Celebration of a century of insulin therapy in children with type 1 diabetes.

Insulin is the key anabolic hormone of metabolism, with clear effects on glycaemia. Near-complete insulin deficiency occurs in type 1 diabetes (T1D), the predominant form affecting children, and uniformly fatal until the discovery of insulin. By the early 20th century, it was known that T1D was caused by the lack of a factor from pancreatic islets, but isolation of this substance proved elusive. In 1921, an unusual team in Toronto comprising a surgeon, a medical student, a physiologist and a biochemist successfully isolated a glucose-lowering pancreatic endocrine secretion. They treated an emaciated 14-year-old boy in 1922, restoring his health and allowing him to live for another 13 years. Thus began an era of remarkable progress and partnership between academia and the pharmaceutical industry to produce drugs that benefit sick people. The Toronto team received the 1923 Nobel Prize, and more Nobel Prizes for work with insulin followed: for elucidation of its amino acid sequence and crystalline structure, and for its role in the development of radioimmunoassays to measure circulating hormone concentrations. Human insulin was the first hormone synthesised by recombinant methods, permitting modifications to enable improved absorption rates and alterations in duration of action. Coupled with delivery via insulin pens, programmable pumps and continuous glucose monitors, metabolic control and quality of life vastly improved and T1D in children was converted from uniformly fatal to a manageable chronic condition. We describe this remarkable ongoing story as insulin remains a paradigm for human ingenuity to heal nature's maladies.

A centennial review of discoveries and advances in diabetes: Children and youth.

Diabetes is an increasingly common chronic metabolic disorder in children worldwide. The discovery of insulin in 1921 resulted in unprecedented advancements that improved the lives of children and youth with diabetes. The purpose of this article is to review the history of diabetes in children and youth over the last century and its implications for future developments in the field. We identified 68 relevant events between 1921 and 2021 through literature review and survey of pediatric endocrinologists. Basic research milestones led to the discovery of insulin and other regulatory hormones, established the normal physiology of carbohydrate metabolism and pathophysiology of diabetes, and provided insight into strategies for diabetes prevention. While landmark clinical studies were initially focused on adult diabetes populations, later studies assessed etiologic factors in birth cohort studies, evaluated technology use among children with diabetes, and investigated pharmacologic management of youth type 2 diabetes. Technological innovations culminated in the introduction of continuous glucose monitoring that enabled semi-automated insulin delivery systems. Finally, professional organizations collaborated with patient groups to advocate for the needs of children with diabetes and their families. Together, these advances transformed type 1 diabetes from a terminal illness to a manageable disease with near-normal life expectancy and increased our knowledge of type 2 diabetes and other forms of diabetes in the pediatric population. However, disparities in access to insulin, diabetes technology, education, and care support remain and disproportionately impact minority youth and communities with less resources. The overarching goal of diabetes management remains promoting a high quality of life and improving glycemic management without undermining the psychological health of children and youth living with diabetes.

Neonatal hyperinsulinism in transient and classical forms of tyrosinemia.

BACKGROUND: The spectrum of disorders associated with hyperinsulinemic hypoglycemia (HHI) has vastly increased over the past 20 years with identification of molecular, metabolic and cellular pathways involved in the regulation of insulin secretion and its actions. Hereditary tyrosinemia (HT1) is a rare metabolic disorder associated with accumulation of toxic metabolites of the tyrosine pathway due to a genetically mediated enzyme defect of fumarylacetoacetate hydrolase. Transient tyrosinemia of the newborn (TTN) is a benign condition with a maturational defect of the enzymes associated with tyrosine metabolism without any genetic abnormalities. RESULTS: We describe two rare cases of HHI, one in a patient with HT1 and for the first time, in a patient with TTN. Each of our patients presented in the neonatal period with persistent hypoglycemia that on biochemical evaluation was consistent with HHI. Each patient received diazoxide therapy for 3.5 months and 17 months of life, respectively and HHI resolved thereafter. CONCLUSION: Despite the fact that HHI has been described in HT1 for several decades, no specific mechanism has been delineated. Although we considered the common embryonal origin of the liver and pancreas with the hepatotoxic effect in HT1 also impacting the latter, this was not a possible explanation for TTN. The commonality between our two patients is the accumulation of certain amino acids which are known to be insulinotropic. We therefore hypothesize that the excess of amino acids such as leucine, lysine, valine and isoleucine in our patients resulted in HHI, which was transient. Both patients responded to diazoxide. This novel presentation in TTN and the reassuring response in both HT1 and TTN to diazoxide will be useful to inform physicians about managing HHI in these patients. Further studies are required to delineate the mechanism of HHI in these infants.

Traditional and novel aspects of the metabolic actions of growth hormone.

Growth hormone has been known to be diabetogenic for almost a century and it's diabetogenic properties fostered consideration of excessive and abnormal GH secretion as a cause of diabetes, as well as a role in the microvascular complications, especially retinopathy. However, besides inducing insulin resistance, GH also is lipolytic and a major anabolic hormone for nitrogen retention and protein synthesis. These actions are best illustrated at the extremes of GH secretion: Gigantism/acromegaly is characterized by excessive growth, CHO intolerance, hyperplasia of bone, little body fat and prominent muscle development, whereas total deficiency of GH secretion or action is associated with adiposity, poor growth, and poor muscle development. These actions also become apparent during puberty and pregnancy, times when GH secretion is increased and account for the characteristic changes in body composition and tendency to diabetes. More recently, tissue specific deletions of the GH receptor (GHR), have uncovered newer metabolic effects including it's essential role in triglyceride export from the liver when GHR is deleted in the liver, leading to hepatic steatosis and ultimately to hepatic adenoma formation, effects which may explain these findings in obesity, a state of diminished GH secretion and action. In addition deletion of GH action in muscle and fat is associated with specific patterns of disturbed phenotype and metabolic effects in CHO, fat, and protein metabolism affecting the specific tissue and whole body function. This chapter provides an overview of these classic and newer metabolic functions of GH, placing this hormone and its actions in a central role of body fuel economy in health and disease.

