduce its hepatotoxic properties.     

Heterogeneous liposome membranes with pH-triggered permeability enhance the in vitro antitumor activity of folate-receptor targeted liposomal doxorubicin

The killing efficacy of doxorubicin from liposome-based delivery carriers has been shown to correlate strongly with its intracellular trafficking and, in particular, its fast and extensive release from the delivery carrier. However, previously explored pH-triggered mechanisms that were designed to become activated during liposome endocytosis have also been shown to interfere with the liposome stability in vivo. We have designed pH-triggered gel-phase liposomes with heterogeneous membranes for the delivery of doxorubicin. These liposomes are triggered to form "leaky" interfacial boundaries between gel-gel phase separated domains on the membrane bilayer with lowering pH. The pH-triggered mechanism does not compromise liposome stability in vivo and results in superior in vitro killing efficacy of delivered doxorubicin when liposomes are endocytosed by a clathrin-mediated pathway. In the present work, we evaluate the general applicability of these liposomes when targeted to the folate receptor (FR) of KB cancer cells in vitro and become endocytosed by a less acidic pathway: the caveolae pathway. FR-targeting liposomes exhibit almost 50% decrease in cell association for increase in liposome size from 120 to 280 nm in diameter after relatively short incubation times (up to 4 h). The fraction of internalized vesicles, however, is approximately 60% of the cell associated vesicles independent of their size. Our findings demonstrate that, for the same doxorubicin uptake per cancer cell, the killing effect of doxorubicin delivered by pH-triggered lipid vesicles is greater (IC(50) = 0.032 mM for a 6 h incubation) than when delivered by a conventional non-pH-responsive composition (IC(50) = 0.194 mM). These findings suggest higher bioexposure of cells to the therapeutic agent possibly via faster and more extensive release from the carrier. Animal studies of FR-targeting non-pH-responsive liposomal doxorubicin report stronger therapeutic potential for the targeted approach relative to nontargeted liposomes and to free doxorubicin. The findings of the present study suggest that the targeted pH-triggered liposomes could potentially further enhance the therapeutic outcomes of doxorubicin in vivo.     

PLGA/Liposome Hybrid Nanoparticles for Short-Chain Ceramide Delivery

Purpose

Rapid premature release of lipophilic drugs from liposomal lipid bilayer to plasma proteins and biological membranes is a challenge for targeted drug delivery. The purpose of this study is to reduce premature release of lipophilic short-chain ceramides by encapsulating ceramides into liposomal aqueous interior with the aid of poly (lactic-coglycolicacid) (PLGA).

Methods

BODIPY FL labeled ceramide (FL-ceramide) and BODIPY-TR labeled ceramide (TR-ceramide) were encapsulated into carboxy-terminated PLGA nanoparticles. The negatively charged PLGA nanoparticles were then encapsulated into cationic liposomes to obtain PLGA/liposome hybrids. As a control, FL-ceramide and/or TR ceramide co-loaded liposomes without PLGA were prepared. The release of ceramides from PLGA/liposome hybrids and liposomes in rat plasma, cultured MDA-MB-231 cells, and rat blood circulation was compared using fluorescence resonance energy transfer (FRET) between FL-ceramide (donor) and TR-ceramide (acceptor).

Results

FRET analysis showed that FL-ceramide and TR-ceramide in liposomal lipid bilayer were rapidly released during incubation with rat plasma. In contrast, the FL-ceramide and TR-ceramide in PLGA/liposome hybrids showed extended release. FRET images of cells revealed that ceramides in liposomal bilayer were rapidly transferred to cell membranes. In contrast, ceramides in PLGA/liposome hybrids were internalized into cells with nanoparticles simultaneously. Upon intravenous administration to rats, ceramides encapsulated in liposomal bilayer were completely released in 2 min. In contrast, ceramides encapsulated in the PLGA core were retained in PLGA/liposome hybrids for 4 h.

Conclusions

The PLGA/liposome hybrid nanoparticles reduced in vitro and in vivo premature release of ceramides and offer a viable platform for targeted delivery of lipophilic drugs.     

