Tarl W. Prow

Nanoparticles and microparticles for skin drug delivery

Skin is a widely used route of delivery for local and systemic drugs and is potentially a route for their delivery as nanoparticles. The skin provides a natural physical barrier against particle penetration, but there are opportunities to deliver therapeutic nanoparticles, especially in diseased skin and to the openings of hair follicles. Whilst nanoparticle drug delivery has been touted as an enabling technology, its potential in treating local skin and systemic diseases has yet to be realised. Most drug delivery particle technologies are based on lipid carriers, i.e. solid lipid nanoparticles and nanoemulsions of around 300 nm in diameter, which are now considered microparticles. Metal nanoparticles are now recognized for seemingly small drug-like characteristics, i.e. antimicrobial activity and skin cancer prevention. We present our unpublished clinical data on nanoparticle penetration and previously published reports that support the hypothesis that nanoparticles >10nm in diameter are unlikely to penetrate through the stratum corneum into viable human skin but will accumulate in the hair follicle openings, especially after massage. However, significant uptake does occur after damage and in certain diseased skin. Current chemistry limits both atom by atom construction of complex particulates and delineating their molecular interactions within biological systems. In this review we discuss the skin as a nanoparticle barrier, recent work in the field of nanoparticle drug delivery to the skin, and future directions currently being explored.

Dry-coated microprojection array patches for targeted delivery of immunotherapeutics to the skin

Dry-coated microprojections (MPs) deliver vaccine to abundant immunogenic cells within the skin to induce immune responses. Success in this targeted vaccine delivery relies on overcoming the challenges of dry-coating the vaccine onto the very small (<or=90 microm length) and densely packed (approximately 20,000 cm(-2)) MPs. In this paper, we show that a gas-jet drying coating method achieves the desired uniform coating. The coating approach is robustly demonstrated on compounds representative of a range of immunotherapeutics (e.g. DNA, proteins), with each uniformly coated on thousands of MPs. Furthermore, the dry-coating remains intact during skin insertion, and then releases within the wet skin cellular environment within 3 min. Finally, we applied ovalbumin protein coated MP patches to immunise mice, achieving comparable antibody levels (p=0.08) with needle and syringe intramuscular injection. In summary, this paper presents a simple, practical and versatile method to achieve uniform coating on very small and densely packed MPs for a needle-free and targeted vaccine delivery technology.

Potent Immunity to Low Doses of Influenza Vaccine by Probabilistic Guided Micro-Targeted Skin Delivery in a Mouse Model

Background Over 14 million people die each year from infectious diseases despite extensive vaccine use [1]. The needle and syringe—first invented in 1853—is still the primary delivery device, injecting liquid vaccine into muscle. Vaccines could be far more effective if they were precisely delivered into the narrow layer just beneath the skin surface that contains a much higher density of potent antigen-presenting cells (APCs) essential to generate a protective immune response. We hypothesized that successful vaccination could be achieved this way with far lower antigen doses than required by the needle and syringe. Methodology/Principal Findings To meet this objective, using a probability-based theoretical analysis for targeting skin APCs, we designed the Nanopatch™, which contains an array of densely packed projections (21025/cm2) invisible to the human eye (110 µm in length, tapering to tips with a sharpness of <1000 nm), that are dry-coated with vaccine and applied to the skin for two minutes. Here we show that the Nanopatches deliver a seasonal influenza vaccine (Fluvax® 2008) to directly contact thousands of APCs, in excellent agreement with theoretical prediction. By physically targeting vaccine directly to these cells we induced protective levels of functional antibody responses in mice and also protection against an influenza virus challenge that are comparable to the vaccine delivered intramuscularly with the needle and syringe—but with less than 1/100th of the delivered antigen. Conclusions/Significance Our results represent a marked improvement—an order of magnitude greater than reported by others—for injected doses administered by other delivery methods, without reliance on an added adjuvant, and with only a single vaccination. This study provides a proven mathematical/engineering delivery device template for extension into human studies—and we speculate that successful translation of these findings into humans could uniquely assist with problems of vaccine shortages and distribution—together with alleviating fear of the needle and the need for trained practitioners to administer vaccine, e.g., during an influenza pandemic.

