Update on investigating hypoglycaemia in childhood

Hypoglycemia in a Pediatric Emergency Department: Single-Center Experience on 402 Children

OBJECTIVES

This study aimed to establish the rate, etiology, and short-term outcome of hypoglycemia in infants and children accessing an emergency department of a tertiary care pediatric hospital.

METHODS

The study was retrospectively conducted on the clinical records of children with hypoglycemia aged 15 days to 17 years who were admitted consecutively to the emergency department during a 6-year period for various clinical conditions. Hypoglycemia was defined as a venous plasma glucose level lower than 45 mg/dL.

RESULTS

Hypoglycemia was detected in 402 patients (female-to-male ratio, 1.26; mean age, 2.6 ± 1.8 years), with a rate of 0.99 per 1000 children. Plasma glucose levels ranged from 3 to 45 (mean, 37.48 ± 7.44) mg/dL. Hypoglycemia was associated with gastroenteritis or other infectious diseases causing protracted fasting in 86.32% of cases, whereas hypoglycemia related to a different etiology (HDE) was observed in 13.68% of hypoglycemic children. Most HDE patients had a final diagnosis of ketotic hypoglycemia, whereas metabolic defects were a rare (1.49%) but nonnegligible etiologic cause. A severe triage code was more frequent in the HDE group (P < 0.001). Factors significantly and independently associated with HDE were impaired level of consciousness, assessed with the AVPU scale (A, alert; V, responding to verbal; P, responding to pain; U, unresponsive; adjusted odds ratio, 2.50; P = 0.025) and clinical onset within 12 hours (adjusted odds ratio, 3.98; P < 0.001).

CONCLUSIONS

In a nonnegligible number of critically ill children, hypoglycemia can be detected. In a minority of cases, hypoglycemia was due to metabolic disorders that should be suspected on the basis of the severity of hypoglycemia, and the recent onset and the presence of neuroglycopenic symptoms.

Exome sequencing revealed DNA variants in NCOR1, IGF2BP1, SGLT2 and NEK11 as potential novel causes of ketotic hypoglycemia in children

Unexplained or idiopathic ketotic hypoglycemia (KH) is the most common type of hypoglycemia in children. The diagnosis is based on the exclusion of routine hormonal and metabolic causes of hypoglycemia. We aimed to identify novel genes that cause KH, as this may lead to a more targeted treatment. Deep phenotyping of ten preschool age at onset KH patients (boys, n = 5; girls, n = 5) was performed followed by trio exome sequencing and comprehensive bioinformatics analysis. Data analysis revealed four novel candidate genes: (1) NCOR1 in a patient with KH, iron deficiency and loose stools; (2) IGF2BP1 in a proband with KH, short stature and delayed bone age; (3) SLC5A2 in a proband with KH, intermittent glucosuria and extremely elevated p-GLP-1; and (4) NEK11 in a proband with ketotic hypoglycemia and liver affliction. These genes are associated with different metabolic processes, such as gluconeogenesis, translational regulation, and glucose transport. In conclusion, WES identified DNA variants in four different genes as potential novel causes of IKH, suggesting that IKH is a heterogeneous disorder that can be split into several novel diseases: NCOR1-KH, IGF2BP1-KH, SGLT2-KH or familial renal glucosuria KH, and NEK11-KH. Precision medicine treatment based on exome sequencing may lead to advances in the management of IKH.

Changes in pediatric plasma acylcarnitines upon fasting for refined interpretation of metabolic stress

BACKGROUND

Childhood fasting intolerance is a life-threatening problem associated with various inborn errors of metabolism. Plasma acylcarnitines reflect fatty acid oxidation and help determine fasting intolerance etiology. Pediatric reference values of plasma acylcarnitines upon fasting are not available, complicating interpretation of stress samples.

METHODS

Retrospective analysis of supervised clinical fasting studies between 01/2005-09/2012. Exclusion criteria involved patients with (suspected) disorders, repeated tests or incomplete results. Remaining children were grouped according to age: group A (≤24 months), B (25-84 months) and C (≥85 months). Median and 2.5^th to 97.5^th percentiles of basic metabolic parameters and acylcarnitines were determined at start and end of testing on the ward and analyzed for significant differences (p<0.05).

RESULTS

Out of 127 fasting studies, 48 were included: group A (n=13), B (n=23) and C (n=12). Hypoglycemia occurred in 21%. Children from group C demonstrated significantly higher end glucose concentrations while end ketone body concentrations were significantly lower compared to younger children. In all groups, free carnitine and C3-carnitine significantly decreased upon fasting, while C2-, C6-, C12:1-, C12-, C14:1-, C14-, C16:1- and C16-carnitine significantly increased. End concentrations of C6-, C12:1-, C12-, C14:1-, C14-, C16:1-, C16- and C18:1-carnitine were significantly lower in children ≥85 months compared to younger children.

