Conceptually, a tissue engineered heart valve would be especially appealing in the pediatric setting since small size and somatic growth constraints would be alleviated. In this study, we utilized porcine small intestinal submucosa (PSIS) for valve replacement. Of note, we evaluated the material responses of PSIS and subsequently its acute function and somatic growth potential in the mitral position.
Methods and Results:
Material and mechanical assessment demonstrated that both fatigued 2ply (∼65 μm) and 4ply (∼110 μm) PSIS specimens exhibited similar failure mechanisms, but at an accelerated rate in the former. Specifically, the fatigued 2ply PSIS samples underwent noticeable fiber pullout and recruitment on the bioscaffold surface, leading to higher yield strength (p < 0.05) and yield strain (p < 0.05) compared to its fatigued 4ply counterparts. Consequently, 2ply PSIS mitral valve constructs were subsequently implanted in juvenile baboons (n = 3). Valve function was longitudinally monitored for 90 days postvalve implantation and was found to be robust in all animals. Histology at 90 days in one of the animals revealed the presence of residual porcine cells, fibrin matrix, and host baboon immune cells but an absence of tissue regeneration.
Conclusions:
Our findings suggest that the altered structural responses of PSIS, postfatigue, rather than de novo tissue formation, are primarily responsible for the valve's ability to accommodate somatic growth during the acute phase (90 days) following mitral valve replacement.
Impact Statement
Tissue engineered heart valves (TEHVs) offer the potential of supporting somatic growth. In this study, we investigated a porcine small intestinal submucosa bioscaffold for pediatric mitral heart valve replacement. The novelty of the study lies in identifying material responses under mechanical loading conditions and its effectiveness in being able to function as a TEHV. In addition, the ability of the scaffold valve to support acute somatic growth was evaluated in the Baboon model. The current study contributes toward finding a solution for critical valve diseases in children, whose current prognosis for survival is poor.
AlsoufiB.Aortic valve replacement in children: options and outcomes. J Saudi Heart Assoc, 26, 33, 2014.
5.
HynesR.O., and NabaA.Overview of the matrisome—an inventory of extracellular matrix constituents and functions. Cold Spring Harb Perspect Biol, 4, a004903, 2012.
6.
NejadS.P., BlaserM.C., SanterreJ.P., CaldaroneC.A., and SimmonsC.A, Biomechanical conditioning of tissue engineered heart valves: too much of a good thing? Adv Drug Deliv Rev, 96, 161, 2016.
7.
DohmenP.M., CostaF.D., LopesS.V., et al.Results of a decellularized porcine heart valve implanted into the juvenile sheep model. Heart Surg Forum, 8, E100, 2005.
8.
KimS.S., LimS.H., HongY.S., et al.Tissue engineering of heart valves in vivo using bone marrow-derived cells. Artif Organs, 30, 554, 2006.
9.
O'BrienM.F., GoldsteinS., WalshS., BlackK.S., ElkinsR., and ClarkeD.The SynerGraft valve: a new acellular (nonglutaraldehyde-fixed) tissue heart valve for autologous recellularization first experimental studies before clinical implantation. Semin Thorac Cardiovasc Surg, 11, 194, 1999.
10.
Mosala NezhadZ., PonceletA., de KerchoveL., GianelloP., FervailleC., and El KhouryG.Small intestinal submucosa extracellular matrix (CorMatrix®) in cardiovascular surgery: a systematic review. Interact Cardiovasc Thorac Surg, 22, 839, 2016.
11.
BadylakS., ObermillerJ., GeddesL., and MathenyR.Extracellular matrix for myocardial repair. Heart Surg Forum, 6, E20, 2003.
12.
Robotin-JohnsonM.C., SwansonP.E., JohnsonD.C., SchuesslerR.B., and CoxJ.L.An experimental model of small intestinal submucosa as a growing vascular graft. J Thorac Cardiovasc Surg, 116, 805, 1998.
13.
MathenyR.G., HutchisonM.L., DrydenP.E., HilesM.D., and ShaarC.J.Porcine small intestine submucosa as a pulmonary valve leaflet substitute. J Heart Valve Dis, 9, 769, 2000.
