Liposomal boron delivery system for neutron capture therapy

Boron neutron capture therapy (BNCT) is a binary cancer treatment based on the nuclear reaction of two essentially nontoxic species, (10)B and thermal neutrons. High accumulation and selective delivery of boron into tumor tissue are the most important requirements to achieve efficient neutron capture therapy of cancers. This review focuses on the liposomal boron delivery system (BDS) as a recent promising approach that meets these requirements for BNCT. BDS involves two strategies: (1) encapsulation of boron in the aqueous core of liposomes and (2) accumulation of boron in the liposomal bilayer. Various boronated liposomes have been developed and significant boron accumulation into tumor tissue with high tumor/blood boron ratios has been achieved by BDS.     

Minimally invasive cytoselective radiation therapy using boron neutron capture reaction

The cell-killing effect of boron neutron capture therapy (BNCT) is due to the nuclear reaction of two essentially nontoxic species, boron-10 ((10)B) and thermal neutrons, whose destructive effect is well observed in boron-loaded tissues. High accumulation and selective delivery of boron into tumor tissue are the most important requirements to achieve efficient neutron capture therapy of cancers. This review focuses on liposomal boron delivery system (BDS) as a recent promising approach that meet these requirements for BNCT. BDS involves two strategies: (1) encapsulation of boron in the aqueous core of liposomes and (2) accumulation of boron in the liposomal bilayer. In this review, recent development of liposomal boron delivery system is summarized.     

Effect of preparation techniques on the properties of curcumin liposomes: characterization of size, release and cytotoxicity on a squamous oral carcinoma cell line

Curcumin, a chemopreventive agent, was incorporated into liposomes using different preparation techniques and characterized for parameters such as drug loading efficiency, size, in vitro release and in vitro cytotoxicity on a squamous carcinoma cell line. Liposomes were prepared with different methods - thin layer evaporation, ethanol injection and sonication methods, respectively, obtaining, multilamellar vesicles (MLVs) and small unilamellar vesicles (SUVs). The preparation techniques influenced the size, encapsulation efficiency, in vitro release and cytotoxicity profiles. Encapsulation efficiency increased with decrease in drug to lipid ratio in the following rank order - MLVs > SUVs > ethanol injection vesicles. In vitro release and in vitro cytotoxicity were a function of the size of vesicle, which varied depending on the preparation technique. Based on these results, it can be concluded that different liposomal formulations can be employed to achieve unique in vivo needs in cancer chemotherapy.     

离子载体A23187介导pH梯度法制备重酒石酸长春瑞滨长循环脂质体

目的:采用A23187制备重酒石酸长春瑞滨长循环脂质体,优化了处方工艺,并考察了含量、包封率、药脂比和体外释放等检测指标。方法:采用A23187介导的pH梯度法制备了重酒石酸长春瑞滨脂质体;用HPLC法检测了脂质体中重酒石酸长春瑞滨的含量和脂质(HSPC)的含量,考察了药脂比;采用阳离子交换树脂分离脂质体和游离药物,HPLC法检测包封率;以4 mmol.L-1NH4Cl-PBS(pH 7.4)为体外释放介质考察了脂质体的体外释放行为。结果:重酒石酸长春瑞滨脂质体包封率为96.1%,药脂比为1∶5(w/w);高药脂比有利于延长药物体外释放的时间。结论:采用A23187介导的pH梯度法制备重酒石酸长春瑞滨脂质体工艺可行、载药量大、包封率高;所建立体外释放的检测方法快速、准确。     

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.     

去氢骆驼蓬碱脂质体的制备和体外释放特性

目的：研究去氢骆驼蓬碱（harmine,HM）脂质体的制备工艺和体外释放特性。方法：运用薄膜分散-pH值梯度法制备HM．脂质体以及高速离心法分离脂质体与游离药物,并测定其包封率;借助综合评分法,评价其粒径、多分散系数、包封率、载药量指标;运用正交优化实验法考察磷脂-胆固醇与药-脂比、超声时间、外相pH值对脂质体的影响,述选最优工艺处方,评价脂质体与原料药的体外释放情况。结果：最优处方因素为磷脂-胆固醇比值为4：1,超声时间为300S,药-脂比值为1：5,外相pH值为6,8,即X13X23X32X43,经实验验证其粒径为（155.0±14．5）nm,多分散系数为（0．148±0．011）,包封率为（80．90±0．01）％,载药量为（11．16±0．01）％;其原料药0．5h累积释放百分比大于50％,不到2h已全部释放,而优化后的脂质体在1h内其累积释放百分比大于50％,4h后释放完成。结论：采用薄膜分散-pH值梯度法,以最优处方制得HM-脂质体,其粒径大小适中、形态均匀,包封率和载药量相对较高,体外释放显示具有较好的缓释特性。     

