Objective To propose a biofunctionalized prosthetic abutment by analyzing physico‐chemical and morphological properties, simvastatin (SIM) release, and biocompatibility of titanium (Ti) disks coated with poly(lactic‐co‐glycolic) acid (PLGA) incorporating SIM. Methods Titanium disks (8 × 3 mm) were distributed into four groups: Ti: pure Ti; Ti + PLGA: Ti coated with PLGA; Ti + PLGA + SIM6%: Ti + PLGA with 6% SIM; and Ti + PLGA + SIM0.6%: Ti + PLGA incorporating 0.6% SIM. PLGA was prepared through chloroform evaporation technique. After complete dissolution of PLGA, SIM was diluted in the solution. Ti + PLGA, Ti + PLGA + SIM6%, and Ti + PLGA + SIM0.6% were dip coated with PLGA and PLGA + SIM, respectively. Samples were sterilized by ethylene oxide. For SIM release assay, disks were submerged in PBS, pH 7.4, 37°C, 30 rpm up to 600 hours. At different time intervals, SIM was quantified by spectrophotometry (238 nm). For characterization of the biomaterial components, it was performed Fourier‐transform infrared spectroscopy, differential scanning calorimetry, scanning electron microscopy (SEM), optical profilometry, and atomic force microscopy. Biocompatibility analyses were performed by MTS colorimetric assay on murine fibroblasts L929, human gingival fibroblasts (HGFs), and stem cells from human exfoliated deciduous teeth (SHEDs). Absorbance was measured at 490 nm, and percentages of viable cells were calculated in relation to positive control (Ti). SEM images were obtained to verify cell adhesion and morphology. One‐way ANOVA followed by Tukey's post hoc test was applied (P < 0.05) for statistical analyses. Results SIM release was slow and continuous, reaching about 21% of the incorporated SIM after 600 hours. Topographical analyses revealed success in coating Ti disks with PLGA incorporating SIM. Regarding biocompatibility test, Ti + PLGA + SIM0.6% showed the highest percentage of L929 viability at days 3 and 7. There was no significant difference for Ti, Ti + PLGA, and Ti + PLGA + SIM0.6% groups on cell viability of both SHEDs and HGFs at days 3 and 7. SEM corroborates that SHEDs and HGFs were able to adhere and proliferate on Ti, Ti + PLGA, and Ti + PLGA + SIM0.6% surfaces. Conclusion A slow and controlled release of SIM was achieved, attributed to a diffusional mass transfer mechanism. Moreover, a homogenous coating topography was obtained. Additionally, 0.6% SIM incorporated into PLGA coating improved fibroblasts L929 viability compared to titanium or PLGA. Also, 0.6% SIM incorporated into PLGA promoted cell viability of about 100% for HGFs and approximately 150% for human mesenchymal stem cells. Therefore, this study allows to consider the use of PLGA‐coated titanium incorporating SIM as a biofunctionalized abutment for dental implants.
RESUMOImplantes inclinados atualmente são utilizados como uma alternativa cirúrgica e protética. Por tanto, estudos in vitro demonstram que o seu uso aumenta a concentração de tensão no osso cortical peri-implantar e questionase se esse fator pode levar ao insucesso da reabilitação oral estética. O objetivo do presente artigo foi avaliar a informação relacionada com a influência de forças funcionais sobre a biomecânica de implantes inclinados nas reabilitações orais implantossuportadas. No intuito de investigar essa hipótese, foi realizada uma revisão da literatura e busca de informações existentes em artigos científicos indexados ao PubMed, que avaliassem o efeito da distribuição das tensões na interface osso-implante de implantes inclinados, através do método de análise dos elementos finitos. Os resultados mostraram que o uso de implantes inclinados aumenta a concentração de tensões no osso cortical peri-implantar sob simulação de cargas parafuncionais. No entanto, análises in-vitro não podem prever de forma precisa o comportamento dos tecidos biológicos. Apesar dessa limitação dos estudos, pode-se concluir que elevados picos de tensões poderiam comprometer os limites de resistência do osso cortical, podendo levar a falhas do conjunto osso-implante. Todavia, quando associados a reabilitações de próteses múltiplas, os implantes inclinados mudam sua biomecânica, favorecendo a distribuição e redução das tensões e o aumento da estabilidade das reabilitações como um todo. Descritores: Implantes dentários • Próteses e implantes • Reabilitação bucal • Análise de elementos finitos. ABSTRACTTilted implants are currently used as a surgical and prosthetic's alternative. Therefore, in-vitro studies demonstrate that their use increases the stress concentration in the peri-implant cortical bone and it wonders whether this can lead to the failure of an aesthetic oral rehabilitation. The aim of this paper was to assess information related to the influence of functional forces on the biomechanics of tilted implants in implant oral rehabilitation. In order to investigate this hypothesis, a literature review was made in scientific articles indexed to PubMed, to assess the effect of the stress distribution in the bone-implant interface of tilted implants, through the analysis of the finite element method. The results showed that the use of tilted implants increases the concentration of stresses in the peri-implant cortical bone under the simulation of parafunctional loads. However, in-vitro tests may not accurately predict the behavior of biological tissues. Despite this limitation of the study, it can be concluded that high peaks of tension could compromise the strength limits of cortical bone, leading to failure of the bone-implant joint. However, when associated with multiple rehabilitations, the titled implants change their biomechanics, favoring the distribution and reduction of tension and the increase of the stability of restorations as a whole. Descriptors: Dental implants • Prostheses and implants • Mouth rehabilitation ...
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