This study investigates the biological effects on a 3D scaffold based on hydroxyapatite cultured with MC3T3 osteoblasts in response to flow-induced shear stress(FSS).The scaffold adopted here(B-HA)derives from the bio...This study investigates the biological effects on a 3D scaffold based on hydroxyapatite cultured with MC3T3 osteoblasts in response to flow-induced shear stress(FSS).The scaffold adopted here(B-HA)derives from the biomorphic transformation of natural wood and its peculiar channel geometry mimics the porous structure of the bone.From the point of view of fluid dynamics,B-HA can be considered a network of micro-channels,intrinsically offering the advantages of a microfluidic system.This work,for the first time,offers a description of the fluid dynamic properties of the B-HA scaffold,which are strongly connected to its morphology.These features are necessary to determine the FSS ranges to be applied during in vitro studies to get physiologically relevant conditions.The selected ranges of FSS promoted the elongation of the attached cells along the flow direction and early osteogenic cell differentiation.These data confirmed the ability of B-HA to promote the differentiation process along osteogenic lineage.Hence,such a bioactive and naturally derived scaffold can be considered as a promising tool for bone regeneration applications.展开更多
基金funded by FAR 2019 Interdepartmental Grant,titled“Microfluidics-based 3D cell culture models for bone regeneration”awarded by the University of Modena and Reggio Emilia.
文摘This study investigates the biological effects on a 3D scaffold based on hydroxyapatite cultured with MC3T3 osteoblasts in response to flow-induced shear stress(FSS).The scaffold adopted here(B-HA)derives from the biomorphic transformation of natural wood and its peculiar channel geometry mimics the porous structure of the bone.From the point of view of fluid dynamics,B-HA can be considered a network of micro-channels,intrinsically offering the advantages of a microfluidic system.This work,for the first time,offers a description of the fluid dynamic properties of the B-HA scaffold,which are strongly connected to its morphology.These features are necessary to determine the FSS ranges to be applied during in vitro studies to get physiologically relevant conditions.The selected ranges of FSS promoted the elongation of the attached cells along the flow direction and early osteogenic cell differentiation.These data confirmed the ability of B-HA to promote the differentiation process along osteogenic lineage.Hence,such a bioactive and naturally derived scaffold can be considered as a promising tool for bone regeneration applications.