The effect of bioengineered acellular collagen patch on cardiac remodeling and ventricular function post myocardial infarction

Biomaterials

Volumn 34, Issue 36, 2013, Pages 9048-9055

  Serpooshan, Vahid ^a   Zhao, Mingming ^a   Metzler, Scott A ^a   Wei, Ke ^b   Shah, Parisha B ^a   Wang, Andrew ^a   Mahmoudi, Morteza ^a   Malkovskiy, Andrey V ^a   Rajadas, Jayakumar ^a   Butte, Manish J ^a   Bernstein, Daniel ^a   Ruiz Lozano, Pilar ^a,b  

^a STANFORD UNIVERSITY   (United States)

^b BURNHAM INSTITUTE   (United States)

Author keywords

Angiogenesis; Cardiac tissue engineering; Cardiomyocyte; Collagen; Heart; Scaffold

Indexed keywords

ANGIOGENESIS; BIOMECHANICAL PROPERTIES; CARDIAC TISSUE ENGINEERING; CARDIOMYOCYTES; LEFT ANTERIOR DESCENDING ARTERIES; LEFT VENTRICULAR REMODELING; PHYSIOMECHANICAL PROPERTIES; STRUCTURAL CONSTRAINTS;

BLOOD VESSELS; CELL CULTURE; COLLAGEN; ECHOCARDIOGRAPHY; SCAFFOLDS; SCAFFOLDS (BIOLOGY); TISSUE; TISSUE REGENERATION;

HEART;

COLLAGEN; TISSUE SCAFFOLD;

ANIMAL CELL; ANIMAL EXPERIMENT; ANIMAL MODEL; ANIMAL TISSUE; ARTICLE; BIOENGINEERING; BLOOD VESSEL; CONTROLLED STUDY; HEART; HEART FUNCTION; HEART INFARCTION; HEART MUSCLE; HEART MUSCLE CONTRACTILITY; HEART VENTRICLE FUNCTION; HEART VENTRICLE REMODELING; HISTOLOGY; IMMUNOHISTOCHEMISTRY; MALE; MOUSE; MYOFIBROBLAST; NONHUMAN; PRIORITY JOURNAL; SMOOTH MUSCLE FIBER; TISSUE REGENERATION;

ANGIOGENESIS; CARDIAC TISSUE ENGINEERING; CARDIOMYOCYTE; COLLAGEN; HEART; SCAFFOLD;

ANIMALS; BIOENGINEERING; BIOMECHANICAL PHENOMENA; COLLAGEN; GELS; HEART; HEART FUNCTION TESTS; IMMUNOHISTOCHEMISTRY; MICE; MICE, INBRED C57BL; MYOCARDIAL INFARCTION; MYOCARDIUM; PLASTICS; RATS; VENTRICULAR FUNCTION; VENTRICULAR REMODELING;

EID: 84883763213     PISSN: 01429612     EISSN: 18785905     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2013.08.017     Document Type: Article

References (44)

