ホンマ ジユン   Honma Jiyun
  本間 順
   所属   医学研究科 医学研究科 (医学部医学科をご参照ください)
   職種   助教
論文種別 原著
言語種別 英語
査読の有無 査読あり
表題 Aligned human induced pluripotent stem cell-derived cardiac tissue improves contractile properties through promoting unidirectional and synchronous cardiomyocyte contraction.
掲載誌名 正式名:Biomaterials
略  称:Biomaterials
ISSNコード:18785905/01429612
掲載区分国外
巻・号・頁 281,pp.121351
著者・共著者 TAKADA Takuma†, SASAKI Daisuke*, MATSUURA Katsuhisa*, MIURA Koichiro, SAKAMOTO Satoru, IIDA Tatsuro, HOMMA Jun, SHIMIZU Tatsuya, HAGIWARA Nobuhisa
発行年月 2021/12
概要 Alignment, as seen in the native myocardium, is crucial for the fabrication of functional cardiac tissue. However, it remains unclear whether the control of cardiomyocyte alignment influences cardiac function and the underlying mechanisms. We fabricated aligned human cardiac tissue using a micro-processed fibrin gel with inverted V-shaped ridges (MFG) and elucidated the effect of alignment control on contractile properties. When human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) were seeded on MFG, hiPSC-CMs were aligned more uniformly than the control, and we succeeded in fabricating the aligned cardiac tissue. Assessing the contractile properties with the direct contractile measurement system, the contractile force, maximum contractile velocity, and relaxation velocity were significantly increased in aligned cardiac tissue compared with non-aligned cardiac tissue. However, gene expression profiles were not different between the two groups, suggesting that functional improvement of cardiac tissue through alignment control might not be dependent on cardiomyocyte maturation. Motion capture analysis revealed that the cardiomyocytes in the aligned cardiac tissues showed more unidirectional and synchronous contraction than the non-aligned cardiac tissues, indicating that cardiac tissue maturation involves electrical integration of cardiomyocytes. Herein, cardiomyocyte alignment control might improve the contractile properties of cardiac tissue through promoting unidirectional and synchronous cardiomyocyte contraction.
DOI 10.1016/j.biomaterials.2021.121351
PMID 34979417