Liposomal drug delivery systems: an update review

The discovery of liposome or lipid vesicle emerged from self forming enclosed lipid bi-layer upon hydration; liposome drug delivery systems have played a significant role in formulation of potent drug to improve therapeutics. Recently the liposome formulations are targeted to reduce toxicity and increase accumulation at the target site. There are several new methods of liposome preparation based on lipid drug interaction and liposome disposition mechanism including the inhibition of rapid clearance of liposome by controlling particle size, charge and surface hydration. Most clinical applications of liposomal drug delivery are targeting to tissue with or without expression of target recognition molecules on lipid membrane. The liposomes are characterized with respect to physical, chemical and biological parameters. The sizing of liposome is also critical parameter which helps characterize the liposome which is usually performed by sequential extrusion at relatively low pressure through polycarbonate membrane (PCM). This mode of drug delivery lends more safety and efficacy to administration of several classes of drugs like antiviral, antifungal, antimicrobial, vaccines, anti-tubercular drugs and gene therapeutics. Present applications of the liposomes are in the immunology, dermatology, vaccine adjuvant, eye disorders, brain targeting, infective disease and in tumour therapy. The new developments in this field are the specific binding properties of a drug-carrying liposome to a target cell such as a tumor cell and specific molecules in the body (antibodies, proteins, peptides etc.); stealth liposomes which are especially being used as carriers for hydrophilic (water soluble) anticancer drugs like doxorubicin, mitoxantrone; and bisphosphonate-liposome mediated depletion of macrophages. This review would be a help to the researchers working in the area of liposomal drug delivery.     

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.     

Liposomal drug delivery systems--clinical applications

Liposomes have been widely investigated since 1970 as drug carriers for improving the delivery of therapeutic agents to specific sites in the body. As a result, numerous improvements have been made, thus making this technology potentially useful for the treatment of certain diseases in the clinics. The success of liposomes as drug carriers has been reflected in a number of liposome-based formulations, which are commercially available or are currently undergoing clinical trials. The current pharmaceutical preparations of liposome-based therapeutic systems mainly result from our understanding of lipid-drug interactions and liposome disposition mechanisms. The insight gained from clinical use of liposome drug delivery systems can now be integrated to design liposomes that can be targeted on tissues, cells or intracellular compartments with or without expression of target recognition molecules on liposome membranes. This review is mainly focused on the diseases that have attracted most attention with respect to liposomal drug delivery and have therefore yielded most progress, namely cancer, antibacterial and antifungal disorders. In addition, increased gene transfer efficiencies could be obtained by appropriate selection of the gene transfer vector and mode of delivery.     

Emerging Research and Clinical Development Trends of Liposome and Lipid Nanoparticle Drug Delivery Systems

Liposomes are spherical-enclosed membrane vesicles mainly constructed with lipids. Lipid nanoparticles are loaded with therapeutics and may not contain an enclosed bilayer. The majority of those clinically approved have diameters of 50–300 nm. The growing interest in nanomedicine has fueled lipid–drug and lipid–protein studies, which provide a foundation for developing lipid particles that improve drug potency and reduce off-target effects. Integrating advances in lipid membrane research has enabled therapeutic development. At present, about 600 clinical trials involve lipid particle drug delivery systems. Greater understanding of pharmacokinetics, biodistribution, and disposition of lipid–drug particles facilitated particle surface hydration technology (with polyethylene glycol) to reduce rapid clearance and provide sufficient blood circulation time for drug to reach target tissues and cells. Surface hydration enabled the liposome-encapsulated cancer drug doxorubicin (Doxil) to gain clinical approval in 1995. Fifteen lipidic therapeutics are now clinically approved. Although much research involves attaching lipid particles to ligands selective for occult cells and tissues, preparation procedures are often complex and pose scale-up challenges. With emerging knowledge in drug target and lipid–drug distribution in the body, a systems approach that integrates knowledge to design and scale lipid–drug particles may further advance translation of these systems to improve therapeutic safety and efficacy.     

