Taína D. Matos Negrón scite author profile

Magnesium (Mg), and its alloys, is being investigated for its potential biomedical applications for its use as a biodegradable metal. However surface modification strategies are needed to modify the surface of the Mg alloy for its applicability in these applications. Self-assembled monolayers (SAMs) have been investigated as a coating strategy on magnesium for biomedical applications. In this report we evaluate the oxidative interfacial stability of phosphonic nanocoatings on magnesium using spectroscopic techniques. Self-assembled mono-/multilayers (SAMs) of octadecylphosphonic acid (ODPA) were formed on the native oxide layer of magnesium alloy using solution deposition technique. The SAMs modified Mg alloy and its oxidative stability were characterized using Fourier transform infrared spectroscopy (FTIR), X-ray photoelectron spectroscopy (XPS), and atomic force microscopy (AFM). FTIR studies indicated mono-/bidentate bonding of the phosphonic SAMs to the Mg alloy surface. XPS confirmed SAM formation showing presence of “P” peaks while consequently showing decrease in peak intensity of Mg peaks. XPS analysis of the phosphonate peaks showed consistent presence of this peak over a period of 21 days. AFM images showed consistent coverage of the Mg alloy over a period of 21 days. The results collectively confirm that the monolayers are stable under the chosen oxidative study.

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Nanostructured self assembled monolayers on magnesium for improved biological performance

Mahapatro

Negrón

Gomes

2016

Materials Technology

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Nanolayers on Magnesium (Mg) Alloy for Metallic Bone Tissue Engineering Scaffolds

Mahapatro¹,

Negrón²,

Bonner³

et al. 2013

j biomat tissue engng

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In-Vitro Corrosion Inhibition of Magnesium Alloy via Organic Nanocoatings

Negrón¹,

Abdel‐Fattah²,

Bonner³

et al. 2011

ECS Trans.

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Magnesium alloy has been gaining interest for its potential biomedical applications as a biodegradable / bioabsorbable metallic implant. However its major disadvantage for biomedical applications is its low corrosion resistance especially in physiological environments. We demonstrate the formation of organic nano-coatings to control the bio-corrosion of Mg alloy. X-ray photoelectron spectroscopy (XPS) determined the surface atomic composition before and after film deposition. The presence of phosphorous "P" after deposition indicated the presence of organic film formation. Similarly, changes in surface hydrophobicity as indicated by contact angle measurements suggested organic thin film formation. Preliminary, In-Vitro corrosion behavior in PBS solutions indicated the effectiveness of these coatings to control the in vitro corrosion of Mg alloy

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Microwave-Assisted Biocatalytic Polymerizations

Mahapatro

Negrón

2013

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