2021
DOI: 10.1016/j.jiec.2020.11.004
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Promoting bone regeneration by 3D-printed poly(glycolic acid)/hydroxyapatite composite scaffolds

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Cited by 60 publications
(30 citation statements)
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“…The PGA scaffold containing HAp nanoparticles was prepared by 3D printing technology, and the bone regeneration rate was 47% 8 weeks after surgery. Compared with the existing scaffolds, the porous PGA/HAp scaffold was implanted in the rabbit skull defect model, and the key defect area was covered by bone tissue, which indicates that the scaffold can promote the bone regeneration process [ 56 ]. Due to the nondegradability, good wear resistance, and low thermal conductivity of zirconia through 3D printing, it is widely used in ceramic abutments, implants, and crowns, as well as the femoral head part of hip prostheses in THA [ 57 ].…”
Section: Materials Of 3d Printingmentioning
confidence: 99%
“…The PGA scaffold containing HAp nanoparticles was prepared by 3D printing technology, and the bone regeneration rate was 47% 8 weeks after surgery. Compared with the existing scaffolds, the porous PGA/HAp scaffold was implanted in the rabbit skull defect model, and the key defect area was covered by bone tissue, which indicates that the scaffold can promote the bone regeneration process [ 56 ]. Due to the nondegradability, good wear resistance, and low thermal conductivity of zirconia through 3D printing, it is widely used in ceramic abutments, implants, and crowns, as well as the femoral head part of hip prostheses in THA [ 57 ].…”
Section: Materials Of 3d Printingmentioning
confidence: 99%
“…Several studies have underlined the fragility of CaP scaffolds (which are highly porous), pointing them out as not suitable for weight-bearing bone defects. Therefore, in order to improve CaP mechanical and structural properties, different combinations have been attempted by adding other components with viscoelastic properties (tolerating high levels of strain or deformation and able to fill irregular-shaped bone defects) such as collagen [ 27 ], alginate [ 28 ], chitosan [ 29 , 30 ], polylactic acid (PLA) [ 31 ], and polyglycolic acid [ 32 ], giving rise to injectable hydrogel systems. They are typically biocompatible due to their large water content, and less prone to provoke an immune response [ 33 ].…”
Section: Strategies Promoting Bone Healing Through An Endogenous Responsementioning
confidence: 99%
“…Chen (2019) et al investigated the 3D printing of composite scaffolds composed of HA and gelatin, CS, and carboxymethyl cellulose (CMC) [ 81 ]. Yeo (2021) et al studied 3D-printed poly(glycolic acid)/HA composite scaffolds to promote bone regeneration [ 82 ]. The most important advantage of 3D-printed scaffolds is that 3D scaffolds can be used as tissue models to replicate the structural complexity of living tissues.…”
Section: Recent Strategies For Compounding Natural and Synthetic Poly...mentioning
confidence: 99%