Stability and transdermal absorption of topical amphotericin B liposome formulations

The aim of this study was to characterize the stability and transdermal absorption of amphotericin B (AmB: 0.05 mg/mg lipid) in hydrogenated soya phosphatidylcholine/cholesterol/charged lipid {dicetyl phosphate (−) or stearylamine (+)} liposomes at molar ratios of 1:1:0, 7:2:0, 7:2:1(−) and 7:2:1(+). The AmB contents in liposomes were determined by HPLC with UV detection at 382 nm. Stabilities of AmB in liposome formulations were compared with those in solution and powder forms, during storage at 4, 30 and 45 °C for 90 days. Absorption studies of AmB across the rat skin were conducted, using vertical Franz diffusion cells at 37 °C for 24 h. The slowest degradation was observed in the positive liposome (7:2:1(+)AmB), with shelf life of 1 year (30 °C). In comparison, the shelf lives of AmB in solution and powder were 4 and 14 days, respectively. AmB in positive liposomes seemed to demonstrate the highest flux in stratum corneum (58 ng/cm²/h), while the highest flux in viable epidermis (23 ng/cm²/h) was observed in negative liposomes. AmB entrapped in charged liposomes showed sustained skin absorption. The positively charged liposome might be the best formulation for AmB, due to its higher stability than other formulations.     

Encapsulation, Stability, and In Vitro Release Characteristics of Liposomal Formulations of Stavudine (D4T)

The objective of this study was to examine the encapsulation of stavudine (d4T), an approved drug for AIDS treatment, in liposomes composed of various lipids and the in vitro release characteristics, and to evaluate the stability. The reverse phase evaporation method was used to prepare liposomes and the effect of cholesterol on drug encapsulation was studied by adding different amounts of cholesterol to a constant amount of lipid. The effect of charge of the lipid bilayer on drug encapsulation was also studied. Stearylamine or dicetylphosphate (10 mol%) were used to induce positive or negative charges, respectively. The particle size of the liposomes was measured using dynamiclightscattering. Stabilitystudies were performed by storing formulations at 4, 25, and 37 C for 12 weeks, and then subjecting them to alternate heat-cool cycles and simulated transportation conditions. Encapsulation of stavudine was found to be maximum (48%) in DSPC liposomes containing equimolar amounts of cholesterol. Encapsulation generally increased with increasing amounts of cholesterol, and also with the incorporation of both positive and negative charge. In vitro release was found to be biphasic, the release controlled by the dialysis membrane and the lipid bilayer. The release of the drug was inhibited in the presence of charge (30%), compared to neutral liposomes. Particle size distribution ranged from 0.6 mu m to 1.4 mu m and was polydisperse. Liposomes were stable with respect to the amount to drug retained for a period of 4 weeks. Beyond 4 weeks, there was a leakage of entrapped drug independent of the temperature of storage. An increase in particle size during storage was observed in the case of neutral but not charged vesicles. A high degree of encapsulation of stavudine in liposomes is feasible by reverse-phase evaporation. Liposomal formulations may be beneficial in alleviating the longterm side effects of stavudine and enhancing in vivo cellular uptake in HIV therapy.     

In vitro evaluation of enrofloxacin-loaded MLV liposomes

Fluoroquinolones are broad-spectrum antimicrobial agents that seem to reach their intracellular target site (DNA gyrase) in Escherichia coli by means of an uptake process through the outer and inner membranes. Delivery of quinolones with liposomes has many advantages than the free form of the drug. Liposomes may represent an excellent device for improving the selective transport of antibiotics in these respects. In this study, enrofloxacin-loaded multilamellar vesicles (MLVs) were prepared and the effects of formulation variables on the liposome characteristics were investigated. Liposomes were prepared by using the dry lipid film method. A number of variables, such as phospholipid (DL-alpha -phosphatidylcholine dipalmitoyl), cholesterol, enrofloxacin (ENF), stearylamine, and dicetyl phosphate molar ratios and alpha -tocopherol amounts, were studied. The liposome size, encapsulation capacity, drug release, stability, and electrophoretic mobility of ENF-loaded liposomes were determined. Using this method, spherical MLVs with high drug content could be produced. Particle size of liposomes changed between 1.63 and 3.31 micro m and liposome size was affected by all formulation variables (p < 0.05) except molar ratio of ENF. MLVs can be used as a carrier system for the controlled release of ENF. The highest encapsulation of ENF amount can be obtained using positively charged SA in the formulation and changing the formulation parameters can vary drug release patterns.     

