In this study we describe the fabrication of a variety of open-cellular titanium alloy(Ti-6 Al-4 V) implants,both reticular mesh and foam structures, using electron beam melting(EBM). These structures allow for th...In this study we describe the fabrication of a variety of open-cellular titanium alloy(Ti-6 Al-4 V) implants,both reticular mesh and foam structures, using electron beam melting(EBM). These structures allow for the elimination of stress shielding by adjusting the porosity(or density) to produce an elastic modulus(or stiffness) to match that of both soft(trabecular) and hard(cortical) bone, as well as allowing for bone cell ingrowth, increased cell density, and all-matrix interactions; the latter involving the interplay between bone morphogenetic protein(BMP-2) and osteoblast functions. The early formation and characterization of elementary vascular structures in an aqueous hydrogel matrix are illustrated.Preliminary results for both animal(sheep) and human trials for a number of EBM-fabricated, and often patient-specific Tialloy implants are also presented and summarized. The results, while preliminary, support the concept and development of successful, porous, engineered "living" implants.展开更多
基金supported in part by the Ministry of Science and Technology Project(2017YFC1104900 and 2016YFC1102601)the National Natural Science Foundation of China(51271182 and 51631007)+2 种基金Chinese Academy of Sciences Project(QYZDJ-SSW-JSC031)the Department of Metallurgical,Materials and Biomedical Engineering(Nune KC and Misra RDK)the Office of Research and Sponsored Projects(Correa-Rodriguez VL and Murr LE)at the University of Texas at El Paso
文摘In this study we describe the fabrication of a variety of open-cellular titanium alloy(Ti-6 Al-4 V) implants,both reticular mesh and foam structures, using electron beam melting(EBM). These structures allow for the elimination of stress shielding by adjusting the porosity(or density) to produce an elastic modulus(or stiffness) to match that of both soft(trabecular) and hard(cortical) bone, as well as allowing for bone cell ingrowth, increased cell density, and all-matrix interactions; the latter involving the interplay between bone morphogenetic protein(BMP-2) and osteoblast functions. The early formation and characterization of elementary vascular structures in an aqueous hydrogel matrix are illustrated.Preliminary results for both animal(sheep) and human trials for a number of EBM-fabricated, and often patient-specific Tialloy implants are also presented and summarized. The results, while preliminary, support the concept and development of successful, porous, engineered "living" implants.
