Glycosaminoglycans (GAGs) are important structural and functional components in native aortic heart valves and in glutaraldehyde (Glut)-fixed bioprosthetic heart valves (BHVs). However, very little is known about the fate of GAGs within the extracellular matrix of BHVs and their contribution to BHV longevity. BHVs used in heart valve replacement surgery have limited durability due to mechanical failure and pathologic calcification. In the present study we bring evidence for the dramatic loss of GAGs from within the BHV cusp structure during storage in saline and both shortand long-term Glut fixation. In order to gain insight into role of GAGs, we compared properties of fresh and Glut-fixed porcine heart valve cusps before and after complete GAG removal. GAG removal resulted in significant morphological and functional tissue alterations, including decreases in cuspal thickness, reduction of water content and diminution of rehydration capacity. By virtue of this diminished hydration, loss of GAGs also greatly increased the ''with-curvature'' flexural rigidity of cuspal tissue. However, removal of GAGs did not alter calcification potential of BHV cups when implanted in the rat subdermal model. Controlling the extent of pre-implantation GAG degradation in BHVs and development of improved GAG crosslinking techniques are expected to improve the mechanical durability of future cardiovascular bioprostheses.
We have recently demonstrated that noncalcific tissue damage can lead to significant collagen degradation in clinically explanted bioprosthetic heart valves (BHVs). In the present study we quantified the early response of glutaraldehyde treated bovine pericardium (GLBP) to cyclic tensile loading to begin to elucidate the mechanisms of noncalcific tissue degeneration in BHV biomaterials. GLBP specimens were cycled at 30 Hz to a maximum uniaxial strain of 16% (corresponding to approximately 1-MPa peak stress), with the loading direction parallel to the preferred collagen fiber (PD) direction. After 30 x 10(6) cycles, specimens were subjected to biaxial mechanical testing, then cycled until 65 x 10(6) cycles. The results indicated a permanent change in the unloaded tissue dimensions of +7.1% strain in the PD direction and -7.7% strain in the cross fiber direction (XD) after 65 x 10(6) cycles and an increase of the collagen crimp period from 40.6 to 45.2 microm by 65 x 10(6) cycles (p = 0.05). Fourier transform IR spectroscopy analysis indicated that cyclic fatigue of GLBP leads to both collagen conformational changes and early denaturation. Furthermore, no significant changes in areal strain were found under 1-MPa equibiaxial stress, indicating that cyclic loading changed the collagen fiber orientation but not the overall tissue compliance. These observations suggest that while deterioration of collagen begins immediately, fiber straightening and reorientation dominates the changes in the mechanical behavior up to 65 x 10(6) cycles. The present study underscores the complexity of the response of biologically derived biomaterials to cyclic mechanical loading. Improved understanding of these phenomena can potentially guide the development of novel chemical treatment methods that seek to improve BHV durability by minimizing these degenerative processes.
Bioprosthetic heart valves (BPHVs) derived from glutaraldehyde-crosslinked porcine aortic valves are frequently used in heart valve replacement surgeries. However, the majority of bioprostheses fail clinically because of calcification and degeneration. We have recently shown that glycosaminoglycan (GAG) loss may be in part responsible for degeneration of glutaraldehyde-crosslinked bioprostheses. In the present studies, we used a mild reaction of periodate-mediated crosslinking to stabilize glycosaminoglycans in the bioprosthetic tissue. We demonstrate the feasibility of periodate reaction by crosslinking major components of extracellular matrix of bioprosthetic heart valve tissue, namely type I collagen and hyaluronic acid (HA). Uronic acid assay of periodate-fixed HA-collagen matrices showed 48% of HA disaccharides were bound to collagen. Furthermore, we show that such reactions are also feasible to fix glycosaminoglycans present in the middle spongiosa layer of bioprosthetic heart valves. The periodate reactions were compatible with conventional glutaraldehyde crosslinking and showed adequate stabilization of extracellular matrix as demonstrated by thermal denaturation temperature and collagenase assays. Moreover, uronic acid assays of periodate-fixed BPHV cusps showed 36% reduction in the amount of unbound GAG disaccharides as compared with glutaraldehyde-crosslinked cusps. We also demonstrate that calcification of BPHV cusps was significantly reduced in the periodate-fixed group as compared with the glutaraldehyde-fixed group in 21-day rat subdermal calcification studies (periodate-fixed tissue Ca 72.01 +/- 5.97 microg/mg, glutaraldehyde-fixed tissue Ca 107.25 +/- 6.56 microg/mg). We conclude that periodate-mediated GAG fixation could reduce structural degeneration of BPHVs and may therefore increase the useful lifetime of these devices.
Glutaraldehyde-fixed porcine aortic valve tissues are widely used for heart valve replacement surgery in the form of bioprosthetic heart valves (BHVs). The durability of BHVs in the clinical setting is limited by tissue degeneration, mechanical failure, and calcification. BHVs rely on the putative ability of glutaraldehyde to render biologic tissues metabolically inert and fully resistant to enzymatic attack. In the present study, we detected and partially characterized the activity of collagen and elastin-degrading enzymes in unimplanted, glutaraldehyde-fixed porcine aortic cusp and wall tissues and compared enzyme activities with those extracted from fresh tissues. Active enzymes capable of degrading extracellular matrix were found to be present in soluble form as well as immobilized on glutaraldehyde-crosslinked tissue matrix. Total levels of collagenolytic activities were evaluated to approximately 0.25 microg of degraded collagen/mg of dry tissue/24 h for both glutaraldehyde-fixed wall and cusp tissues. A major finding of this study was the ability of soluble tissue enzymes to partially degrade glutaraldehyde-fixed collagen and particularly large amounts of glutaraldehyde-fixed elastin. These calcium-dependent gelatinases share many biochemical similarities with matrix metalloproteinases. These data strongly indicate that glutaraldehyde-fixed porcine valvular tissues are not metabolically inert and are not entirely resistant to enzymatic attack, thereby rendering BHVs vulnerable to biologic degeneration and subsequent chronic failure.
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