3D Printed Chondrogenic Functionalized PGS Bioactive Scaffold for Cartilage Regeneration

被引:15
|
作者
Wang, Sinan [1 ,2 ]
Luo, Bin [3 ]
Bai, Baoshuai [2 ]
Wang, Qianyi [1 ]
Chen, Hongying [1 ]
Tan, Xiaoyan [1 ]
Tang, Zhengya [1 ]
Shen, Sisi [1 ]
Zhou, Hengxing [2 ]
You, Zhengwei [3 ]
Zhou, Guangdong [1 ]
Lei, Dong [1 ]
机构
[1] Shanghai Jiao Tong Univ, Shanghai Peoples Hosp 9, Sch Med, Dept Cardiol,Dept Plast & Reconstruct Surg, Shanghai 200011, Peoples R China
[2] Shandong Univ, Qilu Hosp, Ctr Orthopaed, Adv Med Res Inst,Cheeloo Coll Med,Dept Orthopaed, Jinan 250012, Peoples R China
[3] Donghua Univ, Inst Funct Mat, Coll Mat Sci & Engn, Key Lab Modificat Chem Fibers & Polymer Mat, Shanghai 201620, Peoples R China
来源
ADVANCED HEALTHCARE MATERIALS | 2023年 / 12卷 / 27期
基金
中国国家自然科学基金; 上海市自然科学基金;
关键词
3D printing; cartilage regeneration; functionalized scaffolds; poly(glycerol sebacate); swelling absorption; TISSUE; BONE; ELASTOMER; POLYMER; REPAIR;
D O I
10.1002/adhm.202301006
中图分类号
R318 [生物医学工程];
学科分类号
0831 ;
摘要
Tissue engineering is emerging as a promising approach for cartilage regeneration and repair. Endowing scaffolds with cartilaginous bioactivity to obtain bionic microenvironment and regulating the matching of scaffold degradation and regeneration play a crucial role in cartilage regeneration. Poly(glycerol sebacate) (PGS) is a representative thermosetting bioelastomer known for its elasticity, biodegradability, and biocompatibility and is widely used in tissue engineering. However, the modification and drug loading of the PGS scaffold is still a key challenge due to its high temperature curing conditions and limited reactive groups, which seriously hinders its further functional application. Here, a simple versatile new strategy of super swelling-absorption and cross-linked networks locking is presented to successfully create the 3D printed PGS-CS/Gel scaffold for the first time based on FDA-approved PGS, gelatin (Gel) and chondroitin sulfate (CS). The PGS-CS/Gel scaffold exhibits the desirable synergistic properties of well-organized hierarchical structures, excellent elasticity, improved hydrophilicity, and cartilaginous bioactivity, which can promote the adhesion, proliferation, and migration of chondrocytes. Importantly, the rate of cartilage regeneration can be well-matched with degradation of PGS-CS/Gel scaffold, and achieve uniform and mature cartilage tissue without scaffold residual. The bioactive scaffold can successfully repair cartilage in a rabbit trochlear groove defect model indicating a promising prospect of clinical transformation.
引用
收藏
页数:15
相关论文
共 50 条
  • [31] Incorporation of Magnesium Ions into an Aptamer-Functionalized ECM Bioactive Scaffold for Articular Cartilage Regeneration
    Liao, Zhiyao
    Fu, Liwei
    Li, Pinxue
    Wu, Jiang
    Yuan, Xun
    Ning, Chao
    Ding, Zhengang
    Sui, Xiang
    Liu, Shuyun
    Guo, Quanyi
    ACS APPLIED MATERIALS & INTERFACES, 2023, 15 (19) : 22944 - 22958
  • [32] 3D-Printed-Cryogel-Impregnated Functionalized Scaffold Augments Bone Regeneration in Critical Tibia Fracture in Goat
    Nikhil, Aman
    Gugjoo, Mudasir B.
    Das, Ankita
    Ahmad, Syed M.
    Kumar, Ashok
    ADVANCED HEALTHCARE MATERIALS, 2024, 13 (32)
  • [33] Enhancing cartilage regeneration and repair through bioactive and biomechanical modification of 3D acellular dermal matrix
    Gao, Wei
    Cheng, Tan
    Tang, Zhengya
    Zhang, Wenqiang
    Xu, Yong
    Han, Min
    Zhou, Guangdong
    Tao, Chunsheng
    Xu, Ning
    Xia, Huitang
    Sun, Weijie
    REGENERATIVE BIOMATERIALS, 2024, 11
  • [34] 3D printing of lithium osteogenic bioactive composite scaffold for enhanced bone regeneration
    Wang, Wenzhao
    Wei, Jianlu
    Lei, Dong
    Wang, Suning
    Zhang, Boqing
    Shang, Shenghui
    Bai, Baoshuai
    Zhao, Chenxi
    Zhang, Wencan
    Zhou, Changchun
    Zhou, Hengxing
    Feng, Shiqing
    COMPOSITES PART B-ENGINEERING, 2023, 256
  • [35] Direct 3D printing of decellularized matrix embedded composite polycaprolactone scaffolds for cartilage regeneration
    Gruber, Stacey M. S.
    Murab, Sumit
    Ghosh, Paulomi
    Whitlock, Patrick W.
    Lin, Chia-Ying J.
    BIOMATERIALS ADVANCES, 2022, 140
  • [36] 3D printing electrospinning fiber-reinforced decellularized extracellular matrix for cartilage regeneration
    Chen, Weiming
    Xu, Yong
    Li, Yaqiang
    Jia, Litao
    Mo, Xiumei
    Jiang, Gening
    Zhou, Guangdong
    CHEMICAL ENGINEERING JOURNAL, 2020, 382
  • [37] Dual-crosslinked 3D printed gelatin scaffolds with potential for temporomandibular joint cartilage regeneration
    Helgeland, Espen
    Rashad, Ahmad
    Campodoni, Elisabetta
    Goksoyr, Oyvind
    Pedersen, Torbjorn ostvik
    Sandri, Monica
    Rosen, Annika
    Mustafa, Kamal
    BIOMEDICAL MATERIALS, 2021, 16 (03)
  • [38] 3D Bioprinting of a Bioactive Composite Scaffold for Cell Delivery in Periodontal Tissue Regeneration
    Miao, Guohou
    Liang, Liyu
    Li, Wenzhi
    Ma, Chaoyang
    Pan, Yuqian
    Zhao, Hongling
    Zhang, Qing
    Xiao, Yin
    Yang, Xuechao
    BIOMOLECULES, 2023, 13 (07)
  • [39] Polycaprolactone Foam Functionalized With Chitosan Microparticles - a Suitable Scaffold for Cartilage Regeneration
    Filova, E.
    Jakubcova, B.
    Danilova, I.
    Kostakova, E. Kuzelova
    Jarosikova, T.
    Chernyavskiy, O.
    Hejda, J.
    Handl, M.
    Beznoska, J.
    Necas, A.
    Rosina, J.
    Amler, E.
    PHYSIOLOGICAL RESEARCH, 2016, 65 (01) : 121 - 131
  • [40] 3D Printed Anatomical Nerve Regeneration Pathways
    Johnson, Blake N.
    Lancaster, Karen Z.
    Zhen, Gehua
    He, Junyun
    Gupta, Maneesh K.
    Kong, Yong Lin
    Engel, Esteban A.
    Krick, Kellin D.
    Ju, Alex
    Meng, Fanben
    Enquist, Lynn W.
    Jia, Xiaofeng
    McAlpine, Michael C.
    ADVANCED FUNCTIONAL MATERIALS, 2015, 25 (39) : 6205 - 6217
12345