Ralf G. Seipelt

Hypercholesterolemia is common after pediatric heart transplantation: initial experience with pravastatin

BACKGROUNDnCoronary allograft vasculopathy (CAV) is a progressive complication after cardiac transplantation and limits survival. Hyperlipidemia is a known risk factor for CAV, and pravastatin is effective in decreasing cholesterol levels in adults after transplantation. However, few data exist regarding lipid profiles and statin use after pediatric heart transplantation. We evaluated the prevalence of hyperlipidemia in pediatric heart transplant recipients and assessed the efficacy and safety of pravastatin therapy.nnnMETHODSnWe performed a retrospective chart review of lipid profiles > or =1 year after surgery in 50 pediatric cardiac transplant recipients to assess the incidence of hyperlipidemia. Twenty of these patients received pravastatin for hypercholesterolemia. Their primary immunosuppression therapy was cyclosporine/prednisone plus either azathioprine or mycophenolate mofetil. We reviewed serial lipid profiles, creatinine phosphokinase, and liver enzymes.nnnRESULTSnOverall, 36% of the patients (n = 50) had total cholesterol (TC) concentrations > 200 mg/dl and 52% had low-density lipoprotein (LDL) >110 mg/dL beyond 1 year after transplantation. Of the 20 treated with pravastatin, TC (236 +/- 51 vs 174 +/- 33 mg/dl) and LDL levels (151 +/- 32 vs 99 +/- 21 mg/dl) decreased significantly with therapy (p <.0001). We found no symptoms; however, 1 patient had increased creatinine phosphokinase. Liver enzyme concentrations remained normal in all.nnnCONCLUSIONSnHypercholesterolemia is prevalent in pediatric cardiac transplant recipients. Pravastatin therapy is effective in decreasing TC and LDL levels, seems to be safe, and is tolerated well. Further studies are necessary to determine whether pravastatin treatment is beneficial in decreasing CAV.

Alterations in the natriuretic hormone system related to cardiopulmonary bypass in infants with congestive heart failure

This study examined changes in the natriuretic hormone system in five infants with congestive heart failure (CHF) due to intracardiac left-to-right shunting who were exposed to cardiopulmonary bypass (CPB) during surgical repair. Plasma concentrations of three hormones [atrial natriuretic peptide (ANP), brain natriuretic peptide (BNP), and dendroaspis natriuretic peptide (DNP)] and their secondary messenger, guanosine 3′, 5′-monophosphate (cGMP), were measured, and the biological activity of the system was quantified. At baseline, BNP and DNP concentrations were normal in our patients, a finding that is strikingly different from that of adult CHF patients, whereas ANP concentrations were elevated. Following CPB, ANP concentrations decreased (median, 175 vs 44 pg/ml; p = 0.043) and BNP concentrations increased (median, 25 vs 66 pg/ml; p = 0.043), whereas DNP concentrations did not change. Following modified ultrafiltration, BNP concentrations increased (p = 0.043), but other natriuretic peptide concentrations did not change. The calculated biological activity of the natriuretic hormone system decreased following CPB [molar ratio, cGMP / (ANP + BNP + DNP); median, 213 vs 127; p = 0.043)]. Additional studies are needed to expand on these findings and identify patients with other types of congenital heart disease who have perioperative disturbances in the natriuretic hormone system and thus might benefit from pharmacologic intervention.

Hemodynamic and gas transfer properties of a compliant thoracic artificial lung

A compliant thoracic artificial lung (TAL) has been developed for acute respiratory failure or as a bridge to transplantation. The development goal was to increase TAL compliance, lower TAL impedance, and improve right ventricular function during use. Prototypes were tested in vitro and in vivo in eight pigs between 67 and 79 kg to determine hemodynamic and gas transfer properties. The in vitro compliance was 16.2 ± 4.4 ml/mm Hg at pressures < 7.8 mm Hg and 4.3 ± 1.1 ml/mm Hg above 7.8 mm Hg. In vivo, this compliance significantly reduced blood flow pulsatility from 1.7 at the inlet to 0.36 at the outlet. Device resistance was 1.9 and 1.8 mm Hg/(L/min) at a flow rate of 4 L/min in vitro and in vivo, respectively. Approximately 75% of the resistance was at the inlet and outlet. In vivo TAL O2 and CO2 transfer rates were 188 and 186 ml/min, respectively, at 4 L/min of blood and gas flow, and average outlet O2 saturations exceeded 98% for average flow rates up to and including the maximum tested, 5.3 L/min. The new design has a markedly improved compliance and excellent gas transfer but also possesses inlet and outlet resistances that must be reduced in future designs.

In vivo hemodynamic responses to thoracic artificial lung attachment

A thoracic artificial lung (TAL) was attached to the pulmonary circulation in a porcine model. Proximal main pulmonary artery (PA) blood flow, in part or whole, was diverted to the TAL, and TAL outlet blood flow was split between the distal main PA and left atrium (LA). The right ventricle (RV) drove blood flow through the combined TAL/natural lung (NL) pulmonary system. Selective banding placed the TAL in parallel with the NLs, in series with the NLs, or in an intermediary hybrid configuration. Parallel TAL attachment lowered pulmonary system impedance, raised cardiac output (CO), and provided the greatest TAL blood flow rate, but reduced the NL blood flow rate which is important for pulmonary embolic clearance and metabolic blood processing. Hybrid or series TAL attachment raised pulmonary system impedance, lowered CO, increased RV oxygen consumption, and reduced RV oxygen supply. Redesign of the PA anastomoses, TAL inlet graft, and TAL entrance and exit would significantly improve hemodynamics and RV function with TAL attachment. Mean LA pressure increased throughout the experiment, which may indicate damage caused by graft attachment to the LA. Pulmonary resistance–flow rate curves may enable clinical prediction of tolerable TAL attachment configurations.

Topical VEGF Enhances Healing of Thoracic Aortic Anastomosis for Coarctation in a Rabbit Model

Background—Recurrent stenosis after extended end-to-end anastomosis for aortic coarctation is the primary indication for further interventions in children. Tension because of the extended resection and local arterial wall hypoxia are possible pathogenetic mechanisms. We hypothesized that (1) tension interferes with healing and (2) that vascular endothelial growth factor (VEGF), a hypoxia sensitive angiogenic inducer, may enhance healing of the vascular anastomosis. Methods and Results—In a model of coarctation repair, rabbits underwent thoracic aortic end-to-end anastomosis after transection (no-tension; n=15), resection of an aortic ring (tension; n=14) or resection and topical VEGF treatment (0.75 &mgr;g VEGF165; tension+VEGF; n=14). Gross and histologic characteristics of the aortic wall were assessed at 1 week, 1 and 2 months. In the tension only group at 1 month, the severity of vascular remodeling was increased with fibrosis and calcification compared with controls. At 2 months, this group also revealed more luminal stenosis (29% versus 19%; P <0.001). Exogenous VEGF resulted in significantly less fibrosis, calcification and chondroid metaplasia at 1 month (P <0.05) and luminal area was only reduced 3% at 2 months (P <0.001 versus tension group). Conclusions—In a rabbit model of coarctation repair, the addition of tension on the vascular anastomosis resulted in poor healing and luminal stenosis. Topical VEGF maintained luminal integrity by decreasing fibrosis and calcification. These findings suggest that topical VEGF may be a promising new strategy to enhance healing and improve the outcome of vascular anastomoses for coarctation of the aorta.