Microencapsulated liposomes in controlled drug delivery: strategies to modulate drug release and eliminate the burst effect

The release of fluorescein isothiocyanate labeled bovine serum albumin (FITC-BSA) from alginate-microencapsulated liposomes was studied to evaluate the properties of this system for controlled drug delivery. Liposomes composed of phosphatidylcholine (PC) and cholesterol (Chol) (molar ratio 7:3) and of PC, phosphatidylglycerol (PG), and cholesterol (6:1:3) were encapsulated in alginate (Alg) crosslinked with Ca(2+) (Ca-Alg), Al(3+) (Al-Alg), and Ba(2+) (Ba-Alg). Capsules were coated with poly(l-ornithine) followed by a final alginate coat. A rapid initial burst of protein release was observed from liposomes encapsulated in Ca-Alg and Al-Alg. No burst was observed when liposomes were encapsulated in Ba-Alg, indicating that the crosslinking ions could significantly affect the release of entrapped protein. Also, the release from encapsulated liposomes varied significantly with liposome composition, especially with Ca-Alg as observed with encapsulation of PC, dioleoylphosphatidylcholine (DOPC), and DOPC/Chol liposomes. Cholesterol increased the leakiness of the liposomes after encapsulation. In all cases, the release from microencapsulated liposomes was much faster than that from free liposomes suggesting an interaction between the liposomes and the alginate. Differential scanning calorimetry supports the hypothesis that alginate was inserted into the lipid bilayer resulting in a rapid release of protein from microencapsulated liposomes. Moreover, it was observed that the degree of interaction between liposomes and alginate varied with liposome composition.     

马钱子碱新型壳聚糖纳米粒体外肝癌细胞摄取特性的研究

水凝胶是一种亲水性三维空间网络结构,与合成高聚物相比,天然高分子材料如壳聚糖、透明质酸、海藻酸钠等具有良好的生物相容性和生物可降解性,更适宜用作水凝胶基质。脂质体是一种由脂质双分子层形成的球形囊泡,脂质体水凝胶给药系统不仅可发挥脂质体缓控释、刺激响应性释放药物的特点,而且水凝胶屏障可提高脂质体的稳定性,药物可通过口服、注射、局部透皮等多种给药途径进入体内发挥药效,广泛用于药物传递系统和组织工程。综述多种以天然高分子材料为凝胶骨架,且其内含有载药脂质体、类脂囊泡等的水凝胶系统研究进展,对开发新型缓控释制剂、提高水溶性药物透皮吸收和生物利用度、研究智能刺激响应性给药系统等方面具有重要参考价值。

     

Effects of lipid composition and preparation conditions on physical-chemical properties, technological parameters and in vitro biological activity of gemcitabine-loaded liposomes

The effects of lipid composition and preparation conditions on the physicochemical and technological properties of gemcitabine-loaded liposomes, as well as the in vitro anti-tumoral activity of various liposome formulations were investigated. Three liposome formulations were investigated: DPPC/Chol/Oleic acid (8:3:1 molar ratio, liposomes A), DPPC/Chol/DPPS (6:3:1 molar ratio, liposomes B) and DPPC/Chol/DSPE-MPEG (6:3:1 molar ratio, liposomes C). Multilamellar liposomes were prepared by using the TLE, FAT and DRV methods, while small unilamellar liposomes were obtained by extrusion through polycarbonate filters. Light scattering techniques were used to characterize liposome formulations. Loading capacity and release profiles of gemcitabine from various liposome formulations were also investigated. Caco-2 cells were used to evaluate in vitro the antitumoral activity of gemcitabine-loaded liposomes with respect to the free drug and also the intracellular drug uptake. Preparation methods and liposome lipid composition influenced both physicochemical parameters and drug delivery features. Liposomes with a size ranging from 200 nm to 7 microm were obtained. The gemcitabine entrapment was higher than that expected probably due to an interaction with the liposome lipid components. The following decreasing loading capacity order was observed: liposome B>liposome C>liposome A. Gemcitabine release from various liposome formulations is modulated by two different processes, i.e. desorption from and permeation through liposomal bilayers. MTT assay showed a greater cytotoxic effect of gemcitabine-loaded liposomes with respect to the free drug. The following decreasing anticancer activity order was observed between the various liposome formulations: liposome C>liposome A>liposome B. The increased anticancer activity is correlated to the ability of the colloidal carrier to increase the intracellular drug uptake. Due to the encouraging results and to the high liposome modularity various applications of potential therapeutic relevance can be envisaged for liposomes.     

