Paul Human

Inotropic Effect of Triiodothyronine Following Myocardial Ischemia and Cardiopulmonary Bypass: An Experimental Study in Pigs

A significant reduction (p less than 0.0001) in plasma-free triiodothyronine (T3), which is known to have an inotropic effect, has been documented in patients undergoing open-heart procedures. To investigate the effect of this observation, 22 pigs underwent 2 hours (Group 1, r = 10) or 3 hours (Group 2, r = 12) of myocardial ischemia during cardiopulmonary bypass (CPB) at 26 degrees C; the myocardium was protected by cardioplegic solution and cold saline solution at 30-minute intervals. After the pig was rewarmed to 37 degrees C, CPB was discontinued, and measurements of hemodynamic function were made 10 and 70 minutes later. Half of the pigs (Subgroup B) received 6 micrograms of T3 intravenously immediately after removal of the aortic cross-clamp; the remainder (Subgroup A) received no T3. After 2 hours of ischemia, untreated pigs showed significantly reduced myocardial function 10 minutes after discontinuation of CPB. By 70 minutes after the end of CPB, 2 of 5 untreated pigs (Subgroup A) had died of low cardiac output, but all 5 treated pigs (Subgroup B) survived. After 3 hours of ischemia, both groups showed some reduced function at 10 minutes, though the reduction was more marked in untreated animals. By 70 minutes, 4 of 6 untreated pigs had died of myocardial failure and all treated pigs remained alive (p less than 0.03). Surviving pigs in both groups still demonstrated some reduced function compared with values obtained before CPB. When all pigs are considered together, overall survival of those that did not receive T3 was significantly less than those that did (p less than 0.006).(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of the immune response to valve bioprostheses and its role in primary tissue failure

BACKGROUND The role of an immune response in the failure of bioprosthetic heart valves is poorly understood and disregarded by many. To elucidate the nature of the immune response to glutaraldehyde-treated tissue and the possible role of graft-specific antibody in graft mineralization, we performed immune-calcification studies in the rabbit and correlated those results with the analysis of specific antibodies. METHODS Aortic wall buttons (6 mm) were punched from porcine aortic wall tissue fixed with 0.2% glutaraldehyde and detoxified with urazole and then subsequently perforated under sterile conditions. The perforated buttons were then incubated with either immune serum prepared by immunization of New Zealand White rabbits (n = 5) with Freunds incomplete adjuvant emulsions of tissue homogenates of similarly treated aortic wall tissue, or incubated with the corresponding control preimmune sera obtained before immunization of the same animals. The tissue was then implanted subdermally on the back of unrelated New Zealand White rabbits (n = 8) for a period of 3 weeks. After the buttons were explanted, tissue calcium levels were determined by atomic absorption spectroscopy. RESULTS Tissue calcium was increased in all five immune serum-treated replicates (range, 61.8% to 431.2%; mean, 225.9%+/-73.2%) when compared with control samples treated with preimmune sera. Overall, the mean calcium level was significantly increased (p < 0.0001) when tissue was treated with immune sera (66.0+/-10.0 microg/mg versus 22.6+/-4.8 microg/mg in control tissue). Graft specificity of immune sera was confirmed by Western blot analysis. CONCLUSIONS These results strongly suggest a role of circulating graft-specific antibody in the disease of bioprosthetic graft calcification.

Constrictive external nitinol meshes inhibit vein graft intimal hyperplasia in nonhuman primates

