INTRODUCTION — The clinician caring for pregnant patients with gestational diabetes mellitus (GDM) should be knowledgeable about the maternal and fetal consequences of the disorder (eg, increased risk of preeclampsia and macrosomia), management of hyperglycemia, pregnancy monitoring, management of pregnancy complications, postpartum care, and long-term follow-up. This topic will discuss most of these issues; glucose management is reviewed in detail separately:
●(See "Gestational diabetes mellitus: Glucose management and maternal prognosis".)
Screening for and diagnosis of GDM are also reviewed separately. (See "Gestational diabetes mellitus: Screening, diagnosis, and prevention".)
CONSEQUENCES OF GDM — In addition to routine pregnancy issues, the prenatal care of patients with GDM focuses on identifying and managing conditions that are increased among patients with glucose impairment. In contrast to patients with pregestational diabetes, patients with true GDM are not at increased risk of having an infant with congenital anomalies because the onset of the disorder is after organogenesis, and they do not experience diabetes-related vasculopathy because of the short duration of the disorder. However, it is important to note that some patients diagnosed with GDM actually have unrecognized preexisting diabetes if they were not screened prior to or early in pregnancy, so they may have these complications.
Short-term consequences — Complications of pregnancy more common in patients with GDM include:
●Large for gestational age (LGA) newborn and macrosomia – LGA (commonly defined as fetal or neonatal weight at or above the 90th centile for gestational age) and macrosomia are the most common adverse neonatal outcomes associated with GDM.
•The overall rates of LGA and macrosomia (in this study defined as birth weight >4000 g) were 18.0 and 10.5 percent, respectively, in a series including over 1.5 million singleton, nonanomalous live births to individuals with GDM in the United States (2014 to 2020) [1].
•GDM doubles the risk for LGA, and patients with obesity are at very high risk. In one report, the prevalence of LGA among normal weight patients with GDM versus without GDM was 13.6 versus 7.7 percent [2]. The prevalence of LGA among patients with obesity with GDM versus without GDM was 22.3 versus 12.7 percent. Excessive gestational weight gain (>40 pounds [18 kg]) also doubles the risk of LGA [3].
Randomized trials have consistently demonstrated that maternal hyperglycemia significantly increases the chances of having a LGA or macrosomic newborn [4-7]. Maternal hyperglycemia leads to increased transplacental transfer of glucose and other nutrients, which induce fetal hyperinsulinism and, in turn, accelerated fetal growth that is asymmetric (normal head size but broader shoulders and increased thoracic and abdominal diameters compared with newborns of mothers without diabetes). Accelerated fetal growth began as early as 20 to 28 weeks of gestation in a prospective cohort study [8].
Macrosomia and fetal truncal asymmetry are associated with an increased risk of operative birth (cesarean or instrument-assisted vaginal) and adverse neonatal outcomes, such as shoulder dystocia and its associated complications: brachial plexus injury, fracture, and neonatal depression [9-16]. (See "Fetal macrosomia" and "Shoulder dystocia: Risk factors and planning birth of high-risk pregnancies" and "Large for gestational age newborn".)
●Preeclampsia and gestational hypertension – Patients with GDM are at higher risk of developing preeclampsia and gestational hypertension (overall frequency 12 percent [1]) compared with patients without GDM. Insulin resistance causes GDM and also appears to be associated with development of preeclampsia and gestational hypertension, which may account for this association [17-26]. (See "Preeclampsia: Clinical features and diagnosis" and "Gestational hypertension".)
●Polyhydramnios – Polyhydramnios is more common in patients with GDM (incidence 18 percent [27]). The pathogenesis is unclear; fetal polyuria secondary to fetal hyperglycemia is one potential mechanism. Its impact on pregnancy outcome is also uncertain. Two studies reported GDM-related polyhydramnios, which is typically mild, did not significantly increase perinatal morbidity or mortality [28,29]. However, polyhydramnios in patients with or without GDM has been associated with an increased risk for adverse pregnancy outcome in some studies [27]. (See "Polyhydramnios: Etiology, diagnosis, and management", section on 'Outcome'.)
●Stillbirth – Patients with GDM and suboptimal glucose control appear to have an increased risk of stillbirth compared with the general obstetric population [30-32]. A systematic review found 666 stillbirths among 103,000 pregnancies with GDM (approximately 6 stillbirths per 1000 GDM pregnancies compared with 4 stillbirths per 1000 nonGDM pregnancies) [33]. However, the risk of stillbirth does not appear to be increased in patients with good glycemic control, though ascertainment of good control can be challenging [34].