1. Mercola M., Ruiz-Lozano P., Schneider M.D. Cardiac muscle regeneration: lessons from development. Genes Dev 2011, 25:299-309.
2. Steinhauser M.L., Lee R.T. Regeneration of the heart. EMBO Mol Med 2011, 3:701-712.
3. Laflamme M.A., Murry C.E. Heart regeneration. Nature 2011, 473:326-335.
4. Anversa P., Nadal-Ginard B. Myocyte renewal and ventricular remodelling. Nature 2002, 415:240-243.
5. Malliaras K., Kreke M., Marban E. The stuttering progress of cell therapy for heart disease. Clin Pharmacol Ther 2011, 90:532-541.
6. Gho J.M.I.H., Kummeling G.J.M., Koudstaal S., Jansen Of Lorkeers S.J., Doevendans P.A., Asselbergs F.W., et al. Cell therapy, a novel remedy for dilated cardiomyopathy? A systematic review. JCard Fail 2013, 19:494-502.
7. Francis D.P., Mielewczik M., Zargaran D., Cole G.D. Autologous bone marrow-derived stem cell therapy in heart disease: discrepancies and contradictions. Int J Cardiol 2013, 10.1016/j.ijcard.2013.04.152.
8. Takehara N. Cell therapy for cardiovascular regeneration. Ann Vasc Dis 2013, 6:137-144.
9. Trounson A., Thakar R.G., Lomax G., Gibbons D. Clinical trials for stem cell therapies. BMC Med 2011, 9:52.
10. Curtis M.W., Russell B. Cardiac tissue engineering. JCardiovasc Nurs 2009, 24:87-92.
11. Jawad H., Ali N.N., Lyon A.R., Chen Q.Z., Harding S.E., Boccaccini A.R. Myocardial tissue engineering: a review. JTissue Eng Regen Med 2007, 1:327-342.
12. Langer R., Vacanti J.P. Tissue engineering. Science 1993, 260:920-926.
13. Guilak F., Cohen D.M., Estes B.T., Gimble J.M., Liedtke W., Chen C.S. Control of stem cell fate by physical interactions with the extracellular matrix. Cell Stem Cell 2009, 5:17-26.
14. Even-Ram S., Artym V., Yamada K.M. Matrix control of stem cell fate. Cell 2006, 126:645-647.
15. Serpooshan V., Julien M., Nguyen O., Wang H., Li A., Muja N., et al. Reduced hydraulic permeability of three-dimensional collagen scaffolds attenuates gel contraction and promotes the growth and differentiation of mesenchymal stem cells. Acta Biomater 2010, 6:3978-3987.
16. Fujimoto K.L., Tobita K., Merryman W.D., Guan J., Momoi N., Stolz D.B., et al. An elastic, biodegradable cardiac patch induces contractile smooth muscle and improves cardiac remodeling and function in subacute myocardial infarction. JAm Coll Cardiol 2007, 49:2292-2300.
17. Miyagi Y., Chiu L.L.Y., Cimini M., Weisel R.D., Radisic M., Li R.-K. Biodegradable collagen patch with covalently immobilized VEGF for myocardial repair. Biomaterials 2011, 32:1280-1290.
18. Wei H.-J., Chen C.-H., Lee W.-Y., Chiu I., Hwang S.-M., Lin W.-W., et al. Bioengineered cardiac patch constructed from multilayered mesenchymal stem cells for myocardial repair. Biomaterials 2008, 29:3547-3556.
19. Radisic M., Park H., Gerecht S., Cannizzaro C., Langer R., Vunjak-Novakovic G. Biomimetic approach to cardiac tissue engineering. Philos Trans R Soc Lond B Biol Sci 2007, 362:1357-1368.
20. Venugopal J.R., Prabhakaran M.P., Mukherjee S., Ravichandran R., Dan K., Ramakrishna S. Biomaterial strategies for alleviation of myocardial infarction. JR Soc Interface 2012, 9:1-19.
21. Vunjak-Novakovic G., Tandon N., Godier A., Maidhof R., Marsano A., Martens T.P., et al. Challenges in cardiac tissue engineering. Tissue Eng Part B Rev 2010, 16:169-187.
22. Takahashi H., Yokota T., Uchimura E., Miyagawa S., Ota T., Torikai K., et al. Newly developed tissue-engineered material for reconstruction of vascular wall without cell seeding. Ann Thorac Surg 2009, 88:1269-1276.
23. Papadaki M., Bursac N., Langer R., Merok J., Vunjak-Novakovic G., Freed L.E. Tissue engineering of functional cardiac muscle: molecular, structural, and electrophysiological studies. Am J Physiol Heart Circ Physiol 2001, 280:H168-H178.
24. Bursac N., Papadaki M., Cohen R.J., Schoen F.J., Eisenberg S.R., Carrier R., et al. Cardiac muscle tissue engineering: toward an invitro model for electrophysiological studies. Am J Physiol 1999, 277:H433-H444.