A targeted liposome delivery system for combretastatin A4: formulation optimization through drug loading and in vitro release studies

Efficient liposomal therapeutics require high drug loading and low leakage. The objective of this study is to develop a targeted liposome delivery system for combretastatin A4 (CA4), a novel antivascular agent, with high loading and stable drug encapsulation. Liposomes composed of hydrogenated soybean phosphatidylcholine (HSPC), cholesterol, and distearoyl phosphoethanolamine-PEG-2000 conjugate (DSPE-PEG) were prepared by the lipid film hydration and extrusion process. Cyclic arginine-glycine-aspartic acid (RGD) peptides with affinity for alphav beta3-integrins overexpressed on tumor vascular endothelial cells were coupled to the distal end of polyethylene glycol (PEG) on the liposomes sterically stabilized with PEG (non-targeted liposomes; LCLs). Effect of lipid concentration, drug-to-lipid ratio, cholesterol, and DSPE-PEG content in the formulation on CA4 loading and its release from the liposomes was studied. Total liposomal CA4 levels obtained increased with increasing lipid concentration in the formulation. As the drug-to-lipid ratio increased from 10:100 to 20:100, total drug in the liposome formulation increased from 1.05+/-0.11 mg/mL to 1.55+/-0.13 mg/mL, respectively. When the drug-to-lipid ratio was further raised to 40:100, the total drug in liposome formulation did not increase, but the amount of free drug increased significantly, thereby decreasing the percent of entrapped drug. Increasing cholesterol content in the formulation decreased drug loading. In vitro drug leakage from the liposomes increased with increase in drug-to-lipid ratio or DSPE-PEG content in the formulation; whereas increasing cholesterol content of the formulation up to 30 mol-percent, decreased CA4 leakage from the liposomes. Ligand coupling to the liposome surface increased drug leakage as a function of ligand density. Optimized liposome formulation with 100 mM lipid concentration, 20:100 drug-to-lipid ratio, 30 mol-percent cholesterol, 4 mol-percent DSPE-PEG, and 1 mol-percent DSPE-PEG-maleimide content yielded 1.77+/-0.14 mg/mL liposomal CA4 with 85.70+/-1.71% of this being entrapped in the liposomes. These liposomes, with measured size of 123.84+/-41.23 nm, released no significant amount of the encapsulated drug over 48 h at 37 degrees C.     

Characterization of niosomes prepared with various nonionic surfactants for paclitaxel oral delivery

Nonionic surfactant based vesicles (niosomes) are novel drug delivery systems formed from the self‐assembly of nonionic amphiphiles in aqueous media. In the present study niosomal formulations of Paclitaxel (PCT), an antineoplastic agent, were prepared using different surfactants (Tween 20, 60, Span 20, 40, 60, Brij 76, 78, 72) by film hydration method. PCT was successfully entrapped in all of the formulations with encapsulation efficiencies ranging between 12.1 ± 1.36% and 96.6 ± 0.482%. Z‐average sizes of the niosomes were between 229.3 and 588.2 nm. Depending on the addition of the negatively charged dicetyl phosphate to the formulations negative zeta potential values were obtained. High surface charges showed that niosomes can be suspended in water well and this is beneficial for their storage and administration. PCT released from niosomes by a diffusion controlled mechanism. The slow release observed from these formulations might be beneficial for reducing the toxic side effects of PCT. The niosome preparation method was found to be repeatable in terms of size distribution, zeta potential and % drug loading values. The efficiency of niosomes to protect PCT against gastrointestinal enzymes (trypsin, chymotrypsin, and pepsin) was also evaluated for PCT oral delivery. Among all formulations, gastrointestinal stability of PCT was well preserved with Span 40 niosomes. © 2009 Wiley‐Liss, Inc. and the American Pharmacists Association J Pharm Sci 99: 2049–2060, 2010     

