The Human Dermis as a Target of Nanoparticles for Treating Skin Conditions (original) (raw)
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Nanocosmetics and Nanomedicines: New Approaches for Skin Care
Nanotechnology can be used to modify the drug permeation/penetration of encapsulated substances, through the manipulation of many different factors, including direct contact with the skin surface and controlled release. In general, nanoparticles cannot cross the skin barrier, which can be explained by the cell cohesion and lipids of the stratum corneum, the outermost skin layer. The device most commonly used to study the transport of substances and nanoparticles across the skin is the Franz vertical diffusion cell, followed by the substance quantification in the receptor fluid or determination of the amount retained in the skin. Microscopy techniques have also been applied in skin penetration or permeation experiments. This chapter will present the fundamental considerations regarding the transport of encapsulated substances and/or nanoparticles across the skin, the experimental models applied in these studies and a review of the main studies reported in the literature in order to allow the reader to gain insight into the current knowledge available in this area. * Reprinted (Adapted) with permission from Rouse et al., 2007. Since the skin is an organ with multiple layers, it can be used during in vitro skin permeation/penetration studies with its two basic layers, epidermis and dermis (full-thickness skin) or it can be submitted to treatments that separate its layers supplying different types of membranes (split-thickness skin) to be used for in vitro studies [26, 42, 43]. The choice of the membrane is related to the focus of the study (permeation or penetration). In the full-thickness skin membranes only the subcutaneous tissue is removed [26, 42, 43]. On the other hand, split-thickness skin can be obtained in several ways [26, 42, 43] and the isolation of one specific layer of a skin sample with a controlled thickness can be made using heat and force (heat-separated epidermis), dermatome (dermatomed skin) or enzymatic processes (trypsin-isolated stratum corneum) [44, 45]. Epidermis and stratum corneum membranes are more fragile and some mass balance techniques, such as tape stripping, cannot be applied [27]. Divergences can be found in the literature concerning the effect that these processes can have on the skin characteristics. Some studies have demonstrated that the skin barrier is reestablished with the hydration of these membranes [46, 47]. On the other hand, some reports have claimed that the viability of the skin and the flow through the epidermis can be disturbed by these processes [26, 48, 49].
Interaction of dermatologically relevant nanoparticles with skin cells and skin
Beilstein Journal of Nanotechnology, 2014
The investigation of nanoparticle interactions with tissues is complex. High levels of standardization, ideally testing of different material types in the same biological model, and combinations of sensitive imaging and detection methods are required. Here, we present our studies on nanoparticle interactions with skin, skin cells, and biological media. Silica, titanium dioxide and silver particles were chosen as representative examples for different types of skin exposure to nanomaterials, e.g., unintended environmental exposure (silica) versus intended exposure through application of sunscreen (titanium dioxide) or antiseptics (silver). Because each particle type exhibits specific physicochemical properties, we were able to apply different combinations of methods to examine skin penetration and cellular uptake, including optical microscopy, electron microscopy, X-ray microscopy on cells and tissue sections, flow cytometry of isolated skin cells as well as Raman microscopy on whole tissue blocks. In order to assess the biological relevance of such findings, cell viability and free radical production were monitored on cells and in whole tissue samples. The combination of technologies and the joint discussion of results enabled us to look at nanoparticle-skin interactions and the biological relevance of our findings from different angles.
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The topical route of administration has many advantages for the treatment of various skin disorders as well as cosmeceutical purposes. This route bypasses hepatic first-pass effect and systemic availability of many pharmaceuticals is limited to skin organelles such as hair follicles and so could avoid unwanted adverse reactions and increase the localized therapeutic effect. Despite such attributed advantages of the topical route, the most important challenge is skin barrier characteristics that should be overcome to obtain dermal or trans-dermal drug delivery. Different approaches have been recruited to overcome this barrier. In this review, different types of nanoparticles for skin permeation enhancement and targeted delivery to skin organelles are discussed. The potential mechanisms of each nanocarrier in permeation enhancement and dermal delivery are considered and finally, the most important advantages and disadvantages of each group are summarized.
Nanotechnologies in Russia
This paper presents a comparative analysis of the combined and separate influence of ultrasound and DMSO on the transport of a gold nanoshell suspension in intact and injured skin from data on optical coherence tomography and histochemical analysis. Experimental allergic contact dermatitis was used to model injury to the stratum corneum during various pathological changes in the skin. The studies were per� formed on outbred laboratory rats. It is shown that the best method for enhancing transdermal transport of an immersion liquid is multimodal physical and chemical impact (a combination of DMSO and ultrasono� phoresis); the effectiveness of optical clearing of the dermis both in the presence and absence of the stratum corneum is approximately the same. To enhance the transport of nanoparticles into the skin when it under� goes pathological changes related to injuries of the protective barrier, exposure to ultrasound is sufficient.
