Beyond 2D: 3D bioprinting for skin regeneration

被引:28
|
作者
Wang, Rui [1 ,2 ,3 ]
Wang, Yihui [1 ,2 ,3 ]
Yao, Bin [2 ,3 ,4 ]
Hu, Tian [2 ,3 ,4 ]
Li, Zhao [5 ]
Huang, Sha [2 ,3 ,5 ]
Fu, Xiaobing [2 ,3 ,5 ]
机构
[1] Tianjin Med Univ, Tianjin, Peoples R China
[2] Gen Hosp PLA, Hosp Affiliated 1, Key Lab Tissue Repair & Regenerat PLA, Beijing 100048, Peoples R China
[3] Gen Hosp PLA, Hosp Affiliated 1, Beijing Key Res Lab Skin Injury Repair & Regenera, Beijing, Peoples R China
[4] Nankai Univ, Sch Med, Tianjin, Peoples R China
[5] Gen Hosp PLA, Inst Basic Med Sci, Wound Healing & Cell Biol Lab, Beijing 100853, Peoples R China
来源
INTERNATIONAL WOUND JOURNAL | 2019年 / 16卷 / 01期
基金
国家重点研发计划;
关键词
3D bioprinting; extracellular matrices; skin regeneration; EXTRACELLULAR-MATRIX; CROSS-LINKING; STEM-CELLS; COLLAGEN; FABRICATION; FUTURE;
D O I
10.1111/iwj.13003
中图分类号
R75 [皮肤病学与性病学];
学科分类号
100206 ;
摘要
Essential cellular functions that are present in tissues are missed by two-dimensional (2D) cell monolayer culture. It certainly limits their potential to predict the cellular responses of real organisms. Engineering approaches offer solutions to overcome current limitations. For example, establishing a three-dimensional (3D)-based matrix is motivated by the need to mimic the functions of living tissues, which will have a strong impact on regenerative medicine. However, as a novel approach, it requires the development of new standard protocols to increase the efficiency of clinical translation. In this review, we summarised the various aspects of requirements related to well-suited 3D bioprinting techniques for skin regeneration and discussed how to overcome current bottlenecks and propel these therapies into the clinic.
引用
收藏
页码:134 / 138
页数:5
相关论文
共 50 条
  • [31] Recent advances in 3D bioprinting for the regeneration of functional cartilage
    Ji Xiongfa
    Zhu Hao
    Zhao Liming
    Xiao Jun
    REGENERATIVE MEDICINE, 2018, 13 (01) : 73 - 87
  • [32] Neurovascular interactions in 2D and 3D skin equivalent models
    Rovini, Amandine
    Siadous, Robin
    Bordes, Sylvie
    Closs, Brigitte
    Leng, Jacques
    Berthod, Francois
    Amedee, Joelle
    Desmouliere, Alexis
    WOUND REPAIR AND REGENERATION, 2022, 30 (05) : A16 - A16
  • [33] Decellularization and Their Significance for Tissue Regeneration in the Era of 3D Bioprinting
    Gadre, Mrunmayi
    Kasturi, Meghana
    Agarwal, Prachi
    Vasanthan, Kirthanashri S.
    ACS OMEGA, 2024, 9 (07): : 7375 - 7392
  • [34] Advances in tissue engineering and 3D bioprinting for corneal regeneration
    Monostori, Tamas
    Szucs, Diana
    Lovaszi, Borbala
    Kemeny, Lajos
    Vereb, Zoltan
    INTERNATIONAL JOURNAL OF BIOPRINTING, 2024, 10 (02) : 107 - 130
  • [35] 2D or not 2D That is the Question, but 3D is the, answer
    Cronin, Paul
    ACADEMIC RADIOLOGY, 2007, 14 (07) : 769 - 771
  • [36] 3D and 2D/3D holograms model
    A. A. Boriskevich
    V. K. Erohovets
    V. V. Tkachenko
    Optical Memory and Neural Networks, 2012, 21 (4) : 242 - 248
  • [37] Therapeutic Efficacy of Artificial Skin Produced by 3D Bioprinting
    Jang, Kwang-Sik
    Park, Soon-Jung
    Choi, Jong-Jin
    Kim, Ha-Na
    Shim, Kyung-Mi
    Kim, Mi-Jeong
    Jang, Il-Ho
    Jin, Song-Wan
    Kang, Seong-Soo
    Kim, Se-Eun
    Moon, Sung-Hwan
    MATERIALS, 2021, 14 (18)
  • [38] Regenerative Skin Tissue Engineering through 3D Bioprinting
    Sadiq, A.
    Hayat, M. Q.
    AMERICAN JOURNAL OF PATHOLOGY, 2018, 188 (10): : 2438 - 2438
  • [39] Wound and Skin Healing in Space: The 3D Bioprinting Perspective
    Cubo-Mateo, Nieves
    Gelinsky, Michael
    FRONTIERS IN BIOENGINEERING AND BIOTECHNOLOGY, 2021, 9
  • [40] 3D bioprinting applications for the printing of skin: A brief study
    Javaid, Mohd
    Haleem, Abid
    Sensors International, 2021, 2
12345