14.
RuizC.E., IemuraM., MedieS., et al.Transcatheter placement of a low-profile biodegradable pulmonary valve made of small intestinal submucosa: a long-term study in a swine model. J Thorac Cardiovasc Surg, 130, 477-e1, 2005.
15.
PavcnikD., UchidaB.T., TimmermansH.A., et al.Percutaneous bioprosthetic venous valve: a long-term study in sheep. J Vasc Surg, 35, 598, 2002.
16.
YavuzK., GeyikS., PavcnikD., et al.Comparison of the endothelialization of small intestinal submucosa, Dacron, and expanded polytetrafluoroethylene suspended in the thoracoabdominal aorta in sheep. J Vasc Interv Radiol, 17, 873, 2006.
17.
PavcnikD., ObermillerJ., UchidaB.T., et al.Angiographic evaluation of carotid artery grafting with prefabricated small-diameter, small-intestinal submucosa grafts in sheep. Cardiovasc Intervent Radiol, 32, 106, 2009.
18.
WhiteJ.K., AgnihotriA.K., TitusJ.S., and TorchianaD.F.A stentless trileaflet valve from a sheet of decellularized porcine small intestinal submucosa. Ann Thorac Surg, 80, 704, 2005.
19.
RosenM., RoselliE.E., FaberC., RatliffN.B., PonskyJ.L., and SmediraN.G.Small intestinal submucosa intracardiac patch: an experimental study. Surg Innov, 12, 227, 2005.
20.
Sandusky, JrG.E., BadylakS.F., MorffR.J., JohnsonW.D., and LantzG.Histologic findings after in vivo placement of small intestine submucosal vascular grafts and saphenous vein grafts in the carotid artery in dogs. Am J Pathol, 140, 317, 1992.
21.
BoniL., ChalajourF., SasakiT., et al.Reconstruction of pulmonary artery with porcine small intestinal submucosa in a lamb surgical model: viability and growth potential. J Thorac Cardiovasc Surg, 144, 963, 2012.
22.
FallonA., GoodchildT., WangR., and MathenyR.G.Remodeling of extracellular matrix patch used for carotid artery repair. J Surg Res, 175, e25, 2012.
23.
PadalinoM.A., CastellaniC., DedjaA., et al.Extracellular matrix graft for vascular reconstructive surgery: evidence of autologous regeneration of the neoaorta in a murine model. Eur J Cardiothorac Surg, 42, e128, 2012.
24.
FallonA.M., GoodchildT.T., CoxJ.L., and MathenyR.G.In vivo remodeling potential of a novel bioprosthetic tricuspid valve in an ovine model. J Thorac Cardiovasc Surg, 148, 333, 2014.
25.
ToegH.D., AbessiO., Al-AtassiT., et al.Finding the ideal biomaterial for aortic valve repair with ex vivo porcine left heart simulator and finite element modeling. J Thorac Cardiovasc Surg, 148, 1739, 2014.
26.
ZafarF., HintonR.B., MooreR.A., et al.Physiological growth, remodeling potential, and preserved function of a novel bioprosthetic tricuspid valve: tubular bioprosthesis made of small intestinal submucosa-derived extracellular matrix. J Am Coll Cardiol, 66, 877, 2015.
27.
SlaughterM.S., SoucyK.G., MathenyR.G., et al.Development of an extracellular matrix delivery system for effective intramyocardial injection in ischemic tissue. ASAIO J, 60, 730, 2014.
28.
SoucyK.G., SmithE.F., MonrealG., et al.Feasibility study of particulate extracellular matrix (P-ECM) and left ventricular assist device (HVAD) therapy in chronic ischemic heart failure bovine model. ASAIO J, 61, 161, 2015.
29.
QuartiA., NardoneS., ColaneriM., SantoroG., and PozziM.Preliminary experience in the use of an extracellular matrix to repair congenital heart diseases. Interact Cardiovasc Thorac Surg, 13, 569, 2011.
30.
WittR.G., RaffG., Van GundyJ., Rodgers-OhlauM., and SiM.Short-term experience of porcine small intestinal submucosa patches in pediatric cardiovascular surgery. Eur J Cardiothorac Surg, 44, 72, 2013.
