Implant Surfaces and Interface Processes

Kasemo, Bengt Herbert; Gold, Julie

doi:10.1177/08959374990130011901

Cited by 298 publications

(213 citation statements)

References 46 publications

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“…[1] The adsorption of proteins in this early stage strongly influences the biocompatibility of a material. [2] During the adsorption process, the proteins may undergo conformational changes. [3] In some cases the interaction between the surface of the biomaterial and proteins, such as osteointegration, promotes the integration of a biomaterial in the human body.…”

Section: Introductionmentioning

confidence: 99%

The interaction of human serum albumin with titanium studied by means of atomic force microscopy

Keere

Willaert

Tourwe

et al. 2008

Surface & Interface Analysis

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a Titanium is frequently used as a biomaterial for implants in orthopaedics and cardiovascular devices. Understanding the biocompatibility, which is strongly influenced by the adsorption of proteins onto the surface, is very important to improve implants. The surface chemistry of an implant material and its influence on the interaction with body fluid is crucial in that perspective. The main goal of this study was to investigate the conformation of human serum albumin (HSA) with commercially pure titanium (CP Ti) on a molecular level. Both ex situ and in situ AFM imaging showed the conformation of HSA on CP Ti and on mica, which was used as a reference material. Single molecules and aggregates of albumin were observed. HSA can be recognised by the globular shape. The conformation of the adsorbed HSA molecules was different on titanium and mica, for both the ex situ and in situ imaging. The difference in wettability between both substrates caused a larger spread of the protein on the CP Ti surface and thus resulted in a larger perturbation of the native structure of HSA as compared to mica.

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Section: Introductionmentioning

confidence: 99%

The interaction of human serum albumin with titanium studied by means of atomic force microscopy

Keere

Willaert

Tourwe

et al. 2008

Surface & Interface Analysis

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“…In the present work, the cement topography showed some R a and R m values of about 5 and 30 lm, respectively. Previous studies have shown that surface topography features at the cell scale affect the behaviour of cells [26]. For example, looking at the BMSC behaviour on rough titanium surfaces compared to smoother ones with identical surface chemistry, Deligianni [27] found an increased cell adhesion, a slightly higher proliferation and similar ALP activity on rougher surfaces.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of the in vitro cell-material interactions and in vivo osteo-integration of a spinal acrylic bone cement

Verrier

Hughes²,

Alves

et al. 2011

Eur Spine J

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Introduction Polymethylmethacrylate bone cements have proven performance in arthroplasty and represent a common bone filler, e.g. in vertebroplasty. However, acrylic cements are still subject to controversy concerning their exothermic reaction and osteo-integration potential. Therefore, we submitted a highly filled acrylic cement to a systematic investigation on the cell-material and tissueimplant response in vitro and in vivo. Materials and methods Cured Vertecem V? Cements were characterized by electron microscopy. Human bone marrow-derived mesenchymal stem cell morphology, growth and differentiation on the cured cement were followed for 28 days in vitro. The uncured cement was injected in an ovine cancellous bone defect and analysed 4 and 26 weeks post-implantation. Results The rough surface of the cement allowed for good stem cells adhesion in vitro. Up-regulation of alkaline phosphatase was detected after 8 days of incubation. No adverse local effects were observed macroscopically and microscopically following 4 and 26 weeks of implantation of the cement into drill-hole defects in ovine distal femoral epiphysis. Direct bone apposition onto the implant surface was observed resulting in extended signs of osteo-integration over time (35.2 ± 24.2% and 88.8 ± 8.8% at week 4 and 26, respectively). Conclusion Contrary to the established opinion concerning bony tissue response to implanted acrylic bone cements, we observed an early cell-implant in vitro interaction leading to cell growth and differentiation and significant signs of osteo-integration for this acrylic cement using standardized methods. Few outlined limitations, such as the use of low cement volumes, have to be considered in the interpretation of the study results.

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“…The concentration of the peptide at the surface (C s ) can be expressed as (2) where q is the excess amount of peptide per unit area adsorbed on the surface compared to that under bulk solution conditions (i.e., C b ) and δ is the thickness of the adsorbed layer.…”

Section: Iib Model Developmentmentioning

confidence: 99%

Determination of the Adsorption Free Energy for Peptide−Surface Interactions by SPR Spectroscopy

2008

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To understand and predict protein adsorption behavior, we must first understand the fundamental interactions between the functional groups presented by the amino acid residues making up a protein and the functional groups presented by the surface. Limited quantitative information is available, however, on these types of submolecular interactions. The objective of this study was therefore to develop a reliable method to determine the standard state adsorption free energy (ΔG°a ds ) of amino acid residue-surface interactions using surface plasma resonance (SPR) spectroscopy. Two problems are commonly encountered when using SPR for peptide adsorption studies: the need to account for "bulk-shift" effects and the influence of peptide-peptide interactions at the surface. Bulk-shift effects represent the contribution of the bulk solute concentration to the SPR response that occurs in addition to the response due to adsorption. Peptide-peptide interactions, which are assumed to be zero for Langmuir adsorption, can greatly skew the isotherm shape and result in erroneous calculated values of ΔG°a ds . To address these issues, we have developed a new approach for the determination of ΔG°a ds using SPR that is based on the chemical potential. In this article, we present the development of this new approach and its application for the calculation of ΔG°a ds for a set of peptide-surface systems where the peptide has a host-guest amino acid sequence of TGTG-X-GTGT (where G and T are glycine and threonine residues and X represents a variable residue) and the surface consists of alkanethiol self-assembled monolayers (SAMs) with methyl (CH 3 ) and hydroxyl (OH) functionality. This new approach enables bulk-shift effects to be directly determined from the raw SPR versus peptide concentration data plots and the influence of peptide-peptide interaction effects to be minimized, thus providing a very straightforward and accurate method for the determination of ΔG °a ds for peptide adsorption. Further studies are underway to characterize ΔG°a ds for a large library of peptide-SAM combinations.

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Implant Surfaces and Interface Processes

Cited by 298 publications

References 46 publications

The interaction of human serum albumin with titanium studied by means of atomic force microscopy

The interaction of human serum albumin with titanium studied by means of atomic force microscopy

Evaluation of the in vitro cell-material interactions and in vivo osteo-integration of a spinal acrylic bone cement

Determination of the Adsorption Free Energy for Peptide−Surface Interactions by SPR Spectroscopy

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