Resposta tecidual ao compósito 50% hidroxiapatita: 50% poli-hidroxibutirato para substituição óssea em coelhos

Abstract: RESUMOAvaliaram-se a biocompatibilidade, a osseointegração, a osseocondução e a biodegradação de compósitos de 50% hidroxiapatita (HAP-91®) e 50% poli-hidroxibutirato. O compósito foi implantado em defeitos ósseos em 12 coelhos (grupo experimental), sendo comparado a defeitos não preenchidos (grupo-controle, de igual número). Os parâmetros clínicos dor, claudicação, infecção, deiscência e edema foram avaliados nos primeiros oito dias após a cirurgia e aos 45 e 90 dias. Radiografias foram realizadas aos oito, 4… Show more

“…There was no formation of fibrous capsule and inflammatory infiltration related to the biomaterial at any moment, suggesting biocompatibility. Although in lesser amounts, the biomaterial was still present at the day 150, but there was no evidence of phagocytosis in histological sections, as previously described by BORGES et al (2000) and CARLO et al (2009). ALVES et al (2011, who applied hydroxyapatite-polyhydroxybutyrate composite in cats, found fibrous capsule formation in response to a chronic inflammatory process, suggesting that this type of reaction could generate mechanical failure of the implant.…”

“…Coating the implants has been suggested in order to avoid this problem (EPINETTE & MANELY, 2007). Studies using hydroxyapatite as biomaterial in bone repair have proved its osteoconductive and biocompatibility (CARLO et al, 2009;FABBRI et al, 2010) with polymers can enhance its properties. Lignin is a complex natural polymer that is biocompatible and has great potential in association with hydroxyapatite as a biomaterial for bone repair (MARTÍNEZ et al, 2009a) and metal implants coating (ERAKOVIĆ et al, 2012).…”

Hydroxyapatite-lignin composite as a metallic implant-bone tissue osseointegration improver: experimental study in dogs

“…There was no formation of fibrous capsule and inflammatory infiltration related to the biomaterial at any moment, suggesting biocompatibility. Although in lesser amounts, the biomaterial was still present at the day 150, but there was no evidence of phagocytosis in histological sections, as previously described by BORGES et al (2000) and CARLO et al (2009). ALVES et al (2011, who applied hydroxyapatite-polyhydroxybutyrate composite in cats, found fibrous capsule formation in response to a chronic inflammatory process, suggesting that this type of reaction could generate mechanical failure of the implant.…”

“…Coating the implants has been suggested in order to avoid this problem (EPINETTE & MANELY, 2007). Studies using hydroxyapatite as biomaterial in bone repair have proved its osteoconductive and biocompatibility (CARLO et al, 2009;FABBRI et al, 2010) with polymers can enhance its properties. Lignin is a complex natural polymer that is biocompatible and has great potential in association with hydroxyapatite as a biomaterial for bone repair (MARTÍNEZ et al, 2009a) and metal implants coating (ERAKOVIĆ et al, 2012).…”

Hydroxyapatite-lignin composite as a metallic implant-bone tissue osseointegration improver: experimental study in dogs

“…Regarding the porosity of the samples, as reported by Rodrigues et al [ 20 ], Woodard et al [ 21 ], and Carlo et al [ 40 ], the presence of pores is important for the formation of new bone, as they allow the migration and proliferation of osteoblasts and mesenchymal cells. Moreover, the porous structure of hydroxyapatite works as a passive support for vascular neoformation (angiogenesis), making the repair process more dynamic.…”

In vitro characterization of hydroxyapatite and cobalt ferrite nanoparticles compounds and their biocompatibility in vivo

Hydroxyapatite, polycaprolactone and alendronate composites for bone regeneration in rabbits' olecranon: histological features