●Neonatal morbidity – Neonates of pregnancies complicated by GDM have been reported to be at increased risk of multiple, often transient, morbidities, including hypoglycemia, hyperbilirubinemia, hypocalcemia, hypomagnesemia, polycythemia, respiratory distress, and/or cardiomyopathy [35,36]. These risks are related, in large part, to maternal hyperglycemia. (See "Infants of women with diabetes".)
In contrast to most studies, a secondary analysis of data from the Antenatal Late Preterm Steroids (ALPS) trial found that GDM was not associated with a clinically significant difference in neonatal respiratory outcomes; however, information about each participant's glucose control and diabetes treatment was not available [37]. Good glycemic control may have reduced the risk of respiratory problems in the newborns of patients with GDM. Baseline differences between patients with GDM versus those without GDM in this study may also account for the findings.
Long-term consequences — Risks associated with GDM extend beyond the pregnancy and neonatal period. For example:
●GDM is a strong marker for future maternal development of diabetes mellitus (primarily type 2), metabolic syndrome, and cardiovascular disease. (See "Gestational diabetes mellitus: Glucose management and maternal prognosis", section on 'Long-term risk'.)
●GDM increases the offspring's risk for developing obesity and abnormal glucose tolerance. Poorly controlled maternal diabetes during pregnancy may impact neurodevelopmental outcome; however, evidence is circumstantial and of poor quality. (See "Infants of women with diabetes", section on 'Long-term outcome'.)
CLASSIFICATION/TERMINOLOGY — Patients with GDM are classified into two groups [38], which correlate with pregnancy risk and thus guide obstetric management:
●A1: glycemic control achieved without medication
●A2: glycemic control achieved with medication
PREGNANCY MANAGEMENT — The author's general approach to pregnancy management in GDM is shown in the algorithm (algorithm 1).
Glucose monitoring, targets, and management — Glucose management to achieve glucose levels in the target range is the key intervention for reducing the frequency and/or severity of complications related to GDM. Glucose levels are checked before breakfast (ie, fasting glucose level) and at one or two hours after the beginning of each meal.
Commonly used antepartum glycemic targets are:
●Fasting blood glucose concentration: <95 mg/dL (5.3 mmol/L)
●One-hour postprandial blood glucose concentration: <140 mg/dL (7.8 mmol/L)
●Two-hour postprandial glucose concentration: <120 mg/dL (6.7 mmol/L)
Using even tighter postprandial targets did not affect the overall rate of having a large for gestational age (LGA) newborn, but reduced the risk of perinatal death, birth trauma, or shoulder dystocia in a randomized trial [39].
There are no standard criteria for describing suboptimal versus poor glucose control. We consider glucose values 20 to 30 percent above the target range suboptimal.
Glucose monitoring, medical nutritional therapy, exercise, and the use of insulin and/or oral antihyperglycemic medications to achieve and maintain these targets are discussed in detail separately. (See "Gestational diabetes mellitus: Glucose management and maternal prognosis".)
Fetal surveillance
A1 GDM with good glucose control — Patients who are euglycemic with nutritional therapy alone (ie, class A1 GDM) and who have no other pregnancy complications (eg, no macrosomia, preeclampsia, growth restriction, polyhydramnios, or oligohydramnios) do not appear to be at increased risk of stillbirth [40]; therefore, omitting antenatal fetal surveillance (nonstress test [NST] and amniotic fluid index, biophysical profile [BPP]) is a reasonable approach for these patients and this author's approach, but practice patterns vary given the range of existing data on this issue. If the practitioner chooses to order NSTs or BPPs in these pregnancies, the tests should probably be begun closer to term than 32 weeks (eg, 36 weeks) since no increased risk of stillbirth has been demonstrated in this population. (See "Overview of antepartum fetal assessment".)
The American College of Obstetricians and Gynecologists (ACOG) made no specific recommendations for fetal assessment in patients with well-controlled glucose levels on nutritional therapy, except for assessment of amniotic fluid volume; this decision was left to local practice patterns [38].
A2 GDM or A1 GDM with suboptimal glucose control — We obtain twice weekly NSTs plus an amniotic fluid index beginning at 32 weeks of gestation in (algorithm 1):
●All patients who use insulin or an oral antihyperglycemic medication to achieve good glycemic control.
