Dear Impossible Readers,
From the earliest moments of life, minor developmental errors can cause significant and lasting impacts. Rare congenital diseases are conditions present at birth resulting from disruptions during embryonic or foetal development. Unlike genetic rare diseases, which primarily result from DNA mutations, congenital disorders may originate from a combination of genetic, environmental, or unknown factors, often presenting as structural malformations, metabolic imbalances, or developmental delays. Recognising congenital diseases as a distinct category allows healthcare professionals and families to prioritise early diagnosis, prompt interventions, and personalised management plans.
The spectrum of rare congenital diseases is extensive. Congenital Diaphragmatic Hernia (CDH) involves a structural defect in the diaphragm that allows abdominal organs to enter the chest cavity and impairs lung development. Tetralogy of Fallot combines four heart defects, leading to cyanosis and circulatory issues, and is often associated with chromosomal deletions, such as 22q11.2. Congenital Hyperinsulinism (CHI) results from mutations that disrupt pancreatic beta-cell function, leading to ongoing hypoglycaemia and risk of neurological damage. Merosin-deficient Congenital Muscular Dystrophy (MCMD) stems from defective muscle proteins, weakening skeletal muscles, and sometimes impacting the brain. Lastly, Congenital Hypothyroidism can be caused by thyroid dysgenesis or biosynthesis defects, which delay growth and cognitive development if left untreated. These diseases highlight that congenital conditions can be structural, metabolic, muscular, or endocrine, underscoring the importance of developmental processes in early life.
Current treatments for rare congenital diseases are usually tailored to each condition and are mainly supportive, focusing on managing complications and improving quality of life. For example, CDH is typically repaired surgically shortly after birth, along with vigilant neonatal respiratory support. Tetralogy of Fallot often requires early corrective heart surgery, sometimes in multiple stages. CHI is treated with medications like diazoxide that inhibit insulin secretion, and in severe cases, partial pancreatectomy. MCMD depends on physiotherapy, orthopaedic support, and respiratory care, as there is no cure. Congenital Hypothyroidism has a notably effective treatment. Early thyroid hormone replacement to prevent growth delays and cognitive impairment. In all these cases, early diagnosis and coordinated care are essential, as prompt intervention can significantly improve outcomes, even without cures.
The management of congenital rare diseases is becoming increasingly personalised and promising. For CDH, advancements in foetal surgery and prenatal imaging may enable corrections before birth, thereby improving lung development and survival rates. Tetralogy of Fallot could benefit from minimally invasive surgeries and tissue-engineered heart patches, reducing the need for multiple procedures. In CHI, new gene-targeted therapies and pharmacological chaperones might address the underlying beta-cell defects instead of merely managing symptoms. MCMD is a promising candidate for gene therapy, exon skipping, or stem cell–based regenerative treatments aimed at restoring muscle function. Finally, for Congenital Hypothyroidism, although hormone replacement is effective, early intervention could be enhanced through genetic screening and prenatal diagnosis, helping to prevent disease effects before birth. Overall, advances in molecular medicine, prenatal diagnostics, and regenerative technologies point to a future in which congenital diseases are addressed at their developmental origins rather than solely managed after birth.
Managing rare congenital diseases requires a synergy of early detection and a coordinated, multidisciplinary approach. Modern newborn screening and advanced prenatal diagnostics, such as those for Congenital Hypothyroidism, create a “window of opportunity” for intervention before irreversible damage occurs. However, technology alone is not enough. The key element is the “medical home” model. This approach unites neonatologists, surgeons, geneticists, and therapists into a single team, shifting care from merely treating symptoms to supporting the whole child. Ultimately, combining genetic and developmental information enables clinicians to move beyond generic protocols, creating personalized treatment plans that not only improve health outcomes but also give families hope for their child’s future.
From day one, the future takes shape,
Yours Possibly
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Further Reading
Bedzra, E., Contorno, E., Javed, H., Qasim, A., St Louis, J. and Konrad Rajab, T., 2025. Tetralogy of fallot: anatomy, physiology, and outcomes. Congenital Heart Disease, 19(6), p.541.
Cavarzere, P., Mancioppi, V., Battiston, R., Lupieri, V., Morandi, A. and Maffeis, C., 2025. Primary congenital hypothyroidism: a clinical review. Frontiers in endocrinology, 16, p.1592655.
Chaudhari, T., Schmidt Sotomayor, N. and Maheshwari, R., 2024. Diagnosis, management and long term cardiovascular outcomes of phenotypic profiles in pulmonary hypertension associated with congenital diaphragmatic hernia. Frontiers in Pediatrics, 12, p.1356157.
Costeira, M.J., Costa, P., Roque, S., Carvalho, I., Vilarinho, L. and Palha, J.A., 2024. History of neonatal screening of congenital hypothyroidism in Portugal. International Journal of Neonatal Screening, 10(1), p.16.
ElSheikh, A. and Shyng, S.L., 2023. KATP channel mutations in congenital hyperinsulinism: Progress and challenges towards mechanism-based therapies. Frontiers in Endocrinology, 14, p.1161117.
Iannaccone, S.T. and Castro, D., 2013. Congenital muscular dystrophies and congenital myopathies. CONTINUUM: Lifelong Learning in Neurology, 19(6), pp.1509-1534.
Liberatore Junior, R.D., Marques, A.L., Dos Santos, L.L. and Luciano, T.M., 2025. Clinical and epidemiological profile of congenital hyperinsulinism in Brazil. Frontiers in Endocrinology, 16, p.1547855.
Mercer-Rosa, L. and Favilla, E., 2024. Neurodevelopment in patients with repaired tetralogy of Fallot. Frontiers in pediatrics, 12, p.1137131.
Mital, R., Lozier, J.S. and Mead, T.J., 2024. Genetic insights into Tetralogy of Fallot: Oh MYH (6). Pediatric Research, 96(2), pp.297-298.
Qiao, L., Welch, C.L., Hernan, R., Wynn, J., Krishnan, U.S., Zalieckas, J.M., Buchmiller, T., Khlevner, J., De, A., Farkouh-Karoleski, C. and Wagner, A.J., 2024. Common variants increase risk for congenital diaphragmatic hernia within the context of de novo variants. The American Journal of Human Genetics, 111(11), pp.2362-2381.
Renik-Jankowska, W., Buczyńska, A., Sidorkiewicz, I., Kosiński, P. and Zbucka-Krętowska, M., 2024. Exploring new perspectives on congenital diaphragmatic hernia: A comprehensive review. Biochimica et Biophysica Acta (BBA)-Molecular Basis of Disease, 1870(4), p.167105.
Rosenfeld, E. and De León, D.D., 2023. Bridging the gaps: Recent advances in diagnosis, care, and outcomes in congenital hyperinsulinism. Current opinion in pediatrics, 35(4), pp.486-493.
Xie, X., Pei, J., Zhang, L. and Wu, Y., 2025. Global birth prevalence of major congenital anomalies: a systematic review and meta-analysis. BMC Public Health, 25(1), p.449.
Zhang, T.N., Huang, X.M., Zhao, X.Y., Wang, W., Wen, R. and Gao, S.Y., 2022. Risks of specific congenital anomalies in offspring of women with diabetes: A systematic review and meta-analysis of population-based studies including over 80 million births. PLoS medicine, 19(2), p.e1003900.
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