Effect of formulation design and freeze-drying on properties of fluconazole multilamellar liposomes

Fluconazole-entrapped multilamellar liposomes were prepared using the thin-film hydration method. The effects of cholesterol molar ratio, charge-inducing agents, and α-tocopherol acetate on encapsulation efficiency values and in vitro drug release of multilamellar liposomes were studied. Freeze-dried liposomal products were prepared with or without cryoprotectants. Results showed that incorporation of stearylamine resulted in an increased entrapment of fluconazole, whereas incorporation of dicetyl phosphate decreased the drug entrapment efficiency. The incorporation of α-tocopherol acetate into fluconazole multilamellar liposomes resulted in the increase of entrapment efficiency of fluconazole liposomes. In vitro release studies revealed that incorporation of cholesterol into multilamellar liposomal formulations decreased drug permeability from formulations. Positively charged fluconazole multilamellar liposomes gave rise to a slow release rate compared to neutral liposomes whereas negatively charged fluconazole liposomes showed a rapid release rate. Physical stability studies showed that lyophilized cake of liposomes without cryoprotectants was compact and difficult to reconstitute compared to fluffy easily reconstituted cakes upon using cryoprotectants. Fluconazole retained in freeze-dried liposomes without cryoprotectants was 63.452% compared to 91.877% using three grams of trehalose as a cryoprotectant per gram lipid in positively charged multilamellar liposomes. Physical stability studies showed superior potentials of the lyophilized product after reconstitution in comparison with those of a solution product.     

Pilocarpine hydrochloride liposomes: characterization in vitro and preliminary evaluation in vivo in rabbit eye

Liposomes containing either pilocarpine hydrochloride or pilocarpine free base were prepared by the sonication method. This manufacturing process yielded after removal of non-encapsulated solute, small multilamellar vesicles (MLV) as was confirmed by electron microscopy examinations. For an identical liposomal composition, the encapsulation capacity and the drug content of the liposomes were drastically higher for pilocarpine hydrochloride than for pilocarpine free base. Investigation of the preparative parameters revealed that increasing the initial amount of drug decreased the drug content and the encapsulation efficiency of the liposomes formed. Since fixed amounts of lipids were used, the volume sequestration rate decrease was attributed to a moderate viscosity increase of the dispersion medium. Increase of phospholipid concentration at a constant ratio of cholesterol and dicetylphosphate to phosphatidylcholine reduced the aqueous volume entrapped per mg of lipid and subsequently the pilocarpine content in the liposomes. Negatively charged liposomes gave larger rates of pilocarpine hydrochloride and aqueous volume encapsulation than neutral liposomes but, on the contrary, positively charged liposomes gave the lowest rates of pilocarpine hydrochloride and aqueous volume encapsulation. Thus, for drug carrying the same net charge as the phospholipids an increase in the surface charge density of the liposome was not only ineffective, but actually resulted in a lower drug encapsulation due to electrostatic repulsion. Preliminary in vivo results on rabbit eyes suggested that the liposomal vehicle was probably unable to improve sufficiently the corneal penetration of pilocarpine to reach satisfactory therapeutic levels when administered at lower concentrations than commonly used.     