Recent advances in liposome technologies and their applications for systemic gene delivery

The recent clinical successes experienced by liposomal drug delivery systems stem from the ability to produce well-defined liposomes that can be composed of a wide variety of lipids, have high drug-trapping efficiencies and have a narrow size distribution, averaging less than 100 nm in diameter. Agents that prolong the circulation lifetime of liposomes, enhance the delivery of liposomal drugs to specific target cells, or enhance the ability of liposomes to deliver drugs intracellularly can be incorporated to further increase the therapeutic activity. The physical and chemical requirements for optimum liposome drug delivery systems will likely apply to lipid-based gene delivery systems. As a result, the development of liposomal delivery systems for systemic gene delivery should follow similar strategies.     

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.     

Real-time Imaging and Quantification of Brain Delivery of Liposomes

Abstract The surgical delivery of therapeutic agents into the parenchyma of the brain is problematic because it has been virtually impossible to know with any certainty where infused material is going, and how much to infuse. We have started to use liposomes loaded with Gadoteridol (GDL) as a tracer that allows us to follow infusions in real-time on magnetic resonance imaging (MRI). MRI allows precise tracking and measurement of liposomes loaded with markers and therapeutics. This review provides an overview of real-time delivery of liposomes to the central nervous system (CNS), and discusses the technical aspects of delivery, liposomes as colloidal systems of delivery, real-time distribution of liposomes in CNS, and quantification of liposome distribution. Our data suggests that real-time monitoring of liposomal drug infusion is likely to improve outcomes of clinical trials where convection-enhanced delivery (CED) is being used to target drugs to specific brain structures through limitation of systemic toxicity and reduction of side effects. This review is a summary of work done by our group over the past four years.     

植物甾醇对其所构建脂质体膜特性的影响

脂质体作为一种新型的药物载体，具有提高疗效，降低毒性和保护被包载的药物等多种功能。很多关于脂质体体系构建的研究都是采用一定比例的磷脂和胆固醇作为膜材，利用胆固醇可改善脂质双层流动性的特性制备脂质体。植物甾醇是一种天然活性物质，具有重要的生理功能，结构与胆固醇相似。现综述近年来国内外含植物甾醇脂质体构建方面的研究进展，详细分析植物甾醇对构建脂质体膜各方面特性的影响，包括通透性、流动性、稳定性、刚性等。     

Liposome-based depot injection technologies

Liposomes have proven to be versatile carriers for the delivery of drugs. These carriers are biocompatible, since they are generally made from lipids commonly found in biologic systems and are biodegradable by the usual metabolic pathways. A sustained drug delivery system is useful when the efficacy of drugs is limited by the inability to maintain therapeutic concentrations. Furthermore, a depot delivery system can offer important advantages in the clinic, such as significantly reducing dose frequency and providing efficacy without toxicity. Because of their small size (<5μ.m), conventional liposomes (unilamellar and multilamellar) are limited in their ability to provide depot delivery of drugs when administered subcutaneously or intramuscularly. The small size of these liposomes results in relatively fast clearance from the injection site and a short duration of delivery, typically 1–4 days. Multivesicular liposomes (MVLs) are distinct from conventional liposomes in composition, structure, and size and are the only class of commercial liposomes that have demonstrated depot delivery of both small molecule and protein/peptide drugs. These MVLs are characterized by the presence of a continuous bilayer membrane, with numerous internal aqueous compartments that are contiguous and separated by bilayer septums. As a result of their larger size (median diameter typically 10–30μ.m), these MVLs are not rapidly cleared by tissue macrophages and can act as a drug depot providing slow release of drugs delivered through different routes of administration. Moreover, the biocompatibility and biodegradability of the MVL lipid matrix allows for the sustained delivery of drugs to sensitive areas. The unique architecture of MVLs provides high drug loading of water-soluble drugs, reasonable stability during storage, and control over the drug-release rate. Furthermore, the lipid composition of MVLs can be altered to deliver therapeutics over periods ranging from a few days to a month, in order to meet specific therapeutic needs. The capability of altering the rate of drug release from MVLs by varying the lipid composition provides a great deal of versatility for controlled delivery of a wide variety of therapeutics. This article reviews depot delivery with conventional liposomes, demonstrates through several examples the sustained depot delivery of small and macromolecular drugs using MVLs, and summarizes some novel delivery systems that combine liposomes with polymeric matrices and have the potential to expand the platform of liposomal depot delivery.     

