The regeneration of critical sized bone defects requires the application of a scaffold able to instruct cells towards new tissue formation and remodelling. In the case of load-bearing bone parts, the requirement of high mimicry of native tissue is even more crucial since bone-like mechanical competence is required, besides bone-like chemistry and extensive macro-porous architecture. This chapter highlights some of the most recent advances in materials science addressed to this specific issue; in particular, it is illustrated how nature can inspire biomedical engineers to develop new biomorphic devices with hierarchical structure that can pave the way to new-generation smart devices with outstanding functional properties.
New strategies for regeneration of load bearing bones
Simone Sprio;Andrea Ruffini;Massimiliano Dapporto;Anna Tampieri
2016
Abstract
The regeneration of critical sized bone defects requires the application of a scaffold able to instruct cells towards new tissue formation and remodelling. In the case of load-bearing bone parts, the requirement of high mimicry of native tissue is even more crucial since bone-like mechanical competence is required, besides bone-like chemistry and extensive macro-porous architecture. This chapter highlights some of the most recent advances in materials science addressed to this specific issue; in particular, it is illustrated how nature can inspire biomedical engineers to develop new biomorphic devices with hierarchical structure that can pave the way to new-generation smart devices with outstanding functional properties.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
