In cardiovascular tissue engineering, mechanical stimulation of tissue-engineered constructs is known to improve tissue properties. During tissue culture, the mechanical properties of the tissue construct change. To impose a predefined deformation protocol and to avoid negative effects of excessive strain, it is desired to monitor and control deformations during load application. In a previous study, load application and resulting deformation of tissue-engineered heart valve leaflets were monitored during culture inside a bioreactor in real time and noninvasively. A combined experimental–numerical approach was applied to assess volumetric and local leaflet deformation of the cultured heart valve in a diastolic configuration. In this study, this approach was further developed and a feedback controller to regulate deformation was incorporated into the bioreactor system. Functionality of this technique was demonstrated in two tissue engineering experiments in which a total of eight heart valves were cultured by application of two different deformation protocols. Results indicated a good correspondence between the measured and the prescribed deformation values in both experiments. In addition, the cultured heart valves showed mechanical properties in the range of previous tissue engineering studies. The bioreactor system including the deformation measurement and control features has promising possibilities of systematically elucidating the effects of loading protocols on tissue properties. In conclusion, it facilitates the development of an optimal conditioning protocol for tissue engineering of aortic heart valves.
Get full access to this article
View all access options for this article.
References
1.
SodianR., HoerstrupS.P., SperlingJ.S., DaebritzS., MartinD.P., MoranA.M., KimB.S., SchoenF.J., VacantiJ.P., MayerJ.E.Jr.Early in vivo experience with tissue-engineered trileaflet heart valves. Circulation, 102:III22. 2000.
MolA., RuttenM.C.M., DriessenN.J.B., BoutenC.V.C., ZundG., BaaijensF.P.T., HoerstrupS.P.Autologous human tissue-engineered heart valves: prospects for systemic application. Circulation, 114:152. 2006.
4.
KimB.S., NikolovskiJ., BonadioJ., MooneyD.J.Cyclic mechanical strain regulates the development of engineered smooth muscle tissue. Nat Biotechnol, 17:979. 1999.
5.
MolA., BoutenC.V.C., ZundG., GuenterC., VisjagerJ.F., TurinaM.I., BaaijensF.P.T., HoerstrupS.P.The relevance of large strains in functional tissue-engineering of heart valves. Thorac Cardiovasc Surg, 51:78. 2003.
6.
FerdousZ., LazaroL.D., IozzoR.V., HöökM., Grande-AllenK.J.Influence of cyclic strain and decorin deficiency on 3D cellularized collagen matrices. Biomaterials, 29:2740. 2008.
7.
BoerboomR.A., RubbensM.P., DriessenN.J.B., BoutenC.V.C., BaaijensF.P.T.Effect of strain magnitude on the tissue properties of engineered cardiovascular constructs. Ann Biomed Eng, 36:244. 2008.
8.
RubbensM.P., MolA., BoerboomR.A., BankR.A., BaaijensF.P.T., BoutenC.V.C.Intermittent straining accelerates the development of tissue properties in engineered heart valve tissue. Tissue Eng Part A, 15:999. 2009.
9.
MitchellS.B., SandersJ.E., GarbiniJ.L., SchuesslerP.K.A device to apply user-specified strains to biomaterials in culture. IEEE Trans Biomed Eng, 48:2. 2001.
10.
ButcherJ.T., BarrettaB.C., NeremR.M.Equibiaxial strain stimulates fibroblastic phenotype shift in smooth muscle cells in an engineered tissue model of the aortic wall. Biomaterials, 27:5252. 2006.
EngelmayrG.C.Jr., SolettiL., VigmostadS.C., BudilartoS.G., FederspielW.J., ChandranK.B., VorpD.A., SacksM.S.A novel flex-stretch-flow bioreactor for the study of engineered heart valve mechanobiology. Ann Biomed Eng, 36:700. 2008.
13.
IsenbergB.C., TranquilloR.T.Long-term cyclic distension enhances the mechanical properties of collagen-based media equivalents. Ann Biomed Eng, 31:937. 2003.
14.
ZeltingerJ., LandeenL.K., AlexanderH.G., KiddI.D., SibandaB.Development and characterization of tissue-engineered aortic valves. Tissue Eng, 7:9. 2001.
15.
