Effect of CDM3 on the co-culture of human induced pluripotent stem cells with matrigel-coated polycaprolactone to make cardiac patch_Chinese Journal of Clinical Thoracic and Cardiovascular Surgery

Authors：

DAI Yue ¹ , ZHOU Fan ² , ZHENG Jianwei ³ ,  MU Junsheng ¹ , BO Ping ¹ , YOU Bin ¹

1. Department of Cardiac Surgery, Beijing Anzhen Hospital, Capital Medical University, Beijing Institute of Heart Lung and Blood Vessel Diseases, Beijing, 100029, P. R. China;
2. Department of Ultrasound, The Third Medical Center of PLA General Hospital, Beijing, 100039, P. R. China;
3. Heart Center of Sunshine Fusion Hospital, Weifang, 261205, Shandong, P. R. China;

Corresponding?author：

MU Junsheng, Email: wesleymu@hotmail.com

Keywords：

Human induced pluripotent stem cells; polycaprolactone; CDM3; cardiac patch

DOI：

10.7507/1007-4848.202206078

Video：

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Objective To provide experimental data and theoretical support for further studying the maturity of cardiac patches in other in vitro experiments and the safety in other in vivo animal experiments, through standard chemically defined and small molecule-based induction protocol (CDM3) for promoting the differentiation of human induced pluripotent stem cells (hiPSCs) into myocardium, and preliminarily preparing cardiac patches. Methods After resuscitation, culture and identification of hiPSCs, they were inoculated on the matrigel-coated polycaprolactone (PCL). After 24 hours, the cell growth was observed by DAPI fluorescence under a fluorescence microscope, and the stemness of hiPSCs was identified by OCT4 fluorescence. After fixation, electron microscope scanning was performed to observe the cell morphology on the surface of the patch. On the 1st, 3rd, 5th, and 7th days of culture, the cell viability was determined by CCK-8 method, and the growth curve was drawn to observe the cell growth and proliferation. After co-cultured with matrigel-coated PCL for 24 hours, hiPSCs were divided into a control group and a CDM3 group, and continued to culture for 6 days. On the 8th day, the cell growth was observed by DAPI fluorescence under a fluorescence microscope, and hiPSCs stemness was identified by OCT4 fluorescence, and cTnT and α-actin for cardiomyocyte marker identification. Results Immunofluorescence of hiPSCs co-cultured with matrigel-coated PCL for 24 hours showed that OCT4 emitted green fluorescence, and hiPSCs remained stemness on matrigel-coated PCL scaffolds. DAPI emitted blue fluorescence: cells grew clonally with uniform cell morphology. Scanning electron microscope showed that hiPSCs adhered and grew on matrigel-coated PCL, the cell outline was clearly visible, and the morphology was normal. The cell viability assay by CCK-8 method showed that hiPSCs proliferated and grew on PCL scaffolds coated with matrigel. After 6 days of culture in the control group and the CDM3 group, immunofluorescence showed that the hiPSCs in the control group highly expressed the stem cell stemness marker OCT4, but did not express the cardiac markers cTnT and α-actin. The CDM3 group obviously expressed the cardiac markers cTnT and α-actin, but did not express the stem cell stemness marker OCT4. Conclusion hiPSCs can proliferate and grow on matrigel-coated PCL. Under the influence of CDM3, hiPSCs can be differentiated into cardiomyocyte-like cells, and the preliminary preparation of cardiac patch can provide a better treatment method for further clinical treatment of cardiac infarction.

Citation： DAI Yue, ZHOU Fan, ZHENG Jianwei, MU Junsheng, BO Ping, YOU Bin. Effect of CDM3 on the co-culture of human induced pluripotent stem cells with matrigel-coated polycaprolactone to make cardiac patch. Chinese Journal of Clinical Thoracic and Cardiovascular Surgery, 2023, 30(5): 738-745. doi: 10.7507/1007-4848.202206078 Copy