The Preparation of Norfloxacin-loaded Liposomes and their In-vitro Evaluation in Pig's Eye

The effectiveness of norfloxacin as an antibacterial agent in ophthalmology is limited by poor drug delivery and limited ocular bioavailability. Liposomes containing norfloxacin have been prepared from different phospholipids using a novel technique with an encapsulation efficiency sixteen times greater than that of a conventional film method. The in-vitro release of the norfloxacin and the transcorneal characteristics of the liposomes have been evaluated. Differential scanning calorimetry was used to determine the interaction occurring between liposomes and cornea. The release of liposome-entrapped norfloxacin was affected by the pH of the environment. In the in-vitro corneal perfusion studies, norfloxacin-loaded liposome was transferred through the cornea at a slower rate than was the free drug. Norfloxacin-loaded liposomes were accumulated primarily in the cornea. The drug corneal retention of the lipids increased in the order dirnyristoyl-L-α-phosphatidylcholine < dipalmitoyl-L-α-phospha-tidylcholine < distearoyl-L-α-phosphatidylcholine. In the corneal drug-elimination study, liposomal norfloxacin increased the loading of the drug in cornea; the maximum value of the loading occurred 5 h after dosing. The drainage of liposomes from the cornea was somewhat slower than the solution form. Accumulation of norfloxacin in the cornea was greater for the liposome-entrapped drug. The results suggest that norfloxacin-loaded liposomes are absorbed by the cornea via endocytosis.     

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.     

Preparation and in vitro evaluation of liposomal chloroquine diphosphate loaded by a transmembrane pH-gradient method

This study developed an active loading method for encapsulating chloroquine diphosphate (CQ) into liposomes. The effects of different formulation factors on the encapsulation efficiency (EE) and the size of CQ liposomes were investigated. These factors included the internal phase of liposomes, the external phase of liposomes, the ratio of drug to soybean phosphatidylcholine (drug/SPC), the ratio of cholesterol to soybean phosphatidylcholine (Chol/SPC), and the incubation temperature and time. The EE (93%) was obtained when using drug/SPC (1:50 mass ratio), SPC/Chol (1:5 mass ratio) at 0.10M citrate-sodium citrate buffer (pH 3.6). As 5mol% methoxypoly(ethylene glycol)(2000) cholesteryl succinate (CHS-PEG(2000)) or distearoyl phosphatidylethanolamine-poly (ethylene glycol)(2000) (DSPE-PEG(2000)) was added, the size of particle was reduced and the EE was improved. Freeze-drying with 5% trehalose as a cryoprotectant was carried out to achieve long-term stability. The drug release studies were performed in vitro simulating the desired application conditions, such as physiological fluids (pH 7.4), tumor tissues (pH 6.5) and endosomal compartments (pH 5.5). The release of CQ from the liposomes prepared via remote loading showed the significant pH-sensitivity and retention properties, which favored the application of liposomal CQ at tumor tissues and endosomal compartments.     

Development and physico-chemical characterization of a liposomal formulation of istaroxime

Istaroxime, an investigational new drug that targets defective Ca²⁺ cycling without compromising cardiac efficiency, may represent a promising and safe treatment of both acute and chronic heart failure. Even though the compound demonstrated good tolerability in a phase I/II safety study, symptoms related to the gastro-intestinal tract and pain at the injection site were reported as the most frequent side effects. The aim of this study was to encapsulate istaroxime in a drug delivery system (DDS) that could minimize the pain perceived upon administration. The DDS was designed to be quickly destabilized in plasma, in order to minimize alteration of the pharmacokinetic profile of istaroxime. To meet those requirements, a balance between the encapsulation efficiency and the release rate was sought. Transmembrane pH-gradient liposomes formulated with different phosphatidylcholines were investigated as vehicles for an efficient active drug loading. Poly(ethylene glycol)–660-hydroxystearate (PEG–HS) was chosen as excipient to modulate the bilayer fluidity and the release properties of the liposomes. A fast and efficient encapsulation was obtained by modulating the drug-to-lipid ratio, the amount of PEG–HS, and the incubation temperature. High encapsulation efficiency was achieved by incubating the drug with liposomal dispersions at room temperature for 10 min. Almost complete release was obtained in physiological conditions in less than 10 min, suggesting a model formulation potentially useful for drugs presenting similar features and side effects.     

