Effects of cryopreservation, decellularization and novel extracellular matrix conditioning on the quasi-static and time-dependent properties of the pulmonary valve leaflet.

Decellularized allografts offer potential as heart valve substitutes and scaffolds for cell seeding. The effects of decellularization on the quasi-static and time-dependent mechanical behavior of the pulmonary valve leaflet under biaxial loading conditions have not previously been reported in the literature. In the current study, the stress-strain, relaxation and creep behaviors of the ovine pulmonary valve leaflet were investigated under planar-biaxial loading conditions to determine the effects of decellularization and a novel post-decellularization extracellular matrix (ECM) conditioning process. As expected, decellularization resulted in increased stretch along the loading axes. A reduction in relaxation was observed following decellularization. This was accompanied by a reduction in glycosaminoglycan (GAG) content. Based on previous implant studies, these changes may be of little functional consequence in the short term; however, the long term effects of decreased relaxation and GAG content remain unknown. Some restoration of relaxation was observed following ECM conditioning, especially in the circumferential specimen direction, which may help mitigate any detrimental effects due to decellularization. Regardless of processing, creep under biaxial loading was negligible.

Determining cell seeding dosages for tissue engineering human pulmonary valves.

BACKGROUND: This study examines in vitro seeding of decellularized human pulmonary valves (hPVs) with human valve interstitial cells (hVICs) isolated from unrelated donor aortic valve leaflets. An assay was developed to assess seeding using precut uniform sized biopsies from whole hPVs for sequential evaluation of seeding efficiency, proliferation, and migration. MATERIALS AND METHODS: Scaffolds for seeding were created from decellularized hPVs using a reciprocating osmolality, double detergent, enzyme, multiple solvent protocol. hVICs seeded decellularized leaflet and sinus wall scaffolds were incubated in either static or cyclic pressure bioreactors. Low, medium, and high initial cell seeding "dosing" densities were assayed at subsequent three time points, using eight replicates each (n = 576 biopsies including manufactured scaffold controls). Metabolically viable seeded cells were quantified by MTT assay. Histology defined cell locations and morphology. RESULTS: After 24 h of static seeding with 2.5 × 10(5) cells (medium dose), 100 ± 13 cells/mm(2) (2.5%) attached to leaflets, compared with 193 ± 21 cells/mm(2) (8%) for sinuses. Subsequent 4 d in static culture yielded 894 ± 84 and 838 ± 50 cells/mm(2)versus pulsatile culture yielding 80 ± 12 and 79 ± 12 cells/mm(2) for leaflet and sinus, respectively. However, 76.0% ± 12.2% of cells in leaflets in the pulsatile bioreactor were subsurface as compared to 21.4% ± 3.9% in statically cultured leaflets (P < 0.001). CONCLUSION: Different seeding modes suggest a tradeoff between surface proliferation resulting in higher absolute cell numbers for static seeding versus fewer cells in a cyclic pressure bioreactor but with a greater percentage having migrated into the matrix. The medium seeding dose determined to be optimal is actually feasible for tissue engineering heart valves, and can be achieved by fairly traditional cell amplification methods.

Pediatric cardiopulmonary bypass adaptations for long-term survival of baboons undergoing pulmonary artery replacement.

Cardiopulmonary bypass (CPB) protocols of the baboon (Papio cynocephalus anubis) are limited to obtaining experimental data without concern for long-term survival. In the evaluation of pulmonary artery tissue engineered heart valves (TEHVs), pediatric CPB methods are adapted to accommodate the animals' unique physiology enabling survival up to 6 months until elective sacrifice. Aortic access was by a 14F arterial cannula and atrial access by a single 24F venous cannula.The CPB circuit includes a 3.3 L/min flow rated oxygenator, 1/4" x %" arterial-venous loop, 3/8" raceway, and bubble trap. The prime contains 700 mL Plasma-Lyte, 700 units heparin, 5 mL of 50% dextrose, and 20 mg amiodarone. Heparinization (200 u/kg) targets an activated clotting time of 350 seconds. Normothermic CPB was initiated at a 2.5 L/m2/min cardiac index with a mean arterial pressure of 55-80 mmHg. Weaning was monitored with transesophageal echocardiogram. Post-CPB circuit blood was re-infused. Chest tubes were removed with cessation of bleeding. Extubation was performed upon spontaneous breathing. The animals were conscious and upright 3 hours post-CPB. Bioprosthetic valves or TEHVs were implanted as pulmonary replacements in 20 baboons: weight = 27.5 +/- 5.6 kg, height = 73 +/- 7 cm, body surface area = 0.77 m2 +/- 0.08, mean blood flow = 1.973 +/- .254 L/min, core temperature = 37.1 +/- .1 degree C, and CPB time = 60 +/- 40 minutes. No acidosis accompanied CPB. Sixteen animals survived, four expired. Three died of right ventricular failure and one of an anaphylactoid reaction. Surviving animals had normally functioning replacement valves and ventricles. Baboon CPB requires modifications to include high systemic blood pressure for adequate perfusion into small coronary arteries, careful CPB weaning to prevent ventricular distention, and drug and fluid interventions to abate variable venous return related to a muscularized spleno-splanchnic venous capacity.