31.
ZaidiA.H., NathanM., EmaniS., et al.Preliminary experience with porcine intestinal submucosa (CorMatrix) for valve reconstruction in congenital heart disease: histologic evaluation of explanted valves. J Thorac Cardiovasc Surg, 148, 2216, 2014.
32.
GilbertC.L., GnanapragasamJ., BenhaggenR., and NovickW.M.Novel use of extracellular matrix graft for creation of pulmonary valved conduit. World J Pediatr Congenit Heart Surg, 2, 495, 2011.
33.
BoydW.D., SultanP.K., DeeringT.F., and MathenyR.G.Pericardial reconstruction using an extracellular matrix implant correlates with reduced risk of postoperative atrial fibrillation in coronary artery bypass surgery patients. Heart Surg Forum, 13, E311, 2010.
34.
YanagawaB., RaoV., YauT.M., and CusimanoR.J.Potential myocardial regeneration with CorMatrix ECM: a case report. J Thorac Cardiovasc Surg, 147, e41, 2014.
35.
YanagawaB., RaoV., YauT.M., and CusimanoR.J.Initial experience with intraventricular repair using CorMatrix extracellular matrix. Innovations, 8, 348, 2013.
36.
StellyM., and StellyT.C.Histology of CorMatrix bioscaffold 5 years after pericardial closure. Ann Thorac Surg, 96, e127, 2013.
37.
GerdischM.W., SheaR.J., and BarronM.D.Clinical experience with CorMatrix extracellular matrix in the surgical treatment of mitral valve disease. J Thorac Cardiovasc Surg, 148, 1370, 2014.
38.
GerdischM.W., BoydW.D., HarlanJ.L., et al.Early experience treating tricuspid valve endocarditis with a novel extracellular matrix cylinder reconstruction. J Thorac Cardiovasc Surg, 148, 3042, 2014.
39.
CuaC.L., KollinsK., and McConnellP.I.Echocardiographic analysis of an extracellular matrix tricuspid valve. Echocardiography, 31, E264, 2014.
40.
WallenJ., and RaoV.Extensive tricuspid valve repair after endocarditis using CorMatrix extracellular matrix. Ann Thorac Surg, 97, 1048, 2014.
41.
SündermannS.H., BieferH.R.C., EmmertM.Y., and FalkV.Use of extracellular matrix materials in patients with endocarditis. Thorac Cardiovasc Surg, 62, 076, 2014.
42.
EckhauserA.W., HannonD., MolitorM., ScaifeE., and GruberP.J.Repair of traumatic aortoinnominate disruption using CorMatrix. Ann Thorac Surg, 95, e99, 2013.
43.
DuBoseJ.J., and AzizzadehA.Utilization of a tubularized CorMatrix extracellular matrix for repair of an arteriovenous fistula aneurysm. Ann Vasc Surg, 29, 366-e1, 2015.
44.
PoulinF., HorlickE.M., DavidT., WooA., and ThavendiranathanP.3-Dimensional transesophageal echocardiography–guided closure of a gerbode shunt due to cormatrix patch dehiscence. J Am Coll Cardiol, 62, e5, 2013.
45.
PadalinoM.A., QuartiA., AngeliE., et al.Early and mid-term clinical experience with extracellular matrix scaffold for congenital cardiac and vascular reconstructive surgery: a multicentric Italian study. Interact Cardiovasc Thorac Surg, 21, 40, 2015.
46.
WooJ.S., FishbeinM.C., and ReemtsenB.Histologic examination of decellularized porcine intestinal submucosa extracellular matrix (CorMatrix) in pediatric congenital heart surgery. Cardiovasc Pathol, 25, 12, 2016.
47.
SchollF.G., BoucekM.M., ChanK.C., Valdes-CruzL., and PerrymanR.Preliminary experience with cardiac reconstruction using decellularized porcine extracellular matrix scaffold: human applications in congenital heart disease. World J Pediatr Congenit Heart Surg, 1, 132, 2010.
48.
