Continuous glucose monitoring for children with hypoglycaemia: Evidence in 2023.

In 2023, childhood hypoglycaemia remains a major public health problem and significant risk factor for consequent adverse neurodevelopment. Irrespective of the underlying cause, key elements of clinical management include the detection, prediction and prevention of episodes of hypoglycaemia. These tasks are increasingly served by Continuous Glucose Monitoring (CGM) devices that measure subcutaneous glucose at near-continuous frequency. While the use of CGM in type 1 diabetes is well established, the evidence for widespread use in rare hypoglycaemia disorders is less than convincing. However, in the few years since our last review there have been multiple developments and increased user feedback, requiring a review of clinical application. Despite advances in device technology, point accuracy of CGM remains low for children with non-diabetes hypoglycaemia. Simple provision of CGM devices has not replicated the efficacy seen in those with diabetes and is yet to show benefit. Machine learning techniques for hypoglycaemia prevention have so far failed to demonstrate sufficient prediction accuracy for real world use even in those with diabetes. Furthermore, access to CGM globally is restricted by costs kept high by the commercially-driven speed of technical innovation. Nonetheless, the ability of CGM to digitally phenotype disease groups has led to a better understanding of natural history of disease, facilitated diagnoses and informed changes in clinical management. Large CGM datasets have prompted re-evaluation of hypoglycaemia incidence and facilitated improved trial design. Importantly, an individualised approach and focus on the behavioural determinants of hypoglycaemia has led to real world reduction in hypoglycaemia. In this state of the art review, we critically analyse the updated evidence for use of CGM in non-diabetic childhood hypoglycaemia disorders since 2020 and provide suggestions for qualified use.

Early Postnatal Use of Glibenclamide in Permanent Neonatal Diabetes Secondary to Antenatally Diagnosed KJCN11 Mutation.

INTRODUCTION: Heterozygous activating mutations in KCNJ11 cause both permanent and transient neonatal diabetes. A minority of patients also have neurological features. Early genetic diagnosis has important therapeutic implications as treatment with sulfonylurea provides good metabolic control and exerts a protective effect on neuromuscular function. CASE PRESENTATION: A term female infant with normal birth weight (2.73 kg, z-score: -1.69) was admitted to the Neonatal Unit at Addenbrookes Hospital. She had been antenatally diagnosed with KCNJ11 mutation-R201C inherited from her glibenclamide-treated mother who continued sulfonylurea treatment throughout pregnancy. A continuous glucose-monitoring system inserted at 20 h of age showed progressive rise of blood glucose concentrations, prompting treatment with glibenclamide on day 2 of life. Initial attempts to treat with an extemporaneous solution of glibenclamide (starting dose 0.2 mg/kg/day) resulted in inconsistent response and significant hypoglycaemia and hyperglycaemia. A licenced liquid formulation of glibenclamide (AMGLIDIA) at a starting dose of 0.05 mg/kg/day was used with stabilization of blood glucose profile within 24 h. Other than a mild transient elevation in transaminase, treatment was well tolerated. At most recent review (age 12 months), the patient remains well with age-appropriate neurodevelopment. Overall glucose control is reasonable with estimated HbA1c of 7.6% (59.9 mmol/mol). CONCLUSION: Early postnatal glibenclamide treatment of insulin-naive patients with KATP-dependent neonatal diabetes is safe, provides good metabolic control, and has a potential protective effect on neurological function. The formulation of the medicine needs to be carefully considered in the context of the very small doses required in this age group.