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This study evaluates the retrograde approach compared to the antegrade approach in infants with PA-IVS who underwent transcatheter pulmonary valvotomy procedure at National Cardiovascular Center Harapan Kita, Jakarta, Indonesia.
Material and method:
This is a single-centre retrospective study conducted from January 2017 to June 2019 consisting of infants undergoing transcatheter pulmonary valvotomy procedures from our centre.
Results:
Among 3733 records of cardiac catheter procedure in paediatric patients during the last 3 years, there were 12 subjects with PA-IVS, where five subjects were done by antegrade approach and seven by retrograde approach. The retrograde approach is shown to excel the antegrade approach in terms of procedural time by 58.64 minutes (CI 95 % 32.97–84.29, p = 0.008) and PA-RV crossing time by 27 minutes (CI 95 % 14.01–39.99, p = 0.02). There was no significant difference in contrast used (120.23 ± 25.77 versus 150.27 ± 39.26 ml/BSA, p = 0.518), and right ventricle to pulmonary artery systolic pressure gradient after valvotomy (39.571 ± 5.814 versus 53.52 ± 29.15, p = 0.329) between the retrograde and the antegrade approach.
Conclusion:
The retrograde approach offered shorter procedural time and comparably satisfying results than the antegrade approach. The shorter procedural time was preferred due to the shorter duration of general anaesthesia, which may decrease the risk of neurodevelopmental deficits in the patient.
Acute pulmonary hypertension and pulmonary hypertensive crisis may result in adverse clinical outcomes if unsuccessfully treated. Inhaled nitric oxide has long been considered as the standard pharmacotherapy for acute pulmonary hypertension, but lack of feasibility in some settings and evidences challenging its benefits lead to the use of alternative treatment, amongst which is nitroglycerin inhalation. The purpose of this review article is to discuss available data on the use of nitroglycerin inhalation for acute treatment of pulmonary hypertension in children with CHD and its potential benefit in post-operative setting.
Data sources:
Literatures included in this review were acquired by searching in PubMed online database. Keywords used were “Pulmonary Hypertension”, “Congenital heart defects”, “Pediatrics”, “Inhaled nitroglycerin”, and its synonyms.
Study selection:
Title and abstract were screened to select relevant literatures including the three paediatric clinical trials on nitroglycerin inhalation. Critical appraisal of the clinical trials was then done using the University of Oxford Centre of Evidence-Based Medicine Critical Appraisal Tools.
Conclusions:
Paediatric studies showed the benefit of nitroglycerin inhalation in uncorrected cases of CHD during catheterisation procedures. Until recently, there have been no studies conducted in paediatric post-operative CHD cases. Further study is required to provide evidence for inhaled nitroglycerin use in this setting including the appropriate dosing and potential side effects with repeated administration,
To determine if triiodothyronine alters lactate, glucose, and pyruvate metabolism, and if serum pyruvate concentration could serve as a predictor of low cardiac output syndrome in children after cardiopulmonary bypass procedures.
Methods:
This study was ancillary to the Oral Triiodothyronine for Infants and Children undergoing Cardiopulmonary bypass (OTICC) trial. Serum pyruvate was measured in the first 48 patients and lactate and glucose were measured in all 208 patients enrolled in the OTICC study on the induction of anaesthesia, 1 and 24 hours post-aortic cross-clamp removal. Patients were also defined as having low cardiac output syndrome according to the OTICC trial protocol.
Result:
Amongst the designated patient population for pyruvate analysis, 22 received placebo, and 26 received triiodothyronine (T3). Lactate concentrations were nearly 20 times greater than pyruvate. Lactate and pyruvate levels were not significantly different between T3 and placebo group. Glucose levels were significantly higher in the placebo group mainly at 24-hour post-cross-clamp removal. Additionally, lactate and glucose levels peaked at 1-hour post-cross-clamp removal in low cardiac output syndrome and non-low cardiac output syndrome patients, but subsequently decreased at a slower rate in low cardiac output syndrome. Lactate and pyruvate concentrations correlated with glucose only prior to surgery.
Conclusion:
Thyroid supplementation does not alter systemic lactate/pyruvate metabolism after cardiopulmonary bypass and reperfusion. Pyruvate levels are not useful for predicting low cardiac output syndrome. Increased blood glucose may be regarded as a response to hypermetabolic stress, seen mostly in patients with low cardiac output syndrome.
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