Initial transcatheter palliation of hypoplastic left heart syndrome

Initial percutaneous transcatheter palliation of hypoplastic left heart syndrome is now feasible. The primary procedures for palliation include stenting of the ductus arteriosus with a self expanding nitinol stent to secure an adequate systemic blood flow, placement of an internal pulmonary arterial band to protect the pulmonary vascular bed and to prevent pulmonary overcirculation, and widening of the interatrial communication by blade and balloon septostomy or static balloon dilation to decompress the left atrium. Anatomic variations of the ductus arteriosus have important implications for technical success with ductal stenting. Patients who have undergone complete transcatheter palliation with the internal pulmonary band appear to have less immediate morbidity at the time of transplant, with preserved integrity and growth of the branch pulmonary arteries at one year follow-up.

Ductal anatomy: a determinant of successful stenting in hypoplastic left heart syndrome

Interventional palliation for hypoplastic left heart syndrome (HLHS) could reduce the current morbidity and mortality. Stenting of the arterial duct is the critical interventional step for HLHS. We reviewed our experience with 40 consecutive patients with HLHS referred for stenting of the ductus arterious (DA). Thirty-nine of 40 (97%) infants had suitable anatomy and were successfully stented. The infants were grouped by orientation of the ductus in the frontal plane. Type 1 DA anatomy had a leftward loop at a mean orientation of 18 degrees from the vertical plane. Type 2 ductal anatomy was mesoverted, with a mean orientation of 7.1 degrees from the vertical plane. Type 3 ductal anatomy displayed a rightward axis, with a mean of -4 degrees rightward. Orientation of the DA was significantly related to length of the ductus, number of stents required for complete coverage, and technical and procedural complications. Type 1 DA occurred in 65% of patients, and there was 100% technical success, no mortality, and only an 8% incidence of complications. Type 2 anatomy occurred in 27% of patients and there was 100% success. However, the technical and procedural complications increased to approximately 50%. Type 3 ductal anatomy was seen in only 3 patients, 2 of whom were successfully stented. There was no procedural-related mortality, and all stented patients were weaned from prostaglandin. There were only two late complications (coarctation). We conclude that ductal stenting using self-expanding nitinol stents is successful in more than 95% of infants with HLHS. Patients with HLHS and favorable ductal anatomy should be considered for primary ductal stenting.

Improved pretransplant management of infants with hypoplastic left heart syndrome enables discharge to home while waiting for transplantation

For infants whose families select primary transplantation for hypoplastic left heart syndrome (HLHS), the waiting time averages 3 months. Given the relative shortage of organs, the morbidity and mortality of these patients have been high. Therefore, pretransplant management is critical to improve the number of patients who survive to transplantation. This series shows our evolving management for these children, with an emphasis on nonintensive care. Fifty-two infants with HLHS were listed for primary transplantation at our institution during a 6-year period. The management was aimed at manipulating the pulmonary and systemic blood flows by low-dose continuous infusion of prostaglandin E1 (PGE1), early use of inhaled nitrogen, delayed opening of the atrial septum, and discharge to home with PGE1 infusion for continuing care when the child was on room air and growing. Almost all of the children (46/ 52) required nitrogen therapy with initial FiO2 of 0.16-0.17. Patients were weaned off nitrogen by 5 to 6 weeks of age. One fourth of the children needed atrial septal opening, typically at 2 or 3 months of age. Seventeen (32.7%) of the infants were able to spend at least some of their waiting time at home. Forty-five of the 52 children (86.5%) survived to receipt of a donor heart. Newborns with HLHS whose families select primary transplantation as their surgical option can be managed with a minimally invasive approach until receipt of a donor heart with an improvement in mortality rate.

Biochemical nature and cellular distribution of the paired immunoglobulin-like receptors, PIR-A and PIR-B

PIR-A and PIR-B, paired immunoglobulin-like receptors encoded, respectively, by multiple Pira genes and a single Pirb gene in mice, are relatives of the human natural killer (NK) and Fc receptors. Monoclonal and polyclonal antibodies produced against a recombinant PIR protein identified cell surface glycoproteins of approximately 85 and approximately 120 kD on B cells, granulocytes, and macrophages. A disulfide-linked homodimer associated with the cell surface PIR molecules was identified as the Fc receptor common gamma (FcRgammac) chain. Whereas PIR-B fibroblast transfectants expressed cell surface molecules of approximately 120 kD, PIR-A transfectants expressed the approximately 85-kD molecules exclusively intracellularly; PIR-A and FcRgammac cotransfectants expressed the PIR-A/ FcRgammac complex on their cell surface. Correspondingly, PIR-B was normally expressed on the cell surface of splenocytes from FcRgammac-/- mice whereas PIR-A was not. Cell surface levels of PIR molecules on myeloid and B lineage cells increased with cellular differentiation and activation. Dendritic cells, monocytes/macrophages, and mast cells expressed the PIR molecules in varying levels, but T cells and NK cells did not. These experiments define the coordinate cellular expression of PIR-B, an inhibitory receptor, and PIR-A, an activating receptor; demonstrate the requirement of FcRgammac chain association for cell surface PIR-A expression; and suggest that the level of FcRgammac chain expression could differentially affect the PIR-A/PIR-B equilibrium in different cell lineages.

Heart transplantation in children and young adults: early and intermediate-term results

The purpose of this article is to report our short- and intermediate-term follow-up of cardiac transplantation for congenital heart disease and cardiomyopathy in children (age greater than 6 months), adolescents, and young adults. Thirty patients (ages 8 months to 24 years) with end-stage heart failure have undergone cardiac transplantation in our program: 12 (40%) for postoperative end-stage heart failure, 9 (30%) as primary treatment for congenital heart disease, 5 (17%) for dilated cardiomyopathy, and 4 (13%) for restrictive/hypertrophic cardiomyopathy. Nineteen patients (63%) had undergone prior operations; 4 patients received transplants for failed Fontan procedures. Induction therapy with antithymocyte therapy was used routinely, and long-term immunosuppression was by cyclosporine and azathioprine alone. Rejection surveillance/diagnosis was based on echocardiographic criteria. Posttransplantation follow-up ranges from 3 to 78 months. Operative mortality was 3.3% (1/30). No patients have been diagnosed with either accelerated allograft atherosclerosis or posttransplantation lymphoproliferative disease. We conclude that cardiac transplantation may be performed with excellent early and intermediate-term results.