The Mussel Adhesive Protein (Mefp-1) : A GREEN Corrosion Inhibitor

Zhang, Fan

January 2013

Corrosion of metallic materials is a natural process, and our study shows that even in an alkaline environment severe corrosion may occur on a carbon steel surface. While corrosion cannot be stopped it can be retarded. Many of the traditional anti-corrosion approaches such as the chromate process are effective but hazardous to the environment and human health. Mefp-1, a protein derived from blue mussel byssus, is well known for its extraordinary adhesion and film forming properties. Moreover, it has been reported that Mefp-1 confers a certain corrosion protection for stainless steel. All these facts indicate that this protein may be developed into corrosion inhibitors with ‘green’, ‘effective’ and ‘smart’ properties. In this study, a range of surface-sensitive techniques have been used to investigate adsorption kinetics, film forming and film compaction mechanisms of Mefp-1. In situ atomic force microscopy (AFM) enables the protein adsorption on substrates to be visualized, whereas the ex situ AFM facilitates the characterization of micro- and nano-structures of the protein films. In situ Peak Force AFM can be used to determine nano-mechanical properties of the surface layers. The quartz crystal microbalance with dissipation monitoring (QCM-D) was used to reveal the build-up of the Mefp-1 film on substrates and measure the viscoelastic properties of the adsorbed film. Analytical techniques and theoretical calculations were applied to gain insights into the formation and compaction processes such as oxidation and complexation of pre-formed Mefp-1 films. The electron probe micro analyzer (EPMA) and X-ray photoelectron spectroscopy (XPS) were utilized to obtain the chemical composition of the surface layer. Electrochemical impedance spectroscopy (EIS) measurements were performed to evaluate the corrosion inhibition efficiency of different forms of Mefp-1 on carbon steel substrates. The results demonstrate that Mefp-1 adsorbs on carbon steel surfaces across a broad pH interval, and it forms a continuous film covering the substrate providing a certain extent of corrosion protection. At a higher pH, the adsorption is faster and the formed film is more compact. At neutral pH, results on the iron substrate suggest an initially fast adsorption, with the molecules oriented preferentially parallel to the surface, followed by a structural change within the film leading to molecules extending towards solution. Both oxidation and complexation of the Mefp-1 can lead to the compaction of the protein films. Addition of Fe3+ induces a transition from an extended and soft protein layer to a denser and stiffer one by enhancing the formation of tri-Fe3+/catechol complexes in the surface film, leading to water removal and film compaction. Exposure to a NaIO4 solution results in the cross-linking of Mefp-1, which also results in a significant compaction of the pre-formed protein film. Mefp-1 is an effective corrosion inhibitor for carbon steel when added to an acidic solution, and the inhibition efficiency increases with time. As a film-forming corrosion inhibitor, the pre-formed Mefp-1 film provides a certain level of corrosion protection for short term applications, and the protection efficiency can be significantly enhanced by the film compaction processes. For the long term applications, a thin film composed of Mefp-1 and ceria nanoparticles was developed. The deposited Mefp-1/ceria composite film contains micro-sized aggregates of Mefp-1/Fe3+ complexes and CeO2 particles. The Mefp-1/ceria film may promote the further oxidation of ferrous oxides, and the corrosion resistance increases with time. Moreover, phosphate ions react with Fe ions released from the surface and form deposits preferentially at the surface defect sites. The deposits incorporate into the Mefp-1/ceria composite film and heal the surface defects, which result in a significantly improved corrosion inhibition effect for the Mefp-1/ceria composite film in both initial and prolonged exposure situations / <p>QC 20130610</p>

carbon steel

mussel adhesive protein

Mefp-1

inhibitor

adsorption

film forming

complexation

cross-linking

ceria nanoparticle

composite film

EIS

AFM

QCM-D

ATR-FTIR

Confocal Raman Micro-spectroscopy

DFT calculation

Caractérisation moléculaire et structurale du vieillissement cutané au moyen de la micro-imagerie d’absorption infrarouge et de la microspectroscopie de diffusion Raman. / Molecular and structural characterization of the skin aging by the means of the infrared micro-imaging and Raman micro-spectroscopy.

Eklouh-Molinier, Christophe

14 December 2015

La peau assure la protection de l’organisme contre les agressions extérieures. Pourtant, la peau n’est pas à l’abri des effets inéluctables du vieillissement chronologique. En effet, ce processus a pour conséquence d’altérer la structure des différentes couches cutanées au point d’en affecter leurs caractéristiques fonctionnelles. Ce travail de thèse a pour but de caractériser les modifications moléculaires et structurales de la peau au cours du vieillissement chronologique à l’aide de méthodes non-invasives que sont les spectroscopies optiques vibrationnelles. Ainsi avons-nous pu mettre en évidence des altérations structurales du réseau de collagène dans des échantillons de peaux d’âges différents à l’aide d’une approche basée sur l’imagerie IR-TF (Infrarouge à Transformée de Fourier) en mode polarisé. Par la suite, nous avons démontré l’influence des molécules d’eau sur les changements d’orientation des fibres de collagène avec l’âge en adoptant une méthodologie basée sur la substitution, thermodynamiquement favorable, des molécules d’eau liée au collagène (H2O) par des molécules d’eau deutérée (D2O). Lors d’études réalisées in vivo, nous avons établi des corrélations entre les propriétés physiques (mécanique et statut d’hydratation) et les informations moléculaires du stratum corneum (SC) en traitant les données Raman et biométriques par la méthode des moindres carrés partiels (PLS). En s’appuyant sur la complémentarité des techniques biophysiques employées, ces différentes études ont permis d’illustrer le potentiel des spectroscopies vibrationnelles pour évaluer le vieillissement cutané et en déterminer certaines bases moléculaires. / The skin protects the body against external aggressions. However, the skin is not immune to the inevitable effects of the chronological aging. Indeed, this process leads to several structural alterations of the different cutaneous layers to the point of affecting their functional characteristics. This thesis work aims to assess the molecular and structural changes of the skin during chronological aging by using non-invasive methods such as optical vibrational spectroscopies. To do this, we highlighted the structural modifications of the collagen network in different-aged skin samples by using an approach based on FT-IR imaging (Fourier Transform Infrared) in polarized mode. Subsequently, we demonstrated the influence of water molecules on the changes of collagen fibers with age by adopting a methodology based on the substitution, thermodynamically favorable, of the collagen-bound water molecules (H2O) by deuterated water molecules (D2O). In in vivo studies, we have established correlations between physical and molecular properties of the stratum corneum (SC) by analyzing the Raman and biometric measurements with the Partial Least Squares (PLS) processing. Based on the complementarity of the biophysical techniques employed, these studies permitted to evaluate the impact of the chronological aging on the skin and could open some interesting prospects in both cosmetology and dermatology.