●All patients with suboptimal glycemic control. Ideally, patients with suboptimal glucose control will be brought under better control with diet and/or medication.
The evidence supporting antenatal fetal testing in pregnancies complicated by GDM consists primarily of data from observational series that report no or rare fetal losses among a group of pregnancies monitored by various antenatal testing regimens [41,42]. There are no randomized trials evaluating antenatal obstetric management of patients with GDM specifically, and findings from the small number of cohort and case-control studies are inconclusive.
The practice pattern that has evolved over decades is to base use of fetal testing on (1) the severity of GDM (ie, whether euglycemia is achieved and whether it is achieved by nutritional therapy or by pharmacotherapy) and (2) the presence of other risk factors for adverse pregnancy outcome (eg, past history of stillbirth, presence of comorbidities such as chronic hypertension). As some studies have reported that patients with GDM are at increased risk of stillbirth [43,44], we agree with expert opinion, which generally recommends that patients who require insulin or an oral antihyperglycemic medication (ie, class A2 GDM) to maintain euglycemia or who have suboptimally controlled blood glucose levels should be managed the same way as patients with pregestational diabetes or other conditions placing the pregnancy at increased risk of adverse outcome. These patients typically undergo periodic antenatal testing, usually initiated at approximately 32 weeks of gestation.
The timing for initiating testing in the third trimester, the frequency of testing, and the tests utilized (eg, NST, BPP) vary by institution and practice setting. Although we perform NSTs with an amniotic fluid index twice per week, there is no strong evidence favoring twice weekly testing over weekly testing or initiating testing at 32 weeks versus later in gestation. For example, some medical centers begin NSTs weekly at 32 weeks and increase to twice weekly at 36 weeks.
ACOG has suggested antenatal fetal assessment beginning at 32 weeks of gestation for patients treated with insulin or oral medications, even when good glycemic control is achieved with drug therapy, and for patients with suboptimal glucose control on medical nutritional therapy [38].
Monitoring fetal growth — We perform a single third-trimester ultrasound examination at 36 to 39 weeks to estimate fetal weight in all patients with GDM, regardless of degree of metabolic control or requirement for insulin or oral antihyperglycemic medications. Identification of accelerated fetal growth before birth may be useful to identify maternal-fetal pairs who may benefit from scheduled cesarean birth to avoid trauma from shoulder dystocia [45].
In view of the limitations of the available data discussed below, a broad spectrum of practice patterns has evolved. Some clinicians also obtain an ultrasound examination early in the third trimester to identify fetal growth acceleration as this appears to be a sign of suboptimal glycemic control [46], although it does not accurately predict LGA at birth [47]. Others use the information from a 36 to 39 weeks scan to identify maternal-fetal pairs that may benefit from induction of labor before the fetus grows too large. Still others obtain serial ultrasound examinations every four weeks from diagnosis until birth to identify accelerated fetal growth as tightening glycemic control in these pregnancies may reduce the risk of macrosomia; however, a randomized trial comparing tight versus less tight control in GDM failed to show a difference between groups in LGA [39].
Similar to the situation with antenatal testing, some providers do not monitor fetal growth sonographically in euglycemic patients with A1 GDM (medical nutritional therapy alone) because of concerns that false-positive findings will lead to iatrogenic complications. As an example, one study reported an increase in cesarean birth among patients who had a third-trimester ultrasound examination, even after controlling for birth weight [48].
Estimation of fetal weight is challenging because no method of fetal growth assessment performs well; all current methods are neither particularly sensitive nor specific, especially for identifying the large for gestational age (LGA) fetus [49-51]. One review of pregnant patients with diabetes treated with insulin found that the sonographically estimated fetal weight had to be ≥4800 grams for there to be at least a 50 percent chance that the newborn's birth weight would be ≥4500 grams [52]. Studies in nondiabetic pregnancies report similar results [53]. Investigators have tried to find a more sensitive modality to estimate fetal weight, but there is little evidence that these experimental modalities can improve on existing two-dimensional ultrasound technology [54-57]. The diagnosis of LGA/macrosomia is discussed in detail separately. (See "Fetal macrosomia", section on 'Diagnosis' and "Fetal macrosomia", section on 'Patients with diabetes'.)
Management of selected antenatal complications — As discussed above, the following antenatal complications are more prevalent in patients with GDM. (See 'Consequences of GDM' above.)