BibevskiS., and SchollF.G.Feasibility and early effectiveness of a custom, hand-made systemic atrioventricular valve using porcine extracellular matrix (CorMatrix) in a 4-month-old infant. Ann Thorac Surg, 99, 710, 2015.
49.
BibevskiS., LevyA., and SchollFG.Mitral valve replacement using a handmade construct in an infant. Interact Cardiovasc Thorac Surg, 24, 639, 2017.
50.
CzerL.S., MatloffJ., ChauxA., DerobertisM., YoganathanA., and GrayR.J.A 6 year experience with the St. Jude Medical valve: hemodynamic performance, surgical results, biocompatibility and follow-up. J Am Coll Cardiol, 6, 904, 1985.
51.
BortolottiU., SciotiG., MilanoA., et al.Performance of 21-mm size perimount aortic bioprosthesis in the elderly. Ann Thorac Surg, 69, 47, 2000.
52.
SordelliC., SeverinoS., AscioneL., CoppolinoP., and CasoP.Echocardiographic assessment of heart valve prostheses. J Cardiovasc Echogr, 24, 103, 2014.
53.
OrimadegunA., and A. Omisanjo, Evaluation of five formulae for estimating body surface area of Nigerian Children. Ann Med Health Sci Res, 4, 889, 2014.
54.
RedlarskiG., PalkowskiA., and KrawczukM.Body surface area formulae: an alarming ambiguity. Sci Rep, 6, 27966, 2016.
55.
GonzalezB., HernandezL., BibevskiS., et al.Recapitulation of human bio-scaffold mitral valve growth in the baboon model. Circulation, 138(Suppl_1), A11348, 2018.
56.
CheungD.Y., DuanB., and ButcherJ.T.Current progress in tissue engineering of heart valves: multiscale problems, multiscale solutions. Expert Opin Biol Ther, 15, 1155, 2015.
57.
RippelR.A., GhanbariH., and SeifalianA.M.Tissue-engineered heart valve: future of cardiac surgery. World J Surg, 36, 1581, 2012.
58.
EmmertM.Y., and HoerstrupS.P.Tissue engineered heart valves: moving towards clinical translation. Expert Rev Med Devices, 13, 417, 2016.
59.
DohmenP.M., LembckeA., HolinskiS., PrussA., and KonertzW.Ten years of clinical results with a tissue-engineered pulmonary valve. Ann Thorac Surg, 92, 1308, 2011.
60.
MuralaJ.S., Sassalos, P., Owens, S. T., and Ohye, R. G. Porcine small intestine submucosa cylinder valve for mitral and tricuspid valve replacement. J Thorac Cardiovasc Surg, 154, e57, 2017.
61.
InabaY., YagiH., KurodaK., et al.Transplantation of a decellularized mitral valve complex in pigs. Surg Today, 2019 [Epub ahead of print]; DOI: 10.1007/s00595-019-01869-8.
62.
XuY., ChengL., ZhangL., YinH., and YinX.High toughness, 3D textile, SiC/SiC composites by chemical vapor infiltration. Mater Sci Eng A, 318, 183, 2001.
63.
YinX.W., ChengL.F., ZhangL.T., TravitzkyN., and GreilP.Fibre-reinforced multifunctional SiC matrix composite materials. Int Mater Rev, 62, 117, 2017.
64.
BoniL., ChalajourF., SasakiT., et al.Reconstruction of pulmonary artery with porcine small intestinal submucosa in a lamb surgical model: viability and growth potential. J Thorac Cardiovasc Surg, 144, 963, 2012.
65.
RosenM., RoselliE.E., FaberC., RatliffN.B., PonskyJ.L., and SmediraN.G.Small intestinal submucosa intracardiac patch: an experimental study. Surg Innov, 12, 227, 2005.
66.
SuckowM.A., Voytik-HarbinS.L., TerrilL.A., and BadylakS.F.Enhanced bone regeneration using porcine small intestinal submucosa. J Invest Surg, 12, 277, 1999.
67.
EllisS., LinE.J., and TartarD.Immunology of wound healing. Curr Dermatol Rep, 7, 350, 2018.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