Non-invasive imaging of skin physiology and percutaneous penetration using fluorescence spectral and lifetime imaging with multiphoton and confocal microscopy

New multiphoton and confocal microscope technologies and fluorescence lifetime imaging techniques are now being used to non-invasively image, in space (three dimensions),in time, in spectra, in lifetime and in fluorescence anisotropy (total of 7 dimensions), fluorescent molecules in in situ and in vivo biological tissue, including skin. The process involves scanning a 2D area and measuring fluorescence at a given tissue depth below the surface after excitation by a laser beam with a wavelength within the one-photon or two-photon absorption band of the fluorophores followed by the stacking together of a series of 2D images from different depths to reconstruct the full spatial structure of the sample. Our aim in this work is to describe the principles, opportunities, limitations and applications of this new technology and its application in defining skin morphology, disease and skin penetration in vitro and in vivo by drugs, chemicals and nanoparticles. A key emphasis is in the use of fluorescence lifetime imaging to add additional specificity and quantitation to the detection of the various exogenous chemicals and nanoparticles that may be applied to the skin as well as endogenous fluorescent species in the skin. Examples given include equipment configuration; components in skin autofluorescence in various skin strata; imaging and quantification of coexisting drugs and their metabolites; skin pH; nanoparticle zinc oxide skin penetration; liposome delivery of drugs to deeper tissues; and observations in skin ageing and in various skin diseases.

The effect of strain rate on the precision of penetration of short densely-packed microprojection array patches coated with vaccine

If skins non-linear viscoelastic properties are mechanically exploited for precise antigen placement, there is tremendous promise for improved vaccines. To achieve this, we designed a Nanopatch-densely packed micro-nanoprojections (>20,000/cm(2)) to directly deposit antigen to large numbers of epidermal Langerhans cells and dermal dendritic cells. Here, we controllably applied our Nanopatches with discrete conditions between peak strain rates of approximately 100 s(-1)-7000 s(-1) and quantified resulting penetration depths, delivery payloads and skin mechanics. Increasing the strain rate of application, we overcame key skin variability, achieving increases in both projection penetration depth (by over 50% length) and area coverage of a full array (from 50% to 100%). This delivery depth precision opens the way for more fully utilizing the skins immune function. Furthermore, we yielded new insights on mechanical behaviour of skin, including: 1) internal skin property changes that could affect/facilitate penetration; 2) projection design to dictate penetration depth; 3) puncture mechanics of skin in this strain rate range. Indeed, we show delivery of a model vaccine using our tested range of strain rates achieved functionally relevant tunable systemic antibody generation in mice. These findings could be of great utility in extending skin strata vaccine targeting approaches to human use.

Ocular nanoparticle toxicity and transfection of the retina and retinal pigment epithelium

Chitosan, PCEP (poly{[(cholesteryl oxocarbonylamido ethyl) methyl bis(ethylene) ammonium iodide] ethyl phosphate}), and magnetic nanoparticles (MNPs) were evaluated for the safe delivery of genes in the eye. Rabbits were injected with nanoparticles either intravitreally (IV) or subretinally (SR) and sacrificed 7 days later. Eyes were grossly evaluated for retinal pigment epithelium abnormalities, retinal degeneration, and inflammation. All eyes were cryopreserved and sectioned for analysis of toxicity and expression of either enhanced green or red fluorescent proteins. All of the nanoparticles were able to transfect cells in vitro and in vivo. IV chitosan showed inflammation in 12/13 eyes, whereas IV PCEP and IV MNPs were not inflammatory and did not induce retinal pathology. SR PCEP was nontoxic in the majority of cases but yielded poor transfection, whereas SR MNPs were nontoxic and yielded good transfection. Therefore, we conclude that the best nanoparticle evaluated in vivo was the least toxic nanoparticle tested, the MNP.

Applications of multiphoton tomographs and femtosecond laser nanoprocessing microscopes in drug delivery research

Multiphoton tomography for in vivo high-resolution multidimensional imaging has been used in clinical investigations and small animal studies. The novel femtosecond laser tomographs have been employed to detect cosmetics and pharmaceutical components in situ as well as to study the interaction of drugs with intratissue cells and the extracellular matrix under physiological conditions. Applications include the intra-tissue accumulation of sunscreen nanoparticles in humans, the monitoring the metabolic status of patients with dermatitis, the biosynthesis of collagen after administration of anti-aging products, and the detection of porphyrins after application of 5-aminolevulinic acid. More than 2000 patients and volunteers in Europe, Australia, and Asia have been investigated with these unique tomographs. In addition, femtosecond laser nanoprocessing microscopes have been employed for targeted delivery and deposition in body organs, optical transfection and optical cleaning of stem cells, as well as for the optical transfer of molecular beacons to track microRNAs. These diverse applications highlight the capacity for multiphoton tomography and femtosecond laser nanoprocessing tools to advance drug delivery research.

