Calcium and phosphorus concentrations in native and decellularized semilunar valve tissues.

BACKGROUND AND AIM OF THE STUDY: Native, allograft, xenograft and bioprosthetic semilunar valves are all susceptible to calcific degeneration. However, intrinsic differences in baseline calcium and phosphorus tissue concentrations within mammalian normal valve structural components (e.g., cusps, sinus, vessel wall) additionally subdivided by tripartite regions (e.g., right-, left- and non-coronary leaflets) have never been systematically measured and reported. It was originally hypothesized that variations in normative tissue concentrations of calcium and phosphorus may correspond to subsequent clinical patterns of acquired dystrophic calcification; decellularization was also expected to reduce the tissue concentrations of these elements. METHODS: Native semilunar valves were freshly harvested from 12 juvenile sheep. Half of the valves were decellularized (six aortic and six pulmonary), while the other valves were flash-frozen at -80 degrees C within minutes of euthanasia as native valves. Elemental calcium and phosphorus concentrations were measured in the great vessels, sinus walls and cusps using inductively coupled plasma optical emission spectrometry (ICP-OES), and analyzed with non-parametric statistical tests. RESULTS: Calcium concentrations (microg/mg tissue; median (range) were similar in aortic native cusps (0.37 (0.21)), sinus walls (0.37 (0.09)) and aorta (0.37 (0.08)) (p = 0.8298). Pulmonary calcium concentrations were similar in cusps, but 10-25% higher in the native sinus (p = 0.0018) and pulmonary artery (p < 0.0001) compared to analogous aortic structures. All cusps had higher phosphorus concentrations than their respective conduit tissues. No tripartite regional variations were observed. Decellularization did not reduce the calcium content of cusps, but removed 50-55% of vessel and sinus wall calcium. However, up to 85% of phosphorus was removed from all valve tissues (p < 0.001). CONCLUSION: There were no significant differences in normal tissue concentrations of calcium between aortic valve functional structures, and no semilunar tripartite regional differences in either semilunar valve complex. Thus, the distribution of baseline tissue calcium content of healthy young valves is not inherently predictive of selective or asymmetric anatomical patterns of valve degenerative calcification. Native semilunar cusps contain the highest phosphorus concentrations. Decellularization reduces all elemental concentrations except for cuspal calcium.

Pulmonary arterioplasty with decellularized allogeneic patches.

BACKGROUND: Decellularized allogeneic nonvalved pulmonary artery patches for arterioplasty are a relatively new option compared with cryopreserved allogeneic, crosslinked xenogeneic bioprosthetic or synthetic materials. This study examines the midterm experience with a new decellularized allogeneic patch for congenital cardiac reconstructions. METHODS: For this prospective postmarket approval, nonrandomized, inclusive observational study, we collected data on a consecutive cohort of 108 patients with cardiovascular reconstructions using 120 decellularized allogeneic pulmonary artery patches (MatrACELL; LifeNet Health, Inc, Virginia Beach, VA) between September 2009 and December 2012. One hundred of the patches were used for pulmonary arterioplasties. Two patients were lost early to follow-up and excluded from subsequent survival and durability analyses. Data included demographics, surgical outcomes, subsequent reoperations, and catheter reinterventions. These variables were also collected for an immediately preceding retrospective consecutive cohort of 100 patients with 101 pulmonary arterioplasty patches who received classical cryopreserved pulmonary artery allografts (n=59 patches and patients) or synthetic materials (n=41 patients with 42 patches) for pulmonary arterioplasties between 2006 and 2009. RESULTS: In 106 patients with 118 decellularized patches, there were no device-related serious adverse events, no device failures, and no evidence of calcifications on chest roentgenograms. In contrast, the prior comparative pulmonary arterioplasty cohort of 100 patients experienced an overall 14.0% patch failure rate requiring device-related reoperations (p<0.0001) at mean duration of 194±104 days (range, 25 to 477 days). CONCLUSIONS: The intermediate-term data obtained in this study suggest favorable performance by decellularized pulmonary artery patches, with no material failures or reoperations provoked by device failure.

Mesenchymal epimorphin is important for pancreatic duct morphogenesis.

Epithelial-mesenchymal interactions are crucial for the proper development of many organs, including the pancreas. Within the pancreas, the ducts are thought to harbor stem/progenitor cells, and possibly to give rise to pancreatic ductal carcinoma. Little is known about the mechanism of formation of pancreatic ducts in the embryo. Pancreatic mesenchyme contains numerous soluble factors which help to sustain the growth and differentiation of exocrine and endocrine structures. Here, we report that one such morphoregulatory mesenchymal protein, epimorphin, plays an important role during pancreatic ductal proliferation and differentiation. We found that epimorphin is expressed in pancreatic mesenchyme during early stages of development, and at mesenchymal-epithelial interfaces surrounding the ducts at later stages. Strong upregulation of epimorphin expression was seen during in vitro pancreatic duct differentiation. Similarly, in vitro pancreatic duct formation was inhibited by a neutralizing antibody against epimorphin, whereas addition of recombinant epimorphin partially rescued duct formation. Together, our study demonstrates the role of epimorphin in pancreatic ductal morphogenesis.