脂质体包裹的反义寡核苷酸逆转耐甲氧西林金黄色葡萄球菌耐药性的研究

目的：用人工合成磷脂二棕榈酰磷脂酰胆碱（dipalmitoyl phosphatidylcholine，DPPC），二肉豆蔻酰磷脂酰甘油（dimyristoyl phosphatidylglycerol，DMPG）制备反义寡核苷酸阴离子脂质体并研究脂质体包裹的抑制耐甲氧西林金黄色葡萄球菌（methicillin resistant staphylococcus aureus，MRSA）耐药基因表达信号传导通路中BlaRlmRNA表达的反义寡核苷酸（antisense phosphothioate oligodeoxynucleotides，AS-ODNs）对MRSA耐药性的影响。方法：设计合成AS-ODNs；薄膜分散冻干法制备其脂质体；透射电镜观察脂质体的形态；离心纯化脂质体并用紫外分光光度计测定包封率、渗漏率；振荡法检测体外释放度；平板克隆形成实验计数菌落数CFU；微量法测定细菌生长曲线。结果：反义寡核苷酸阴离子脂质体大小均匀，为圆球体，包封率为77．38％，冷冻条件下保存1月后渗漏率为0．18％，体外释放度实验表明24h后约60％的药物从脂质体中释放，反义寡核苷酸脂质体可显著抑制MRSA生长，脂质体包裹的不同剂量的AS-ODNs中MRSA的菌落形成单位（CFU）与空白对照组比较明显减少，具有剂量依赖性，且效果明显优于未被脂质体包裹的AS-ODNs。结论：采用薄膜分散冻干法制备反义寡核苷酸阴离子脂质体，包封率较高，质量稳定，反义寡核苷酸脂质体能逆转MRSA的耐药性，效果明显优于单用AS-ODNs，可作为反义寡核苷酸进入细菌的载体。     

Radiopaque liposomes: effect of formulation conditions on encapsulation efficiency

Liposomes containing sodium ioxitalamate were prepared by sonication. Suitable amounts of purified soybean phosphatidylcholine and cholesterol were used at various molar ratios. Stearylamine or dicetylphosphate were added to this lipid composition when charged liposomes were required. After sonication and removal of unencapsulated solute, this manufacturing process yielded small multilamellar vesicles as confirmed by electron microscopy. These liposomes did not exhibit a narrow range of size distribution; the mean particle size varied from 135 to 145 nm. With respect to the efficiency of encapsulation, two parameters were distinguishable: the volume of encapsulated aqueous space per unit of lipid weight and the percentage of the contrast agent added that became encapsulated in the liposomes. Investigation of the preparative parameters revealed that increased molar ratios of cholesterol yielded higher aqueous volume and iodine contents in the liposomes, which were attributed to a reduction of the liposome permeability to the contrast agent. However, the inclusion of cholesterol into the bilayer liposomal membrane was limited, probably by solubility restrictions. Negatively and positively charged liposomes had higher rates of encapsulation than did neutral liposomes. This result was expected since efficient encapsulation of polar compounds requires formation of large aqueous spaces within the vesicles per mole of lipids. Increase of the lipid fractions at a constant, reduced the aqueous volume entrapped per millimole of lipid and, consequently, the iodine content in the liposomes. However, an increase in the initial sodium ioxitalamate concentration diminished the aqueous volume entrapped in the liposomes but increased the iodine content.     

Liposomal Formulation of a Cytokine Restraining Agent, (CRA)-HP 228: Encapsulation, Stability, and Release Characteristics