25. Carrier R.L., Papadaki M., Rupnick M., Schoen F.J., Bursac N., Langer R., et al. Cardiac tissue engineering: cell seeding, cultivation parameters, and tissue construct characterization. Biotechnol Bioeng 1999, 64:580-589.
26. Tucker O.P., Syburra T., Augstburger M., van Melle G., Gebhard S., Bosman F., et al. Small intestine without mucosa as a growing vascular conduit: a porcine experimental study. JThorac Cardiovasc Surg 2002, 124:1165-1175.
27. Ott H.C., Matthiesen T.S., Goh S.-K., Black L.D., Kren S.M., Netoff T.I., et al. Perfusion-decellularized matrix: using nature's platform to engineer a bioartificial heart. Nat Med 2008, 14:213-221.
28. Walsh R.G. Design and features of the Acorn CorCap Cardiac Support Device: the concept of passive mechanical diastolic support. Heart Fail Rev 2005, 10:101-107.
29. Christman K.L., Lee R.J. Biomaterials for the treatment of myocardial infarction. JAm Coll Cardiol 2006, 48:907-913.
30. Gaballa M.A., Sunkomat J.N.E., Thai H., Morkin E., Ewy G., Goldman S. Grafting an acellular 3-dimensional collagen scaffold onto a non-transmural infarcted myocardium induces neo-angiogenesis and reduces cardiac remodeling. JHeart Lung Transplant 2006, 25:946-954.
31. Lee C.H., Singla A., Lee Y. Biomedical applications of collagen. Int J Pharm 2001, 221:1.
32. Pachence J.M. Collagen-based devices for soft tissue repair. JBiomed Mater Res 1996, 33:35-40.
33. Serpooshan V., Muja N., Marelli B., Nazhat S.N. Fibroblast contractility and growth in plastic compressed collagen gel scaffolds with microstructures correlated with hydraulic permeability. JBiomed Mater Res 2011, 96:609-620.
34. Abou Neel E.A., Cheema U., Knowles J.C., Brown R.A., Nazhat S.N. Use of multiple unconfined compression for control of collagen gel scaffold density and mechanical properties. Soft Matter 2006, 2:986-992.
35. Serpooshan V., Quinn T.M., Muja N., Nazhat S.N. Characterization and modelling of a dense lamella formed during self-compression of fibrillar collagen gels: implications for biomimetic scaffolds. Soft Matter 2011, 7:2918-2926.
36. Serpooshan V., Quinn T.M., Muja N., Nazhat S.N. Hydraulic permeability of multilayered collagen gel scaffolds under plastic compression-induced unidirectional fluid flow. Acta Biomater 2013, 9(1):4673-4680.
37. Engler A.J., Carag-Krieger C., Johnson C.P., Raab M., Tang H.Y., Speicher D.W., et al. Embryonic cardiomyocytes beat best on a matrix with heart-like elasticity: scar-like rigidity inhibits beating. JCell Sci 2008, 121:3794-3802.
38. Arshi A., Nakashima Y., Nakano H., Eaimkhong S., Evseenko D., Reed J., et al. Rigid microenvironments promote cardiac differentiation of mouse and human embryonic stem cells. Sci Technol Adv Mater 2013, 14:025003.
39. Rehfeldt F., Engler A.J., Eckhardt A., Ahmed F., Discher D.E. Cell responses to the mechanochemical microenvironment-implications for regenerative medicine and drug delivery. Adv Drug Deliv Rev 2007, 59:1329-1339.
40. Reilly G.C., Engler A.J. Intrinsic extracellular matrix properties regulate stem cell differentiation. JBiomech 2010, 43:55-62.
41. Li Z., Guo X., Palmer A.F., Das H., Guan J. High-efficiency matrix modulus-induced cardiac differentiation of human mesenchymal stem cells inside a thermosensitive hydrogel. Acta Biomater 2012, 8:3586-3595.
42. Brown R.A., Wiseman M., Chuo C.B., Cheema U., Nazhat S.N. Ultrarapid engineering of biomimetic materials and tissues: fabrication of nano- and microstructures by plastic compression. Adv Funct Mater 2005, 15:1762-1770.
43. Bitar M., Salih V., Brown R.A., Nazhat S.N. Effect of multiple unconfined compression on cellular dense collagen scaffolds for bone tissue engineering. JMater Sci-Mater Med 2007, 18:237-244.
44. Pedraza C.E., Marelli B., Chicatun F., McKee M.D., Nazhat S.N. An invitro assessment of a cell-containing collagenous extracellular matrix-like scaffold for bone tissue engineering. Tissue Eng Part A 2010, 16:781-793.