CONCLUSIONS

Fasting-induced counter-regulatory mechanisms to maintain energy homeostasis are age-dependent. This influences the changes in basic metabolic parameters and acylcarnitine profiles. Our data enable improved interpretation of the individual fasting response and may support assessment of minimal safe fasting times or treatment responses in patients.

Dysregulated glucose homeostasis in congenital central hypoventilation syndrome

Background Congenital central hypoventilation syndrome (CCHS) is a rare disorder of autonomic control. A hypoglycaemic seizure in a 4-year-old girl with CCHS led to a more detailed examination of glycaemic control in a cohort of children with CCHS. Methods We conducted an observational cohort study of glucose homeostasis in seven children (3 months to 12 years) with genetically confirmed CCHS using a combination of continuous glucose monitoring (CGM), fasting studies and oral glucose tolerance test (OGTT). CGM was used to compare the effect of diazoxide and dietary intervention in the index patient. Results Hypoglycaemia was not elicited by fasting in any of the patients. Increased postprandial glycaemic variability was evident in all patients using CGM, with seven of seven patients demonstrating initial postprandial hyperglycaemia (plasma-glucose concentration >7.8 mmol/L), followed by asymptomatic hypoglycaemia (plasma-glucose concentration ≤2.8 mmol/L) in two of seven patients that was also demonstrated on OGTT. Both diazoxide and low Glycaemic Index (GI) dietary intervention reduced the proportion of CGM readings <4 mmol/L; however, diazoxide also increased the proportion of readings in the hyperglycaemic range. Conclusions Glucose variability associated with autonomic dysfunction may be unrecognised in CCHS, particularly in children with more severe phenotypes. This report highlights the occurrence of hyperglycaemia as well as hypoglycaemia in CCHS. Given the challenges of recognising hypoglycaemia based on clinical symptomatology, the use of CGM may facilitate its identification allowing appropriate management. The observed normoglycaemia during fasting combined with increased postprandial plasma blood glucose level (BGL) variability is more consistent with dumping syndrome than persistent hyperinsulinism. Dietary modifications therefore may be more effective than diazoxide in managing hypoglycaemia.

Safety of d-ribose as a novel food pursuant to Regulation (EU) 2015/2283

Following a request from the European Commission, the EFSA Panel on Dietetic Products, Nutrition and Allergies (NDA) was asked to deliver an opinion on D-ribose as a novel food (NF) pursuant to Regulation (EU) 2015/2283. The applicant intends to market the NF as ingredient in a variety of foods, food supplements and in certain foods for specific groups. The NF is produced by fermentation using a transketolase-deficient strain of Bacillus subtilis and marketed as Bioenergy Ribose™. The information provided on the batch-to-batch variability, specifications, stability, production process and history of the organism used as a source of the NF is sufficient and does not raise safety concerns. The Panel considers that the effects observed in a subchronic toxicity study in rats could be the consequence of nutritional imbalances, but toxicological effects could not be ruled out; from this study, the Panel derived a No observed adverse effect level (NOAEL) of 3.6 g/kg body weight (bw) per day. From the human studies indicating a potential decrease in glucose levels and/or the occurrence of transient symptomatic hypoglycaemia at intakes of 10 g of d-ribose, the Panel defined 70 mg/kg bw per day as the NOAEL with respect to hypoglycaemia that can be considered applicable for adults. For children, the Panel acknowledges the lack of human data directly relevant for this population group. Based on the NOAEL derived from the subchronic toxicity study in rats, an acceptable level of intake of 36 mg/kg bw per day was defined that would also take into account the potentially increased sensitivity of certain population groups to hypoglycaemia. The Panel concludes that the NF is safe for the general population at intake levels up to 36 mg/kg bw per day and considers that the safety of the NF at the intended uses and use levels as proposed by the applicant has not been established.

Endocrine check-up in adolescents and indications for referral: A guide for health care providers

The American Academy of Pediatrics recommends that young people between the ages of 11 and 21 years should be seen annually by their pediatricians, since annual checkups can be an important opportunity for health evaluation and anticipatory guidance. Parents of infants and young children are accustomed to regularly visiting a pediatrician for their child's checkups. Unfortunately, when children reach the teen years, these annual checkups may decrease in frequency. In routine check-ups and medical office visits, particular attention should be paid to the possibility of a developmental or endocrine disorder. Early diagnosis and treatment may prevent medical complications in adulthood and foster age-appropriate development. Our purpose is to acquaint readers with the concept, based on current scientific understanding, that some endocrine disorders may be associated with a wide range of deleterious health consequences including an increased risk of hypertension and hyperlipidemia, increased risk of coronary artery disease, type 2 diabetes, significant anxiety and lack of self-esteem. Understanding the milestones and developmental stages of adolescence is essential for pediatricians and all other health providers who care for adolescents. Treating adolescents involves knowledge of a variety of medical, social and legal information; in addition, close working relationships must be established within the adolescent's network to create an effective care system. In summary, we underline the importance of a periodic endocrine checkup in adolescents in order to identify endocrine problems early and develop an approach to treatment for those patients who need help during this time. Indications for endocrine referral for professional and other healthcare providers are also included. These lists are clearly not intended to be comprehensive, but will hopefully serve as a guide for specific clinical circumstances.