RabkinE., HoerstrupS.P., AikawaM., MayerJ.E., SchoenF.J.Evolution of cell phenotype and extracellular matrix in tissue-engineered heart valves during in-vitro maturation and in-vivo remodeling. J Heart Valve Dis, 11:308. 2002.
16.
Schenke-LaylandK., OpitzF., GrossM., DoringC., HalbhuberK.J., SchirrmeisterF., WahlersTh., StockU.A.Complete dynamic repopulation of decellularized heart valves by application of defined physical signals—an in vitro study. Cardiovasc Res, 60:497. 2003.
17.
FlanaganT.C., CornelissenC., KochS., TschoekeB., SachwechS., Schmitz-RodeT., JockenhoevelS.The in vitro development of autologous fibrin-based tissue-engineered heart valves through optimised dynamic conditioning. Biomaterials, 28:3388. 2007.
18.
SodianR., LuedersC., KraemerL., KueblerW., ShakibaeiM., ReichartB., DaebritzS., HetzerR.Tissue-engineering of autologous human heart valves using cryopreserved vascular umbilical cord cells. Ann Thorac Surg, 81:2207. 2006.
19.
StockU.A., DegenkolbeI., AttmannT., Schenke-LaylandK., FreitagS., LutterG.Prevention of device-related tissue damage during percutaneous deployment of tissue-engineered heart valves. J Thorac Cardiovasc Surg, 131:1323. 2006.
20.
MolA., DriessenN.J.B., RuttenM.C.M., HoerstrupS.P., BoutenC.V.C., BaaijensF.P.T.Tissue-engineering of human heart valve leaflets: a novel bioreactor for a strain-based conditioning approach. Ann Biomed Eng, 33:1. 2005.
21.
SyedianZ.H., TranquilloR.T.Controlled cyclic stretching of tissue-engineered heart valves: effects on mechanical properties and ECM organization. Abstract presented at the ASME Summer Bioengineering Conference (SBC2008), Marco Island, FL, 2008Abstract no. SBC2008-192583.
22.
KortsmitJ., DriessenN.J.B., RuttenM.C.M., BaaijensF.P.T.Real time, non-invasive assessment of leaflet deformation in heart valve tissue-engineering. Ann Biomed Eng, 37:532. 2009.
23.
LiptakB.Instrument Engineers' Handbook: Process Control. Radnor, PA: Chilton Book Company, 1995.
24.
ClarkR.E., FinkeE.H.Scanning and light microscopy of human aortic leaflets in stressed and relaxed states. J Thorac Cardiovasc Surg, 67:792. 1974.
25.
SaurenA.A.H.J.The mechanical behaviour of the aortic valve [Ph.D. thesis]Technische Hogeschool: Eindhoven, The Netherlands, 1981.
SchnellA.M., HoerstrupS.P., ZundG., KolbS., SodianR., VisjagerJ.F., GrunenfelderJ., SuterA., TurinaM.Optimal cell source for cardiovascular tissue-engineering: venous vs. aortic human myofibroblasts. Thorac Cardiovasc Surg, 49:221. 2001.
28.
Rabkin-AikawaE., FarberM., AikawaM., SchoenF.J.Dynamic and reversible changes of interstitial cell phenotype during remodeling of cardiac valves. J Heart Valve Dis, 13:841. 2004.
29.
MolA., van LieshoutM.I., Dam-de VeenG.C., NeuenschwanderS., HoerstrupS.P., BaaijensF.P.T., BoutenC.V.C.Fibrin as a cell carrier in cardiovascular tissue-engineering applications. Biomaterials, 26:3113. 2005.
30.
HoerstrupS.P., ZundG., YeQ., SchoeberleinA., SchmidA.C., TurinaM.I.Tissue engineering of a bioprosthetic heart valve: stimulation of extracellular matrix assessed by hydroxyproline assay. ASAIO J, 45:397. 1999.
31.
KortsmitJ., DriessenN.J.B., RuttenM.C.M., BaaijensF.P.T.Non-destructive and non-invasive assessment of mechanical properties in heart valve tissue-engineering. Tissue Eng Part A, 15:797. 2009.
32.
BalguidA., RubbensM.P., MolA., BankR.A., BogersA.J., van KatsJ.P., de MolB.A., BaaijensF.P., BoutenC.V.The role of collagen cross-links in biomechanical behavior of human aortic heart valve leaflets—relevance for tissue-engineering. Tissue Eng, 13:1501. 2007.
