Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants

This paper investigates the effects on the blood compatibility of surface nanostructuring of Parylene-C coating. The proposed technique, based on the consecutive use of O2 and SF6 plasma, alters the surface roughness and enhances the intrinsic hydrophobicity of Parylene-C. The degree of hydrophobici...

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Main Authors: Luigi Brancato, Deborah Decrop, Jeroen Lammertyn, Robert Puers
Format: Article
Language:English
Published: MDPI AG 2018-06-01
Series:Materials
Subjects:
Online Access:http://www.mdpi.com/1996-1944/11/7/1109
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spelling doaj-de6588eccd044f82b558e7608adc23da2020-11-24T20:57:41ZengMDPI AGMaterials1996-19442018-06-01117110910.3390/ma11071109ma11071109Surface Nanostructuring of Parylene-C Coatings for Blood Contacting ImplantsLuigi Brancato0Deborah Decrop1Jeroen Lammertyn2Robert Puers3ESAT-MICAS, KU Leuven, Kasteelpark Arenberg 10, 3001 Heverlee, BelgiumDepartment of Biosystems–MeBioS, KU Leuven, Willem de Croylaan 42, 3001 Heverlee, BelgiumDepartment of Biosystems–MeBioS, KU Leuven, Willem de Croylaan 42, 3001 Heverlee, BelgiumESAT-MICAS, KU Leuven, Kasteelpark Arenberg 10, 3001 Heverlee, BelgiumThis paper investigates the effects on the blood compatibility of surface nanostructuring of Parylene-C coating. The proposed technique, based on the consecutive use of O2 and SF6 plasma, alters the surface roughness and enhances the intrinsic hydrophobicity of Parylene-C. The degree of hydrophobicity of the prepared surface can be precisely controlled by opportunely adjusting the plasma exposure times. Static contact angle measurements, performed on treated Parylene-C, showed a maximum contact angle of 158°. The nanostructured Parylene-C retained its hydrophobicity up to 45 days, when stored in a dry environment. Storing the samples in a body-mimicking solution caused the contact angle to progressively decrease. However, at the end of the measurement, the plasma treated surfaces still exhibited a higher hydrophobicity than the untreated counterparts. The proposed treatment improved the performance of the polymer as a water diffusion barrier in a body simulating environment. Modifying the nanotopography of the polymer influences the adsorption of different blood plasma proteins. The adsorption of albumin—a platelet adhesion inhibitor—and of fibrinogen—a platelet adhesion promoter—was studied by fluorescence microscopy. The adsorption capacity increased monotonically with increasing hydrophobicity for both studied proteins. The effect on albumin adsorption was considerably higher than on fibrinogen. Study of the proteins simultaneous adsorption showed that the albumin to fibrinogen adsorbed ratio increases with substrate hydrophobicity, suggesting lower thrombogenicity of the nanostructured surfaces. Animal experiments proved that the treated surfaces did not trigger any blood clot or thrombus formation when directly exposed to the arterial blood flow. The findings above, together with the exceptional mechanical and insulation properties of Parylene-C, support its use for packaging implants chronically exposed to the blood flow.http://www.mdpi.com/1996-1944/11/7/1109Parylene-Cprotein adsorptionhaemocompatibilityhydrophobicitypackaging
collection DOAJ
language English
format Article
sources DOAJ
author Luigi Brancato
Deborah Decrop
Jeroen Lammertyn
Robert Puers
spellingShingle Luigi Brancato
Deborah Decrop
Jeroen Lammertyn
Robert Puers
Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants
Materials
Parylene-C
protein adsorption
haemocompatibility
hydrophobicity
packaging
author_facet Luigi Brancato
Deborah Decrop
Jeroen Lammertyn
Robert Puers
author_sort Luigi Brancato
title Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants
title_short Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants
title_full Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants
title_fullStr Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants
title_full_unstemmed Surface Nanostructuring of Parylene-C Coatings for Blood Contacting Implants
title_sort surface nanostructuring of parylene-c coatings for blood contacting implants
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2018-06-01
description This paper investigates the effects on the blood compatibility of surface nanostructuring of Parylene-C coating. The proposed technique, based on the consecutive use of O2 and SF6 plasma, alters the surface roughness and enhances the intrinsic hydrophobicity of Parylene-C. The degree of hydrophobicity of the prepared surface can be precisely controlled by opportunely adjusting the plasma exposure times. Static contact angle measurements, performed on treated Parylene-C, showed a maximum contact angle of 158°. The nanostructured Parylene-C retained its hydrophobicity up to 45 days, when stored in a dry environment. Storing the samples in a body-mimicking solution caused the contact angle to progressively decrease. However, at the end of the measurement, the plasma treated surfaces still exhibited a higher hydrophobicity than the untreated counterparts. The proposed treatment improved the performance of the polymer as a water diffusion barrier in a body simulating environment. Modifying the nanotopography of the polymer influences the adsorption of different blood plasma proteins. The adsorption of albumin—a platelet adhesion inhibitor—and of fibrinogen—a platelet adhesion promoter—was studied by fluorescence microscopy. The adsorption capacity increased monotonically with increasing hydrophobicity for both studied proteins. The effect on albumin adsorption was considerably higher than on fibrinogen. Study of the proteins simultaneous adsorption showed that the albumin to fibrinogen adsorbed ratio increases with substrate hydrophobicity, suggesting lower thrombogenicity of the nanostructured surfaces. Animal experiments proved that the treated surfaces did not trigger any blood clot or thrombus formation when directly exposed to the arterial blood flow. The findings above, together with the exceptional mechanical and insulation properties of Parylene-C, support its use for packaging implants chronically exposed to the blood flow.
topic Parylene-C
protein adsorption
haemocompatibility
hydrophobicity
packaging
url http://www.mdpi.com/1996-1944/11/7/1109
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