Browsing by Author "Jansen, John A."
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Item Bone reaction adjacent to microplasma-sprayed calcium phosphate-coated oral implants subjected to an occlusal load, an experimental study in the dog(2011-02) Junker, R.; Manders, P. J.D.; Wolke, J.; Borisov, Y.; Braceras, I.; Jansen, John A.; INGENIERÍA DE SUPERFICIESBackground: A new microplasma spraying equipment (MSE) to deposit calcium phosphate (CaP) ceramic coatings onto titanium substrates has been developed. With this system, it is possible to spray fine particles and to apply textured hydroxylapatite coatings onto titanium surfaces. Moreover, due to the low heat power of the microplasma jet, overheating of the powder particles as well as excessive local overheating of the substrate are diminished. Furthermore, because of the small laminar plasma jet, it is possible to achieve high spray efficiency in the case of spraying for dental implants. Also, the low level of noise (25-50 dB) and hardly any dust makes it possible to operate MSE under conditions of normal workrooms. Objective: The aim was to investigate, in a mandibular dog model, the effect of functional load on soft-tissue adaptation as well as crestal bone-level changes around titanium implants provided with newly developed microplasma-sprayed CaP coatings. Material and methods: For histomorphometrical evaluation, 56 screw-type titanium implants were inserted into the mandibles of seven adult Beagle dogs. The implants were either acid etched without an additional coating, coated with a conventionally plasma-sprayed CaP ceramic (PS), coated with a microplasma-sprayed CaP ceramic (MPS) or with a microplasma-sprayed coating at only the apical part (aMPS). To assess the effect of occlusal loading, a split-mouth design was used. Six weeks after implantation, the implants in one half of the mandible of each dog were functionally loaded whereas the contra lateral implants served as control. One year after loading, the animals were sacrificed. Soft-tissue dimension as well as marginal bone level were histologically assessed. Results: Histometric analysis of undecalcified histologic sections included the evaluation of the sulcus depth, the dimension of the junctional epithelium and the connective tissue as well as the first bone-to-implant contact. For MPS-surfaced implants, functional loading was associated with - compared with the non-loaded state - unchanged soft-tissue dimension. Furthermore, the soft-tissue dimension did not differ from the dimensions around non-coated, PS and aMPS implants. Moreover, the first bone-to-implant contact was not significantly altered by functional loading and comparable non-coated, PS and aMPS implants. Conclusion: Within the limits of the experiment, we conclude that, in comparison, functional loading does not affect the marginal soft-tissue response to MPS CaP-coated implants. However, in comparison, functional loading might affect marginal bone response to MPS CaP-coated implants.Item Effect of nanotubes and apatite on growth factor release from PLLA scaffolds(2011-06) Zande, Meike van der; Walboomers, X. Frank; Olalde, Beatriz; Jurado, Maria J.; Álava, J. Iñaki; Boerman, Otto C.; Jansen, John A.; Biomateriales; Tecnalia Research & InnovationThere is an evident clinical need for artificial bone restorative materials. In this respect, novel composites based on poly(L-lactic acid) (PLLA) have been described. The bone response of such polymer-based composites is usually improved by the addition of bone morphogenetic protein-2 (BMP-2). However, released BMP-2 is cleared almost immediately from the site of implantation by diffusion, whereas a prolonged retention of BMP-2 onto the scaffold has been suggested to be more favourable. Besides the ability to improve the mechanical strength and osteoconductivity of polymeric scaffolds, both carbon nanotubes (CNTs) and microhydroxyapatite (μHA) have been described to facilitate such retention of BMP-2 when incorporated into a composite scaffold. Therefore, in the current study, radiolabelled BMP-2 was loaded onto plain PLLA and composite PLLA-CNT-μHA scaffolds. Subsequently, the scaffolds were implanted subcutaneously for 5 weeks in rats and BMP-2 release was measured. Release started with an initial phase of quick release, followed by a gradual release of BMP-2. Both scaffold types comprised the same in vivo release properties for BMP-2. The bioactivity of the BMP-2 remained unaltered. It can be concluded that incorporated CNTs and μHA did not affect BMP-2 release from composite scaffold materials.Item Genetic profiling of osteoblast-like cells cultured on a novel bone reconstructive material, consisting of poly-l-lactide, carbon nanotubes and microhydroxyapatite, in the presence of bone morphogenetic protein-2(2010-11) Van Der Zande, Meike; Walboomers, X. Frank; Brännvall, Mathias; Olalde, Beatriz; Jurado, Maria J.; Álava, J. Iñaki; Jansen, John A.; Biomateriales; Tecnalia Research & InnovationIn bone tissue engineering composite materials have been introduced, combining a degradable polymer matrix with, for instance, carbon nanotubes (CNTs) to improve mechanical properties or with microhydroxyapatite (μHA) to improve osteoconduction. The addition of bone morphogenetic protein-2 (BMP-2) can further improve the biological response to the material. However, the influence of such an elaborate composite formation on osteoprogenitor cells is unknown. To examine this, rat bone marrow (RBM) cells were cultured on porous poly-l-lactic acid and composite scaffolds, with or without added BMP-2. Cell proliferation and differentiation were studied using DNA, alkaline phosphatase and scanning electron microscopic analysis. Further, genetic profiles were examined by microarray investigation. Results showed that the composite scaffold had no significant effect on the proliferation of RBM cells, but indicated a negative effect on cell differentiation. The addition of BMP-2 also had no significant effect on the proliferation of RBM cells, but differentiation towards the osteogenic lineage was confirmed. In the arrays results, the addition of BMP-2 alone led to the expression of genes involved in (minor) inflammation. The composite scaffold, and even more distinctly the combination of the composite scaffold with BMP-2, led to the expression of genes, based on gene ontology, connected to tumorigenesis. Therefore, CNT- and μHA-containing composite materials are not recommended as a bone restorative material.