Cytokine restraining agents (CRAs) are a family of compounds having profound anti-inflammatory properties. Among them, HP 228 is a heptapeptide, containing some unnatural amino acids, with the unique ability to restrain the pathological effects of cytokines without interfering with their essential immune functions. A liposomal formulation of HP 228 was developed to protect the drug from proteolytic enzymes and to provide controlled release of the drug. The liposomes were prepared using either dimyristoyl phosphatidylcholine or dipalmitoyl phosphatidylcholine and cholesterol by the thin-film hydration method. Dicetyl phosphate was added to the lipids to provide negative charge to the liposomes. Homogeneous size distribution of multilamellar vesicles (MLVs) was achieved by extruding them through the 800-nm polycarbonate membranes. The size distribution was characterized using a submicrometer particle size analyzer. Encapsulation efficiency of HP 228 was determined by adding protamine to MLVs and separating the supernatant from the liposome protamine aggregate. Enzymatic stability of the drug was evaluated in phosphate-buffered saline, pH 7.0 and 37°C. The studies were conducted in the presence of trypsin and chymotrypsin. The encapsulation of HP 228 increased with the increase in fatty acid chain length. Encapsulation was further increased in negatively charged liposomes compared with neutral liposomes. The encapsulation efficiency was over 50%. Also, the negative charge helped in preventing the aggregation of the liposomes and promoted the electrostatic interaction between the lipid and the drug. Encapsulating the drug in the aqueous compartment of the liposomes completely protected HP 228 from trypsin and chymotrypsin. The rate of release of HP 228 was measured using a side-by-side diffusion chamber and was found to be drastically lower from the liposomes, as compared with the drug solution, making the formulation suitable for controlled release of HP 228.     

Development of liposomal capreomycin sulfate formulations: effects of formulation variables on peptide encapsulation

PURPOSE: The aim of this work was the investigation of the effects of preparation variables on drug content for the development of capreomycin sulfate (CS) liposomal formulations as potential aerosol antitubercular agents. METHODS: Dipalmitoylphosphatidylcholine (DPPC), hydrogenated phosphatidylcholine (HPC) and distearoylphosphatidylcholine (DSPC) were used for liposome preparation. A freeze-thawing method was chosen for CS encapsulation. Peptide entrapment, size and morphology were evaluated by UV spectrophotometry, photocorrelation spectroscopy (PCS) and transmission electron microscopy (TEM), respectively. A 2(3) full factorial protocol was designed to evaluate the conditions for CS encapsulation improvement. RESULTS: Peptide content ranged between 1 and 8%. Vesicles showed a narrow size distribution, with average diameters around 1 microm and a good morphology. A mathematical model was generated for each liposomal system and check point analyses revealed good agreement between experimental and predicted values. DPPC liposomes were found to provide the highest CS content. CONCLUSIONS: Peptide content was successfully increased by assessing formulation variable effects using a 2(3) factorial design that proved to be a time saving method helpful in developing new CS liposomal formulations for a possible application in aerosol antitubercular therapies.     

In Vitro andIn Vivo Studies of Different Liposomes Containing Topotecan

Liposome as a carrier of topotecan (TPT), a promising anticancer drug, has been reported in attempt to improve the stability and antitumor activity of TPT. However, the biodistribution pattern of TPT liposome in vivo and PEG-modified liposome containing TPT have not been studied systemically. In this paper, the in vitro stability and in vivo biodistribution behavior of several liposomes containing TPT with different lipid compositions and PEG-modification were studied. Compared with the 'fluid' liposome (S-Lip) composed of soybean phosphatidylcholine (SPC), the 'solid' liposome (H-Lip) composed of hydrogenated soybean phosphatidylcholine HSPC decreased the leaking efficiency of TPT from liposome and enhanced the stability of liposome in fetal bovine serum (FBS) or human blood plasma (HBP). The results of biodistribution studies in S180 tumor-bearing mice showed that liposomal encapsulation increased the concentrations of total TPT and the ratio of lactone form in plasma. Compared with free TPT, S-Lip and H-Lip resulted in 5- and 19-fold increase in the area under the curve (AUC(0-->infinity)), respectively. PEG-modified H-Lip (H-PEG) showed 3.7-fold increase in AUC(0-->infinity) compared with H-Lip, but there was no significant increase in t(1/2) and AUC(0-->infinity) for PEG-modified S-Lip (S-PEG) compared with S-Lip. Moreover, the liposomal encapsulation changed the biodistribution behavior, and H-Lip and H-PEG dramatically increased the accumulation of TPT in tumor, and the relative tumor uptake ratios were 3.4 and 4.3 compared with free drug, respectively. There was also a marked increase in the distribution of TPT in lung when the drug was encapsulated into H-Lip and H-PEG. Moreover, H-PEG decreased the accumulation of TPT in bone marrow compared with unmodified H-Lip. All these results indicated that the membrane fluidity of liposome has an important effect on in vitro stability and in vivo biodistribution pattern of liposomes containing TPT, and PEG-modified 'solid' liposome may be an efficient carrier of TPT.     