Archives of Dermatological Research, 2011
Recent advances in the field of pharmacology and nanotechnology have drawn attention on nanoparticles as novel D. Papakostas and F. Rancan contributed equally to this work.
Current Pharmaceutical Design, 2024
Nanocosmetics have attracted a considerable audience towards natural care due to their low cost, target-specific delivery, and reduced toxicity compared to chemical-based cosmetics. Nanofomulations, including nanoemulsions, nanotubes, and polymeric carriers, have become next-generation products explored for the multifaced applications of nanotechnology in skin care. The rise in the cosmetic industry demands innovative and personalized products designed using nanocarriers for better targeting and improving patient compliance. Furthermore, nanocosmetics increase the efficiency of skin permeation active ingredient entrapment, providing better UV protection. Moreover, it offers controlled drug release, targeting active sites and enhancing physical stability. Further, overcoming the drawback of penetration problems makes them sustainable formulations for precision medicine. Skincare nourishment with nanocosmetics using Indian spices helps to maintain, beautify, and rejuvenate human skin. Nanophytopharmaceuticals extracted from plants, including alkaloids, flavonoids, antioxidants, and volatile oils, are essential phyto-products for skin care. Nano herbals and nanocosmetics are a growing market and gift of nature that nourishes and cures skin ailments like acne, pemphigus, anti-aging, albinism, psoriasis, and fungal infections. The emerging concern is highlighted in the investigation of nanoformulation toxicity and safety concerns in skin care. Further, it helps to manifest research, development, and innovation in expanding the scope of herbal industries.
Anais Brasileiros de Dermatologia, 2014
The scientific community and general public have been exposed to a series of achievements attributed to a new area of knowledge: Nanotechnology. Both abroad and in Brazil, funding agencies have launched programs aimed at encouraging this type of research. Indeed, for many who come into contact with this subject it will be clear the key role that chemical knowledge will play in the evolution of this subject. And even more, will see that it is a science in which the basic structure is formed by distilling different areas of inter-and multidisciplinary knowledge along the lines of new paradigms. In this article, we attempt to clarify the foundations of nanotechnology, and demonstrate their contribution to new advances in dermatology as well as medicine in general. Nanotechnology is clearly the future.
Nanoparticles and microparticles for skin drug delivery
Advanced Drug Delivery Reviews, 2011
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 N 10 nm 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.
Use and potential of nanotechnology in cosmetic dermatology
Clinical, Cosmetic and Investigational Dermatology, 2010
Biotechnology and nanotechnology are the key technologies of the twenty-first century, having enormous potential for innovation and growth. The academic and industrial goals for these technologies are the development of nanoscale biomolecular substances and analytical instruments for investigating cell biology at the cellular and molecular levels. Developments in nanotechnology will provide opportunities for cosmetic dermatology to develop new biocompatible and biodegradable therapeutics, delivery systems and more active compounds. Cosmetics have the primary function of keeping up a good appearance, changing the appearance, or correcting body odors, while maintaining the skin and its surroundings in good conditions. Thus cosmetic dermatology, recognizing the new realities of skin care products, has to emphasize the functional aspects of cosmetics through an understanding of their efficacy and safety in promoting good health. Nanoscience may help the scientific community to find more innovative and efficacious cosmetics. Understanding the physical model of the cell as a machine is essential to understand how all the cell components work together to accomplish a task. The efficacy and safety of new nanomaterials has to be deeply studied by ex vivo tests and innovative laboratory techniques. New delivery systems and natural nanocompounds, such as chitin nanofibrils for wound healing, are being used in cosmetic dermatology with good results, as are nanostructured TiO 2 and ZnO sunscreens. The challenge is open.
Penetration of Metallic Nanoparticles in Human Full-Thickness Skin
Journal of Investigative Dermatology, 2007
The potential and benefits of nanoparticles in nanobiotechnology have been enthusiastically discussed in recent literature; however, little is known about the potential risks of contamination by accidental contact during production or use. Although theories of transdermal drug delivery suggest that skin structure and composition do not allow the penetration of materials larger than 600 Da, some articles on particle penetration into the skin have been recently published. Consequently, we wanted to evaluate whether metallic nanoparticles smaller than 10 nm could penetrate and eventually permeate the skin. Two different stabilized nanoparticle dispersions were applied to excised human skin samples using vertical diffusion cells. At established time points, solutions in receiving chambers were quantified for nanoparticle concentration, and skin was processed for light transmission and electron microscope examination. The results of this study showed that nanoparticles were able to penetrate the hair follicle and stratum corneum (SC), occasionally reaching the viable epidermis. Yet, nanoparticles were unable to permeate the skin. These results represent a breakthrough in skin penetration because it is early evidence where rigid nanoparticles have been shown to passively reach the viable epidermis through the SC lipidic matrix.