Laura A. Walsh scite author profile

Herein, we demonstrate that nanotopographical cues can be utilized to enable biologics >66 kDa to be transported across epithelial monolayers. When placed in contact with epithelial monolayers, nanostructured thin films loosen the epithelial barrier and allow for significantly increased transport of FITC-albumin, FITC-IgG, and a model therapeutic, etanercept. Our work highlights the potential to use drug delivery systems which incorporate nanotopography to increase the transport of biologics across epithelial tissue.

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Nanotopography Facilitates in Vivo Transdermal Delivery of High Molecular Weight Therapeutics through an Integrin-Dependent Mechanism

Walsh

Ryu

Bock

et al. 2015

Nano Lett.

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Transdermal delivery of therapeutics is restricted by narrow limitations on size and hydrophobicity. Nanotopography has been shown to significantly enhance high molecular weight paracellular transport in vitro. Herein, we demonstrate for the first time that nanotopography applied to microneedles significantly enhances transdermal delivery of etanercept, a 150 kD therapeutic, in both rats and rabbits. We further show that this effect is mediated by remodeling of the tight junction proteins initiated via integrin binding to the nanotopography, followed by phosphorylation of myosin light chain (MLC) and activation of the actomyosin complex, which in turn increase paracellular permeability.

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PEGylated silicon nanowire coated silica microparticles for drug delivery across intestinal epithelium

et al. 2012

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Composite particles made by growing nanoscopic silicon wires from the surface of monodispersed, microsized silica beads were tested in this study for their ability to affect the integrity and permeability of an epithelial cell layer. Polyethylene glycol (PEG) is known to sterically stabilize particles and prevent protein binding; as such, it is a routine way to impart in vivo longevity to drug carriers. The effect of the silica beads, both with and without silicon nanowires and PEG, on the disruption of the tight junctions in Caco-2 cells was evaluated by means of: (a) analysis of the localization of zonula occludens-1 (ZO-1), claudin-1 and f-actin; (b) measurements of trans-epithelial electrical resistance (TEER); (c) real-time quantitative RT-PCR analysis of the expression of PKC-α and PKC-z, which regulate the fluidity of cell membranes, and RhoA and Rac1, which are mainly involved in mechanotransduction processes; and (d) drug permeability experiments with fluorescein-sodium. The results have shown that Si-nanowire-coated silica microparticles added to Caco-2 cells in culture lead to alterations in tight junction permeability and the localization of ZO-1 and f-actin, as well as to decreased width of ZO-1 and claudin-1 at the tight junction and increased expression of PKC transcripts. Si-nanowire-coated silica microparticles increased the permeability of Caco-2 cell monolayers to fluorescein-sodium in proportion to their amount. Effects indicative of loosening the Caco-2 cell monolayers and increasing their permeability were less pronounced for PEGylated particles, owing to their greater supposed inertness in comparison with the non-functionalized beads and nanowires. The analyzed Si-nanowire-coated silica microparticles have thus been shown to affect membrane barrier integrity in vitro, suggesting the possibility of using nanostructured microparticles to enhance drug permeability through the intestinal epithelium in vivo.

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The Effect of Nanotopography on Modulating Protein Adsorption and the Fibrotic Response

Kam

Walsh

Bock

et al. 2014

Tissue Engineering Part A

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Understanding and modulating the cellular response to implanted biomaterials is crucial for the field of tissue engineering and regenerative medicine. Since cells typically reside in an extracellular matrix containing nanoscale architecture, identifying synthetic nanostructures that induce desirable cellular behaviors could greatly impact the field. Using nanoimprint lithography, nanostructured patterns were generated on thin film polymeric materials. The ability of these surfaces to influence protein adsorption, fibroblast proliferation and morphology, and fibrotic markers was investigated. Nanostructured features with aspect ratios greater than five allowed for less protein adsorption, resulting in decreased fibroblast proliferation and rounded cellular morphology. These nanofeatures also induced significantly lower gene expression of collagen 1a2, collagen 3a1, and growth factors such as connective tissue growth factor, integrin linked kinase, transforming growth factor b1 (TGF-b1), and epidermal growth factor, key factors associated with a fibrotic response. The results demonstrate that select nanostructured surfaces could be used to modulate the fibrotic behavior in cells and have the potential to be used as antifibrotic architecture for medical implants or tissue engineering scaffolds.

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Laura A. Walsh

Nanostructure-Mediated Transport of Biologics across Epithelial Tissue: Enhancing Permeability via Nanotopography

Nanotopography Facilitates in Vivo Transdermal Delivery of High Molecular Weight Therapeutics through an Integrin-Dependent Mechanism

PEGylated silicon nanowire coated silica microparticles for drug delivery across intestinal epithelium

The Effect of Nanotopography on Modulating Protein Adsorption and the Fibrotic Response

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