Liposomes a vesicular nanocarrier: potential advancements in cancer chemotherapy

The indispensable obligation behind the successful therapy of a disease is to deliver the effective drug/bioactive concentration with sustained release manner at the diseased organs without any exposure to the healthy tissues. Novel drug-delivery systems increase the concentration and persistence of drug at the vicinity of the target site and thereby minimize the undesired side effects of the drug to the normal tissues of body. With advances in nanotechnology, several new drug delivery approaches have become available that may fulfil the requirement of safe and effective drug therapy. Among these techniques, vesicular drug-delivery systems, particularly liposomes, are under rigorous research for their applicability to deliver FDA-approved and newer drugs. Liposomes have been widely investigated as one of the most widely used nanocarriers in cancer therapy and have shown their potential in spatial and temporal release of bioactive agents for the effective treatment of various life-threatening diseases, including cancer. Various targeted and triggered-release approaches of bioactive substances using liposomes further improve the applicability of liposomes in cancer therapeutics. Thus, keeping these points in view, the present review has been focussed on application of liposomes for development of liposome technology and its novel applications for effective cancer therapy.     

High-affinity targeting of biotin-labeled liposomes to streptavidin-conjugated ligands

Cell-specific delivery of drug-loaded liposomal carrier systems can be achieved through the use of liposomes with covalently attached proteins. For such targeting strategies to be successful a number of potential difficulties, related to the preparation of the liposomes as well as optimization of properties that maximize in vivo access and binding to a defined target cell population, must be overcome. The studies summarized here have attempted to identify specific factors that will promote binding of targeted liposomes to defined target surfaces. Liposomes containing biotinylated phospha-tidylethanolamine were used to demonstrate that the avidity of a targeted liposome for streptavidin-coated ELISA plates and cells is influenced by liposome lipid composition, the amount of targeting molecule present per liposome, the nature of the targeting ligand, and the target surface. Specifically, it is demonstrated that the three most important factors (in order of importance) controlling the apparent affinity of targeted liposomes are (1) target ligand concentration in the liposomal membrane; (2) the presence of a spacer grout between the biotin and the phospholipid headgroup; and (3) the addition of cholesterol. Other less important factors that influence target liposome binding include whether the target ligand is attached to a saturated phospholipid compared to an unsaturated lipid and whether the bulk phospholipid species in the liposome is unsaturated versus saturated. These studies suggest that targeted liposomes exhibiting a broad range of binding avidities, as estimated by the concentration of liposomes required to achieve saturation of a target surface, can be prepared by selective design of the liposomal carrier. Advantages of the biotinylated liposome for targeting include the relative ease of preparation the possibility of preparation of large-scale batches suitable for clinical development), the ease of incorporation of the targeting ligand, and, importantly, the ability to alter the apparent affinity of the liposome for the target cell through choice of the biotin-labeled lipid and targeting molecule concentration. The potential for developing a two-step targeting strategy based on the use of biotinylated liposomes is discussed.     

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.     

Enhanced systemic exposure of fexofenadine via the intranasal administration of chitosan-coated liposome

The present study aimed to develop the intranasal delivery system of fexofenadine for the prolonged drug release via the preparation of mucoadhesive liposome. By using thin layer film hydration method, liposome of fexofenadine was prepared with DPPC/DPPG, resulting in the small lipid vesicles (359 ± 5.5 nm) with narrow size distribution (PI<0.1). Subsequently, the surface of anionic liposome was coated by chitosan and in vitro characteristics of liposomes were evaluated along with the pharmacokinetic studies in rats. Chitosan coated liposomes were stable for 6-month storage at 4 °C without any significant size change and drug leakage. Furthermore, it exhibited strong mucoadhesive properties in mucin adsorption test, which was 3-fold higher than uncoated liposomes. Compared to the oral delivery of powder formulation, the intranasal delivery of fexofenadine significantly (p<0.05) increased systemic exposure of fexofenadine in rats. Particularly, the intranasal administration of chitosan coated liposome exhibited approximately 5 fold enhancement of AUC with more sustained drug release in rats compared to the oral delivery. In conclusion, intranasal administration of chitosan coated liposome appeared to be effective to enhance the bioavailability as well as prolonged exposure of fexofenadine in rats.     

