Wyniki neonatologiczne i przebieg cukrzycy u dzieci z GCK-MODY urodzonych przez kobiety z rozpoznaną cukrzycą GCK-MODY

Introduction

Gestational diabetes is one of the most common medical disorders and may cause numerous maternal and foetal complications [1]. It constitutes one of the most frequent pregnancy health problems next to hypertension, anaemia, proteinuria, and urinary tract infections. Therefore, early gestational diabetes detection and implementation of guideline-based screening tests prepared by experts are crucial. Risk factors for gestational diabetes include: maternal age over 35 years, polycystic ovary syndrome, history of macrosomia or congeni-tal malformations in newborns in a previous pregnancy, hypertension, overweight, previous pregnancy loss, family history of diabetes mellitus type 2, gestational diabetes in previous pregnancies, and pluriparity. Current epidemiological data concerning the prevalence of gestational diabetes in study populations is ambiguous. The incidence rate of gestational diabetes is estimated at about 3-20% of preg-nancies [1, 2].
The first described form of maturity-onset diabetes of the young (MODY) was MODY-2. The disorder is caused by mutations in the glucokinase (GCK) gene on chromosome 7. As a result, it leads to pancreatic beta cells dysfunction. The first mutation of GCK gene was detected in 1992 [3]. The clinical presentation of diabetes caused by glucokinase mutations, is mild and fasting glucose levels are slightly elevated. The disorder is most commonly diagnosed before the age of 35 years. GCK gene mutations are inherited in an autosomal dominant way [4, 5].
Fasting hyperglycaemia along with much lower two-hour post-load glucose concentration in oral glucose tolerance test than would be expected from the impaired fasting glycaemia, is characteristic for GCK-MODY. Glycated haemoglobin level is mildly elevat-ed and ketoacidosis is rarely observed in this type of diabetes [6].
Usually, genetic testing in patients with gestational diabetes is not performed, thus this form of diabetes is frequently underes-timated. In most cases after labour, diabetes care is no longer provided to the patient and her newly born child.
Due to a complicated and expensive diagnostic procedure, there is a lack of objective population studies, thus the incidence rate of all of the types of monogenic diabetes is difficult to assess. However, probably 1% of patients under 25 years of age are affected with MODY. The prevalence of GCK-MODY in the general population is difficult to estimate as well, owing to the absence of significant symptoms and mild hyperglycaemia [2]. According to various publications, GCK-MODY is present in 20-50% of patients with genet-ically determined diabetes [7, 8]. In Great Britain the prevalence of MODY-2 is assessed at 20% [9].
Glucose is the main energy source for the foetus. Foetal glucose consumption is around 6 mg/min and is two times higher than in adults. Glucose crosses the placental barrier by diffusion, and its concentration in foetal blood is about 10-20 mg/dl lower than in pregnant women’s blood. Developmental defects are detected in 6-9% of gestational diabetes pregnancies and in 1-2% of pregnancies in the general population. It refers almost exclusively to pregestational diabetes. The increasing incidence rate of congenital defects due to gestational diabetes should be primarily linked with diabetes that existed prior to conception but was detected during pregnancy. Sacral agenesis is more frequently observed in infants of diabetic mothers than in the general population (the incidence rate is 200-600 times higher). The risk of cardiovascular defects is five times higher, and the risk of central nervous system malformations is 10 times higher. The incidence rate of congenital defects was decreased to 0.8% in patients with normoglycaemia during organogenesis, in comparison to 7.5% of women, whose diabetes was not managed properly during this crucial period of pregnancy [10, 11].
Metabolic changes in gestational diabetes can lead to retardation of foetal development. Between the seventh and fourteenth week of pregnancy foetuses of diabetic mothers are retarded in development by five days in comparison to foetuses of nondiabetic mothers. Therefore, it may be a cause of low birth weight in infants of diabetic mothers. In the group of patients with gestational diabe-tes, 10-30% are expected to give birth preterm. Preterm labours occur more frequently than in nondiabetic mothers. It should be noted that preterm births are associated with many neonatal complications, such as hypoxia, periventricular and intraventricular haemorrhage, respiratory distress syndrome, or infections.
The incidence rate of macrosomia in neonates of diabetic mothers (25-40%) is much higher than in the general population (8-14%). Macrosomia is usually observed in infants of mothers who have a short history of diabetes and were significantly overweight or those who already gave birth to an infant with birth weight over 4000 g. Hyperglycaemia during pregnancy is reported to be the major cause of macrosomia. Maternal hyperglycaemia causes foetal hyperglycaemia and hyperinsulinaemia, which in turn stimulates lipogene-sis and leads to adipose tissue development [12]. Macrosomic infants are born with birth weight between 4000 and 4500 g and are pre-disposed to birth injuries, especially those with undiagnosed macrosomia. A much less common complication of gestational diabetes is hypotrophy. Hypotrophy is defined as birth weight below the sex-specific 10th percentile for gestational age.
Intrauterine hypotrophy is observed among infants whose mothers have a long history of diabetes and suffer from vascular complications. Hypotrophic neonates have a higher incidence rate of perinatal shock, acute hypoxia, hypoglycaemia, hypocalcaemia, and polycythaemia [12].
Moreover, in the first hours of life, newborns of diabetic mothers are at risk of metabolic complications such as hypoglycaemia (25-50%), hypocalcaemia (10-50%), and hypomagnesaemia (30-75%). Aforementioned metabolic disorders may be manifested by symptoms of central nervous and cardiovascular systems, including drowsiness, apathy, anxiety, limb tremors, seizures, cyanosis, and apnoea, finally leading to circulatory failure and cardiac arrest [13].
Prolonged hypoglycaemia is a particularly important consideration because it may cause intracranial haemorrhage and cerebral cortex damage in a child [11, 12].
In addition, newborns of diabetic mothers, in comparison to newborns of healthy women, are at higher risk of hyperbilirubi-naemia. Another major complication, frequently encountered in neonates of diabetic patients (10-50%), is hypertrophic cardiomyopathy. The disorder may be asymptomatic or can be manifested by cardiac failure. Echocardiography reveals thickened septum and ventricular walls as well as left ventricular outflow tract obstruction. Usually, the condition is transient and echocardiographic dimensions normalise within the first year of life [12].

