Cardiac tissue engineering is a strategy to replace damaged contractile tissue and model cardiac diseases to discover therapies. Current cardiac and vascular engineering approaches independently create aligned contractile tissue or perfusable vasculature, but a combined vascularized cardiac tissue remains to be achieved. Here, we sought to incorporate a patterned microvasculature into engineered heart tissue, which balances the competing demands from cardiomyocytes to contract the matrix versus the vascular lumens that need structural support. Low-density collagen hydrogels (1.25 mg/mL) permit human embryonic stem cell-derived cardiomyocytes (hESC-CMs) to form a dense contractile tissue but cannot support a patterned microvasculature. Conversely, high collagen concentrations (density ≥6 mg/mL) support a patterned microvasculature, but the hESC-CMs lack cell–cell contact, limiting their electrical communication, structural maturation, and tissue-level contractile function. When cocultured with matrix remodeling stromal cells, however, hESC-CMs structurally mature and form anisotropic constructs in high-density collagen. Remodeling requires the stromal cells to be in proximity with hESC-CMs. In addition, cocultured cardiac constructs in dense collagen generate measurable active contractions (on the order of 0.1 mN/mm2) and can be paced up to 2 Hz. Patterned microvascular networks in these high-density cocultured cardiac constructs remain patent through 2 weeks of culture, and hESC-CMs show electrical synchronization. The ability to maintain microstructural control within engineered heart tissue enables generation of more complex features, such as cellular alignment and a vasculature. Successful incorporation of these features paves the way for the use of large scale engineered tissues for myocardial regeneration and cardiac disease modeling.
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References
1.
RogerV.L., GoA.S., Lloyd-JonesD.M., BenjaminE.J., BerryJ.D., BordenW.B., et al.Executive summary: heart disease and stroke statistics-2012 update: a report from the American heart association. Circulation, 125, 188, 2012.
LaflammeM.A., ChenK.Y., NaumovaA.V., MuskheliV., FugateJ.A., DuprasS.K., et al.Cardiomyocytes derived from human embryonic stem cells in pro-survival factors enhance function of infarcted rat hearts. Nat Biotechnol, 25, 1015, 2007.
4.
CaspiO., HuberI., KehatI., HabibM., ArbelG., GepsteinA., et al.Transplantation of human embryonic stem cell-derived cardiomyocytes improves myocardial performance in infarcted rat hearts. J Am Coll Cardiol, 50, 1884, 2007.
5.
ShibaY., FernandesS., ZhuW.-Z., FiliceD., MuskheliV., KimJ., et al.Human ES-cell-derived cardiomyocytes electrically couple and suppress arrhythmias in injured hearts. Nature, 489, 322, 2012.
6.
van LaakeL.W., PassierR., Monshouwer-KlootsJ., VerkleijA.J., LipsD.J., FreundC., et al.Human embryonic stem cell-derived cardiomyocytes survive and mature in the mouse heart and transiently improve function after myocardial infarction. Stem Cell Res, 1, 9, 2007.
7.
ZimmermannW.-H., and EschenhagenT.Cardiac tissue engineering for replacement therapy. Heart Fail Rev, 8, 259, 2003.
8.
MolA., van LieshoutM.I., Dam-de VeenC.G., NeuenschwanderS., HoerstrupS.P., BaaijensF.P.T., et al.Fibrin as a cell carrier in cardiovascular tissue engineering applications. Biomaterials, 26, 3113, 2005.
9.
ThomsonK.S., KorteF.S., GiachelliC.M., RatnerB.D., RegnierM., and ScatenaM.Prevascularized microtemplated fibrin scaffolds for cardiac tissue engineering applications. Tissue Eng Part A, 19, 967, 2013.
10.
PaulJ.D., CoulombeK.L.K., TothP.T., ZhangY., MarsboomG., BindokasV.P., et al.SLIT3-ROBO4 activation promotes vascular network formation in human engineered tissue and angiogenesis in vivo. J Mol Cell Cardiol, 64, 124, 2013.
11.
TullochN.L., MuskheliV., RazumovaM.V., KorteF.S., RegnierM., HauchK.D., et al.Growth of engineered human myocardium with mechanical loading and vascular coculture. Circ Res, 109, 47, 2011.
