Tiziana Svaldo Lanero scite author profile

In this work, long‐term antibacterial, antiadhesion, and antibiofilm activities are afforded to industrial stainless steel surfaces following a green and bio‐inspired strategy. Starting from catechol bearing synthetic polymers, the film cross‐linking and the grafting of active (bio)molecules are possible under environmentally friendly conditions (in aqueous media and at room temperature). A bio‐inspired polyelectrolyte, a polycation‐bearing catechol, is used as the film‐anchoring polymer while a poly(methacrylamide)‐bearing quinone groups serves as the cross‐linking agent in combination with a polymer bearing primary amine groups. The amine/quinone reaction is exploited to prepare stable solutions of nanogels in water at room temperature that can be easily deposited to stainless steel. This coating provides quinone‐functionalized surfaces that are then used to covalently anchor active (bio)molecules (antibiofilm enzyme and antiadhesion polymer) through thiol/quinone reactions.

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Mechanical properties of single living cells encapsulated in polyelectrolyte matrixes

Lanero

Cavalleri

Krol

et al. 2006

Journal of Biotechnology

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Biointerface multiparametric study of intraocular lens acrylic materials

Bertrand

Bozukova

Lanero

et al. 2014

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Microtopography of the eye surface of the crab Carcinus maenas : an atomic force microscope study suggesting a possible antifouling potential

Greco

Lanero

Torrassa

et al. 2013

J. R. Soc. Interface.

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Marine biofouling causes problems for technologies based on the sea, including ships, power plants and marine sensors. Several antifouling techniques have been applied to marine sensors, but most of these methodologies are environmentally unfriendly or ineffective. Bioinspiration, seeking guidance from natural solutions, is a promising approach to antifouling. Here, the eye of the green crab Carcinus maenas was regarded as a marine sensor model and its surface characterized by means of atomic force microscopy. Engineered surface micro-and nanotopography is a new mechanism found to limit biofouling, promising an effective solution with much reduced environmental impact. Besides giving a new insight into the morphology of C. maenas eye and its characterization, our study indicates that the eye surface probably has antifouling/fouling-release potential. Furthermore, the topographical features of the surface may influence the wettability properties of the structure and its interaction with organic molecules. Results indicate that the eye surface microand nanotopography may lead to bioinspired solutions to antifouling protection.

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