Preeclampsia and gestational hypertension — Management of preeclampsia and gestational hypertension is similar to that in patients without GDM. Labetalol can be used for management of severe hypertension; hypoglycemic symptoms are unlikely to be masked in patients with GDM. (See "Preeclampsia: Antepartum management and timing of delivery" and "Gestational hypertension" and "Hypoglycemia in adults with diabetes mellitus".)
However, administration of antenatal corticosteroids (ACS), if indicated, has hyperglycemic effects, beginning approximately 12 hours after the first steroid dose and lasting for approximately five days [58,59]. We monitor capillary blood glucose concentrations regularly (eg, at least every four times daily, but more frequently depending on glucose levels and difficulty in obtaining control) beginning 12 hours after the first dose of betamethasone and continuing for 24 hours after the second dose. We then reduce the frequency to four times per day if glucose levels are reasonably well controlled. If a fasting level exceeds 100 mg/dL (5.5 mmol/L) or a postprandial level exceeds 140 mg/mL (7.8 mmol/L), we would treat with subcutaneous insulin. We initiate a continuous intravenous insulin infusion on the labor unit if values are persistently elevated despite escalation of the subcutaneous regimen or if initial values are above 180 mg/dL (10.0 mmol/L). (See "Pregestational (preexisting) diabetes mellitus: Obstetric issues and management", section on 'Antenatal glucocorticoids in patients at risk for preterm birth'.)
ACS are generally not recommended at ≥34 weeks of gestation in patients with diabetes. While the Antenatal Late Preterm Steroids (ALPS) trial found a modest benefit in late preterm gestations, this trial specifically excluded patients with diabetes because of concerns for impact on glycemic control. (See "Antenatal corticosteroid therapy for reduction of neonatal respiratory morbidity and mortality from preterm delivery".)
Preterm labor — Management of preterm labor is the same as that in patients without GDM. Indomethacin and nifedipine are first-line medications for tocolysis, with the choice dependent on gestational age. If these medications are contraindicated, terbutaline can be used, but maternal glucose levels need to be monitored closely since beta agonists increase glucose levels. For fasting levels >100 mg/dL (5.5 mmol/L) or postprandial levels >140 mg/mL (7.8 mmol/L), we treat with subcutaneous insulin. (See "Inhibition of acute preterm labor".)
Coadministration of ACS accentuates the increase in glucose levels. Gestational ages for use (ie, <34 weeks), monitoring, and treatment are as described above for patients with preeclampsia or gestational hypertension. (See 'Preeclampsia and gestational hypertension' above.)
Macrosomia and prediction/prevention of shoulder dystocia — Macrosomia (which is commonly defined as ≥4500 grams in GDM) is diagnosed by ultrasound and often accompanied by polyhydramnios. A major concern in the birth of the macrosomic fetus is the occurrence of shoulder dystocia. Scheduled cesarean birth is typically offered to patients with GDM and estimated fetal weight ≥4500 grams to prevent shoulder dystocia. (See 'Route of birth' below.)
Decision-making regarding induction of fetuses <4500 grams versus expectant management are reviewed separately. (See "Shoulder dystocia: Risk factors and planning birth of high-risk pregnancies", section on 'Patients with diabetes'.)
Timing of birth — One of the key issues of the management of patients with GDM is whether to induce labor and, if so, when. The major potential benefits of induction are avoidance of late stillbirth and avoidance of birth-related complications of continued fetal growth, such as shoulder dystocia or a cesarean birth for failure to progress. The potential disadvantages are the risks of induction (eg, longer labor, increased tendency for intervention) and greater neonatal morbidity if the induction is before 39 weeks [43]. Increasing evidence suggests that induction of labor in patients with GDM does not result in higher cesarean birth rates than expectant management [60-62].
The optimal timing of birth in GDM has not been evaluated in well-designed trials. The available data [60,63-68] are inadequate to allow a strong evidence-based recommendation; thus, common practice varies somewhat worldwide [69,70]. The approach is based primarily on whether the patient is A1 or A2 GDM and the adequacy of glucose control.
A1 GDM with good glucose control — Our approach, and the practice pattern that has evolved in many institutions, is to manage pregnancies of patients who remain euglycemic with nutritional therapy and exercise alone (A1 GDM) by beginning a discussion about the possibility of induction of labor and the tradeoffs of induction versus expectant management when the pregnancy reaches 39+0 weeks of gestation, and scheduling an induction between 39+0 to 41+0 weeks of gestation; induction reduces the risks associated with late-term (41+0 to 41+6) and postterm (≥42+0) pregnancy. (See "Postterm pregnancy".)