12.
ZimmermannW.-H., MelnychenkoI., WasmeierG., DidiéM., NaitoH., NixdorffU., et al.Engineered heart tissue grafts improve systolic and diastolic function in infarcted rat hearts. Nat Med, 12, 452, 2006.
13.
DuanY., LiuZ., O'NeillJ., WanL.Q., FreytesD.O., and Vunjak-NovakovicG.Hybrid gel composed of native heart matrix and collagen induces cardiac differentiation of human embryonic stem cells without supplemental growth factors. J Cardiovasc Transl Res, 4, 605, 2011.
14.
StevensK.R., KreutzigerK.L., DuprasS.K., KorteF.S., RegnierM., MuskheliV., et al.Physiological function and transplantation of scaffold-free and vascularized human cardiac muscle tissue. Proc Natl Acad Sci U S A, 106, 16568, 2009.
15.
KreutzigerK.L., MuskheliV., JohnsonP., BraunK., WightT.N., and MurryC.E.Developing vasculature and stroma in engineered human myocardium. Tissue Eng Part A, 17, 1219, 2011.
16.
StokerM.E., GerdesA.M., and MayJ.F.Regional differences in capillary density and myocyte size in the normal human heart. Anat Rec, 202, 187, 1982.
17.
LepicE., BurgerD., LuX., SongW., and FengQ.Lack of endothelial nitric oxide synthase decreases cardiomyocyte proliferation and delays cardiac maturation. Am J Physiol Cell Physiol, 291, C1240, 2006.
18.
ZhuW.Z., XieY., MoyesK.W., GoldJ.D., AskariB., and LaflammeM.A.Neuregulin/ErbB signaling regulates cardiac subtype specification in differentiating human embryonic stem cells. Circ Res, 107, 776, 2010.
19.
HedhliN., HuangQ., KalinowskiA., PalmeriM., HuX., RussellR.R., et al.Endothelium-derived neuregulin protects the heart against ischemic injury. Circulation, 123, 2254, 2011.
20.
CaspiO., LesmanA., BasevitchY., GepsteinA., ArbelG., HuberI., et al.Tissue engineering of vascularized cardiac muscle from human embryonic stem cells. Circ Res, 100, 263, 2007.
21.
SekineH., ShimizuT., HoboK., SekiyaS., YangJ., YamatoM., et al.Endothelial cell coculture within tissue-engineered cardiomyocyte sheets enhances neovascularization and improves cardiac function of ischemic hearts. Circulation, 118, S145, 2008.
22.
SasagawaT., ShimizuT., SekiyaS., HaraguchiY., YamatoM., SawaY., et al.Design of prevascularized three-dimensional cell-dense tissues using a cell sheet stacking manipulation technology. Biomaterials, 31, 1646, 2010.
23.
NaitoH., MelnychenkoI., DidiéM., SchneiderbangerK., SchubertP., RosenkranzS., et al.Optimizing engineered heart tissue for therapeutic applications as surrogate heart muscle. Circulation, 114, I72, 2006.
24.
MontgomeryM., ZhangB., and RadisicM.Cardiac tissue vascularization: from angiogenesis to microfluidic blood vessels. J Cardiovasc Pharmacol Ther, 19, 382, 2014.
25.
CoulombeK.L.K., and MurryC.E.Vascular Perfusion of Implanted Human Engineered Cardiac Tissue. Proc IEEE Annu Northeast Bioeng Conf, 1, 2014, 2014.
26.
AbdallaS., MakhoulG., DuongM., ChiuR.C.J., and CecereR.Hyaluronic acid-based hydrogel induces neovascularization and improves cardiac function in a rat model of myocardial infarction. Interact Cardiovasc Thorac Surg, 17, 767, 2013.
27.
HuangN.F., YuJ., SieversR., LiS., and LeeR.J.Injectable biopolymers enhance angiogenesis after myocardial infarction. Tissue Eng, 11, 1860, 2005.
28.
MaddenL.R., MortisenD.J., SussmanE.M., DuprasS.K., FugateJ.A., CuyJ.L., et al.Proangiogenic scaffolds as functional templates for cardiac tissue engineering. Proc Natl Acad Sci U S A, 107, 15211, 2010.
