Diabetic Mother, Infant of
The classifications of maternal diabetes are outlined in Table 1.Table 1. Whites classification of maternal diabetes.
|Gestational diabetes (GD):||Diabetes not known to be present before pregnancy|
|GD diet||Normal glucoses maintained by diet alone|
|GD insulin||Insulin required|
|Class A:||Glucose intolerence prior to pregnancy not requiring insulin|
|Class B:||Insulin-dependent; onset after 20 years of age|
|Class C:|| C1: Onset at 10 to 19 years of age|
C2: Duration 10 to 19 years
|Class D:|| D1: Onset before 10 years of age|
D2: Duration 20 years
D3: Calcification of vessels of the leg (macrovascular disease)
D4: Benign retinopathy (microvascular disease)
D5: Hypertension (not preeclampsia)
|Class F:||Nephropathy (kidney abnormality) with >500 mg of protein per day in urine|
|Class R:||Proliferative retinopathy of the eye or vitreous hemorrhage (bleeding within the eye)|
|Class RF:||Criteria for both classes R and F coexist|
|Class G:||Many reproductive failures|
|Class H:||Clinical evidence of atherosclerotic heart disease|
|Class T:||Prior kidney transplantation|
* Modified from Diabetes Complicating Pregnancy: The Joslin Clinic Method. New York: Wiley-. Liss 1995. 2nd Ed. Florence M. Brown, John W. Hare.
The classification of diabetes during pregnancy is important because the outcome of both the mother and the baby are related to the severity and the duration (represented by the different classes) of the mother's diabetic condition.
In mothers with gestational diabetes, there is an increased risk of large (macrosomic) babies and babies with low blood sugars (hypoglycemia) after birth; however, the overall risk of complications is low.
Large babies and babies with low blood sugars also are associated with Classes A, B, C, and D.1 Large (macrosomic) babies increase the need for cesarean section delivery because the baby can be too big to pass through the mother's pelvis and vaginal canal.
Class F mothers have the highest risk of delivering abnormally small babies with poor growth while inside the mother's uterus.1 Class F mothers also have an increased risk of anemia, high blood pressure (hypertension), and decreased kidney function.
Class H mothers have an increased risk of a heart attack or heart failure and sudden death, along with an increased risk of producing abnormally small babies.
Class R mothers have an increased risk of worsened retinopathy, bleeding into the eye (vitreous hemorrhage), or detachment of the retina. They also have an increased risk of delivering small babies, most often by cesarean section.
All classes have an increased risk of abnormally large amounts of amniotic fluid (polyhydramnios). Polyhydramnios increases the risk of pre-term labor and delivery, delivery of the baby's umbilical cord before the baby (cord prolapse), or early separation of the placenta from the uterus (placental abruption). Cord prolapse and placental abruption can dangerously cut off blood supply to the placenta and the baby.
Infants of diabetic mothers, or IDMs, have a significantly increased risk of breathing problems (respiratory distress), especially if they are born before 37 weeks, because their lungs are slower to mature.
Approximately 30% to 40% of IDMs have low blood sugar (i.e., glucose is less than 40 mg/dl) after birth. This condition usually occurs early after birth, often by one to two hours of age. Low blood sugar occurs because of excess insulin in the baby. The excess insulin was produced in the baby while inside the mother's uterus in response to high blood sugars delivered across the placenta from the mother's blood. Prolonged or severe low blood sugar (i.e., hypoglycemia) can cause seizures and brain damage. Therefore, IDMs will have their blood sugars checked (usually by "heel stick") shortly after birth and then several times over the next one to two days.
Approximately 20% of IDMs will have low calcium. If a baby is very sick, shaky, or lethargic, or has seizures despite normal blood glucose, a blood calcium measurement should be performed.
An abnormally high red blood cell count (polycythemia) can occur in IDMs, increasing their risk of jaundice (yellow skin color), feeding difficulties, respiratory distress, or lethargy. The risk of jaundice is increased significantly in IDMs even if they are not polycythemic. One study found that 19% of IDMs developed bilirubin levels greater than 16 mg/dl. Bilirubin is the yellow pigment that comes from the red blood cells and produces the yellow skin color. When there is too much bilirubin in a baby's blood, it can cause brain damage. Fortunately, this problem is treated easily with light treatment (phototherapy).
