Early natural history of neotissue formation in tissue-engineered vascular grafts in a murine model

被引:24
|
作者
Reinhardt, James W. [1 ]
Rosado, Juan de Dios Ruiz [2 ]
Barker, Jenny C. [1 ]
Lee, Yong-Ung [1 ]
Best, Cameron A. [1 ,3 ]
Yi, Tai [1 ]
Zeng, Qiang [1 ]
Partida-Sanchez, Santiago [2 ]
Shinoka, Toshiharu [1 ,4 ]
Breuer, Christopher K. [1 ,5 ]
机构
[1] Nationwide Childrens Hosp, Abigail Wexner Res Inst, Ctr Tissue Engn, Columbus, OH 43205 USA
[2] Nationwide Childrens Hosp, Abigail Wexner Res Inst, Ctr Microbial Pathogenesis, Columbus, OH 43205 USA
[3] Ohio State Univ, Coll Med, Biomed Sci Grad Program, Columbus, OH 43210 USA
[4] Nationwide Childrens Hosp, Dept Cardiothorac Surg, Columbus, OH 43205 USA
[5] Nationwide Childrens Hosp, Dept Surg, Columbus, OH 43205 USA
来源
REGENERATIVE MEDICINE | 2019年 / 14卷 / 05期
关键词
bioresorbable; infiltration; inflammation; neotissue; platelets; remodeling; thrombosis; vascular graft; PREVENTS STENOSIS; PLATELETS; GROWTH; INFLAMMATION; MACROPHAGES; DEFICIENCY; THROMBOSIS; ASPIRIN; CELLS;
D O I
10.2217/rme-2018-0133
中图分类号
Q813 [细胞工程];
学科分类号
摘要
Aim: To characterize early events in neotissue formation during the first 2 weeks after vascular scaffold implantation. Materials & methods: Biodegradable polymeric scaffolds were implanted as abdominal inferior vena cava interposition grafts in wild-type mice. Results: All scaffolds explanted at day 1 contained a platelet-rich mural thrombus. Within the first few days, the majority of cell infiltration appeared to be from myeloid cells at the peritoneal surface with modest infiltration along the lumen. Host reaction to the graft was distinct between the scaffold and mural thrombus; the scaffold stimulated an escalating foreign body reaction, whereas the thrombus was quickly remodeled into collagen-rich neotissue. Conclusion: Mural thrombi remodel into neotissue that persistently occludes the lumen of vascular grafts.
引用
收藏
页码:389 / 408
页数:20
相关论文
共 50 条
  • [21] The role of myeloid cell-derived PDGF-B in neotissue formation in a tissue-engineered vascular graft
    Onwuka, Ekene
    Best, Cameron
    Sawyer, Andrew
    Yi, Tai
    Heuer, Eric
    Sams, Malik
    Wiet, Matthew
    Zheng, Hong
    Kyriakides, Themis
    Breuer, Christopher
    REGENERATIVE MEDICINE, 2017, 12 (03) : 249 - 261
  • [22] Tissue-engineered Vascular Grafts for Congenital Heart Surgery
    Breuer, Christopher
    FASEB JOURNAL, 2020, 34
  • [23] Spontaneous reversal of stenosis in tissue-engineered vascular grafts
    Drews, Joseph D.
    Pepper, Victoria K.
    Best, Cameron A.
    Szafron, Jason M.
    Cheatham, John P.
    Yates, Andrew R.
    Hor, Kan N.
    Zbinden, Jacob C.
    Chang, Yu-Chun
    Mirhaidari, Gabriel J. M.
    Ramachandra, Abhay B.
    Miyamoto, Shinka
    Blum, Kevin M.
    Onwuka, Ekene A.
    Zakko, Jason
    Kelly, John
    Cheatham, Sharon L.
    King, Nakesha
    Reinhardt, James W.
    Sugiura, Tadahisa
    Miyachi, Hideki
    Matsuzaki, Yuichi
    Breuer, Julie
    Heuer, Eric D.
    West, T. Aaron
    Shoji, Toshihiro
    Berman, Darren
    Boe, Brian A.
    Asnes, Jeremy
    Galantowicz, Mark
    Matsumura, Goki
    Hibino, Narutoshi
    Marsden, Alison L.
    Pober, Jordan S.
    Humphrey, Jay D.
    Shinoka, Toshiharu
    Breuer, Christopher K.
    SCIENCE TRANSLATIONAL MEDICINE, 2020, 12 (537)
  • [24] Construction of vascular grafts based on tissue-engineered scaffolds
    Lang, Zhongliang
    Chen, Tianao
    Zhu, Shilu
    Wu, Xizhi
    Wu, Yongqi
    Miao, Xiaoping
    Wang, Qiang
    Zhao, Liping
    Zhu, Zhiqiang
    Xu, Ronald X.
    MATERIALS TODAY BIO, 2024, 29
  • [25] Tissue-Engineered Vascular Grafts: Emerging Trends and Technologies
    Gupta, Prerak
    Mandal, Biman B.
    ADVANCED FUNCTIONAL MATERIALS, 2021, 31 (33)
  • [26] Biofabrication of small diameter tissue-engineered vascular grafts
    Weekes, Angus
    Bartnikowski, Nicole
    Pinto, Nigel
    Jenkins, Jason
    Meinert, Christoph
    Klein, Travis J.
    ACTA BIOMATERIALIA, 2022, 138 : 92 - 111
  • [27] A Rat Model for the In Vivo Assessment of Biological and Tissue-Engineered Valvular and Vascular Grafts
    Sugimura, Yukiharu
    Schmidt, Anna Kathrin
    Lichtenberg, Artur
    Assmann, Alexander
    Akhyari, Payam
    TISSUE ENGINEERING PART C-METHODS, 2017, 23 (12) : 982 - 994
  • [28] Hemodynamic Characterization of a Mouse Model for Investigating the Cellular and Molecular Mechanisms of Neotissue Formation in Tissue-Engineered Heart Valves
    James, Iyore A.
    Yi, Tai
    Tara, Shuhei
    Best, Cameron A.
    Stuber, Alexander J.
    Shah, Kejal V.
    Austin, Blair F.
    Sugiura, Tadahisa
    Lee, Yong-Ung
    Lincoln, Joy
    Trask, Aaron J.
    Shinoka, Toshiharu
    Breuer, Christopher K.
    TISSUE ENGINEERING PART C-METHODS, 2015, 21 (09) : 987 - 994
  • [29] A critical role for macrophages in neovessel formation and the development of stenosis in tissue-engineered vascular grafts
    Hibino, Narutoshi
    Yi, Tai
    Duncan, Daniel R.
    Rathore, Animesh
    Dean, Ethan
    Naito, Yuji
    Dardik, Alan
    Kyriakides, Themis
    Madri, Joseph
    Pober, Jordan S.
    Shinoka, Toshiharu
    Breuer, Christopher K.
    FASEB JOURNAL, 2011, 25 (12): : 4253 - 4263
  • [30] An Early Study on the Mechanisms that Allow Tissue-Engineered Vascular Grafts to Resist Intimal Hyperplasia
    Prichard, Heather L.
    Manson, Roberto J.
    DiBernardo, Louis
    Niklason, Laura E.
    Lawson, Jeffrey H.
    Dahl, Shannon L. M.
    JOURNAL OF CARDIOVASCULAR TRANSLATIONAL RESEARCH, 2011, 4 (05) : 674 - 682
12345