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Sook Hee Ku et al.
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Valentina Martinelli et al.
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Zhenghang Zhao et al.
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Daisuke Sato et al.
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Valentina Martinelli et al.
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Rosana A. Bassani et al.
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Min Young Lee et al.
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Jin-Oh You et al.
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Claire J. Fearnley et al.
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Porous polycaprolactone scaffold for cardiac tissue engineering fabricated by selective laser sintering
W. Y. Yeong et al.
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J. O. Aguilar et al.
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Electrical stimulation systems for cardiac tissue engineering
Nina Tandon et al.
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Yan Zhang et al.
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Marianna Foldvari et al.
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Cristina Buzea et al.
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Milica Radisic et al.
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O Ishii et al.
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JJ Zhao et al.
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M Radisic et al.
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WH Zimmermann et al.
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CH Xu et al.
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HT Yang et al.
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M Müller et al.
FASEB JOURNAL (2000)