Aim of the study

The aim of the study was to assess the impact of diabetes during pregnancy in women affected with GCK-MODY on neonatal health outcome, and a trial to determine the clinical and biochemical characteristics of children delivered by women with GCK-MODY.

Material and methods

The study population included children who were under care in the Department of Paediatrics, Diabetology, and Endocrinology in Gdansk, the Department of Endocrinology and Diabetology of the Medical University of Silesia, the Department of Paediatrics, Endo-crinology, and Diabetology with the Cardiology Unit of the Medical University in Bialystok, and the Department of Paediatrics, Oncol-ogy, Haematology, and Diabetology of the Medical University in Lodz.
Patients diagnosed with GCK-MODY and subjects with a suspicion of genetically determined diabetes were enrolled in the study retrospectively and prospectively.
The risk of GCK-MODY was evaluated on the basis of the medical history of the patient, clinical course of the disease, and la-boratory tests performed during diagnostic procedures.
Diabetes was diagnosed according to Polish Diabetes Association criteria (PTD).
The study population included 50 children. Data concerning the course of pregnancy and mothers’ health status was collected.
Researchers gathered general information about patients’ sex, date of birth, age, and presented symptoms at time of diagnosis of diabetes. Data from family history included presence of type 1 and type 2 diabetes, gestational diabetes, monogenic diabetes, carbo-hydrate and lipid disorders, as well as reported vascular complications such as myocardial infarction or stroke. Perinatal data comprised method of delivery, birth weight and length, gestational week in which a child was born, Apgar in first and fifth minute of life, and oc-currence of hyperglycaemia or hypoglycaemia after birth.