Pediatric hypoglycemia

Hypoglycemia in the pediatric population is a common finding important to recognize and manage to prevent brain injury. Recent advances in molecular genetics have provided new insight into its biochemical and physiologic basis and have led to more appropriate and specific treatment. Although a major cause of brain injury in pediatrics, the ability to predict the long-term outcome in these patients remains difficult. Identification of these at-risk individuals is important. The physiologic adaptations associated with transition from fetal to neonatal life are now better understood thus allowing for improved surveillance and management. Despite these advances, analytical limitations of point-of-care testing instruments at low glucose concentration continue to persist, This review aims to address these questions and provide an overview of pediatric hypoglycemia and the molecular pathways involved.

Neonatal hypoglycemia

Glucose is essential for cerebral metabolism. Unsurprisingly therefore, hypoglycemia may result in encephalopathy. Knowledge of the homeostatic mechanisms that maintain blood glucose concentrations within a tight range is the key for diagnosis and appropriate management of hypoglycemia. Neonatal hypoglycemia can be transient and is commonly observed in at-risk infants. A wide range of rare endocrine and metabolic disorders can present with neonatal hypoglycemia, of which congenital hyperinsulinism is responsible for the most severe form of hypoglycemia. Collection of appropriate blood samples for hormones and intermediary metabolites during an episode of hypoglycemia is critical for diagnosis and appropriate management. Prompt diagnosis with aggressive early intervention remains the mainstay of treatment to avert irreversible brain damage.

The molecular mechanisms, diagnosis and management of congenital hyperinsulinism

Congenital hyperinsulinism (CHI) is the result of unregulated insulin secretion from the pancreatic β-cells leading to severe hypoglycaemia. In these patients it is important to make an accurate diagnosis and initiate the appropriate management so as to avoid hypoglycemic episodes and prevent the potentially associated complications like epilepsy, neurological impairment and cerebral palsy. At a genetic level abnormalities in eight different genes (ABCC8, KCNJ11, GLUD1, GCK, HADH, SLC16A1, HNF4A and UCP2) have been reported with CHI. Loss of function mutations in ABCC8/KCNJ11 lead to the most severe forms of CHI which are usually medically unresponsive. At a histological level there are two major subgroups, diffuse and focal, each with a different genetic etiology. The focal form is sporadic in inheritance and is localized to a small region of the pancreas whereas the diffuse form is inherited in an autosomal recessive (or dominant) manner. Imaging using a specialized positron emission tomography scan with the isotope fluroine-18 L-3, 4-dihydroxyphenyalanine (18F-DOPA-PET-CT) is used to accurately locate the focal lesion pre-operatively and if removed can cure the patient from hypoglycemia. Understanding the molecular mechanisms, the histological basis, improvements in imaging modalities and surgical techniques have all improved the management of patients with CHI.

Intermittent hyperglycemia due to autonomic nervous system dysfunction: a new feature in patients with congenital central hypoventilation syndrome

OBJECTIVE

To analyze glycemic profile in children with congenital central hypoventilation syndrome, which is characterized by autonomic nervous system dysfunction.

STUDY DESIGN

We carried out a university hospital-based observational study. Participants included 14 patients assessed from 2007 to 2009 with a median age of 7.6 (25th-75th percentiles, 1.5-9.6) years at the time of the study. Glucose metabolism was assessed by calculating 24-hour plasma glucose (before and after meals) and fasting insulin concentrations and carrying out an oral glucose tolerance test (OGTT). The main outcome measure was the proportion of patients with abnormal glucose concentrations.

RESULTS

Abnormal plasma glucose concentrations were found in 6 (43%) of the 14 patients with high fasting (n = 1) or postprandial (n = 5) hyperglycemia. OGTT was performed in 8 patients, of whom 3 (38%) had impaired glucose tolerance. Indices of insulin resistance and secretion were normal. No difference in clinical aspects relating to the presence of affected organs and/or systems related to central nervous system dysfunction, age, or auxology findings was found between patients with normal (43%) and abnormal (57%) glucose homeostasis over a 24-hour glycemia cycle or OGTT.

CONCLUSION

This study provides new information about glucose homeostasis in congenital central hypoventilation syndrome, revealing a high incidence of hyperglycemia and expanding the spectrum of the disease. It highlights the link between autonomic nervous system dysfunction and glycemic dysregulation. Regular, long-term monitoring of glucose metabolism is recommended in these patients.