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IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle
![IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle](https://www.mdpi.com/ijms/ijms-22-02475/article_deploy/html/images/ijms-22-02475-g007.png)
IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle
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Electrical coupling via gap junctions. (a) Schematic diagram of gap... | Download Scientific Diagram
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Gap junction-mediated cell-to-cell communication in oral development and oral diseases: a concise review of research progress | International Journal of Oral Science
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Gap junction-mediated cell-to-cell communication in oral development and oral diseases: a concise review of research progress | International Journal of Oral Science
![IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle](https://www.mdpi.com/ijms/ijms-22-02475/article_deploy/html/images/ijms-22-02475-g003-550.jpg)
IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle
![IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle](https://www.mdpi.com/ijms/ijms-22-02475/article_deploy/html/images/ijms-22-02475-g003.png)
IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle
![IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle](https://pub.mdpi-res.com/ijms/ijms-22-02475/article_deploy/html/images/ijms-22-02475-g001.png?1614597603)
IJMS | Free Full-Text | Gap Junctional Communication via Connexin43 between Purkinje Fibers and Working Myocytes Explains the Epicardial Activation Pattern in the Postnatal Mouse Left Ventricle
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