OBJECTIVE External mesh support of vein grafts has been shown to mitigate the formation of intimal hyperplasia. The aim of the present study was to address the issue of optimal mesh size in a nonhuman primate model that mimics the dimensional mismatch typically encountered between clinical vein grafts and their target arteries. METHODS The effect of mesh size on intimal hyperplasia and endothelial preservation was assessed in bilateral femoral interposition grafts in Chacma baboons (n(Sigma) = 32/n = 8 per mesh size). No mesh support (group I) was compared with external nitinol meshes at three different sizes: loose fitting (group II), 25% diameter constricting (group III), and 50% diameter constricting (group IV). Mesh sizes were seen not only in isolation but also against the background of anastomotic size mismatch at implantation, expressed as quotient of cross-sectional area of host artery to vein graft (Q(C)). RESULTS Significant amounts of intimal hyperplasia were found in group I (Q(C) median 0.20; intimal hyperplasia 6 weeks = 1.63 +/- 0.34 mm(2); intimal hyperplasia 12 weeks = 1.73 +/- 0.5 mm(2)) and group II (Q(C) median 0.25; intimal hyperplasia 6 weeks = 1.96 +/- 1.64 mm(2); intimal hyperplasia 12 weeks = 2.88 +/- 1.69 mm(2)). In contrast, group III (Q(C) median 0.45; intimal hyperplasia 6 weeks = 0.08 +/- 0.13 mm(2); intimal hyperplasia 12 weeks = 0.18 +/- 0.32 mm(2)) and IV (Q(C) median 1.16; intimal hyperplasia 6 weeks = 0.02 +/- 0.03 mm(2); intimal hyperplasia 12 weeks = 0.11 +/- 0.10 mm(2)) showed dramatically suppressed intimal hyperplasia (P < .01) at both time points. Endothelial integrity was only preserved in group IV (P < .05). There were no significant differences in vascularization and inflammation in either interlayer or intergroup comparisons. CONCLUSION By using an animal model that addressed the clinical phenomenon of diameter discrepancy between vein graft and bypassed artery, we could demonstrate that suppression of intimal hyperplasia required constrictive mesh sizes.

Comparison of processing and sectioning methodologies for arteries containing metallic stents.

The histological study of arteries with implanted metallic scaffolding devices, known as stents, remains a technical challenge. Given that the arterial response to stent implantation can sometimes lead to adverse outcomes, including the re-accumulation of tissue mass within the stent (or in-stent restenosis), overcoming these technical challenges is a priority for the advancement of research and development in this important clinical field. Essentially, the task is to section the stent-tissue interface with the least amount of disruption of tissue and cellular morphology. Although many methacrylate resin methodologies are successfully applied toward the study of endovascular stents by a variety of research laboratories, the exact formulations, as well as subsequent processing and sectioning methodology, remain largely coveted. In this paper, we describe in detail a methyl methacrylate resinembedding methodology that can successfully be applied to tungsten carbide blade, as well as saw and grinding sectioning methods and transmission electron microscopy. In addition, we present a comparison of the two sectioning methodologies in terms of their effectiveness with regard to morphological, histochemical, and immunohistochemical analyses. This manuscript contains online supplemental material at http://www.jhc.org. Please visit this article online to view these materials.

Bioprosthetic heart valves: the need for a quantum leap

More than 250000 bioprosthetic heart valves are being implanted annually. Although the majority of recipients are elderly developed‐world patients, the most urgent need for tissue valves is in younger patients, where rapid degeneration of contemporary prostheses remains a serious obstacle. After decades of empirical and mostly futile attempts to extend the longevity of tissue valve prostheses, new insights and solutions are on the horizon. Aetiologically, a shift of focus from mineralization to immune responses and inflammation emerges. On the development side, new engineering approaches to both selective extraction of tissue components and cross‐links are increasingly defining the new direction. In order to dramatically improve the performance of bioprosthetic heart valves, these new developments need to lead to a broad consensus for a paradigm shift in a hitherto rather stagnant field of medical research.

15-Deoxyspergualin for induction of graft nonreactivity after cardiac and renal allotransplantation in primates.

