Willian Fernando Zambuzzi scite author profile

BackgroundIt is known that physico/chemical alterations on biomaterial surfaces have the capability to modulate cellular behavior, affecting early tissue repair. Such surface modifications are aimed to improve early healing response and, clinically, offer the possibility to shorten the time from implant placement to functional loading. Since FAK and Src are intracellular proteins able to predict the quality of osteoblast adhesion, this study evaluated the osteoblast behavior in response to nanometer scale titanium surface texturing by monitoring FAK and Src phosphorylations.MethodologyFour engineered titanium surfaces were used for the study: machined (M), dual acid-etched (DAA), resorbable media microblasted and acid-etched (MBAA), and acid-etch microblasted (AAMB). Surfaces were characterized by scanning electron microscopy, interferometry, atomic force microscopy, x-ray photoelectron spectroscopy and energy dispersive X-ray spectroscopy. Thereafter, those 4 samples were used to evaluate their cytotoxicity and interference on FAK and Src phosphorylations. Both Src and FAK were investigated by using specific antibody against specific phosphorylation sites.Principal FindingsThe results showed that both FAK and Src activations were differently modulated as a function of titanium surfaces physico/chemical configuration and protein adsorption.ConclusionsIt can be suggested that signaling pathways involving both FAK and Src could provide biomarkers to predict osteoblast adhesion onto different surfaces.

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Receptor activator NFκB-ligand and osteoprotegerin protein expression in human periapical cysts and granulomas

Menezes

Bramante

Paiva

et al. 2006

Oral Surgery, Oral Medicine, Oral Pathology, Oral Radiology, an

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On the road to understanding of the osteoblast adhesion: Cytoskeleton organization is rearranged by distinct signaling pathways

Zambuzzi

Bruni‐Cardoso

Granjeiro

et al. 2009

J of Cellular Biochemistry

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Pre-osteoblast adhesion attracts increasing interest in both medicine and dentistry. However, how this physiological event alters osteoblast phenotype is poorly understood. We therefore attempted to address this question by investigating key biochemical mechanism that governs pre-osteoblast adhesion on polystyrene surface. Importantly, we found that cofilin activity was strongly modulated by PP2A (Ser/Thr phosphatase), while cell-cycle was arrested. Accordingly, we observed that the profile of cofilin phosphorylation (at Ser03) was similar to phospho-PP2A (at Tyr307). Also, it is plausible to suggest during pre-osteoblast adhesion that PP2A phosphorylation at Y307 was executed by phospho-Src (Y416). In addition, it was observed that MAPKp38, but not MAPK-erk, played a key role on pre-osteoblast adhesion by phosphorylating MAPKAPK-2 and ATF-2 (also called CRE-BP1). Also, the up-modulation of RhoA reported here suggests its involvement at the beginning of osteoblast attachment, while Akt remained active during all periods. Altogether, our results clearly showed that osteoblast adhesion is under an intricate network of signaling molecules, which are responsible to guide their interaction with substrate mainly via cytoskeleton rearrangement.

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