Micro-Spectroscopie confocale Raman

Vieillissement cutané

Fibres de collagène

Eau liée

Confocal Raman micro-Spectroscopy

Skin aging

Infrared micro-Imaging in polarized mode

Collagen fibers

Bound water

610

Spectroscopies vibrationnelles (MCR et ATR-FTIR) et Chromatographie Liquide couplée à la Spectrométrie de Masse Haute Résolution (LC-HR-MS) : Outils d’investigation in vivo de l’impact du vieillissement cutané sur le Stratum Corneum aux niveaux tissulaire, supra-moléculaire et moléculaire / Vibrational spectroscopies (MCR and ATR-FTI) and Liquid Chromatography coupled Mass Spectrometry High Resolution : In vivo investigation tools for the effect of skin aging on the Stratum Corneum at tissular, supra-molecular and molecular levels

Boireau-Adamezyk, Elise

22 May 2015

La peau est l’organe le plus étendu du corps humain. Doté d’une membrane biologique fine appelée la couche cornée, celle-ci le protège du desséchement et des agressions extérieures chimiques ou mécaniques auxquelles le corps humain doit faire face. Ce travail de thèse a consisté, dans un premier temps, à décrire via la littérature existante les effets de l’âge,dûs au vieillissement intrinsèque et extrinsèque,sur la physiologie cutanée du Stratum Corneum (SC).La partie expérimentale basée sur la microscopie vibrationnelle traitera des variations de la fonction barrière et de l’hydratation du SC lors du vieillissement chronologique et photo-vieillissement. D’autres méthodes ont également été utilisées comme la chromatographie liquide en phase normale couplée à la spectrométrie de masse haute résolution dotée d’une source APCI et d’un détecteur Orbitrap pour l’étude de la composition détaillée des lipides du SC ainsi que des méthodes plus globales comme la PIE ou la cornéométrie. Le caractère non invasif de toutes ces méthodes a permis de réaliser ces études in vivo. L’évolution de la fonction barrière a été étudiée aux niveaux tissulaire, moléculaire et supramoléculaire par micro-spectroscopie confocale Raman et spectroscopie Infrarouge. Puis le lien moléculaire a été fait entre le vieillissement intrinsèque et les céramides de la matrice lipidique intercornéocytaires par chromatographie en phase liquide couplée à la spectrométrie de masse. Les molécules discriminantes entre population jeune et âgée ont été déterminées par analyse chimiométrique. L’évolution de l’hydratation cutanée aux niveaux tissulaire, moléculaire et supramoléculaire a également été l’objet d’une investigation approfondie. Les variations de la composition des NMF et la teneur en eau dans le SC lors du vieillissement cutané ont été mises en lumière en utilisant des descripteurs spectraux Raman. Les variations structurelles des molécules d’eau impactant l’organisation supramoléculaire des édifices lipidiques ont également été évaluées. Au cours du vieillissement, la fonction barrière cutanée et hydratation sont conservées. / Skin is the external surface defining the human body in space. Its outer-most layer is a thin biological membrane, called Stratum Corneum(SC), that protects the internal organs from desiccation as well as chemical or mechanical external aggressions. The present thesis aimsin a first step, to summarize the current knowledge regarding the effects of intrinsic and extrinsic aging on SCphysiology,based on available literature. The experimental part addresses the gaps in our understanding of the effects of chronological aging and photoaging on the SC barrier function and hydration, using traditional methods (such as trans epidermal water loss and skin conductance) as well as more advanced ones (vibrational spectroscopies, liquid chromatography in normal phase tandem mass spectrometry high resolution with an APCI source and an Orbitrap detector. As these methods are non-invasive, all studies have been carried out in vivo. The evolution of the barrier function has been studied at the tissular, molecular and supramolecular levels using confocal Raman micro-spectroscopy and infrared spectroscopy. Then the link between the intrinsic aging and the ceramides of the intercorneocytary lipid matrix has been studied by liquid chromatography tandem mass spectrometry. The discriminant molecules between young and old population have been identified by a chemometric analysis. The evolution of cutaneous hydration at the tissular, molecular and supramolecular level has also been investigated. The variations in the NMF composition and the SC water content have been studied by Raman spectral descriptors. Moreover, the structural variations of water molecules impacting the supramolecular organization of the lipid structures have been evaluated. Chronological aging and chronic exposure to environmental factors mildly affect SC barrier function and hydration levels. However, the processes controlling these properties are affected by aging in a site-dependent fashion.

Fonction barrière

Hydratation cutanée

SC

Lipides

Céramides

Mobilité de l’eau

Chronological aging and photoaging

Barrier function

Cutaneous hydration

SC

Lipids

Ceramides

Mobility of water