1.	Virani SS, Alonso A, Benjamin EJ, et al. Heart disease and stroke statistics-2020 update: A report from the American Heart Association. Circulation, 2020, 141(9): e139-e596.
2.	Sutton MG, Sharpe N. Left ventricular remodeling after myocardial infarction: Pathophysiology and therapy. Circulation, 2000, 101(25): 2981-2988.
3.	Anderson JL, Morrow DA. Acute myocardial infarction. N Engl J Med, 2017, 376(21): 2053-2064.
4.	Yu H, Lu K, Zhu J, et al. Stem cell therapy for ischemic heart diseases. Br Med Bull, 2017, 121(1): 135-154.
5.	Laflamme MA, Murry CE. Heart regeneration. Nature, 2011, 473(7347): 326-335.
6.	Cahill TJ, Choudhury RP, Riley PR. Heart regeneration and repair after myocardial infarction: Translational opportunities for novel therapeutics. Nat Rev Drug Discov, 2017, 16(10): 699-717.
7.	Karagiannis P, Takahashi K, Saito M, et al. Induced pluripotent stem cells and their use in human models of disease and development. Physiol Rev, 2019, 99(1): 79-114.
8.	Burridge PW, Matsa E, Shukla P, et al. Chemically defined generation of human cardiomyocytes. Nat Methods, 2014, 11(8): 855-860.
9.	Gerecht-Nir S, Radisic M, Park H, et al. Biophysical regulation during cardiac development and application to tissue engineering. Int J Dev Biol, 2006, 50(2-3): 233-243.
10.	Iberite F, Gruppioni E, Ricotti L. Skeletal muscle differentiation of human iPSCs meets bioengineering strategies: Perspectives and challenges. NPJ Regen Med, 2022, 7(1): 23.
11.	Csobonyeiova M, Polak S, Nicodemou A, et al. iPSCs in modeling and therapy of osteoarthritis. Biomedicines, 2021, 9(2): 186.
12.	Nguyen R, Da Won Bae S, Qiao L, et al. Developing liver organoids from induced pluripotent stem cells (iPSCs): An alternative source of organoid generation for liver cancer research. Cancer Lett, 2021, 508: 13-17.
13.	Van Lent J, Verstraelen P, Asselbergh B, et al. Induced pluripotent stem cell-derived motor neurons of CMT type 2 patients reveal progressive mitochondrial dysfunction. Brain, 2021, 144(8): 2471-2485.
14.	Kerr CM, Richards D, Menick DR, et al. Multicellular human cardiac organoids transcriptomically model distinct tissue-level features of adult myocardium. Int J Mol Sci, 2021, 22(16): 8482.
15.	Streeter BW, Davis ME. Therapeutic cardiac patches for repairing the myocardium. Germany: Springer International Publishing, 2018: 1-24.
16.	Siddiqui N, Asawa S, Birru B, et al. PCL-based composite scaffold matrices for tissue engineering applications. Mol Biotechnol, 2018, 60(7): 506-532.
17.	Sowmya B, Hemavathi AB, Panda PK. Poly (ε-caprolactone)-based electrospun nano-featured substrate for tissue engineering applications: A review. Prog Biomater, 2021, 10(2): 91-117.
18.	Hendrickson T, Mancino C, Whitney L, et al. Mimicking cardiac tissue complexity through physical cues: A review on cardiac tissue engineering approaches. Nanomedicine, 2021, 33: 102367.
19.	Wanjare M, Hou L, Nakayama KH, et al. Anisotropic microfibrous scaffolds enhance the organization and function of cardiomyocytes derived from induced pluripotent stem cells. Biomater Sci, 2017, 5(8): 1567-1578.
20.	Sridharan D, Palaniappan A, Blackstone BN, et al. In situ differentiation of human-induced pluripotent stem cells into functional cardiomyocytes on a coaxial PCL-gelatin nanofibrous scaffold. Mater Sci Eng C Mater Biol Appl, 2021, 118: 111354.
21.	Rachel K, Pathak S, Moorthi A, et al. 5-Azacytidine incorporated polycaprolactone-gelatin nanoscaffold as a potential material for cardiomyocyte differentiation. J Biomater Sci Polym Ed, 2020, 31(1): 123-140.
22.	Rosenblatt-Velin N, Lepore MG, Cartoni C, et al. FGF-2 controls the differentiation of resident cardiac precursors into functional cardiomyocytes. J Clin Invest, 2005, 115(7): 1724-1733.
23.	Ramesh S, Govarthanan K, Ostrovidov S, et al. Cardiac differentiation of mesenchymal stem cells: Impact of biological and chemical inducers. Stem Cell Rev Rep, 2021, 17(4): 1343-1361.
24.	Anderson ME, Goldhaber J, Houser SR, et al. Embryonic stem cell-derived cardiac myocytes are not ready for human trials. Circ Res, 2014, 115(3): 335-338.
25.	Chong JJ, Yang X, Don CW, et al. Human embryonic-stem-cell-derived cardiomyocytes regenerate non-human primate hearts. Nature, 2014, 510(7504): 273-277.
26.	Xu SJ, Mu JS, Zhang JQ, et al. In vitro three-dimensional coculturing poly3-hydroxybutyrate-co-3-hydroxyhexanoate with mouse-induced pluripotent stem cells for myocardial patch application. J Biomater Appl, 2016, 30(8): 1273-1282.
27.	Zhang Z, Zhou F, Zheng J, et al. Preparation of myocardial patches from DiI-labeled rat bone marrow mesenchymal stem cells and neonatal rat cardiomyocytes contact co-cultured on polycaprolactone film. Biomed Mater, 2022, 17(4): 045015.
28.	Niu H, Mu J, Zhang J, et al. Comparative study of three types of polymer materials co-cultured with bone marrow mesenchymal stem cells for use as a myocardial patch in cardiomyocyte regeneration. J Mater Sci Mater Med, 2013, 24(6): 1535-1542.
29.	Tan X, Dai Q, Guo T, et al. Efficient generation of transgene- and feeder-free induced pluripotent stem cells from human dental mesenchymal stem cells and their chemically defined differentiation into cardiomyocytes. Biochem Biophys Res Commun, 2018, 495(4): 2490-2497.
30.	Jiang Y, Li X, Guo T, et al. Ranolazine rescues the heart failure phenotype of PLN-deficient human pluripotent stem cell-derived cardiomyocytes. Stem Cell Reports, 2022, 17(4): 804-819.

