@Article{chd.2025.071773,
AUTHOR = {Jun He, Jianli Luo, Yanling Wang, Dai Zhou, Shuanglin Xiang},
TITLE = {Precision Pharmacology in Pediatric Congenital Heart Disease: Gene Editing and Organoid Models Addressing Developmental Challenges},
JOURNAL = {Structural and Congenital Heart Disease},
VOLUME = {20},
YEAR = {2025},
NUMBER = {5},
PAGES = {613--623},
URL = {http://www.techscience.com/schd/v20n5/64663},
ISSN = {3071-1738},
ABSTRACT = {Pediatric congenital heart disease (CHD) pharmacotherapy faces three fundamental barriers: developmental pharmacokinetic complexity, anatomic-genetic heterogeneity, and evidence chain gaps. Traditional agents exhibit critical limitations: digoxin’s narrow therapeutic index (0.5–0.9 ng/mL) is exacerbated by <i>ABCB1</i> mutations (toxicity risk increases 4.1-fold), furosemide efficacy declines by 35% in neonates due to NKCC2 immaturity, and β-blocker responses vary by <i>CYP2D6</i> polymorphisms (poor metabolizers require 50–75% dose reduction). Novel strategies demonstrate transformative potential—CRISPR editing achieves 81% reversal of <i>BMPR2</i>-associated pulmonary vascular remodeling, metabolically matured cardiac organoids replicate adult myocardial energy metabolism for drug screening, and SGLT2 inhibitors activate triple mechanisms (calcium overload mitigation, mitophagy, fibrosis reversal). However, clinical translation requires overcoming developmental barriers: age-dependent enzyme expression (infant <i>CYP2D6</i> = 30–60% adult activity), post-Fontan hepatotoxicity (bosentan trough concentrations elevates 1.8-fold), and AI model limitations (32% error in complex CHD). Future integration of placental transfer models, disease-specific organoids, and multi-omics mapping of FOXO/CRIM1 pathways will shift paradigms from symptom control to curative repair.},
DOI = {10.32604/chd.2025.071773}
}