Targeted liposomal drug delivery in cancer

Liposomes, which are biodegradable and essentially non-toxic vehicles, can encapsulate both hydrophilic and hydrophobic materials, and are utilized as drug carriers in drug delivery systems. In addition, liposomes can be used to carry radioactive compounds as radiotracers can be linked to multiple locations in liposomes. One option is the hydrated compartment inside the liposome, another the lipid core into which especially hydrophobic conjugates can be attached, and the third option is the outer lipid leaflet where molecules can be bound by covalent linkage. Delivery of agents to the reticuloendothelial system (RES) is easily achieved, since most conventional liposomes are trapped by the RES. For the purpose of delivery of agents to target organs other than RES, long-circulating liposomes have been developed by modifying the liposomal surface. Understanding of the in vivo dynamics of liposome-carried agents is required for the evaluation of the bioavailability of drugs encapsulated in liposomes. In this review, we focus on the in vivo trafficking of liposomes visualized by positron emission tomography (PET) and discuss the characteristics of liposomes that affect the targeting of drugs in vivo.     

High-affinity targeting of biotin-labeled liposomes to streptavidin-conjugated ligands

Abstract

Cell-specific delivery of drug-loaded liposomal carrier systems can be achieved through the use of liposomes with covalently attached proteins. For such targeting strategies to be successful a number of potential difficulties, related to the preparation of the liposomes as well as optimization of properties that maximize in vivo access and binding to a defined target cell population, must be overcome. The studies summarized here have attempted to identify specific factors that will promote binding of targeted liposomes to defined target surfaces. Liposomes containing biotinylated phospha-tidylethanolamine were used to demonstrate that the avidity of a targeted liposome for streptavidin-coated ELISA plates and cells is influenced by liposome lipid composition, the amount of targeting molecule present per liposome, the nature of the targeting ligand, and the target surface. Specifically, it is demonstrated that the three most important factors (in order of importance) controlling the apparent affinity of targeted liposomes are (1) target ligand concentration in the liposomal membrane; (2) the presence of a spacer grout between the biotin and the phospholipid headgroup; and (3) the addition of cholesterol. Other less important factors that influence target liposome binding include whether the target ligand is attached to a saturated phospholipid compared to an unsaturated lipid and whether the bulk phospholipid species in the liposome is unsaturated versus saturated. These studies suggest that targeted liposomes exhibiting a broad range of binding avidities, as estimated by the concentration of liposomes required to achieve saturation of a target surface, can be prepared by selective design of the liposomal carrier. Advantages of the biotinylated liposome for targeting include the relative ease of preparation the possibility of preparation of large-scale batches suitable for clinical development), the ease of incorporation of the targeting ligand, and, importantly, the ability to alter the apparent affinity of the liposome for the target cell through choice of the biotin-labeled lipid and targeting molecule concentration. The potential for developing a two-step targeting strategy based on the use of biotinylated liposomes is discussed.     

Enhanced Anticancer Therapy Mediated by Specialized Liposomes

It has been a central aim of experimental and clinical therapeutics to deliver therapeutic agents as close as possible to, or if possible within, a diseased cell. Such targeting achieves two major aims of drug delivery, the maximum dose of therapeutic agent to the diseased cell and avoidance of uptake by and, usually, accompanying side-effects to normal, healthy cells. Conventional liposomes, originally used for studies in membrane biophysics and biochemistry, have been used in therapy for the past two decades. However, when applied to deliver drugs into cells, conventional liposomes proved inefficient and so novel unconventional or specialized liposomes are constantly being prepared to enhance cell-specific delivery in-vivo. One possible way of achieving better targeting is combination of the positive attributes of more than one specialized type of liposome into one vesicle. Although a limited number of studies has examined the combined effect of such dual-speciality liposomes, more studies are warranted using appropriate models. Liposomes are composed of one, a few, or many concentric bilayer membranes which alternate with aqueous spaces. The drugs are encapsulated within the aqueous internal volume if they are hydrophilic or in the lipid bilayers if they are hydrophobic (Kim 1993). Liposomes range in size from 25 nm to more than 20 μm (Sugarman & Perez-Soler 1992). Depending on their solubility and method of formulation antimicrobial, cytotoxic and other conventional drugs, hormones, antigens, enzymes, genetic material, viruses and bacteria can be incorporated in either the aqueous or hydrophobic phase. This review discusses the types and characteristics of non-conventional liposomes used in various modes of cancer therapy, mainly chemotherapy and gene therapy. It concludes with suggestions on improving these novel liposomal to effect better targeting to cancer cells.     