Effect of liposomes and niosomes on skin permeation of enoxacin

The skin permeation and partitioning of a fluorinated quinolone antibacterial agent, enoxacin, in liposomes and niosomes, after topical application, were elucidated in the present study. In vitro percutaneous absorption experiments were performed on nude mouse skin with Franz diffusion cells. The influence of vesicles on the physicochemical property and stability of the formulations were measured. The enhanced delivery across the skin of liposome and niosome encapsulated enoxacin had been observed after selecting the appropriate formulations. The optimized formulations could also reserve a large amount of enoxacin in the skin. A significant relationship between skin permeation and the cumulative amount of enoxacin in the skin was observed. Both permeation enhancer effect and direct vesicle fusion with stratum corneum may contribute to the permeation of enoxacin across skin. Formulation with niosomes demonstrated a higher stability after 48 h incubation compared to liposomes. The inclusion of cholesterol improved the stability of enoxacin liposomes according to the results from encapsulation and turbidity. However, adding negative charges reduced the stability of niosomes. The ability of liposomes and niosomes to modulate drug delivery without significant toxicity makes the two vesicles useful to formulate topical enoxacin.     

Effect of bovine serum albumin on the stability of methotrexate-encapsulated liposomes

The effect of bovine serum albumin (BSA) on the encapsulation efficiency and stability of liposomes containing methotrexate (MTX) having different surface charges and cholesterol contents were investigated. The encapsulation efficiency of MTX was lower and the release of MTX was faster by the addition of BSA. The leaking of MTX from lipid bilayer depends upon the BSA concentrations. These results may be derived from the interaction of BSA with lipid bilayers. The dynamic structural changes of BSA were monitored indirectly using circular dichroism spectra. Observed dynamic structural changes of BSA with liposomes are presumed to reflect the interaction of BSA with liposomes. Negatively charged liposomes have more strong interaction with BSA than neutral and positively charged liposomes. BSA attacks lipid bilayers whether it is at the inner or at the outer phase of lipid bilayer and induces leakage of entrapped MTX. Especially, negatively charged liposomes are more sensitive than others. The inclusion of cholesterol in the lipid layers inhibits the interaction of BSA with liposomes and shows protective effect against BSA-induced leakage of MTX. To endure the attacking of BSA, liposomes as drug carriers should be made using cholesterol.     

Hydrophilic gels containing chlorophyllin-loaded liposomes: development and stability evaluation

The aim of this study was to develop and characterize hydrophilic gels containing chlorophyllin(CHL)-loaded liposomes as well as to evaluate their stability. Two different CHL-loaded liposome dispersions using non-hydrogenated and hydrogenated soybean lecithin were prepared, characterized for their particle size, polydispersity index and trapping efficiency and incorporated in Carbopol 940 NF hydrogel. The gels obtained were analyzed for flow properties, pH values and CHL content. The control liposome-free gel was obtained by incorporating the CHL solution in the hydrogel. The stability of the gels was evaluated in terms of rheological properties, pH values and CHL content during 6 months' storage at 20 +/- 2 degrees C. Suitable gel formulations for topical use were obtained revealing shear-thinning plastic flow behaviour without significant thixotropy during the whole period of examination. High yield values of the samples during the whole period indicated a long-term stability of the gel formulations. The gel formulations expressed a mild acid value acceptable for topical preparations. After 6 months' storage the CHL content was highest in the gel containing non-hydrogenated lecithin liposomes, followed by the gel containing hydrogenated lecithin liposomes and liposome-free gel, indicating that the encapsulation of CHL in liposomes led to a greater stability of CHL.     

