题名 | Three-dimensional (3D) printed scaffold and material selection for bone repair |
作者 | |
发表日期 | 2019-01-15 |
发表期刊 | ACTA BIOMATERIALIA 影响因子和分区 |
语种 | 英语 |
原始文献类型 | Review |
关键词 | 3D printing Bone tissue engineering Bone defect Porous scaffold Biomaterials |
其他关键词 | BETA-TRICALCIUM PHOSPHATE ; MESENCHYMAL STEM-CELLS ; BIOACTIVE GLASS SCAFFOLDS ; PROMOTES CHONDROGENIC DIFFERENTIATION ; POLY(PROPYLENE FUMARATE) SCAFFOLDS ; POROUS HYDROXYAPATITE SCAFFOLDS ; EPSILON-CAPROLACTONE SCAFFOLDS ; POLY(LACTIC ACID) SCAFFOLDS ; POLY-LACTIC-ACID ; MECHANICAL-PROPERTIES |
摘要 | Critical-sized bone defect repair remains a substantial challenge in clinical settings and requires bone grafts or bone substitute materials. However, existing biomaterials often do not meet the clinical requirements of structural support, osteoinductive property, and controllable biodegradability. To treat large-scale bone defects, the development of three-dimensional (3D) porous scaffolds has received considerable focus within bone engineering. A variety of biomaterials and manufacturing methods, including 3D printing, have emerged to fabricate patient-specific bioactive scaffolds that possess controlled micro-architectures for bridging bone defects in complex configurations. During the last decade, with the development of the 3D printing industry, a large number of tissue-engineered scaffolds have been created for preclinical and clinical applications using novel materials and innovative technologies. Thus, this review provides a brief overview of current progress in existing biomaterials and tissue engineering scaffolds prepared by 3D printing technologies, with an emphasis on the material selection, scaffold design optimization, and their preclinical and clinical applications in the repair of critical-sized bone defects. Furthermore, it will elaborate on the current limitations and potential future prospects of 3D printing technology. Statement of Significance 3D printing has emerged as a critical fabrication process for bone engineering due to its ability to control bulk geometry and internal structure of tissue scaffolds. The advancement of bioprinting methods and compatible ink materials for bone engineering have been a major focus to develop optimal 3D scaffolds for bone defect repair. Achieving a successful balance of cellular function, cellular viability, and mechanical integrity under load-bearing conditions is critical. Hybridization of natural and synthetic polymerbased materials is a promising approach to create novel tissue engineered scaffolds that combines the advantages of both materials and meets various requirements, including biological activity, mechanical strength, easy fabrication and controllable degradation. 3D printing is linked to the future of bone grafts to create on-demand patient-specific scaffolds. (C) 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved. |
资助项目 | Maryland Stem Cell Research Fund, USA [2018-MSCRFD-4271] |
出版者 | ELSEVIER SCI LTD |
出版地 | OXFORD |
ISSN | 1742-7061 |
EISSN | 1878-7568 |
卷号 | 84页码:16-33 |
DOI | 10.1016/j.actbio.2018.11.039 |
页数 | 18 |
WOS类目 | Engineering, Biomedical ; Materials Science, Biomaterials |
WOS研究方向 | Engineering ; Materials Science |
WOS记录号 | WOS:000456902700002 |
收录类别 | SCIE ; PUBMED ; EI ; SCOPUS |
EI入藏号 | 20215111347835 |
URL | 查看原文 |
PubMed ID | 30481607 |
SCOPUSEID | 2-s2.0-85058509279 |
ESI高被引论文 | 2020-03 ; 2020-05 ; 2020-09 ; 2020-11 ; 2021-01 ; 2021-03 ; 2021-05 ; 2021-07 ; 2021-09 ; 2021-11 ; 2022-01 ; 2022-03 ; 2022-05 ; 2022-07 ; 2022-09 ; 2022-11 ; 2023-01 ; 2023-03 ; 2023-05 ; 2023-07 ; 2023-09 ; 2023-11 ; 2024-01 ; 2024-03 ; 2024-05 ; 2024-07 ; 2024-09 ; 2024-11 |
通讯作者地址 | [Jia, Xiaofeng]null |
Scopus学科分类 | Biotechnology;Biomaterials;Biochemistry;Biomedical Engineering;Molecular Biology |
TOP期刊 | TOP期刊 |
引用统计 | |
文献类型 | 期刊论文 |
条目标识符 | https://kms.wmu.edu.cn/handle/3ETUA0LF/10692 |
专题 | 其他_附属第三医院(瑞安市人民医院) |
通讯作者 | Jia, Xiaofeng |
作者单位 | 1.Department of Orthopaedics,The Third Affiliated Hospital of Wenzhou Medical University,Wenzhou,325200,China; 2.Department of Industrial and Systems Engineering,Virginia Tech,Blacksburg,24061,United States; 3.Department of Neurosurgery,University of Maryland School of Medicine,Baltimore,21201,United States; 4.Department of Orthopedics,University of Maryland School of Medicine,Baltimore,21201,United States; 5.Department of Anatomy and Neurobiology,University of Maryland School of Medicine,Baltimore,21201,United States; 6.Department of Biomedical Engineering,Johns Hopkins University School of Medicine,Baltimore,21205,United States; 7.Department of Anesthesiology and Critical Care Medicine,Johns Hopkins University School of Medicine,Baltimore,21205,United States |
第一作者单位 | 其他_附属第三医院(瑞安市人民医院) |
第一作者的第一单位 | 其他_附属第三医院(瑞安市人民医院) |
推荐引用方式 GB/T 7714 | Zhang, Lei,Yang, Guojing,Johnson, Blake N.,et al. Three-dimensional (3D) printed scaffold and material selection for bone repair[J]. ACTA BIOMATERIALIA,2019,84:16-33. |
APA | Zhang, Lei, Yang, Guojing, Johnson, Blake N., & Jia, Xiaofeng. (2019). Three-dimensional (3D) printed scaffold and material selection for bone repair. ACTA BIOMATERIALIA, 84, 16-33. |
MLA | Zhang, Lei,et al."Three-dimensional (3D) printed scaffold and material selection for bone repair".ACTA BIOMATERIALIA 84(2019):16-33. |
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