This relatively noninterventional approach is based on the favorable outcomes reported in a classic uncontrolled case series of 196 patients with class A diabetes managed this way [40]. Although clinical practice varies from institution to institution, there is generally consensus that these patients should not be electively delivered before 39+0 weeks of gestation [71]. Timing of induction between 39+0 and 41+0 weeks is more controversial.
While a study using decision analysis found that fetal and neonatal mortality may be minimized by birth at 38 weeks of gestation, this mathematical model alone is insufficient for changing our clinical practice [72]. ACOG has opined that birth should not be planned before 39+0 weeks of gestation unless otherwise indicated and that expectant management up to 40+6 weeks is generally appropriate with antepartum testing [38].
A2 GDM and A1 GDM with suboptimal glucose control — For patients with GDM whose glucose levels are medically managed with insulin or oral antihyperglycemic medications (A2 GDM) and patients with A1 GDM with suboptimal glucose control, we suggest induction of labor at 39+0 weeks of gestation based on data from a retrospective cohort study of patients with GDM suggesting that the infant mortality rate at 39+0 weeks (8.7 out of 10,000) was statistically lower than the risk of stillbirth plus infant mortality with expectant management over an additional week (15.2 out of 10,000) [43]. In addition, induction may reduce the risk of shoulder dystocia compared with later birth since birth weight should be less in the absence of ongoing growth in utero [63,64].
Early term birth (37+0 to 38+6 weeks) is not indicated in uncomplicated A2 GDM with well-controlled glucose levels as the risk of stillbirth is low while neonatal morbidity rates are increased at this gestational age [73]; however, if a concomitant medical condition (eg, hypertension) is present or glycemic control is suboptimal on pharmacotherapy, birth should be undertaken as clinically indicated prior to 39+0 weeks of gestation [63,64]. Fetal weight also needs to be considered. (See 'Route of birth' below.)
ACOG suggests birth at 39+0 to 39+6 weeks of gestation for patients with A2 GDM that is well controlled with medication [73]. However, guidance for patients with suboptimal glycemic control on pharmacologic therapy is less precise. They suggest birth at 37+0 to 38+6 weeks of gestation may be reasonable, but that birth prior to 37+0 weeks should only be initiated when more aggressive efforts to control blood glucose levels, such as hospitalization, have failed [38].
Route of birth — Cesarean birth is performed for standard obstetric indications. Estimated fetal weight ≥4500 grams is an important consideration in decision-making.
●Scheduled cesarean birth – Scheduled cesarean birth to avoid birth trauma is typically offered to patients at 39+0 weeks with GDM and estimated fetal weight ≥4500 grams. The fetal weight threshold at which scheduled cesarean birth should be performed to reduce the risk of birth trauma from shoulder dystocia is controversial. It has been estimated that in diabetic pregnancies with an estimated fetal weight of ≥4500 grams, 443 cesareans would need to be performed to prevent one permanent brachial plexus injury [45]. Whether this tradeoff justifies the increased risks of cesarean birth is unclear. The ACOG practice bulletin on GDM recommends discussing the risks and benefits of scheduled cesarean birth with patients with GDM and estimated fetal weight ≥4500 grams [38].
●Trial of labor — If a patient with GDM and estimated fetal weight ≥4500 grams decides to undergo a trial of labor, we follow labor progress closely and perform an instrument-assisted vaginal birth only if second-stage descent has progressed normally because forceps- or vacuum-assisted birth is associated with a higher risk of shoulder dystocia and brachial plexus injury, with the risk even higher with the use of vacuum as compared with forceps [74,75]. (See "Shoulder dystocia: Risk factors and planning birth of high-risk pregnancies", section on 'Planning birth in high-risk pregnancies'.)
Glycemic monitoring during labor and birth — Insulin requirements usually decrease during labor as oral caloric intake is typically reduced and the work of labor, particularly uterine contractions, requires extra energy. A reasonable target range for intrapartum glucose levels is 70 to 125 mg/dL (3.9 to 6.9 mmol/L). Hyperglycemia is treated to reduce the risk of neonatal hypoglycemia. Although prolonged neonatal hypoglycemia is primarily due to fetal exposure to chronic hyperglycemia during pregnancy and resultant fetal pancreatic hyperplasia, transient hypoglycemia can be caused by intrapartum maternal hyperglycemia, which induces an acute rise in fetal insulin [76-80].
