Paediatric acute care cardiology collaborative data registry validation.

BACKGROUND: The Pediatric Acute Care Cardiology Collaborative (PAC3) was established to improve acute care cardiology outcomes through the development of an accurate and well-validated clinical registry. We report the validation results of the initial PAC3 registry audits and describe a novel regional audit format developed to accommodate a rapidly expanding membership facilitate collaborative learning and allow for necessary modification due to the COVID-19 pandemic. MATERIALS AND METHODS: Six hospitals were audited using a regional audit format and three hospitals were subsequently audited virtually. Critical and challenging-to-collect data elements were audited among at least 40 randomly selected cases. Discrepancies were categorised as either major or minor depending on their relative importance to patient outcomes and clinical care. Results were tabulated and reported. RESULTS: We audited 386 encounters and 27,086 individual data fields across 9 hospitals. The aggregate overall accuracy rate was 99.27% and the aggregate major discrepancy rate was 0.51%. The overall accuracy rate ranged from 98.77% to 99.59%, and the major discrepancy rate ranged from 0.26% to 0.88% across the cohort. No appreciable difference was seen between audit formats. Both the regional and virtual audit methods were viewed favourably by participants. CONCLUSIONS: A low data discrepancy rate was found demonstrating that the PAC3 registry is a highly accurate data source for use in quality improvement, benchmarking, and research. Regional audits and virtual audits were both successfully implemented.

Optimization of adenoviral vector-mediated gene transfer to pulmonary arteries in newborn swine.

Efficient pulmonary vascular gene transfer in neonates would aid in understanding the pathophysiology of, and ultimately allow the development of specific therapies for, pulmonary vascular diseases. The purpose of this study was to optimize efficiency, and evaluate the duration, of catheter-based adenoviral vector-mediated pulmonary artery gene transfer in newborn pigs. An adenovirus vector encoding LacZ was infused via percutaneously placed catheters that were advanced to segmental pulmonary arteries under fluoroscopic guidance. Optimal viral dose and duration of expression were determined by histochemical evaluation of gene transfer efficiency 72 hr, 2 weeks, and 1 month after gene delivery. The effect of protamine on the efficiency of gene transfer was studied by assaying transgene protein in lung at 72 hr. The optimal viral dose was 2 x 10(10) plaque-forming units (PFU). Seventy-two hours after infusion, expression predominated in medium-sized artery endothelial cells, 40% of which expressed beta-galactosidase. At 2 weeks, the distribution of expression had changed such that the majority of transduced cells were seen not in arteries but in gas exchange units of lung. No histochemical evidence of transgene expression was seen 1 month after virus infusion. The addition of protamine to virus infusate resulted in a fivefold increase in transgene protein product in lung tissue assayed 72 hr after gene transfer. Adenoviral vector-mediated gene transfer in neonatal swine results in high-efficiency transduction of arterial endothelial cells. However, the time course of gene transfer is not significantly prolonged compared with the adult. The addition of protamine results in a significant improvement in transduction efficiency, permitting lower doses of virus.

Angiogenesis and morphogenesis of murine fetal distal lung in an allograft model.

Neovascularization is crucial to lung morphogenesis; however, factors determining vessel growth and formation are poorly understood. The goal of our study was to develop an allograft model that would include maturation of the distal lung, thereby ultimately allowing us to study alveolar development, including microvascular formation. We transplanted 14-day gestational age embryonic mouse lung primordia subcutaneously into the back of nude mice for 3.5-14 days. Lung morphogenesis and neovascularization were evaluated by light microscopy, in situ hybridization, and immunohistochemical techniques. Embryonic 14-day gestational age control lungs had immature structural features consistent with pseudoglandular stage of lung development. In contrast, 14 days after subcutaneous transplantation of a 14-day gestational age lung, the allograft underwent significant structural morphogenesis and neovascularization. This was demonstrated by continued neovascularization and cellular differentiation, resulting in mature alveoli similar to those noted in the 2-day postnatal neonatal lung. Confirmation of maturation of the allograft was provided by progressive type II epithelial cell differentiation as evidenced by enhanced local expression of mRNA for surfactant protein C and a threefold (P < 0.008) increase in vessel formation as determined by immunocytochemical detection of platelet endothelial cell adhesion molecule-1 expression. Using the tyrosine kinase Flk-1 receptor (flk-1) LacZ transgene embryos, we determined that the neovascularization within the allograft was from the committed embryonic lung endothelium. Therefore, we have developed a defined murine allograft model that can be used to study distal lung development, including neovascularization. The model may be useful when used in conjunction with an altered genetic background (knockout or knock in) of the allograft and has the further decided advantage of bypassing placental barriers for introduction of pharmacological agents or DNA directly into the lung itself.

Qualitative and quantitative analysis of embryonic pulmonary vessel formation.