Liposomes in ultrasonic drug and gene delivery

Liposome-based drug and gene delivery systems have potential for significant roles in a variety of therapeutic applications. Recently, liposomes have been used to entrap gas and drugs for ultrasound-controlled drug release and ultrasound-enhanced drug delivery. Echogenic liposomes have been produced by different preparation methods, including lyophilization, pressurization, and biotin-avidin binding. Presently, significant in vivo applications of liposomal ultrasound-based drug and gene delivery are being made in cardiac disease, stroke and tumor therapy. Translation of these vehicles into the clinic will require a better understanding of improved physical properties to avoid rapid clearance, as well as of possible side effects, including those of the ultrasound. The aim of this review is to provide orientation for new researchers in the area of ultrasound-enhanced liposome drug and gene delivery.     

Strategies for improving the intratumoral distribution of liposomal drugs in cancer therapy

ABSTRACT

Introduction: A major limitation of current liposomal cancer therapies is the inability of liposome therapeutics to penetrate throughout the entire tumor mass. This inhomogeneous distribution of liposome therapeutics within the tumor has been linked to treatment failure and drug resistance. Both liposome particle transport properties and tumor microenvironment characteristics contribute to this challenge in cancer therapy. This limitation is relevant to both intravenously and intratumorally administered liposome therapeutics.

Areas covered: Strategies to improve the intratumoral distribution of liposome therapeutics are described. Combination therapies of intravenous liposome therapeutics with pharmacologic agents modulating abnormal tumor vasculature, interstitial fluid pressure, extracellular matrix components, and tumor associated macrophages are discussed. Combination therapies using external stimuli (hyperthermia, radiofrequency ablation, magnetic field, radiation, and ultrasound) with intravenous liposome therapeutics are discussed. Intratumoral convection-enhanced delivery (CED) of liposomal therapeutics is reviewed.

Expert opinion: Optimization of the combination therapies and drug delivery protocols are necessary. Further research should be conducted in appropriate cancer types with consideration of physiochemical features of liposomes and their timing sequence. More investigation of the role of tumor associated macrophages in intratumoral distribution is warranted. Intratumoral infusion of liposomes using CED is a promising approach to improve their distribution within the tumor mass.     

Drug absorption by the respiratory mucosa: cell culture models and particulate drug carriers.

The inhalation route is of increasing interest for both local and systemic drug delivery, including macromolecular biopharmaceuticals, such as peptides, proteins, and gene therapeutics. In addition to appropriate aerosolization for deposition in relevant areas of the respiratory tract, therapeutic molecules may require an advanced carrier system for safe and efficient delivery to their target. Two approaches to obtain novel carrier systems for pulmonary drug delivery are large porous microparticles with a low aerodynamic diameter and lectin-functionalized liposomes. Epithelial cells of alveolar or bronchial origin, obtained either from patient material or from established cell lines, can be grown on permeable filter supports, resulting in polarized monolayers with functional intercellular junctions. With such in vitro models, transport of drugs into pulmonary epithelial cells and/or across the air-blood barrier, as well as the effect and efficacy of novel drug carrier systems can be systematically studied.     

Liposomes as drug carrier systems. Preparation, classification and therapeutic advantages of liposomes]

Bangham et al. (1965) created first the concept of the liposome as a microparticulate lipoidal vesicle separated from its aqueous environment by one or more lipid bilayers. Later Gregoriadis and Ryman (1972) suggested to use liposomes as drug carrier systems. Nowadays liposomes are under extensive investigation for improving the delivery of therapeutic agents, enzymes, vaccines and genetic materials. Liposomes offer an excellent opportunity to selective targeting of drugs which is expected to optimize the pharmacokinetical parameters, the pharmacological effect and to reduce the toxicity of the encapsulated drugs. To understand the system it is important to know the basic properties of these lipoidal vesicles. Our aim was to focus on the lipid composition and the method of liposome preparation what determine the liposomal membrane fluidity, permeability, vesicle size, charge density, steric hindrance and stability of the liposomes as principle factors those influence the fate of liposomes, their interactions with the blood components and other tissues after systemic administration or local use.