Recombinant human growth hormone plus recombinant human insulin-like growth factor-1 coadministration therapy in short children with low insulin-like growth factor-1 and growth hormone sufficiency: results from a randomized, multicenter, open-label, parallel-group, active treatment-controlled trial.

BACKGROUND/AIMS: Growth hormone (GH) and insulin-like growth factor-1 (IGF-1) both contribute to growth. To determine if recombinant human (rh)GH + rhIGF-1 therapy is more effective than rhGH alone to treat short stature, we assessed the efficacy and safety of coadministered rhGH + rhIGF-1 in short children with GH sufficiency and low IGF-1. METHODS: In a 3-year, randomized, multicenter, open-label trial, patients with height SD score ≤-2.0 and IGF-1 SD score ≤-1.0 for age and sex, and with stimulated GH ≥10 ng/ml for age and sex, were randomized to receive (all doses in µg/kg/day): 45 rhGH alone (group A), 45 rhGH + 50 rhIGF-1 (group B), 45 rhGH + 100 rhIGF-1 (group C) or 45 rhGH + 150 rhIGF-1 (group D). Height velocity (HV) and Δ height SD score were measured. RESULTS: The first-year HV (modified intention-to-treat population) was 9.3 ± 1.7 cm/year (group A), 10.1 ± 1.3 cm/year (group B), 9.7 ± 2.5 cm/year (group C) and 11.2 ± 2.1 cm/year (group D) (p = 0.001 for groups A vs. D). This effect was sustained, resulting in a height SD score improvement during the second and third years. Most treatment-emergent adverse events were mild and transient. CONCLUSION: In children with short stature, GH sufficiency and low IGF-1, coadministration of rhGH/rhIGF-1 (45/150 µg/kg) significantly accelerated linear growth compared with rhGH alone, with a safety profile similar to the individual monotherapies.

Evolution of hepatic steatosis to fibrosis and adenoma formation in liver-specific growth hormone receptor knockout mice.

BACKGROUND: Non-alcoholic fatty liver disease (NAFLD) is one of the most common forms of chronic liver diseases closely associated with obesity and insulin resistance; deficient growth hormone (GH) action in liver has been implicated as a mechanism. Here, we investigated the evolution of NAFLD in aged mice with liver-specific GHR deletion. METHODS: We examined glucose tolerance, insulin responsiveness, and lipid profiles in aged male mice (44-50 weeks) with GHRLD. We performed proteomics analysis, pathway-based Superarray assay, as well as quantitative RT-PCR to gain molecular insight into the mechanism(s) of GHR-deficiency-mediated NAFLD. In addition, we examined the pathological changes of livers of aged GHRLD male mice. RESULTS: The biochemical profile was consistent with that of the metabolic syndrome: abnormal glucose tolerance, impaired insulin secretion, and hyperlipidemia. RT-qPCR analysis of key markers of inflammation revealed a three- to fivefold increase in TNFα and CCL3, confirming the presence of inflammation. Expression of fibrotic markers (e.g., Col1A2 and Col3A1) was significantly increased, together with a two- to threefold increase in TGFß transcripts. Proteomics analyses showed a marked decrease of Mup1 and Selenbp2. In addition, pathway-analysis showed that the expression of cell cycle and growth relevant genes (i.e., Ccnd1, Socs2, Socs3, and Egfr) were markedly affected in GHRLD liver. Microscopic analyses (H&E) of GHRLD livers revealed the presence of hepatic adenomas of different stages of malignancy. CONCLUSION: Abrogation of GH signaling in male liver leads to metabolic syndrome, hepatic steatosis, increased inflammation and fibrosis, and development of hepatic tumor. Since obesity, a common precursor of NAFLD, is a state of deficient GH secretion and action, the GHRLD model could be used to unravel the contribution of compromised hepatic GH signaling in these pathological processes, and help to identify potential targets for intervention.

Clinical review: Diabetes in the adolescent: transitional issues.

CONTENT: Orchestrating a seamless transition from pediatric to adult care can be a daunting task in caring for youth with diabetes mellitus. This clinical review focuses on physical and psychosocial aspects affecting the care of adolescents and young adults with diabetes, evaluates how these aspects can be barriers in the process of transitioning these patients to adult diabetes care, and provides clinical approaches to optimizing the transition process in order to improve diabetes care and outcomes. EVIDENCE ACQUISITION AND SYNTHESIS: A PubMed search identified articles related to transition to adult diabetes care and physical and psychosocial assessment of adolescents with diabetes. An Internet search for transition of diabetes care identified online transition resources. The synthesis relied on the cumulative experience of the authors. We identify barriers to successful transition and provide a checklist for streamlining the process. CONCLUSIONS: Key points in the transition to adult diabetes care include: 1) starting the process at least 1 year before the anticipated transition; 2) assessing individual patients' readiness and preparedness for adult care; 3) providing guidance and education to the patient and family; 4) utilizing transition guides and resources; and 5) maintaining open lines of communication between the pediatric and adult providers. No current single approach is effective for all patients. Challenges remain in successful transition to avoid short- and long-term complications of diabetes mellitus.