Penetration of Metallic Nanoparticles in Human Full-Thickness Skin

Baroli, Bianca Maria; Ennas, Maria Grazia; Loffredo, F; Isola, Michela; Pinna, Raimondo; López‐Quintela, M. Arturo

doi:10.1038/sj.jid.5700733

Cited by 401 publications

(241 citation statements)

References 49 publications

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“…Fluorescence microscope images indicate that QDs were localized in the uppermost layers of the SC and the hair follicles. This is similar to other reports that found that QD621 were localized in the outer root sheath of porcine hair follicles [9], TiO 2 microparticles and polystyrene nanoparticles distributed near orifices in human hair follicles [1,17], and metallic nanoparticles less than 10 nm were capable of penetrating the SC and hair follicles [18]. QDs can work their way between the corneocytes of the stratum corneum and penetrate deep in the epidermis and dermis of an in vivo model with UVR penetration exacerbation [10].…”

Section: Discussionsupporting

confidence: 80%

In vivo skin penetration and metabolic path of quantum dots

Tang

Zhang

Song

et al. 2013

Sci. China Life Sci.

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The skin is the largest organ of the body and is a potential route of exposure to sunscreens and cosmetics containing nanoparticles; however, the permeability of the skin to these nanoparticles is currently unknown. In this paper, we studied the transdermal delivery capacity through mouse skin of water-soluble CdSeS quantum dots (QDs) and the deposition of these QDs in the body. QD solution was coated onto the dorsal hairless skin of male ICR mice. Fluorescence microscopy and transmission electron microscopy (TEM) were used to observe the distribution of QDs in the skin and organs, and inductively coupled plasma-mass spectrometry (ICP-MS) was used to measure the 111 Cd content to indicate the concentration of QDs in plasma and organs. Experimental results indicate that QDs can penetrate into the dermal layer and are limited to the uppermost stratum corneum layers and the hair follicles. Through blood circulation, QDs deposit mostly in liver and kidney and are difficult to clear. 111 Cd concentration was greater than 14 ng g 1 in kidney after 120 h after 0.32 nmol QDs was applied to a mouse. These results suggest that QDs have in vivo transdermal delivery capacity through mouse skin and are harmful to the liver and kidney. quantum dots, nanoparticles, skin penetration, metabolism, ICP-MS Citation:Tang L, Zhang C L, Song G M, et al. In vivo skin penetration and metabolic path of quantum dots.

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Section: Discussionsupporting

confidence: 80%

In vivo skin penetration and metabolic path of quantum dots

Tang

Zhang

Song

et al. 2013

Sci. China Life Sci.

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“…Wide-range applications stimulated intensive study of interaction of nanoparticles with a living tissue and in particular the penetration and migration of the nanoparticles inside the tissue. Some authors suggested that the processes governing the penetration of reactive radicals (see extensive discussion of these effects in Section 4) [29] and those governing nanoparticles are not the same [30], making a good case for penetration selectivity argument. In addition, penetration efficacy of nanoparticles inside various tissues is distinctly different.…”

Section: Interaction Of Nanoparticles With Cellsmentioning

confidence: 99%

“…The above synergy takes advantage of the superior capability of nanoparticles to penetrate through the skin barrier [30], thus liberating plasma from its limitation as an intrinsically topical technique. The potential specificity of nanoparticles to attach to diseased cells as against healthy cells [136] offers selectivity, and the use of ROS or RNS carried by nanoparticles as the main agent against either cancer cells or pathogens reduces the reliance on toxic materials (e.g.…”

Section: Synergy In Reaction Chemistrmentioning

confidence: 99%

Plasmas meet nanoparticles—where synergies can advance the frontier of medicine

Kong¹,

Keidar²,

Ostrikov³

2011

J. Phys. D: Appl. Phys.

107

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To cite this version:M G Kong, M Keidar, K Ostrikov. Plasmas meet nanoparticleswhere synergies can advance the frontier of medicine. Journal of Physics D: Applied Physics, IOP Publishing, 2011, 44 (17) AbstractNanoparticles and low-temperature plasmas have been developed, independently and often along different routes, to tackle the same set of challenges in biomedicine. There are intriguing similarities and contrasts in their interactions with cells and living tissues, and these are reflected directly in the characteristics and scope of their intended therapeutic solutions, in particular their chemical reactivity, selectivity against pathogens and cancer cells, safety to healthy cells and tissues, and targeted delivery to diseased tissues. Time has come to ask the inevitable question of possible plasma-nanoparticle synergy and the related benefits to the development of effective, selective, and safe therapies for modern medicine. This perspective article offers a detailed review of the strengths and weakenesses of nanomedicine and plasma medicine as a stand-alone technology, and then provides a critical analysis of some of the major opportunities enabled by synergising the nanotechnology and the plasma technology. It is shown that the plasma-nanoparticle synergy is best captured through the plasma nanotechnology and its benefits for medicine are highly promising.

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“…Small molecules are able to move freely within the intercellular spaces and diffusion rates are governed largely by their lipophilicity, but also physicochemical properties such as molecular weight or volume, solubility and hydrogen bonding ability [Potts & Guy 1995]. However, the free movement of macromolecules or www.intechopen.com [Baroli et al 2007]. This suggests that for such materials, the SC could present an additional barrier that is not present for small molecules.…”

Section: Skin As a Site For Particle Deliverymentioning

confidence: 98%