Successful pregnancy in a woman with glycogen storage disease type III

Endocrine involvement in hepatic glycogen storage diseases: pathophysiology and implications for care

Hepatic glycogen storage diseases constitute a group of disorders due to defects in the enzymes and transporters involved in glycogen breakdown and synthesis in the liver. Although hypoglycemia and hepatomegaly are the primary manifestations of (most of) hepatic GSDs, involvement of the endocrine system has been reported at multiple levels in individuals with hepatic GSDs. While some endocrine abnormalities (e.g., hypothalamic‑pituitary axis dysfunction in GSD I) can be direct consequence of the genetic defect itself, others (e.g., osteopenia in GSD Ib, insulin-resistance in GSD I and GSD III) may be triggered by the (dietary/medical) treatment. Being aware of the endocrine abnormalities occurring in hepatic GSDs is essential (1) to provide optimized medical care to this group of individuals and (2) to drive research aiming at understanding the disease pathophysiology. In this review, a thorough description of the endocrine manifestations in individuals with hepatic GSDs is presented, including pathophysiological and clinical implications.

Glycogen storage disease type IIIa in pregnant women: A guide to management

Glycogen storage disease type IIIa (GSD-IIIa) is an autosomal recessive disorder that impairs glycogenolysis, producing ketotic hypoglycaemia, hepatomegaly, cardiac and skeletal myopathy. During pregnancy, increased metabolic demand requires careful management. There are few case reports about pregnancy in GSD-IIIa, however none detail management during caesarean section. This case describes a 25-year-old women with GSD-IIIa diagnosed at 5 months of age. She had modest metabolic control with complications including hepatomegaly, mild skeletal myopathy and poor enteral function requiring multiple operative interventions. She had a planned pregnancy managed by a multidisciplinary team, which included a metabolic geneticist, maternal-fetal medicine specialist and metabolic dietitian. Nocturnal cornstarch was provided to meet basal carbohydrate requirements and a high protein diet with regular carbohydrates was consumed throughout the day. The woman remained well during the antenatal period and had an induction of labour at 38 weeks gestation. She had an emergency caesarean section in early labour due to an abnormal cardiotocography (CTG). The intraoperative and postoperative period were uncomplicated. A live baby boy was born in good condition, weighing 2440 g with APGARs of 9 and 9 at 1 and 5 min. She was managed in labour with glucose 10% IV at 3.5 mg/kg/min, hourly blood sugar level (BSL) monitoring and early epidural anaesthetic. The aim of the first 24-h post-partum was prevention of hypoglycaemia, which required strict management with dextrose 10% IV at 3.5 mg/kg/min, oral carbohydrate supplementation and BSL monitoring. This case highlights the complexity of GSD-IIIa as well as provides a proposed plan for management during pregnancy.

Pregnancy and myopathies: Reciprocal impacts between pregnancy, delivery, and myopathies and their treatments. A clinical review

During pregnancy, women undergo physical and physiological changes, which can impact the neuromuscular disease course, but also delivery and fetus health. Generally, there is little impact on the disease course, but sometimes an impairment is noticed, which could be attributed to pregnancy and not to disease progression. Cardiac and respiratory functions have to be assessed at the beginning of pregnancy and a close follow-up is mandatory in case of disorder. Labour and delivery are often impacted. Labour is prolonged because of muscle weakness that is an increased risk of instrumental delivery or Cesarean sections. Patients with myotonic dystrophy are at risk of postpartum hemorrhage. Fetal loss can be associated with fetal disease in myotonic dystrophy, and is at high risk for patients with active inflammatory myopathy only.

Dietary management in glycogen storage disease type III: what is the evidence?

In childhood, GSD type III causes relatively severe fasting intolerance, classically associated with ketotic hypoglycaemia. During follow up, history of (documented) hypoglycaemia, clinical parameters (growth, liver size, motor development, neuromuscular parameters), laboratory parameters (glucose, lactate, ALAT, cholesterol, triglycerides, creatine kinase and ketones) and cardiac parameters all need to be integrated in order to titrate dietary management, for which age-dependent requirements need to be taken into account. Evidence from case studies and small cohort studies in both children and adults with GSD III demonstrate that prevention of hypoglycaemia and maintenance of euglycemia is not sufficient to prevent complications. Moreover, over-treatment with carbohydrates may even be harmful. The ageing cohort of GSD III patients, including the non-traditional clinical presentations in adulthood, raises ‬‬‬new questions.