In order to assess the immunosuppressive potentials of 15-deoxyspergualine (15-DS) in a preclinical experiment, heterotopi cardiac (n=27, group I) and classic renal (n=25, group II) allotransplantations were performed in Chacma baboons. The following immunosuppressive regimens were applied: Groups IB and IIB were treated with 15-DS alone (4 mg/kg/day) for p.o. days 0–9. Groups IC and IIC were treated with cyclosporine A (10–40 mg/kg/day) for p.o. days 0–30. Groups ID and IID received a combination of 15-DS (for p.o. days 0–9) and CsA (for p.o. days 0–30). Groups IA and IIA served as control and received no medication. The mean graft survival was 11.0 days for group IA, 28.2 days for group IB (P<0.05; IB vs. IA), 32.4 days for group IC, and 43.1 days for group ID (P<0.025; ID vs. IA). After renal transplantation, the corresponding figures were 12.3 days for group IIA, 8.5 days for group IIB, 30.4 days for group IIC and 148.9 days for group IID (P<0.025; IID vs. IIA). After cardiac and renal transplantation, acute rejection was the main cause of graft failure. Treatment-related side effects, mainly gastrointestinal complications, were observed only in primates, who were treated with 15-DS alone. After cardiac transplantation, permanent graft non-reactivity was not achieved, but a delayed rejection occurred within a mean of 21.8 days after immuno-suppression had been stopped. Following renal transplantation, graft nonreactivity was also not achieved in groups IIB and IIC. In group IID, however, 4 of 8 animals (50%) were graft-tolerant 340, 256, 244, and 164 days after treatment discontinuation. Thus, the combination of 15-DS and CsA led to a significant prolongation of graft survival in both groups. Long-term nonreactivity was achieved only after renal transplantation, when initially treated with 15-DS and CsA.

High glutaraldehyde concentrations mitigate bioprosthetic root calcification in the sheep model

BACKGROUND Fixation at high glutaraldehyde (GA) concentrations mitigated bioprosthetic calcification in the rat model. The present study intended to verify this observation in the circulatory sheep model. METHODS Porcine aortic roots were either fixed in 0.2%, 1.0%, or 3.0% GA. Eight roots per group were implanted in the distal aortic arch of sheep. After six weeks and six months calcification and inflammation were quantitatively and qualitatively assessed. RESULTS By increasing the GA concentration from 0.2% to 3.0%, aortic wall calcification could be reduced by 38% after 6 weeks and 34% after 6 months of implantation (p < 0.01). Mineralization coincided with the presence of elastin although calcium was predominantly found in cell nuclei and membranes. Leaflet calcification was absent in all groups after 6 weeks but in a few leaflets presented as heterogeneous, nodular spongiosa deposits after 6 months. Overall, differences between 0.2%-, 1.0%-, and 3.0%-fixed tissue were quantitative but not qualitative regarding distribution patterns. There was no significant difference in inflammatory host reaction between all groups. CONCLUSIONS We have shown in the circulatory sheep model that the anticalcific effect of better cross-linking seems to outweigh the intrinsic pro-calcific effect of GA accumulation in bioprosthetic aortic wall tissue.

Utilization of shape memory in external vein-graft meshes allows extreme diameter constriction for suppressing intimal hyperplasia: A non-human primate study

OBJECTIVE Constrictive external Nitinol meshes have been shown to suppress neointimal tissue formation and preserve endothelial integrity in vein grafts. As this mitigating effect increased with the degree of constriction, we investigated whether extreme constriction was possible without leading to detrimental luminal encroachment. METHODS A senescent non-human primate model (Chacma baboons/bilateral femoral interposition grafts) mimicking the clinical size-mismatch between vein grafts and run-off arteries was used. Control grafts were either untreated (group 1) or spray-coated with fibrin glue (group 2). Nitinol meshes constricting the lumen by <or=80% (group 3) were compared with longitudinally pleated meshes of identical circumference that constricted the lumen by >90% (group 4). Anastomotic size mismatch at implantation was expressed as quotient of cross-sectional area of run-off artery to vein graft (Q(C)). RESULTS At 6 months, all vein grafts without mesh support showed thick eccentric layers of neointimal tissue (group 1: 348 +/- 130 microm [Q(C) median at implant 0.19]; group 2: 318 +/- 142 microm [Q(C) median at implant 0.17]). Fibrin glue-spraying had no effect. In contrast, neointimal tissue was absent in all mesh-supported grafts (P < .007 in all cases) both at 6 weeks/6 months (group 3: 7.5 +/- 8.8 mum and 2.5 +/- 4.4 microm [Q(C) median at implant 1.47]; group 4: 1.3 +/- 0.6 microm and 3.8 +/- 5.6 microm [Q(C) median at implant 3.09]). Except for mild tissue buckling (fold height <356 microm) in one group 3 graft, none of the mesh-constricted grafts showed wall folds. Endothelial coverage was only complete in the mesh-supported groups (100% in group 3 and 4 vs 85 +/- 14%; P < .023 in group 1). Fibrin glue alone (52 +/- 48%) did not preserve endothelialization of control grafts (P < .38). CONCLUSION Extreme vein graft constriction using external Nitinol meshes is possible without detrimental tissue buckling. Although moderate constriction was found to be sufficient for mitigating diffuse intimal hyperplasia and endothelial detachment, extreme constriction may occasionally be required to eliminate luminal irregularities.