SaifJ., SchwarzT.M., ChauD.Y.S., HenstockJ., SamiP., LeichtS.F., et al.Combination of injectable multiple growth factor-releasing scaffolds and cell therapy as an advanced modality to enhance tissue neovascularization. Arterioscler Thromb Vasc Biol, 30, 1897, 2010.
31.
HaoX., SilvaE.A., Månsson-BrobergA., GrinnemoK.H., SiddiquiA.J., DellgrenG., et al.Angiogenic effects of sequential release of VEGF-A165 and PDGF-BB with alginate hydrogels after myocardial infarction. Cardiovasc Res, 75, 178, 2007.
32.
XiaoY., ZhangB., LiuH., MiklasJ.W., GagliardiM., PahnkeA., et al.Microfabricated perfusable cardiac biowire: a platform that mimics native cardiac bundle. Lab Chip, 14, 869, 2014.
33.
RaghavanS., NelsonC.M., BaranskiJ.D., LimE., and ChenC.S.Geometrically controlled endothelial tubulogenesis in micropatterned gels. Tissue Eng Part A, 16, 2255, 2010.
34.
BaranskiJ.D., ChaturvediR.R., StevensK.R., EyckmansJ., CarvalhoB., SolorzanoR.D., et al.Geometric control of vascular networks to enhance engineered tissue integration and function. Proc Natl Acad Sci U S A, 110, 7586, 2013.
35.
MoyaM.L., HsuY.-H., LeeA.P., HughesC.C.W., and GeorgeS.C.In vitro perfused human capillary networks. Tissue Eng Part C Methods, 19, 730, 2013.
36.
RoeckleinB.A., and Torok-StorbB.Functionally distinct human marrow stromal cell lines immortalized by transduction with the human papilloma virus E6/E7 genes. Blood, 85, 997, 1995.
37.
ZhengY., ChenJ., CravenM., ChoiN.W., TotoricaS., Diaz-SantanaA., et al.In vitro microvessels for the study of angiogenesis and thrombosis. Proc Natl Acad Sci U S A, 109, 9342, 2012.
38.
CrossV.L., ZhengY., Won ChoiN., VerbridgeS.S., SutermasterB.A., BonassarL.J., et al.Dense type I collagen matrices that support cellular remodeling and microfabrication for studies of tumor angiogenesis and vasculogenesis in vitro. Biomaterials, 31, 8596, 2010.
39.
FanD., TakawaleA., LeeJ., and KassiriZ.Cardiac fibroblasts, fibrosis and extracellular matrix remodeling in heart disease. Fibrogenesis Tissue Repair, 5, 15, 2012.
40.
CamellitiP., BorgT.K., and KohlP.Structural and functional characterisation of cardiac fibroblasts. Cardiovasc Res, 65, 40, 2005.
ZalewskiA., ShiY., and JohnsonA.G.Diverse origin of intimal cells: smooth muscle cells, myofibroblasts, fibroblasts, and beyond? Circ Res, 91, 652, 2002.
47.
Torok-StorbB., IwataM., GrafL., GianottiJ., HortonH., and ByrneM.C.Dissecting the marrow microenvironment. Ann N Y Acad Sci, 872, 164, 1999.
48.
GrafL., IwataM., and Torok-StorbB.Gene expression profiling of the functionally distinct human bone marrow stromal cell lines HS-5 and HS-27a. Blood, 100, 1509, 2002.
49.
CarlsonM.A., and LongakerM.T.The fibroblast-populated collagen matrix as a model of wound healing: a review of the evidence. Wound Repair Regen, 12, 134, 2004.
50.
von TellD., ArmulikA., and BetsholtzC.Pericytes and vascular stability. Exp Cell Res, 312, 623, 2006.
51.
ArmulikA., GenovéG., and BetsholtzC.Pericytes: developmental, physiological, and pathological perspectives, problems, and promises. Dev Cell, 21, 193, 2011.
52.
MillerJ.S., StevensK.R., YangM.T., BakerB.M., NguyenD.H., CohenD.M., et al.Rapid casting of patterned vascular networks for perfusable engineered three-dimensional tissues. Nat Mater, 11, 768, 2012.
53.