1. Virani SS, Alonso A, Benjamin EJ, et al. Heart disease and stroke statistics-2020 update: A report from the American Heart Association. Circulation, 2020, 141(9): e139-e596.
2. Sutton MG, Sharpe N. Left ventricular remodeling after myocardial infarction: Pathophysiology and therapy. Circulation, 2000, 101(25): 2981-2988.
3. Anderson JL, Morrow DA. Acute myocardial infarction. N Engl J Med, 2017, 376(21): 2053-2064.
4. Yu H, Lu K, Zhu J, et al. Stem cell therapy for ischemic heart diseases. Br Med Bull, 2017, 121(1): 135-154.
5. Laflamme MA, Murry CE. Heart regeneration. Nature, 2011, 473(7347): 326-335.
6. Cahill TJ, Choudhury RP, Riley PR. Heart regeneration and repair after myocardial infarction: Translational opportunities for novel therapeutics. Nat Rev Drug Discov, 2017, 16(10): 699-717.
7. Karagiannis P, Takahashi K, Saito M, et al. Induced pluripotent stem cells and their use in human models of disease and development. Physiol Rev, 2019, 99(1): 79-114.
8. Burridge PW, Matsa E, Shukla P, et al. Chemically defined generation of human cardiomyocytes. Nat Methods, 2014, 11(8): 855-860.
9. Gerecht-Nir S, Radisic M, Park H, et al. Biophysical regulation during cardiac development and application to tissue engineering. Int J Dev Biol, 2006, 50(2-3): 233-243.
10. Iberite F, Gruppioni E, Ricotti L. Skeletal muscle differentiation of human iPSCs meets bioengineering strategies: Perspectives and challenges. NPJ Regen Med, 2022, 7(1): 23.
11. Csobonyeiova M, Polak S, Nicodemou A, et al. iPSCs in modeling and therapy of osteoarthritis. Biomedicines, 2021, 9(2): 186.
12. Nguyen R, Da Won Bae S, Qiao L, et al. Developing liver organoids from induced pluripotent stem cells (iPSCs): An alternative source of organoid generation for liver cancer research. Cancer Lett, 2021, 508: 13-17.
13. Van Lent J, Verstraelen P, Asselbergh B, et al. Induced pluripotent stem cell-derived motor neurons of CMT type 2 patients reveal progressive mitochondrial dysfunction. Brain, 2021, 144(8): 2471-2485.
14. Kerr CM, Richards D, Menick DR, et al. Multicellular human cardiac organoids transcriptomically model distinct tissue-level features of adult myocardium. Int J Mol Sci, 2021, 22(16): 8482.
15. Streeter BW, Davis ME. Therapeutic cardiac patches for repairing the myocardium. Germany: Springer International Publishing, 2018: 1-24.
16. Siddiqui N, Asawa S, Birru B, et al. PCL-based composite scaffold matrices for tissue engineering applications. Mol Biotechnol, 2018, 60(7): 506-532.
17. Sowmya B, Hemavathi AB, Panda PK. Poly (ε-caprolactone)-based electrospun nano-featured substrate for tissue engineering applications: A review. Prog Biomater, 2021, 10(2): 91-117.
18. Hendrickson T, Mancino C, Whitney L, et al. Mimicking cardiac tissue complexity through physical cues: A review on cardiac tissue engineering approaches. Nanomedicine, 2021, 33: 102367.