MRI evaluation of the antitumor activity of paramagnetic liposomes loaded with prednisolone phosphate

The design of long circulating liposomes co-loaded with the glucocorticoid prednisolone phosphate (PLP) and the amphiphilic paramagnetic contrast agent Gd-DOTAMA(C(18))(2) allowed the MRI-guided in vivo visualization of the delivery and biodistribution of PLP, as well as the monitoring of drug efficacy. The performance of this theranostic probe was investigated in a mouse model bearing a melanoma B16 syngeneic tumor. The release kinetics of the drug were evaluated in vitro where it displayed a peculiar behavior characterized by a fast process (completed in few hours) involving only a small portion (<5%) of the drug. Interestingly, the incorporation of the amphiphilic imaging reporter in the liposomal bilayer slightly increased the amount of the fast-release portion (<10%), thus suggesting that it could be attributed to a drug fraction embedded in the liposomal bilayer. In fact, the release of a hydrophilic imaging probe encapsulated in the inner core of the same long circulating liposomes formulated for carrying the drug, displayed different, single-step, kinetics. The in vivo monitoring of the antitumor activity of the nanomedicine revealed that the incorporation of the MRI probe into the liposome bilayer did not significantly affect the drug efficacy. The in vivo experiments also indicated a relevant and fast liposome uptake from macrophage-rich organs like spleen and liver, which reduced the tumor accumulation of the liposomes. The accumulation of the amphipatic MRI label caused the occurrence of a long-term residual T(1) contrast still detectable 1week after injection.     

The effect of lipid composition and liposome size on the release properties of liposomes-in-hydrogel

To study the release of liposome-associated drugs into hydrogels, we designed and synthesized two pH-sensitive rhodamine derivatives to use as model compounds of different lipophilicities. The dyes were fluorescent when in the free form released from liposomes into the chitosan hydrogel, but not when incorporated within liposomes. The effect of liposomal composition, surface charge and vesicle size on the release of those incorporated dyes was evaluated. The lipophilicity of the rhodamine derivatives affected both the amount and rate of release. While liposome size had only a minor effect on the release of dyes into the hydrogel, the surface charge affected the release to a greater extent. By optimizing the characteristics of liposomes we could develop a liposomes-in-hydrogel system for application in wound therapy. We further characterized liposomes-in-hydrogel for their rheological properties, textures and moisture handling, as well as their potential to achieve a controlled release of the dye. The polymer-dependent changes in the hydrogel properties were observed upon addition of liposomes. The charged liposomes exhibited stronger effects on the textures of the chitosan hydrogels than the neutral ones. In respect to the ability of the system to handle wound exudates, chitosan-based hydrogels were found to be superior to Carbopol-based hydrogels.     

Preparation and properties of poly(vinyl alcohol)-stabilized liposomes

The purpose of this work is to evaluate the improvement in physical stability of poly(vinyl alcohol) (PVA) modified liposomes. Liposomes composed of soya phosphatidylcholile (SPC) and cholesterol (1:1 molar ratio) were prepared by reverse phase evaporation method. Two types of interaction between liposome and PVA were investigated: PVA addition into lipid bilayer during liposome preparation and coating of already formed liposomes with PVA. The microparticles system was morphologically characterized by transmission electron microscopy (TEM) and particles analysis. Changes in particles size and zeta potential confirmed the existence of a thick polymer layer on the surface of liposomes. The amount of PVA adsorbing to liposomes and the encapsulation efficiency increased with increasing polymer concentration. The physical stability was evaluated by measuring the release rate of contents at 20 and 37 degrees C, the PVA modified liposomes were more stable than the conventional liposomes. Comparing with PVA-coated liposomes, the liposomes with PVA addition to the bilayer were more stable, and had higher entrapment efficiency.     

Liposome aggregation in presence of the sweeteners cyclamate and saccharine

The interaction of the sweeteners saccharine and cyclamate with large unilamellar liposomes and planar bilayer lipid membranes (BLM) was studied. Application of the methods of light scattering and sound velocimetry showed that saccharine induces aggregation of liposomes, while cyclamate probably caused increase of the hydration of liposome surface. The sweeteners induced changes of BLM compressibility in a direction perpendicular to the membrane plane. The cyclamate induced considerably larger decreases in the elasticity module than saccharine. The obtained results show that both saccharine and cyclamate interacts with the surface of lipid bilayer and could modify the physical properties of lipid membranes.