The incidence of major congenital anomalies (birth defects) is increased from 6% to 9% in IDMs, compared to a rate of 2% in the general population. The frequency of congenital anomalies is not increased in gestational diabetes; however, two-thirds of these anomalies involve the brain, the nervous system, or the heart. Caudal agenesis (failure of formation of the lower vertebrae and sacrum of the spine) more frequently occurs in IDMs whose mothers had poor blood sugar control around the time of conception and during the first few weeks of pregnancy.
A significant decrease in the incidence of congenital anomalies has been reported with rigorous glucose control in the periconception period.2 Congenital anomalies can be reduced even more if the mother takes folate supplements during the early part of pregnancy.
Poor feeding is a common problem that affects up to 37% of IDMs, often prolonging the hospital stay.
Macrosomia (large birth weight, i.e., larger than 4 kilograms, or 8 pounds) occurs in about one-third of IDMs, and it correlates with high blood sugars and serum fat concentrations in the third trimester of pregnancy.3 Usually, macrosomia is not seen in those mothers with more severe and longer-standing diabetes (e.g., Classes F and R).
Poor heart function or myocardial dysfunction is rare, but increased, in IDMs because of the enlargement of the septum or the wall between the ventricles (the two large pumping chambers of the heart). This condition is called ventricular septal hypertrophy, and can cause congestive heart failure, poor cardiac output, and heart enlargement. However, it often has no associated problems. Sometimes, a heart murmur is heard when IDMs have poor heart function.
Even when there are associated problems with the heart, they usually resolve by two weeks, and the hypertrophy resolves by four months. Good diabetic control during pregnancy can reduce the incidence and the severity of this complication.
Renal vein thrombosis or clotting of the vessel draining blood from the kidney, causing the kidney to swell, is rare; however, it can occur before or after birth in IDMs. It is caused by abnormally low blood anticoagulants that may develop in the baby whose mother is poorly controlled for her diabetes during pregnancy.
Small left colon syndrome can occur in IDMs. This syndrome can cause the delayed passage of a stool after birth, resulting in abdominal distention and a delay in normal feeding.
Good glucose control and prevention of ketoacidosis prior to conception and in the first two months of pregnancy will decrease the risk of congenital anomalies. Later in the pregnancy, glucose control is important to prevent macrosomia, hypoglycemia (after birth), and ventricular septal hypertrophy of the baby's heart. It generally is recommended that the mother's fasting blood glucose should be from 70 to 90 mg/dl, and, two hours after eating, her blood glucose should be less than 120 mg/dl.2
If a pregnant diabetic woman participates in a program of pregnancy management and surveillance from before conception until delivery, she has at least a 95% chance of having a completely healthy child.1
Early screening for congenital anomalies usually includes a serum alpha-fetoprotein level of the mother to screen for open neural tube defects (spina bifida) and a detailed ultrasound at 18 to 20 weeks. Follow-up ultrasounds may be required for polyhydramnios (increased amniotic fluid), abnormal fetal growth, or early separation of the placenta.
Tests of fetal well being, including daily fetal movement counts and biweekly biophysical testing (ultrasound and fetal heart rate monitoring), usually begin at 28 to 32 weeks.
An amniocentesis may be performed prior to delivery if the mother is at less than 38 weeks gestation to document fetal lung maturity.
The mother's glucose will be monitored closely during labor, and insulin and glucose treatments often will be adjusted.
The baby will require frequent blood glucose checks after birth, beginning in the first two hours of birth. These check-ups usually are continued every 2 to 4 hours for at least 24 hours.
The red blood cell count, or hematocrit, will be checked after birth to ensure that the baby does not have polycythemia. If significant jaundice occurs, bilirubin levels will be checked.
If the baby has jitteriness, lethargy, or poor feeding, despite normal glucoses, the calcium level will be checked.
A thorough physical examination will be performed to look for any physical abnormalities and to listen to the heart for any evidence of a heart murmur.