19. Wanjare M, Hou L, Nakayama KH, et al. Anisotropic microfibrous scaffolds enhance the organization and function of cardiomyocytes derived from induced pluripotent stem cells. Biomater Sci, 2017, 5(8): 1567-1578.
20. Sridharan D, Palaniappan A, Blackstone BN, et al. In situ differentiation of human-induced pluripotent stem cells into functional cardiomyocytes on a coaxial PCL-gelatin nanofibrous scaffold. Mater Sci Eng C Mater Biol Appl, 2021, 118: 111354.
21. Rachel K, Pathak S, Moorthi A, et al. 5-Azacytidine incorporated polycaprolactone-gelatin nanoscaffold as a potential material for cardiomyocyte differentiation. J Biomater Sci Polym Ed, 2020, 31(1): 123-140.
22. Rosenblatt-Velin N, Lepore MG, Cartoni C, et al. FGF-2 controls the differentiation of resident cardiac precursors into functional cardiomyocytes. J Clin Invest, 2005, 115(7): 1724-1733.
23. Ramesh S, Govarthanan K, Ostrovidov S, et al. Cardiac differentiation of mesenchymal stem cells: Impact of biological and chemical inducers. Stem Cell Rev Rep, 2021, 17(4): 1343-1361.
24. Anderson ME, Goldhaber J, Houser SR, et al. Embryonic stem cell-derived cardiac myocytes are not ready for human trials. Circ Res, 2014, 115(3): 335-338.
25. Chong JJ, Yang X, Don CW, et al. Human embryonic-stem-cell-derived cardiomyocytes regenerate non-human primate hearts. Nature, 2014, 510(7504): 273-277.
26. Xu SJ, Mu JS, Zhang JQ, et al. In vitro three-dimensional coculturing poly3-hydroxybutyrate-co-3-hydroxyhexanoate with mouse-induced pluripotent stem cells for myocardial patch application. J Biomater Appl, 2016, 30(8): 1273-1282.
27. Zhang Z, Zhou F, Zheng J, et al. Preparation of myocardial patches from DiI-labeled rat bone marrow mesenchymal stem cells and neonatal rat cardiomyocytes contact co-cultured on polycaprolactone film. Biomed Mater, 2022, 17(4): 045015.
28. Niu H, Mu J, Zhang J, et al. Comparative study of three types of polymer materials co-cultured with bone marrow mesenchymal stem cells for use as a myocardial patch in cardiomyocyte regeneration. J Mater Sci Mater Med, 2013, 24(6): 1535-1542.
29. Tan X, Dai Q, Guo T, et al. Efficient generation of transgene- and feeder-free induced pluripotent stem cells from human dental mesenchymal stem cells and their chemically defined differentiation into cardiomyocytes. Biochem Biophys Res Commun, 2018, 495(4): 2490-2497.
30. Jiang Y, Li X, Guo T, et al. Ranolazine rescues the heart failure phenotype of PLN-deficient human pluripotent stem cell-derived cardiomyocytes. Stem Cell Reports, 2022, 17(4): 804-819.

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Effect of CDM3 on the co-culture of human induced pluripotent stem cells with matrigel-coated polycaprolactone to make cardiac patch

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