VollertI., SeiffertM., BachmairJ., SanderM., EderA., ConradiL., et al.In vitro perfusion of engineered heart tissue through endothelialized channels. Tissue Eng Part A, 20, 854, 2014.
54.
LarsenM., ArtymV.V., GreenJ.A., and YamadaK.M.The matrix reorganized: extracellular matrix remodeling and integrin signaling. Curr Opin Cell Biol, 18, 463, 2006.
55.
De JongeN., KantersF.M.W., BaaijensF.P.T., and BoutenC.V.C.Strain-induced collagen organization at the micro-level in fibrin-based engineered tissue constructs. Ann Biomed Eng, 41, 763, 2013.
56.
NicholJ.W., EngelmayrG.C., ChengM., and FreedL.E.Co-culture induces alignment in engineered cardiac constructs via MMP-2 expression. Biochem Biophys Res Commun, 373, 360, 2008.
57.
ThomopoulosS., FomovskyG.M., and HolmesJ.W.The development of structural and mechanical anisotropy in fibroblast populated collagen gels. J Biomech Eng, 127, 742, 2005.
58.
WangP.Y., YuJ., LinJ.H., and TsaiW.B.Modulation of alignment, elongation and contraction of cardiomyocytes through a combination of nanotopography and rigidity of substrates. Acta Biomater, 7, 3285, 2011.
SassoliC., PiniA., MazzantiB., QuercioliF., NistriS., SaccardiR., et al.Mesenchymal stromal cells affect cardiomyocyte growth through juxtacrine Notch-1/Jagged-1 signaling and paracrine mechanisms: clues for cardiac regeneration. J Mol Cell Cardiol, 51, 399, 2011.
61.
LiY., HiroiY., and LiaoJ.K.Notch signaling as an important mediator of cardiac repair and regeneration after myocardial infarction. Trends Cardiovasc Med, 20, 228, 2010.
62.
AoyagiT., and MatsuiT.The cardiomyocyte as a source of cytokines in cardiac injury. J Cell Sci Ther, 2012(S5), pii:003, 2011.
63.
SanoM., FukudaK., KodamaH., PanJ., SaitoM., MatsuzakiJ., et al.Interleukin-6 family of cytokines mediate angiotensin II-induced cardiac hypertrophy in rodent cardiomyocytes. J Biol Chem, 275, 29717, 2000.
64.
HirotaH., YoshidaK., KishimotoT., and TagaT.Continuous activation of gp130, a signal-transducing receptor component for interleukin 6-related cytokines, causes myocardial hypertrophy in mice. Proc Natl Acad Sci, 92, 4862, 1995.
65.
SilverF.H., SiperkoL.M., and SeehraG.P.Mechanobiology of force transduction in dermal tissue. Ski Res Technol, 9, 3, 2003.
66.
MasudaS., MatsuuraK., AnazawaM., IwamiyaT., ShimizuT., and OkanoT.Formation of vascular network structures within cardiac cell sheets from mouse embryonic stem cells. Regen Ther, 2, 6, 2015.
67.
WongT., McGrathJ.A., and NavsariaH.The role of fibroblasts in tissue engineering and regeneration. Br J Dermatol, 156, 1149, 2007.
68.
LundyS.D., ZhuW.-Z., RegnierM., and LaflammeM.A.Structural and functional maturation of cardiomyocytes derived from human pluripotent stem cells. Stem Cells Dev, 22, 1991, 2013.
69.
KorteF.S., DaiJ., BuckleyK., FeestE.R., AdamekN., GeevesM.A., et al.Upregulation of cardiomyocyte ribonucleotide reductase increases intracellular 2 deoxy-ATP, contractility, and relaxation. J Mol Cell Cardiol, 51, 894, 2011.
70.
KreutzigerK.L., PiroddiN., McMichaelJ.T., TesiC., PoggesiC., and RegnierM.Calcium binding kinetics of troponin C strongly modulate cooperative activation and tension kinetics in cardiac muscle. J Mol Cell Cardiol, 50, 165, 2011.
71.
PalpantN.J., PabonL., RobertsM., HadlandB., JonesD., JonesC., et al.Inhibition of -catenin signaling respecifies anterior-like endothelium into beating human cardiomyocytes. Development, 142, 3198, 2015.
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