Risk factors that influence adoption of Building Information Modelling (BIM) for refurbishment of complex building projects: stakeholders perceptions

Bacterial cellulose is a naturally occurring polysaccharide with numerous biomedical applications that range from drug delivery platforms to tissue engineering strategies. BC possesses remarkable biocompatibility, microstructure, and mechanical properties that resemble native human tissues, making it suitable for the replacement of damaged or injured tissues. In this review, we will discuss the structure and mechanical properties of the BC and summarize the techniques used to characterize these properties. We will also discuss the functionalization of BC to yield nanocomposites and the surface modification of BC by plasma and irradiation-based methods to fabricate materials with improved functionalities such as bactericidal capabilities.

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Nanostructured Biointerfaces

Allain¹,

Echeverry-Rendón²,

Pavón³

et al. 2017

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Xe+-irradiation effects on multilayer thin-film optical surfaces in EUV lithography

Allain¹,

Hassanein²,

Allain³

et al. 2006

Nuclear Instruments and Methods in Physics Research Section B:

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Bacterial envelope damage inflicted by bioinspired nanospikes grown in a hydrogel

Arias

Devorkin

Spear

et al. 2020

Preprint

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Device-associated infections are one of the deadliest complications accompanying the use of biomaterials, and despite recent advances in the development of anti-biofouling strategies, biomaterials that exhibit both functional tissue restoration and antimicrobial activity have been challenging to achieve. Here, we report the fabrication of bio-inspired bactericidal nanospikes in bacterial cellulose and investigate the mechanism underlying this phenomenon. We demonstrate these structures affects preferentially stiff membranes like those in Gram-positive bacteria, but exhibit cytocompatibility towards mammalian cells, a requisite for tissue restoration. We also reveal the bactericidal activity of the nanospikes is due to a pressure-induced mechanism, which depends on the cell's adherence time, nanospike's geometry and spacing, cell shape, and mechanical properties of the cell wall. Our findings provide a better understanding of the mechanobiology of bacterial cells at the interface with nanoscale structures, which is fundamental for the rational design bactericidal topographies.

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Jean Paul Allain

Surface Modification of Bacterial Cellulose for Biomedical Applications

Nanostructured Biointerfaces

Xe+-irradiation effects on multilayer thin-film optical surfaces in EUV lithography

Bacterial envelope damage inflicted by bioinspired nanospikes grown in a hydrogel

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