The baby's long-term development will be followed; studies have shown a mild decrease in IQs (93 versus 102) of IDMs with a maternal history of ketones in the urine (ketonuria) during pregnancy, as compared to IDMs with no maternal ketonuria.2 However, significant differences in mental development have not been found between IDMs with good sugar control without ketonuria and other normal babies.
If the baby is well after birth, he/she should be nursed or given formula in the first hour. The first blood sugar should be checked within two hours of birth or sooner if the baby develops jitteriness, lethargy, or seizures. If the blood sugar is low (less than 40 mg/dl), the baby should be fed immediately, and the blood sugar rechecked within one to two hours. If the blood sugar is extremely low (less than 25 mg/dl), if the baby is sick or unable to eat, or if the blood sugar remains low despite feeding, an IV with glucose water should be started for the baby. The blood sugar will be rechecked frequently until it is normal and stable.
If congenital anomalies exist, they will need to be treated accordingly; some birth defects may require surgery.
If the baby develops significant jaundice, phototherapy may be required for a short period (usually from two to five days) to break down the bilirubin in the skin.
If the lungs are not mature, the baby could require help with breathing using a machine called a respirator. The baby also could benefit from surfactant. Surfactant is a soap suds-like material that is administered to help lubricate and expand the lungs. Surfactant often is deficient in immature lungs, and most commonly occurs in those IDMs born at less than 37 weeks.
If the baby has difficulty feeding, he/she may require intermittent gavage feeds with a feeding tube. Extra time in the hospital may be required for the baby to learn to feed by either the breast or the bottle.
If the baby develops abdominal distention or has difficulty stooling, a gastrointestinal x-ray with gastrograffin may be required to check if a microcolon is present.
In a series of studies from the Joslin Diabetes Center, only 2% to 3% of IDMs developed insulin-dependant diabetes mellitus before 20 years of age. The risk of subsequent diabetes is slightly higher if both the mother and the father have insulin-dependent diabetes. The risks and the complications to the baby outlined herein do not pertain when only the father has insulin-dependant diabetes.
Cloherty JP, Stark AR. Manual of neonatal care. Philadelphia, Lippencott-Raven, 1997.
Fanaroff AA, Martin RJ. Metabolic and endocrine disorders. In: Neonatal-perinatal medicine: diseases of the fetus and infant. 6th ed. St. Louis: Mosby-Year Book, Inc.
About the Author
Dr. Paisley is a second year fellow in Neonatal-Perinatal Medicine in the Section of Neonatology, Department of Pediatrics, University of Colorado School of Medicine in Denver, Colorado. Jan trained in Pediatrics at the University of Utah and was honored to receive a highly prestigious Pediatric Scientist Development Program award.
Jan preferred clinical practice, however, and she has been working for the past 7 years as a general Pediatrician in Ft. Collins, Colorado.
She joined the Neonatal-Perinatal Medicine Training Program in 1998 and is working with Dr. Adam Rosenberg and Dr. William Hay on aspects of cerebral glucose metabolism in a fetal animal model and in newborn human infants.
Dr. Hay is a Professor of Pediatrics at the University of Colorado School of Medicine, Denver, Colorado.
He is the Director of the Training Program in Neonatal-Perinatal Medicine, Director of the Neonatal Clinical Research Center (as Associate Director of the National Institutes of Health and Department of Pediatrics sponsored Pediatric Clinical Research Center), and Scientific Director of The Perinatal Research Center at the University of Colorado Health Sciences Center.
Dr. Hay holds three NIH research grants and a NIH Training Grant in Perinatal Medicine and Biology.
His clinical and basic research interests focus on fetal physiology, fetal and neonatal nutrition and metabolism, glucose disorders in preterm infants, small-for-gestational aged infants, and infants of diabetic mothers, and oxygen monitoring.
Dr. Hay is Secretary-Treasurer of the American Pediatric Society and is a member of the NIH Human Embryology and Development Study Section. He travels widely around the United States and internationally as a visiting scientist and professor.
Dr. Hay also is the senior editor for Current Pediatric Diagnosis and Treatment (a Lange Publication) and co-editor of NeoReviews (American Academy of Pediatrics).
Copyright 2012 Jan E. Paisley, M.D., and William W. Hay, Jr., M.D., All Rights Reserved