An update on liposomes in drug delivery: a patent review (2014-2018)

ABSTRACT

Introduction: Pharmacotherapy is limited by the inefficient drug targeting of non-healthy cells/tissues. In this pharmacological landscape, liposomes are contributing to the impulse given by Nanotechnology to optimize drug therapy.

Areas covered: The analysis of the state-of-the-art in liposomal formulations for drug delivery purposes have underlined that lately published patents (since 2014) are exploring alternative compositions and ways to optimize the stability and drug loading content/release profile. These improvements are complemented by improved long-circulating structures and further liposome functionalizations, which have definitively opened the road for the (co-)delivery of therapeutics to the site of action. Liposomes are also contributing to new drug delivery approaches involving the generation of extracellular vesicles by targeted cells, while opening new ways to combine disease diagnosis and therapy (theranosis).

Expert opinion: Patent publications on liposomal formulations have expanded new ways in drug delivery. New lipid compositions and strategies to optimize stability and drug vehiculization capabilities have settle solid pillars in liposome fabrication. Despite, their architecture has been satisfactorily adapted for combining passive and active drug targeting concepts, new inputs of liposomes into the disease arena should answer for: a simple/scalable/cost-effective formulation; a safe/stable/controllable formulation meeting quality control regulations; and, a confirmed therapeutic efficiency in clinical investigations.     

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.     

Liposomal Formulations of Inflammatory Bowel Disease Drugs: Local <Emphasis Type="BoldItalic">versus</Emphasis> Systemic Drug Delivery in a Rat Model

Purpose Based on adherence to intestinal mucosa, intralumenally administered liposomal formulations of 5-aminosalicylate (5-ASA) and 6-mercaptopurine (6-MP) were studied for their potential to enhance local drug delivery to intestinal tissue for the treatment of inflammatory bowel disease.Methods 5-ASA was encapsulated in standard phospholipid liposomes while 6-MP required encapsulation in nonphospholipid liposomes to obtain equivalent drug loading. Encapsulation efficiency was measured by size-exclusion chromatography/high-performance liquid chromatogtaphy (HPLC). Liposomal formulations or solution of the drugs were injected into unligated jejunum to compare pharmacokinetics and into ligated loops of rat ileum and colon to evaluate local delivery. Dextran sulfate and acetic acid induced colitis were used as models of lower intestinal inflammation. Plasma, tissue and luminal drug and metabolite levels were measured by liquid scintillation counting or HPLC.Results Encapsulation efficiency of 6-MP was dependent on lipid content and composition. While liposomal encapsulation significantly reduced systemic absorption of 5-ASA this was not the case for 6-MP. Liposomal adherence to intestinal tissue resulted in increased tissue levels for 5-ASA; however, 6-MP local tissue levels were not improved compared to solution drug.Conclusions Nonphospholipid liposomes optimize encapsulation of 6-MP. While liposomal formulations show potential for local drug delivery to diseased bowel, drug physicochemical properties, absorption, and metabolic profiles dictate tissue-targeting potential. Liposomes reduce systemic availability from paracellular absorption of hydrophilic 5-ASA, but fail to improve local tissue delivery of 6-MP, a molecule absorbed by passive membrane permeation that undergoes extensive first- pass metabolism.     

Specific features of drug encapsulation in liposomes (A review)

Liposomes are hollow particles, the internal space of which is bounded by a lipid membrane. Liposomes are promising drug delivery systems for organs and tissues because of their colloidal properties, controlled size, surface characteristics, membrane action, and biocompatibility. Liposomal drugs have found wide use in the diagnosis and chemotherapy of cancer, vaccinology, ophthalmology, pulmonology, and the treatment of other pathologies. This review describes the methods of encapsulation of biologically active compounds with various physicochemical properties in liposomes, which is very important for the production of liposomal drugs.     