Mouse model of glycogen storage disease type III

Glycogen storage disease type IIIa (GSD IIIa) is caused by a deficiency of the glycogen debranching enzyme (GDE), which is encoded by the Agl gene. GDE deficiency leads to the pathogenic accumulation of phosphorylase limit dextrin (PLD), an abnormal glycogen, in the liver, heart, and skeletal muscle. To further investigate the pathological mechanisms behind this disease and develop novel therapies to treat this disease, we generated a GDE-deficient mouse model by removing exons after exon 5 in the Agl gene. GDE reduction was confirmed by western blot and enzymatic activity assay. Histology revealed massive glycogen accumulation in the liver, muscle, and heart of the homozygous affected mice. Interestingly, we did not find any differences in the general appearance, growth rate, and life span between the wild-type, heterozygous, and homozygous affected mice with ad libitum feeding, except reduced motor activity after 50 weeks of age, and muscle weakness in both the forelimb and hind legs of homozygous affected mice by using the grip strength test at 62 weeks of age. However, repeated fasting resulted in decreased survival of the knockout mice. Hepatomegaly and progressive liver fibrosis were also found in the homozygous affected mice. Blood chemistry revealed that alanine transaminase (ALT), aspartate transaminase (AST) and alkaline phosphatase (ALP) activities were significantly higher in the homozygous affected mice than in both wild-type and heterozygous mice and the activity of these enzymes further increased with fasting. Creatine phosphokinase (CPK) activity was normal in young and adult homozygous affected mice. However, the activity was significantly elevated after fasting. Hypoglycemia appeared only at a young age (3 weeks) and hyperlipidemia was not observed in our model. In conclusion, with the exception of normal lipidemia, these mice recapitulate human GSD IIIa; moreover, we found that repeated fasting was detrimental to these mice. This mouse model will be useful for future investigation regarding the pathophysiology and treatment strategy of human GSD III.

Pregnancy and its management in women with GSD type III - a single centre experience

We present a review of our experience and pregnancy outcome in patients with GSD III managed by our centre. Between 1997 and 2010 there were 15 pregnancies in seven women with GSD III. Four women had GSD IIIb (nine pregnancies) and three GSD IIIa (six pregnancies). There was a successful outcome in all 15 pregnancies with delivery of 15 liveborn infants. Four infants were of low birthweight (<2nd centile) but all have developed normally apart from one with behavioural/psychiatric problems. Three women had pre-existing cardiomyopathy prior to pregnancy. One of these women had deterioration of her cardiomyopathy during pregnancy and again in the post-partum period. Women with GSD III do not seem to have any issues with fertility. Overall the outcome of pregnancy for both mother and child is good. Care needs to be taken to avoid maternal hypoglycemia which may be associated with intrauterine growth restriction and low birth weight. Cardiac function should be monitored carefully particularly in those with pre-existing cardiomyopathy.

Multidisciplinary management of an obstetric patient with glycogen storage disease type 3

A 22-year-old primiparous woman with known glycogen storage disease type 3a presented to our hospital during her 12th week of pregnancy. Glycogen storage disease type 3 is a rare inherited disorder resulting from a deficiency of the glycogen debranching enzyme, causing the accumulation of abnormal short-chain glycogen in liver, blood cells, myocardium and striated muscle. Symptoms improve after puberty but the increased metabolism of pregnancy predisposes to hypoglycaemia, ketosis and lactic acidosis. Cardiomyopathy, distal weakness and peripheral neuropathy may present after the third decade. The patient was managed antenatally with regular cornflour feeds and was scheduled for elective caesarean delivery. She presented in early labour at 38 weeks and delivered a healthy neonate by urgent caesarean delivery under spinal anaesthesia. Intravenous dextrose infusion and regular blood glucose monitoring were used during the perinatal period to prevent hypoglycaemia. An arterial line was inserted in the operating room for frequent blood sampling and to avoid muscle cramps which could be induced by the intermittent inflation of the automated blood pressure cuff. Obstetric, anaesthetic and neonatal outcomes were uneventful.

Pregnancy in glycogen storage disease type Ib: gestational care and report of first successful deliveries

Patients with type Ia glycogen storage disease (GSD) have been surviving well into adulthood since continuous glucose therapy was introduced in the 1970s, and there have been many documented successful pregnancies in women with this condition. Historically, few individuals with type Ib GSD, however, survived into adulthood prior to the introduction of granulocyte colony stimulating factor (G-CSF) in the late 1980s. There are no previously published reports of pregnancies in GSD type Ib. In this case report we describe the course and management of five successful pregnancies in three patients with GSD type Ib. Patient 1 experienced an increase in glucose requirement in all three of her pregnancies, starting from the second trimester onwards. There were no major complications related to neutropenia except for oral ulcers. The infants did well, except for respiratory distress in two of them at birth. Patient 2 used cornstarch to maintain euglycemia, but precise dosing was not part of her regimen, and, hence, an increase in metabolic demands was difficult to demonstrate. She developed a renal calculus and urinary tract infection during her pregnancy and had chronic iron deficiency anemia but no neutropenia. The neonate did well after delivery. Patient 3 had poor follow-up during pregnancy. Increasing glucose requirements, worsening lipid profile, neutropenia associated with multiple infections, and anemia were noted. The newborn infant did well after delivery. In addition to the case reports, the challenges of the usage of G-CSF, the treatment of enterocolitis, and comparisons with the management of GSD Ia are discussed.