Liposomal gel with chloramphenicol: characterisation and in vitro release

The aim of our study was to develop a liposomal carrier system for the local treatment of bacterial vaginosis, capable to efficiently deliver entrapped drug during an extended period of time. Chloramphenicol was entrapped in liposomes composed of egg phosphatidylcholine/egg phosphatidylgycerol-sodium (9:1, molar ratio) and prepared by two different methods, the proliposome method and the polyol dilution method. Both liposome preparations were characterised and compared for particle size, polydispersity, entrapment efficiency and tested for in vitro stability in media that simulate human vaginal conditions (buffer pH 4.5 and vaginal fluid simulant). To achieve application viscosity of liposomes and to further improve their stability, liposomes prepared by the proliposome method were incorporated in the bioadhesive gel made of Carbopol 974P NF resin. In vitro release studies of liposomes incorporated in the gel have shown a prolonged release of entrapped chloramphenicol compared to control gel. Even after 24 hours of incubation in the vaginal fluid simulant, more than 40% of the originally entrapped drug was still retained in the gel. Storage stability studies have proven the ability of the Carbopol 974P NF gel to preserve the original size distribution of incorporated liposomes. All the performed experiments confirm the applicability of liposomes as a novel drug carrier system for the local treatment of bacterial vaginosis.     

Design and Evaluation of Liposomal Formulation of Pilocarpine Nitrate

Prolonged release drug delivery system of pilocarpine nitrate was made by optimizing thin layer film hydration method. Egg phosphatidylcholine and cholesterol were used to make multilamellar vesicles. Effects of charges over the vesicles were studied by incorporating dicetylphosphate and stearylamine. Various factors, which may affect the size, shape, encapsulation efficiency and release rate, were studied. Liposomes in the size range 0.2 to 1 µm were obtained by optimizing the process. Encapsulation efficiency of neutral, positive and negatively charged liposomes were found to be 32.5, 35.4 and 34.2 percent, respectively. In vitro drug release rate was studied on specially designed model. Biological response in terms of reduction in intraocular pressure was observed on rabbit eyes. Pilocarpine nitrate liposomes were lyophilized and stability studies were conducted.     

Improved Permeability of Acyclovir: Optimization of Mucoadhesive Liposomes Using the Phospholipid Vesicle-Based Permeation Assay

The antiviral drug acyclovir (ACV) suffers from poor solubility both in lipophilic and hydrophilic environment, leading to low and highly variable bioavailability. To overcome these limitations, this study aimed at designing mucoadhesive ACV-containing liposomes to improve its permeability. Liposomes were prepared from egg phosphatidylcholine (E-PC) and E-PC/egg phosphatidylglycerol (E-PC/E-PG) and their surfaces coated with Carbopol. All liposomal formulations were fully characterized and for the first time the phospholipid vesicle-based permeation assay (PVPA) was used for testing in vitro permeability of drug from mucoadhesive liposome formulations. The negatively charged E-PC/E-PG liposomes could encapsulate more ACV than neutral E-PC liposomes. Coating with Carbopol increased the entrapment in the neutral E-PC liposomes. The incorporation of ACV into liposomes exhibited significant increase in its in vitro permeability, compared with its aqueous solution. The neutral E-PC liposomal formulations exhibited higher ACV permeability values compared with charged E-PC/E-PG formulations. Coating with Carbopol significantly enhanced the permeability from the E-PC/E-PG liposomes, as well as sonicated E-PC liposomes, which showed the highest permeability of all tested formulations. The increased permeability was according to the formulations’ mucoadhesive properties. This indicates that the PVPA is suitable to distinguish between permeability of ACV from different mucoadhesive liposome formulations developed for various routes of administration.     