Optimization of diamine bridges in glutaraldehyde treated bioprosthetic aortic wall tissue.

OBJECTIVE Bioprosthetic calcification can be significantly mitigated by both increased concentrations of glutaraldehyde (GA) and the introduction of diamine (DA) bridges. The purpose of the present study was to evaluate whether an optimal effect of DA-enhanced fixation can be achieved by titration of dialdehyde and diamine concentrations. METHODS Porcine aortic roots were fixed at 0.05% GA (under-fixation) or 0.2% GA and 0.7% GA (commercial fixation). An interim step of DA treatment (L-Lysine; 0, 25, 50 or 100 mM; 37 degrees C; 2 days) was followed by completion of the GA fixation (37 degrees C; 5 days). Aortic wall coupons (12 mm) were punched out and implanted subcutaneously into seven-week old Long-Evans rats for 60 days. Calcium content was assessed by atomic absorption spectroscopy and histology. RESULTS Increasing the L-Lysine concentrations beyond 25 mM was essential to achieve the anti-calcific effect of DA-enhanced fixation. This effect was proportional to the GA concentrations applied. Compared to non-enhanced GA fixation (0 mM DA), calcification increased by 17.4% (p = 0.2114) in 0.05% fixed tissue but decreased by 32.0% (p < 0.0001) and 45.1% (p < 0.0002) in 0.2% and 0.7% GA, respectively, when the DA concentration was 100 mM. Histologically the extent, but not the pattern of calcification, was affected. CONCLUSION The calcium mitigating effect of diamine-treatment as an interim step of glutaraldehyde fixation is proportional to the GA concentration applied. Within commercial 0.7% GA fixation 100 mM DA has the potential to practically halve aortic wall calcification.

Stentless bioprosthetic heart valve research: sheep versus primate model

BACKGROUND The mild inflammatory response against stented bioprosthetic heart valves in the sheep model is often opposed by a more distinct response in failing human implants. With the emergence of stentless root prostheses with their significantly larger proportion of tissue interacting with the immune system of the host, a more relevant animal model than the sheep may be needed. METHODS Valved, porcine aortic roots of 5 cm length were fixed in 0.2% glutaraldehyde and implanted in the upper descending aorta of Merino sheep (n = 5; 43+/-3 kg) and Chacma baboons (n = 5; 17+/-3 kg). After 6 weeks of tissue calcification, pannus outgrowth and inflammation were assessed by atomic absorption spectrophotometry, histologic damage scoring (0 to 3), image analysis, and transmission electron microscopy. RESULTS The main difference between the two animal models was in aortic wall calcification (64.8+/-39.8 microg/mg in the sheep model versus 4.1+/-5.9 microg/mg in the primate model; p > 0.005). In both models, leaflet calcification was negligible (2.6+/-2.4 microg/mg in the sheep versus 2.5+/-1.9 microg/mg in the primate), and the overall extent of inflammation was comparable (1.2+/-0.8 versus 0.98+/-0.7; p = 0.18 in the sheep and the primate, respectively). Qualitatively, the sheep demonstrated a macrophage-dominated reaction whereas the inflammatory demarcation often resembled a granulocyte-dominated xenograft response in the primate. Pannus outgrowth was comparable in length (8.4+/-2.3 mm versus 9.1+/-4.3 mm proximally and 7.1+/-3.4 mm versus 7.4+/-5.1 mm distally, in the sheep and baboon, respectively; p > 0.05). CONCLUSIONS Our results confirm the sheep as a significantly stronger calcification model for stentless aortic heart valves than the primate. Remaining antigenicity of porcine tissue as a result of incomplete cross-linking, however, elicits a distinctly stronger xenograft-type reaction in the primate model.