Results

Mean age of the patients enrolled to the study was 11.17 ±4.92 years, and the mean age at the time of diagnosis of GCK-MODY was 8.25 ±4.76 years (Table I).
The study revealed that the majority of children of mothers affected with GCK-MODY were born in term, i.e. after the 38th completed week of pregnancy, whereas 6% of children were born premature, before completing the 38th week.
In the study population, mean birth weight was 3356.80 ±557.53 g, and the lowest birth body weight of an infant diagnosed with GCK-MODY was 1760 g. Mean birth length was 53.3 ±4.41 cm (Table II).
Left Fisher test demonstrated a statistically significant difference between the absence of macrosomia (birth weight > 91st per-centile) in children with GCK-MODY diabetes in comparison to the general paediatric population (p = 0.0229; Fig. 1).
Among children with glucokinase mutation, born by mothers affected with GCK-MODY, 62% (n = 32) received 10 points in Apgar score in the first minute of life, whereas 92% (n = 46) obtained 10 points in Apgar score in the fifth minute of life. Two patients received less than 7 points in Apgar score in the first minute of life.
In the study group the mean fasting glucose concentration was 120 ±20 mg/dl, whereas the mean glucose levels 60 and 120 minutes after oral glucose load were, respectively, 208 ±35 mg/dl and 175 ±38 mg/dl. Median values of fasting insulinaemia 60 and 120 minutes after oral glucose load were, respectively, 34 IU/ml and 29 IU/ml. Mean glycated haemoglobin level at the time of the diagnosis was 6.43 ±0.71% and mean fasting C-peptide value was 1.26 ±0.62 ng/ml (Table III).
In the studied group of children, the median level of anti-glutamic acid antibodies was 0.74 (n < 5), islet antibodies was 10 (n < 20), and anti-insulin antibodies was 3.6 (n < 5). In four children with GCK-MODY antibodies were positive, i.e. in 8% of patients.
In patients who were treated with insulin the daily dose was between 0.14 do 0.7 unit /kg/day (median 0.26 u/kg/day) (Table III).
In the studied group of patients, a positive significant correlation between fasting glucose levels in mothers and birth weight in babies was seen (R = 0.64; p < 0.05; Fig. 2). Also, positive correlation between mothers’ and children’s HbA1c was seen.
In the presented study, no perinatal deaths, congenital malformations, or episodes of hypoglycaemia, were reported in infants of GCK-MODY mothers.
In the conducted analysis correlation between HbA1c in mothers and birth weight in children, and between glucose levels in children and the age of diagnosis, were not detected. We did not find any relation between weight gain in pregnancy by mothers, their HbA1c, fasting glucose levels in mothers, and APGAR score in children.