Encapsulation,Stability and In-vitro Release Characteristics of Liposomal Formulations of Colchicine

The severe toxicity and low therapeutic index of colchicine limit its therapeutic use. Encapsulation in liposomes might reduce these toxic effects. The objective of this study was to determine the factors influencing encapsulation of colchicine in liposomes and to optimize the encapsulation parameters. Colchicine was encapsulated in multilamellar liposomes and large unilamellar liposomes prepared using various phospholipids. The effects of method of preparation, type of vesicle, charge, and concentration of cholesterol on encapsulation of colchicine in liposomes were investigated. Also, stability of colchicine under stress conditions and at various temperatures, and in-vitro release characteristics were determined. A significant difference in encapsulation of colchicine in multilamellar liposomes was observed when prepared by two different methods. Induction of charge on the liposome surface increased encapsulation of colchicine in multilamellar liposomes, but did not affect large unilamellar liposomes. The liposome preparations could withstand simulated transport conditions and frequent changes in temperature. Particle size and concentration of colchicine did not change significantly during storage at various temperatures for six months. In order to retain encapsulated colchicine in liposomes, storage at or below room temperature was found to be suitable. In-vitro release of colchicine from large unilamellar liposomes was biphasic and was influenced by two rate-limiting barriers, the dialysis membrane and the liposome bi-layers. For optimum encapsulation and stability of colchicine liposomes were prepared from a mixture of 1,2-distearoyl-sn-glycero-3-phosphocholine, cholesterol and either stearylamine or dicetyl phosphate.     

The effect of different lipid components on the in vitro stability and release kinetics of liposome formulations

Liposomes are colloidal carriers that form when certain (phospho)lipid molecules are hydrated in an aqueous media with some energy input. The ideal liposome formulation with optimum stability will improve drug delivery by decreasing the required dose and increasing the efficacy of the entrapped drug at the target organ or tissue. The most important parameter of interest in this article was to compare the efficacy of three different liposomes formulated with DSPC, DMPC, and DPPC, all saturated neutral phospholipids with different acyl chain lengths and transition temperatures. DMPC has a phase transition temperature (Tc) below 37°C, whereas the other two phospholipids possess Tcs above the physiological temperature. These lipids were then added to a cholesterol concentration of 21% to optimize the stability of the vesicles. The liposomes were prepared by a sonication and incubated in phosphate buffered saline (PBS) at 4°C and 37°C. The encapsulation efficiency, initial size, and drug retention of the vesicles were tested over a 48-hr period employing radiolabeled inulin as a model drug. The phase transition temperature of liposomes, which depends on the Tc of the constituent lipids, was an important factor in liposome stability. Of all the liposomes tested, the greatest encapsulation efficiency was found for the DSPC liposomes (2.95%) that also had the greatest drug retention over 48 hr at both 4°C (87.1 ± 6.8%) and 37°C (85.2 ± 10.1%), none of these values being significantly different from time zero. The lowest drug retention was found for DMPC liposomes for which a significant difference in drug retention was seen after only 15 min at both 4°C (47.3 ± 6.9%) and 37°C (53.8 ± 4.3%). The DPPC liposomes showed a significant difference in drug retention after 3 hr at 4°C (62.1 ± 8.2%) and after 24 hr at 37°C (60.8 ± 8.9%). Following the initial drop at certain time intervals a plateau was reached for all of the liposome formulations after which no significant difference in drug retention was observed. In conclusion, liposomes with higher transition temperatures appear to be more stable in PBS either at 4°C or 37°C, indicating that the increase in acyl chain length (and therefore transition temperature) is directly proportional to stability.