Analysis of the metabolic deterioration of ex vivo skin from ischemic necrosis through the imaging of intracellular NAD"P…H by multiphoton tomography and fluorescence lifetime imaging microscopy

Ex vivo human skin has been used extensively for cosmeceutical and drug delivery studies, transplantable skin allografts, or skin flaps. However, it has a half-life of a few days due to ischemic necrosis. Traditional methods of assessing viability can be time-consuming and provide limited metabolic information. Using multiphoton tomography and fluorescence lifetime imaging (MPT-FLIM) we assess ischemic necrosis of ex vivo skin by NAD(P)H autofluorescence intensity and fluorescence lifetime. Ex vivo skin is stored in the presence and absence of nutrient media (Dulbecco Modified Eagle Medium) at -20, 4, and 37 degrees C and room temperature over a 7-day time course to establish different rates of metabolic deterioration. At higher temperatures we observe a decrease in NAD(P)H autofluorescence, higher image noise, and a significant increase in the average fluorescence lifetime (tau(m)) from approximately 1000 to 2000 ps. Additionally, significant distortions in NAD(P)H fluorescence lifetime histograms correspond to the reduction in autofluorescence. Skin kept at 4 degrees C, with or without media, showed the least change. Our findings suggest that MPT-FLIM enables useful noninvasive optical biopsies to monitor the metabolic state and deterioration of human skin for research and clinical purposes.

The Initial Fetal Human Retinal Vasculature Develops by Vasculogenesis

There is increasing evidence that the hemangioblast, a common progenitor for hematopoietic cells and endothelial cells, participates in embryonic and extra‐embryonic vasculogenesis in some organs. Whether resident angioblasts or endothelial progenitor cells (EPCs) contribute to human retinal vasculogenesis is still a matter of controversy. To address this controversy, fetal human retinas of 6–23 weeks gestation (WG) were examined using immunohistochemistry and a panel of antibodies against endothelial cell markers (CD34, CD31), a marker for retinal angioblasts and endothelium (CD39/ecto‐ADPase), and a marker for precursors and hemangioblasts (CXCR4). Confocal microscopic spectral analysis and double labeling with Ki67 was used to identify the proliferating cell types. In the inner neuroblastic layer of the 6–8 WG retina and in the putative ganglion cell layer in avascular regions of older eyes (14 WG–20 WG), scattered CD39+ angioblasts were well in advance of forming vasculature. There was a layer of CXCR4+ cells in the inner retina that was reduced in size with development. As blood vessels formed, CD39+ cells were always well in advance of the vascular front and they expressed CXCR4. This demonstrates that a pool of resident angioblasts express CD39 and CXCR4 as they differentiate and participate in vasculogenesis in the fetal human. They retain expression of CD39 as endothelial cells in the newly formed retinal vasculature but they down‐regulate CXCR4 expression. Developmental Dynamics 235:3336–3347, 2006.

Quantum dot penetration into viable human skin.

Abstract Systematic studies probing the effects of nanoparticle surface modification and formulation pH are important in nanotoxicology and nanomedicine. In this study, we use laser-scanning fluorescence confocal microscopy to evaluate nanoparticle penetration in viable excised human skin that was intact or tape-stripped. Quantum dot (QD) fluorescent nanoparticles with three surface modifications: Polyethylene glycol (PEG), PEG-amine (PEG-NH2) and PEG-carboxyl (PEG-COOH) were evaluated for human skin penetration from aqueous solutions at pH 7.0 and at pHs of solutions provided by the QD manufacturer: 8.3 (PEG, PEG-NH2) and 9.0 (PEG-COOH). There was some penetration into intact viable epidermis of skin for the PEG-QD at pH 8.3, but not at pH 7.0 nor for any other QD at the pHs used. Upon tape stripping 30 strips of stratum corneum, all QDs penetrated through the viable epidermis and into the upper dermis within 24 h.