Sodium-hydrogen exchanger inhibition, pharmacologic ischemic preconditioning, or both for extended cardiac allograft preservation.

BACKGROUND: The aim of this study was to determine the efficacy of cariporide (a sodium-hydrogen exchanger inhibitor), BMS180448 (a pharmacologic ischemic preconditioning agent), and the combination thereof, as adjuvant therapies for extended cardiac allograft preservation. METHODS: A porcine model of donor brain death and orthotopic heart transplantation was used. All hearts were arrested and stored for 14 hr in an extracellular preservation solution. Control hearts (CON; n=3) did not receive any additional treatment. Treated hearts received BMS180448 alone (BMS; n=3), cariporide alone (CAR; n=6), or both BMS180448 and cariporide (B+C; n=6). Donors of BMS180448-treated hearts received 2 mg/kg, 15 min before explantation. Donors and recipients of cariporide-treated hearts received 2 mg/kg, 15 min before explantation and reperfusion, respectively. RESULTS: The CON and BMS arms of the study were terminated after three transplantations because initial results in these groups were poor. Significantly, none of the control hearts could be weaned successfully from bypass, whereas all of the treated hearts were weaned successfully (CAR vs. CON and B+C vs. CON: P=0.012). The rate of troponin I release during the first 3 hr after reperfusion was significantly lower in CAR (P=0.0180) and B+C (P=0.0154) recipients than in CON recipients. Mean plasma troponin I levels (microg/mL) 3 hr after reperfusion were as follows: CON 633+/-177, BMS 576+/-110, CAR 346+/-93, and B+C 296+/-97. CONCLUSION: In this porcine model of extended cardiac allograft preservation, cariporide was more effective than BMS180448 as an adjuvant to our usual preservation solution. There was no additional benefit from the combination of the two therapies.

Functional evidence of reversible ischemic injury immediately after the sympathetic storm associated with experimental brain death.

BACKGROUND: Acute brain death from increased intracranial pressure results in a transient increase in myocardial adenosine and lactate, which indicates that oxygen demand exceeds oxygen delivery during the sympathetic "storm". The aim of this study was to determine the functional significance of this period of ischemia. METHODS: Brain death was inflicted on 40 Westran pigs (36.5-68.0 kg) by inflating a 21-ml subdural balloon over 3 minutes. In 38 animals, micromanometry and sonomicrometry were used to obtain left ventricular pressure-volume loops to determine the preload recruitable stroke work (PRSW) relationship. Data files were recorded before and at 15-minute intervals after beginning balloon inflation. Plasma troponin I was measured before and 60 minutes after beginning balloon inflation in the 38 instrumented and 2 non-instrumented animals. RESULTS: All animals experienced the classical sympathetic storm. The slope of the PRSW relationship decreased, and the volume-axis intercept shifted to the right 15 minutes after beginning balloon inflation (p < 0.0001). Progressive incremental recovery (leftward shift) occurred between subsequent time points (p < or = 0.0018). In the instrumented animals, the mean plasma troponin I level increased from 1.4 +/- 1.6 microg/liter to 2.8 +/- 2.3 microg/liter (p < 0.001). However, troponin I was not detected before or after induction of brain death in the plasma of either non-instrumented animal (p = 0.001). CONCLUSIONS: The sympathetic storm produced transient contractile dysfunction, consistent with ischemic injury. However, troponin I release reflected surgical instrumentation and not brain death.

The initial rate of troponin I release post-reperfusion reflects the effectiveness of myocardial protection during cardiac allograft preservation.

OBJECTIVE: To determine if the initial rate of troponin I release post-reperfusion reflects the effectiveness of myocardial protection during cardiac allograft preservation. METHODS: A porcine model of orthotopic heart transplantation was used. Data from two control groups (CON(4) and CON(14)) and two treatment groups (CAR(4) and CAR(14)) were analysed. Hearts in CON(4) (n=6) and CAR(4) (n=6) were subjected to 4 h of ischaemia while hearts in CON(14) (n=3) and CAR(14) (n=6) were subjected to 14 h of ischaemia. All hearts were arrested and stored in the same extracellular preservation solution. Both donor and recipient animals in the CAR(4) and CAR(14) groups received a single intravenous dose of cariporide (2 mg/kg), prior to explantation and reperfusion, respectively. RESULTS: Mean (SEM) plasma troponin I levels (microg/ml) 3 h post-reperfusion were: CON(4) 210+/-52, CAR(4) 68+/-21, CON(14) 633+/-177, CAR(14) 346+/-93. On multiple linear regression analysis, the rate of troponin I release over the first 3 h post-reperfusion was significantly lower in hearts stored for 4 h compared to hearts stored for 14 h (P<0.0001) and in hearts treated with cariporide compared to control hearts (P=0.0017). Early graft function was superior in hearts treated with cariporide, when compared to control hearts stored for the same period of time. All of the CAR(14) hearts could be weaned from cardiopulmonary bypass whereas none of the CON(14) could be weaned (6/6 vs. 0/3; P=0.012). While all hearts stored for 4 h could be weaned, contractility, as measured by the preload recruitable stroke work (PRSW) relationship, was significantly better preserved in CAR(4) hearts than in CON(4) hearts (P<0.0001). CONCLUSIONS: The initial rate of troponin I release post-reperfusion is determined by the duration of cardiac allograft ischaemia. Altering the myocardial preservation strategy can reduce the rate of release. Such reductions are associated with improvements in early graft function. These findings validate the initial rate of troponin I release post-reperfusion as an end-point when comparing cardiac allograft preservation strategies. In addition, the present study provides indirect evidence that troponin I degradation during ischaemia-reperfusion is related to the accumulation of intracellular calcium.