Discussion

Diabetes during pregnancy is a heterogenous disorder. GCK-MODY, caused by glucokinase defect, along with type 1 and type 2 di-abetes, is considered as one of the most frequent types of diabetes in pregnancy [13, 14].
GCK-MODY is underdiagnosed on account of the mild clinical course of this disease. In addition, in a substantial percentage of women, period of pregnancy is the only time when screening and diagnosis of carbohydrate metabolism disorders are carried out.
Early diagnosis of GCK-MODY enables us to optimise diabetes care of both pregnant women and foetuses. Moreover, it al-lows us to implement preventive procedures against diabetes development after delivery [13, 15, 16]. It should be noted that due to the dominant pattern of inheritance of GCK-MODY, there is a high risk of transmission of mutated gene to the offspring, which can lead to diabetes presentation even in the first months of life [15, 17, 18].
Several parameters, which may be influenced by diabetes, were assessed in neonates of GCK- MODY mothers. Researchers investigated birth weight, perinatal condition, and the presence of congenital malformations in patients.
The incidence rate of foetal macrosomia in the general population is 8-14%, whereas in diabetic mothers it varies between 25 and 42%. Macrosomia is mainly caused by hyperglycaemia in pregnant women. Intrauterine hypotrophy, a contrasting disorder, occurs in patients with a long history of diabetes, who present vascular complications such as nephropathy and retinopathy [19]. The presence of inactivating GCK mutation in pregnant women may lead to increased birth body weight in newborns. On the other hand, if the foetus carries the mutation, its birth weight is decreased due to reduction of insulin secretion [20].
In the presented study, glucokinase gene mutation was detected in all of the infants of GCK-MODY mothers. The birth weight in the study group was similar to the mean birth weight in the general population. There were no macrosomic neonates of patients with GCK-MODY. Moreover, a statistically significant difference in the absence of macrosomia was revealed between the study group and the general paediatric population. In observed patients, levels of glycaemia, insulinaemia, and, indirectly, birth weight were influenced by the presence of GCK-MODY in mothers and inheritance of GCK mutation by foetuses. It is presumed that opposite action of maternal hyperglycaemia, which stimulates insulin secretion, and hyposecretion of insulin in foetuses, conclusively leads to normal birth weight. Furthermore, researchers stated a statistically significant positive correlation between fasting glycaemia in mothers and birth weight in newborns. This phenomenon may be explained by the anabolic action of insulin in foetuses in response to hyperglycaemia in mothers.
The majority of examined neonates with glucokinase gene mutation, who were delivered by patients affected with GCK-MODY, received 10 points in the Apgar scale (62% in the first minute of life, 92% in the fifth minute of life). According to literature data, the achieved result is much more satisfying than the score obtained by newborns of mothers with gestational diabetes.
In Kock et al.’s study concerning infants of patients with gestational diabetes, the mean Apgar score was 8.4 points in the first minute [21]. In Wender-Ożegowska et al.’s research the achieved result was similar at 8 points [22]. The better clinical state of new-borns delivered by patients with GCK-MODY in comparison with subjects affected with other types of diabetes probably results from the milder clinical course of this disorder.
Another parameter investigated in the presented study was the incidence rate of perinatal deaths and congenital defects in new-borns of GCK-MODY mothers. According to the literature data, it can be concluded that diabetes during pregnancy predisposes to peri-natal deaths. In Czajkowski et al.’s work [23] the incidence rate was 6.6%. A similar result was obtained in Cypryk et al.’s study. Re-searchers reported perinatal deaths in 6.4% of neonates of diabetic patients [23, 24] in comparison with 1.4% of newborns of healthy mothers [25].
In the presented study, perinatal deaths, congenital malformations, and episodes of hypoglycaemia were not reported in infants of GCK-MODY mothers. This can be explained by the mild clinical course of monogenic diabetes. An additional factor, which might have influenced the absence of hypoglycaemia after birth, was the genetic defect of glucokinase detected in the whole group of examined children.
Mean fasting glucose concentration in the examined children was 120 mg/dl, whereas 120 minutes after glucose load the mean glucose concentration was 175 mg/dl. The achieved results were consistent with typical clinical features of GCK-MODY [4]. At the moment of diagnosis of the disease, the glycated haemoglobin level presented by children was 6.43% and was higher than in their moth-ers at the moment of diagnosis. In the group of patients treated with insulin, the total daily dose of insulin was usually around 0.26 U/kg/24 hours; a much lower dose than in patients affected with type 1 diabetes. Such low insulin requirements, comparable to those required by type 1 diabetic patients during remission period, raise doubts about the need for insulin therapy in the examined patients. However, it should be noted that in certain patients insulin therapy was implemented due to a suspicion of type 1 diabetes, before mak-ing a diagnosis of GCK-MODY, and that 8% of studied patients had positive antibodies.
Furthermore, a positive correlation between HbA1c levels in patients with glucokinase mutation and HbA1c levels in their mothers was reported, which indicates the presence of the same type of mutation as well as the phenotype and severity of clinical symp-toms related to it.

Conclusions

Gestational diabetes is one of the most common medical disorders and may cause numerous maternal and foetal complications. Car-bohydrate metabolism disorders are frequently detected during pregnancy. One of the types of diabetes that may clinically manifest in pregnancy is GCK-MODY. The clinical course of the disease is mild. Patients usually present slightly elevated fasting glucose concen-tration. According to the presented study, possible consequences of GCK-MODY during pregnancy on foetal development are generally less severe and may differ from those characteristic for other types of diabetes. Further investigation of particular phenotypes of GCK-MODY, depending on the type of inherited mutation, in mothers and their children is required.

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