Novel sulfobutyl ether cyclodextrin gradient leads to highly active liposomal irinotecan formulation

Objectives Liposomal delivery of irinotecan could provide protection against drug hydrolysis, deliver more active lactone form to tumours and prolong irinotecan exposure time. Nevertheless, conventional drug‐loading technologies have typically resulted in undesired drug retention properties. To resolve the problem, a modified gradient loading method was developed and the resulting formulations were evaluated in a systemic manner. Methods Irinotecan was loaded into liposomes using a novel sulfobutyl ether beta‐cyclodextrin (sbe‐CD) gradient. The effect of drug‐to‐lipid ratio (D/L) and polyethylene glycol (PEG) grafting density were investigated. Drug release experiments were performed in ammonium‐containing medium based on the fluorescence dequenching phenomenon of irinotecan. Pharmacokinetic studies were performed in normal balb/c mice treated with different formulations. To compare the anti‐tumour effect of different formulations, an RM‐1 prostate cancer model was used. Acute toxicity studies were performed in healthy female c57 mice. Key findings Irinotecan could be encapsulated into liposomes with > 90% loading efficiency at a high drug‐to‐lipid mass ratio (> 0.5). In‐vitro release experiments revealed that sbe‐CD anion was more able to retain irinotecan than sulfate. Moreover, the elevated D/L ratio elicited decreased drug release kinetics. Both trends had also been observed when the effects of anions and D/L ratio on half‐life of irinotecan were assessed. Pegylated liposomal irinotecan loaded with sbe‐CD/triethylammonium gradient had irinotecan half‐life values ranging from 9.4 to 13.1 h, surpassing vesicles prepared by the triethylammonium sulfate method (～4.5 h). In the RM‐1 tumour model, all the liposomal irinotecan formulations were more therapeutically active than free irinotecan and the formulation with a high D/L ratio was the most efficacious. Moreover, the high D/L formulation might be less toxic than free irinotecan based on acute toxicity studies. Conclusions The novel sbe‐CD gradient could mediate effective irinotecan loading and improve irinotecan retention, thus resulting in highly active liposomal irinotecan formulations. The improvement in drug retention might be associated with the formation of complicated aggregates inside vesicles.     

Tamoxifen citrate encapsulated sustained release liposomes: preparation and evaluation of physicochemical properties

The present study was designed for the development of a stable sustained release liposomal drug delivery system for tamoxifen citrate (TC) using soya phosphatidylcholine (SPC), cholesterol (CH) and span 20 as main ingredients. Liposomes were prepared by formation of thin lipid film followed by hydration. The mean vesicle diameter was found to be 203.5 ± 19.5 nm with 21% of the liposomal population having average diameter below 76.72 ± 6.7 nm. There was a good vesicular distribution with the polydispersity index of 0.442 ± 0.03. The maximum loading of drug was determined to be 53.60% of the initial amount that is 34.58 μg of drug per mg of lipid. Amongst the different storage conditions, liposomes stored at 2–8°C were found to be most stable and only 4% of the drug was lost over the storage period of 5 weeks. In vitro release studies of liposomes showed that 50% of drug was released within 3 hours (h) whereas 95% drug was released in 30 h. This indicates the usefulness of the liposomal delivery system for sustaining the in vitro release of tamoxifen citrate.     

BIOPHARMACEUTICAL EVALUATION OF THE LIPOSOMES PREPARED BY REHYDRATION OF FREEZE-DRIED EMPTY LIPOSOMES (FDELs) WITH AN AQUEOUS SOLUTION OF A DRUG

We have evaluated a method for preparation of a dispersion of liposomes encapsulating a drug, namely rehydration of freeze-dried empty (not containing drug) liposomes with an aqueous drug solution (FDEL method). In the present study, we characterized and compared this method with the conventional method using a lipid composition of DPPC–DPPG–cholesterol in a molar ratio of 27:3:20. Two hydrophilic compounds, [³H]-inulin and [³H]-mannitol, were used as model drugs. Liposomal preparations by the FDEL method had an encapsulation efficiency of 2.9 and 6.7% for [³H]-inulin and [³H]-mannitol, respectively, when rehydrated and incubated at 70 °C. Since non-specific adsorption of these markers to liposomal membrane is negligible, this method produces liposomes which encapsulate a drug in the intravesicular space. One-tenth of the marker encapsulated in the liposomes prepared by the FDEL method (F-liposomes) was released very rapidly on incubation with rat plasma, followed by the slow release of the remaining fraction thereafter. No such rapid-release phase was observed for the liposomes prepared by the conventional method (C-liposomes). This suggests the existence of two types of encapsulation, loose encapsulation and tight encapsulation, in F-liposomes at least. Pharmacokinetic parameters of marker encapsulated tightly in F-liposomes were comparable to those in C-liposomes. It is likely that amphipathic drugs such as doxorubicin are incorporated into liposomes more easily than inulin and mannitol when formulated by the FDEL method. These results therefore suggest that the FDEL method is useful in the preparation of a liposomal formulation of a drug.     

