Contribution of developmental changes in energy metabolism to excitation-contraction coupling of a ventricular cell: A simulation study

Hitomi I. Sano; Tamami Toki; Yasuhiro Naito; Masaru Tomita

Contribution of developmental changes in energy metabolism to excitation-contraction coupling of a ventricular cell: A simulation study

Hitomi I. Sano, Tamami Toki, Yasuhiro Naito, Masaru Tomita

環境情報学部

研究成果: Conference article › 査読

抄録

In fetal guinea pigs, ventricular cells have higher anaerobic glycolytic capacity and lower mitochondrial enzyme activity. Here, we implemented developmental changes in glycolytic enzyme activity, concentrations of glycogen, and total creatine in late embryonic and adult ventricular cell models. We then simulated the effects of hypoxic conditions on dynamic changes in contractile force and ATP concentration. Our model demonstrates that fetal ventricular cells maintain ATP for longer periods of time than adult ventricular cells. This is consistent with reported dynamics of ventricular cells under hypoxic conditions.

本文言語	English
論文番号	7042982
ページ（範囲）	73-76
ページ数	4
ジャーナル	Computing in Cardiology
巻	41
号	January
出版ステータス	Published - 2014 1月 1
イベント	41st Computing in Cardiology Conference, CinC 2014 - Cambridge, United States 継続期間: 2014 9月 7 → 2014 9月 10

ASJC Scopus subject areas

コンピュータサイエンス（全般）
循環器および心血管医学

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引用スタイル

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AB - In fetal guinea pigs, ventricular cells have higher anaerobic glycolytic capacity and lower mitochondrial enzyme activity. Here, we implemented developmental changes in glycolytic enzyme activity, concentrations of glycogen, and total creatine in late embryonic and adult ventricular cell models. We then simulated the effects of hypoxic conditions on dynamic changes in contractile force and ATP concentration. Our model demonstrates that fetal ventricular cells maintain ATP for longer periods of time than adult ventricular cells. This is consistent with reported dynamics of ventricular cells under hypoxic conditions.

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