Rainer H. Müller

Solid lipid nanoparticles (SLN) for controlled drug delivery - a review of the state of the art.

Solid lipid nanoparticles (SLN) introduced in 1991 represent an alternative carrier system to traditional colloidal carriers, such as emulsions, liposomes and polymeric micro- and nanoparticles. SLN combine advantages of the traditional systems but avoid some of their major disadvantages. This paper reviews the present state of the art regarding production techniques for SLN, drug incorporation, loading capacity and drug release, especially focusing on drug release mechanisms. Relevant issues for the introduction of SLN to the pharmaceutical market, such as status of excipients, toxicity/tolerability aspects and sterilization and long-term stability including industrial large scale production are also discussed. The potential of SLN to be exploited for the different administration routes is highlighted. References of the most relevant literature published by various research groups around the world are provided.

Solid lipid nanoparticles (SLN) and nanostructured lipid carriers (NLC) in cosmetic and dermatological preparations

Solid lipid nanoparticles (SLN) were developed at the beginning of the 1990 s as an alternative carrier system to emulsions, liposomes and polymeric nanoparticles. The paper reviews advantages-also potential limitations-of SLN for the use in topical cosmetic and pharmaceutical formulations. Features discussed include stabilisation of incorporated compounds, controlled release, occlusivity, film formation on skin including in vivo effects on the skin. As a novel type of lipid nanoparticles with solid matrix, the nanostructured lipid carriers (NLC) are presented, the structural specialties described and improvements discussed, for example, increase in loading capacity, physical and chemical long-term stability, triggered release and potentially supersaturated topical formulations. For both SLN and NLC, the technologies to produce the final topical formulation are described, especially the production of highly concentrated lipid nanoparticle dispersions >30-80% lipid content. Production issues also include clinical batch production, large scale production and regulatory aspects (e. g. status of excipients or proof of physical stability).

Nanosuspensions as particulate drug formulations in therapy. Rationale for development and what we can expect for the future.

An increasing number of newly developed drugs are poorly soluble; in many cases drugs are poorly soluble in both aqueous and organic media excluding the traditional approaches of overcoming such solubility factors and resulting in bioavailability problems. An alternative and promising approach is the production of drug nanoparticles (i.e. nanosuspensions) to overcome these problems. The major advantages of this technology are its general applicability to most drugs and its simplicity. In this article, the production of nanoparticles on a laboratory scale is presented, special features such as increased saturation solubility and dissolution velocity are discussed, and special applications are highlighted, for example, mucoadhesive nanosuspensions for oral delivery and surface-modified drug nanoparticles for site-specific delivery to the brain. The possibilities of large scale production -- the prerequisite for the introduction of a delivery system to the market -- are also discussed.

Nanostructured lipid matrices for improved microencapsulation of drugs.

At the beginning of the nineties solid lipid nanoparticles (SLN) have been introduced as a novel nanoparticulate delivery system produced from solid lipids. Potential problems associated with SLN such as limited drug loading capacity, adjustment of drug release profile and potential drug expulsion during storage are avoided or minimised by the new generation, the nanostructured lipid carriers (NLC). NLC are produced by mixing solid lipids with spatially incompatible lipids leading to special structures of the lipid matrix, i.e. three types of NLC: (I) the imperfect structured type, (II) the structureless type and (III) the multiple type. A special preparation process-applicable to NLC but also SLN-allows the production of highly concentrated particle dispersions (>30-95%). Potential applications as drug delivery system are described.

Nanosuspensions for the formulation of poorly soluble drugs: I. Preparation by a size-reduction technique

Abstract A basic problem of poorly soluble drugs is often an insufficient bioavailability. To allow the i.v. injection of these drugs, they were formulated as nanosuspensions by high pressure homogenization. The effect of the production parameters pressure and cycle number on the mean particle size and on the polydispersity of the nanosuspension was investigated with special attention to contamination by microparticles — the limiting factor for i.v. injection. Properties of the nanosuspensions are increased saturation solubility C s and dissolution rate d c /d t . These phenomena are explained using the Prandtl and the Ostwald–Freundlich equations. These properties promote the dissolution of the nanosuspensions in the blood after i.v. injection. The size distribution obtained and the use of an APV Gaulin homogenizer (FDA approved for parenterals) lead to a pharmaceutical product considered acceptable by the regulatory authorities.