Development of topotecan loaded lipid nanoparticles for chemical stabilization and prolonged release

Topotecan is an important cytotoxic drug that has gained broad acceptance in clinical use for the treatment of refractory ovarian and small-cell lung cancer. The lactone active form of topotecan can be hydrolyzed in vivo, decreasing the drug’s therapeutic efficacy. Lipid encapsulation may promote in vivo stabilization by removing topotecan from aqueous media. Earlier reports of topotecan lipid nanoencapsulation have focused on liposomal encapsulation; however, the higher stability and cost-effectiveness of solid lipid nanoparticles (SLN) highlight the potential of these nanoparticles as an advantageous carrier for topotecan. The initial motivation for this work was to develop, for the first time, solid lipid nanoparticles and nanostructured lipid carriers (NLC) with a high drug loading for topotecan. A microemulsion technique was employed to prepare SLNs and NLCs and produced homogeneous, small size, negatively charged lipid nanoparticles with high entrapment efficiency and satisfactory drug loading. However, low recovery of topotecan was observed when the microemulsion temperature was high and in order to obtain high quality nanoparticles, and precise control of the microemulsion temperature is critical. Nanoencapsulation sustained topotecan release and improved its chemical stability and cytotoxicity. Surprisingly, there were no significant differences between the NLCs and SLNs, and both are potential carriers for topotecan delivery.     

Curcumin-loaded γ-cyclodextrin liposomal nanoparticles as delivery vehicles for osteosarcoma

The delivery of curcumin, a broad-spectrum anticancer drug, has been explored in the form of liposomal nanoparticles to treat osteosarcoma (OS). Curcumin is water insoluble and an effective delivery route is through encapsulation in cyclodextrins followed by a second encapsulation in liposomes. Liposomal curcumin's potential was evaluated against cancer models of mesenchymal (OS) and epithelial origin (breast cancer). The resulting 2-Hydroxypropyl-γ-cyclodextrin/curcumin - liposome complex shows promising anticancer potential both in vitro and in vivo against KHOS OS cell line and MCF-7 breast cancer cell line. An interesting aspect is that liposomal curcumin initiates the caspase cascade that leads to apoptotic cell death in vitro in comparison with DMSO-curcumin induced autophagic cell death. In addition, the efficiency of the liposomal curcumin formulation was confirmed in vivo using a xenograft OS model. Curcumin-loaded γ-cyclodextrin liposomes indicate significant potential as delivery vehicles for the treatment of cancers of different tissue origin. FROM THE CLINICAL EDITOR: Curcumin-loaded γ-cyclodextrin liposomes were demonstrated in vitro to have significant potential as delivery vehicles for the treatment of cancers of mesenchymal and epithelial origin. Differences between mechanisms of cell death were also evaluated.     

Effect of various formulation variables on the encapsulation and stability of dibucaine base in multilamellar vesicles

Formulation of local anesthetics in liposomal topical drug delivery system could provide a sustained and localized anesthesia. The aim of this study was to develop a liposomal dibucaine base (DB) local anesthetic delivery system. DB-loaded multilamellar vesicles (MLVs) were prepared through varying lipid composition, induced charge and pH of the hydration medium. Liposomes were characterized for morphology, size, entrapment efficiency (EE), in vitro drug release and stability including leakage stability. The percentage of drug entrapped in liposomes was found to be hydration medium pH dependent and charge dependent and more pronounced for negatively charged liposomes prepared using hydration medium of pH 9. In vitro release studies of liposomes have shown a sustained release of entrapped dibucaine compared to control solution. Results revealed that adjusting the various formulation variables of dibucaine base MLVs could yield stable and effective topical liposomal local anesthetic formulations.