Vessel formation in the lung has been described as occurring by two mechanisms: proximal, or branch, pulmonary arteries develop via angiogenesis; and distal, smaller vessels form by vasculogenesis. Connections between the proximal and distal vessels establish the final vascular network. The preponderance of vessel formation has been suspected to occur during the canalicular stage of lung development. To test these hypotheses, reporter gene expression under control of the regulatory domain of fetal liver kinase-1 (flk), an early endothelial cell-specific marker, was used to evaluate mouse lungs from embryonic day 10.5 (E10.5) through 2 wk postnatal age. Morphologic assessment was performed after histochemical staining, and quantification of vessel development by a chemiluminescent assay was compared with overall embryonic lung growth. LacZ expression under flk promoter control allowed: (1) early identification of differentiating endothelial cells of the branch pulmonary arteries; (2) visualization of distal vessels forming in the lung mesenchyme (primary capillary network) with subsequent remodeling; (3) recognition of early continuity between proximal and distal vessels, occurring by E10.5; and (4) assessment of developing pulmonary veins and venous confluence. Quantitative analysis revealed increased flk regulated beta-galactosidase (beta-gal) activity of 12 ng beta-gal/lung at E12.5 to 3,215 ng beta-gal/lung at 2 wk, which corresponded to overall lung growth during this period as shown by an increase in total protein content per lung from 35 microg at E12.5 to 6,456 microg at 2 wk after birth. We identified endothelial cell precursors of the developing pulmonary vasculature before vessel lumen formation. Continuity between the proximal pulmonary artery and vessels forming in the distal mesenchyme was present even at the earliest stage evaluated, suggesting endothelial cell differentiation at the site of vessel formation (i.e., vasculogenesis) as occurs with development of the aorta. Finally, we demonstrated that lung vessel development was not accentuated during the canalicular stage, but occurred at all stages and directly corresponded to overall lung growth.

Temporally regulated expression patterns following in utero adenovirus-mediated gene transfer.

Developmental patterns of gene expression were determined following intravascular administration of adenovirus in utero, during sequential stages of murine development. Replication-deficient adenovirus (AdCMV.LacZ) was injected into yolk sac vessels of mouse embryos 12, 13, 15 and 18 days post-conception (d.p.c.). beta-Galactosidase (beta-gal) expression was evaluated 24-48 h after injection, at birth, and 5 weeks following normal delivery. Gene expression was detected in myocardial cells, endothelial cells of heart, lung, kidney, adrenal, gut, and in hepatocytes. The patterns of expression were distinct for each stage of virus administration and time-point of analysis. Intensity of individual organ expression varied with injection time-point, with the largest number of organs express- ing the transgene when embryos were injected at 15 d.p.c. beta-Gal activity was detected in only a subset of cells expressing the murine coxsackievirus and adenovirus receptor (CAR), indicating factors other than receptor distribution were responsible for the pattern of transgene expression observed. These studies begin to define critical parameters affecting intravascular gene delivery in utero and indicate that intrinsic developmental regulatory mechanisms may control exogenous gene expression. Intravenous administration of adenovirus provides a unique approach for in utero gene transduction and will be a useful adjunct in evaluating genes which have early lethal mutations.

In vivo adenovirus-mediated gene transfer via the pulmonary artery of rats.

Gene transfer into the pulmonary vasculature has the potential to be a powerful technique for both investigation of pulmonary pathophysiology and development of genetic therapies for pulmonary vascular disease. To evaluate the potential for in vivo pulmonary arterial gene transfer, we infused adenoviral vectors into the left pulmonary artery of Sprague-Dawley and cotton rats. Access to the left pulmonary artery was obtained by a percutaneous transcatheter approach or through thoracotomy and pulmonary arteriotomy. With the thoracotomy approach, both pulmonary arterial inflow and pulmonary venous outflow were occluded during vector influsion and throughout a subsequent 20-minute dwell period. The success of gene transfer was assessed by staining for evidence of recombinant gene expression in lungs excised at time points ranging from 48 to 72 hours after virus infusion. With the thoracotomy technique, pulmonary gene transfer was successful in 15% of surviving Sprague-Dawley rats and 30% of surviving cotton rats. Percutaneous catheter-based pulmonary gene transfer was not successful. In rats with pulmonary gene transfer, 1% to 8% of total left lung cells expressed the recombinant gene. Recombinant gene expression was found in endothelial cells (0.2% to 18% of total transduced cells), smooth muscle cells (0% to 3%), macrophages (1% to 7%), airway epithelial cells (2% to 50%), and alveolar epithelial cells (38% to 94%). Investigation of the low rate of successful gene transfer in individual animals suggested that insufficient physical contact between the virions and pulmonary cells was the most likely cause. In vivo gene transfer into the rat pulmonary vasculature can be accomplished with adenovirus vectors.(ABSTRACT TRUNCATED AT 250 WORDS)