Nanocrystal technology, drug delivery and clinical applications.

Nanotechnology will affect our lives tremendously over the next decade in very different fields, including medicine and pharmacy. Transfer of materials into the nanodimension changes their physical properties which were used in pharmaceutics to develop a new innovative formulation principle for poorly soluble drugs: the drug nanocrystals. The drug nanocrystals do not belong to the future; the first products are already on the market. The industrially relevant production technologies, pearl milling and high pressure homogenization, are reviewed. The physics behind the drug nanocrystals and changes of their physical properties are discussed. The marketed products are presented and the special physical effects of nanocrystals explained which are utilized in each market product. Examples of products in the development pipelines (clinical phases) are presented and the benefits for in vivo administration of drug nanocrystals are summarized in an overview.

Solid lipid nanoparticles (SLN) for controlled drug delivery. I. Production, characterization and sterilization

Abstract Solid lipid nanoparticles (SLN) were produced by high pressure homogenization of a melted lipid (Dynasan 112) dispersed in water at increased temperature (70°C). Soy lecithin and poloxamer 188 were used as surfactants and stabilizers of the particles. The effect of homogenization parameters (pressure, cycle number) was studied and optimized to yield solid lipid nanoparticles of a quality suitable for intravenous injection. Particles were characterized by photon correlation spectroscopy (PCS) and zeta potential measurements, the fraction of large particles being the limiting factor for i.v. injection was determined using a Coulter Counter. The optimum formulation was suitable for i.v. injection (monograph ‘Particulate Matter’, USP XXII). SLN stabilized with soy lecithin could be sterilized by autoclaving.

Effect of light and temperature on zeta potential and physical stability in solid lipid nanoparticle (SLN™) dispersions

Abstract Aqueous dispersions of solid lipid nanoparticles (SLN™) are basically stable for up to 3 years, however some systems show particle growth followed by gelation. To assess the destabilizing factors, a poloxamer 188 stabilized Compritol SLN formulation was prepared. Its stability was investigated as a function of storage temperature, light exposure and packing material (untreated and siliconized vials of glass quality I). In general, introduction of energy to the system (temperature, light) led to particle growth and subsequent gelation. This process was accompanied by a decrease in zeta potential from approximately −25 mV to −15 mV. The effect of the packing material was less pronounced. However, siliconization of the vials almost eliminated particle growth. By optimization of the storage conditions (8°C, in the dark, siliconized vials), a stability of the less stable aqueous Compritol SLN over 3 years was achieved.

Solid lipid nanoparticles as carrier for sunscreens: in vitro release and in vivo skin penetration

The aim of this study was the comparison of two different formulations (solid lipid nanoparticles (SLN) and conventional o/w emulsion) as carrier systems for the molecular sunscreen oxybenzone. The influence of the carrier on the rate of release was studied in vitro with a membrane-free model. The release rate could be decreased by up to 50% with the SLN formulation. Further in vitro measurements with static Franz diffusion cells were performed. In vivo, penetration of oxybenzone into stratum corneum on the forearm was investigated by the tape stripping method. It was shown that the rate of release is strongly dependent upon the formulation and could be decreased by 30-60% in SLN formulations. In all test models, oxybenzone was released and penetrated into human skin more quickly and to a greater extent from the emulsions. The rate of release also depends upon the total concentration of oxybenzone in the formulation. In vitro-in vivo correlations could be made qualitatively.

Lipid nanoparticles for parenteral delivery of actives

The present review compiles the applications of lipid nanoparticles mainly solid lipid nanoparticles (SLN), nanostructured lipid carriers (NLC) and lipid drug conjugates (LDC) in parenteral delivery of pharmaceutical actives. The attempts to incorporate anticancer agents, imaging agents, antiparasitics, antiarthritics, genes for transfection, agents for liver, cardiovascular and central nervous system targeting have been summarized. The utility of lipid nanoparticles as adjuvant has been discussed separately. A special focus of this review is on toxicity caused by these kinds of lipid nanoparticles with a glance on the fate of lipid nanoparticles after their parenteral delivery in vivo viz the protein adsorption patterns.