Cariporide (HOE-642) improves cardiac allograft preservation in a porcine model of orthotopic heart transplantation.

BACKGROUND: Acute graft dysfunction caused by ischemia-reperfusion injury is recognized as a major source of morbidity and mortality following adult heart transplantation. The aim of this study was to determine whether treating the donor and recipient with cariporide, an inhibitor of the sodium-hydrogen exchanger, could reduce ischemia-reperfusion injury. METHODS: A porcine model of donor brain death, hypothermic ischemic preservation, and orthotopic cardiac transplantation was used. Allografts in both the control group (CON, n=6) and treatment group (CAR, n=6) were arrested and stored for 4 hours in the extracellular crystalloid cardioplegia currently used in the clinical transplantation program at our institution. In addition, both the donor and recipient animals in the CAR group received a single intravenous dose of cariporide (2 mg/kg) 15 minutes before harvesting and reperfusion, respectively. RESULTS: The initial rate of troponin I release was significantly lower in recipients of CAR hearts than in recipients of CON hearts (P =0.020). All hearts were weaned successfully from bypass. More CAR hearts were weaned successfully at the first attempt, at 1 hour post-reperfusion, than CON hearts (6 of 6 vs 3 of 6), but this did not achieve statistical significance. Left ventricular contractility (preload recruitable stroke-work relationship) and left ventricular compliance (end-diastolic pressure-volume relationship) were significantly better preserved in CAR hearts than CON hearts (both P <0.0001). CONCLUSIONS: Myocardial injury was reduced, and contractile function was better preserved in allografts that received cariporide, compared with allografts that received conventional preservation alone.

Lazaroid (U74389G)-supplemented cardioplegia: results of a double-blind, randomized, controlled trial in a porcine model of orthotopic heart transplantation.

BACKGROUND: U74389G (16-desmethyl tirilazad), a 21-aminosteroid or "lazaroid," inhibits lipid peroxidation, which is an important element of ischemia-reperfusion injury. The aim of this study was to determine whether the addition of U74389G to the cardioplegic preservation solution could improve early cardiac allograft function. METHODS: A porcine model of donor brain death and orthotopic cardiac transplantation was used. Hearts were arrested and preserved for 6 hours in an aspartate-enriched extracellular cardioplegia that had been supplemented with either U74389G and its carrier (n = 7) or the carrier alone (n = 9). Epicardial sonomicrometry and transmyocardial micromanometry were used to obtain pressure-volume loops before and after transplantation. Left ventricular wall volume was measured by volume displacement. RESULTS: A higher proportion of U74389G-treated hearts were weaned successfully from cardiopulmonary bypass, but this difference did not achieve statistical significance (86% [6 of 7] vs 56% [5 of 9]; p = 0.308). In the hearts that were weaned successfully, preservation of left ventricular contractility, as judged by the pre-load recruitable stroke work relationship, was significantly better in the U74389G-treated hearts (p = 0.0271). In contrast, left ventricular compliance, as judged by the end-diastolic pressure-volume relationship, was significantly better preserved in the control group (p < 0.0001). U74389G-treated hearts developed less myocardial edema, as judged by the post-transplant left ventricular wall volume/baseline steady-state epicardial end-diastolic volume ratio (64 +/- 9% vs 76 +/- 11%; p = 0.045). CONCLUSIONS: The benefit obtained from U74389G-supplemented cardioplegic preservation solution was marginal for hearts stored for 6 hours. After longer ischemic times, the benefit may be clearer.

The preload recruitable stroke work relationship as a measure of left ventricular contractile dysfunction in porcine cardiac allografts.

OBJECTIVE: Paradoxically, it has been reported that after 1.5-4 h of hypothermic ischaemic preservation there is complete recovery of contractile function in canine cardiac allografts, as assessed by the preload recruitable stroke work (PRSW) relationship. This raises questions about the suitability of the canine heart as a model for preservation research and the PRSW relationship as an end-point. The aim of the present study was to evaluate the PRSW relationship as an index of left ventricular contractility in porcine cardiac allografts. METHODS: Eighteen orthotopic heart transplants were performed in inbred Westran pigs. Brain death was induced in the donor pigs 1 h prior to explantation. The donor hearts were arrested with extracellular cardioplegia, which was stored in ice prior to administration. On explantation, the donor hearts were immersed in cardioplegia and stored in ice. The donor hearts were subjected to either 4 (IT4, n = 6), 6 (IT6, n = 9) or 14 (IT14, n = 3) h of ischaemia. Post-transplant, all hearts were supported with dobutamine (10 mcg/kg per min). The PRSW relationship was derived from pressure-volume loops obtained by epicardial sonomicrometry and transmyocardial micromanometry. Multiple linear regression was used to describe and compare the PRSW relationship before brain death in the donor and after weaning from bypass in the recipient. RESULTS: Eleven hearts were weaned successfully from cardiopulmonary bypass: IT4 100% (6/6), IT6 56% (5/9) and IT14 0% (0/3) (IT4 versus IT14: P = 0.012). Analysis of the PRSW relationship revealed a reduction in contractility in both the IT4 and IT6 groups (both P < 0.0001), but a greater reduction in the IT6 group (P < 0.0001). Notably, the volume-axis intercept of the PRSW relationship was found to be a better discriminator of post-preservation contractile dysfunction than the slope of the PRSW relationship. CONCLUSIONS: The porcine heart's susceptibility to ischaemic injury makes it ideal for evaluating the effect of different preservation strategies on contractile recovery. The PRSW relationship can be used to evaluate the differences in contractile recovery, though the nature of the effect of ischaemic preservation necessitates analysis by multiple linear regression.