●A1 GDM – Patients with GDM who were euglycemic without use of insulin or oral antihyperglycemic medications during pregnancy generally do not develop hyperglycemia during labor and birth and thus do not need their blood glucose levels checked. However, because of concerns about the validity of baseline glycemic assessments in the outpatient environment, some practitioners and centers choose to check a few blood glucose levels during labor.
●A2 GDM – Patients with GDM who used insulin or oral antihyperglycemic medications antepartum may need insulin during labor and birth to maintain intrapartum glucose levels in the target range. Periodic assessment of maternal glucose levels during labor and treatment of hyperglycemia are prudent, although intrapartum maternal hyperglycemia leading to an adverse neonatal outcome is infrequent [81]. Intrapartum glucose monitoring and management of fluids, insulin, and oral antihyperglycemic medications during spontaneous labor, before induction, and before scheduled cesarean birth are discussed in detail separately. (See "Pregestational (preexisting) and gestational diabetes: Intrapartum and postpartum glucose management".)
POSTPARTUM MANAGEMENT AND FOLLOW-UP — Patients with GDM should be able to resume a normal diet postpartum.
Breastfeeding — Breastfeeding should be encouraged since it benefits both the mother and child. (See "Maternal and economic benefits of breastfeeding" and "Infant benefits of breastfeeding".)
Breastfeeding improves maternal glucose metabolism and thus may reduce the glucose levels obtained during a postpartum glucose tolerance test (GTT) [82-84], especially if the patient breastfeeds during the test [85]. Theoretically, this could lead to a spurious result.
Several prospective studies have reported that breastfeeding decreased the long-term incidence of type 2 diabetes after a diagnosis of GDM compared with not breastfeeding [86-89]. Higher lactation intensity and longer duration were inversely associated with the risk, independent of weight loss and after adjusting for risk factors for type 2 diabetes (sociodemographic characteristics, prenatal metabolic status and course, perinatal outcome, lifestyle behaviors).
Contraception — While any type of contraception is acceptable as long as the usual medical contraindications to use are absent, the advantages of long-acting reversible contraception (eg, intrauterine device [IUD], contraceptive implant) are the minimal risk of unplanned pregnancy and convenience [90]. There is no convincing evidence that hormonal contraceptives (estrogen-progestin or progestin-only) increase the user's risk of developing type 1 or type 2 diabetes [91]. Choosing contraceptives with lower systemic hormone levels should, in theory, minimize any changes in metabolic parameters. If a patient is concerned about hormonal issues, a copper-releasing IUD is a good alternative. (See "Contraception: Counseling and selection".)
Screening for overt diabetes — After birth, the hyperglycemic effects of placental hormones dissipate rapidly. Thus, most patients revert back to their prepregnancy glycemic status shortly after birth, ranging from almost immediately to a week postpartum. Most patients who were taking antihyperglycemic medications antepartum do not need them postpartum.
●Check postpartum glucose levels – Since some patients with GDM may have previously unrecognized type 2 diabetes mellitus, we check glucose concentrations after birth to exclude ongoing hyperglycemia. In a patient with A1 GDM, it is common to check only a single fasting glucose and, if normal, cease checking blood glucose values. In a patient with A2 GDM, we usually check glucose levels for 24 hours, obtaining both fasting and postprandial blood glucose values; if all are normal, then we would cease checking. However, if any values are abnormal, we would continue to check levels during the hospital stay to ascertain whether ongoing medical therapy is needed.
If fasting glucose concentrations suggest overt diabetes (fasting glucose ≥126 mg/dL [7 mmol/L] or a postprandial glucose is ≥200 mg/dL [11.1 mmol/L]), treatment of hyperglycemia is absolutely warranted; the type of treatment (diet, exercise, weight reduction, medication) should be decided on a case-by-case basis, often with consultation from a diabetologist or the patient's primary care provider. Postpartum glucose monitoring and therapy, if indicated, are reviewed separately. (See "Pregestational (preexisting) and gestational diabetes: Intrapartum and postpartum glucose management", section on 'Gestational diabetes'.)
●Obtain a GTT at 4 to 12 weeks – Patients with normal/near normal postpartum blood glucose levels should undergo a two-hour 75 gram oral GTT 4 to 12 weeks after delivery to check for diabetes or prediabetes (table 1). (See "Gestational diabetes mellitus: Glucose management and maternal prognosis", section on 'Follow-up'.)
•Those diagnosed with diabetes are managed as medically appropriate. (See "Initial management of hyperglycemia in adults with type 2 diabetes mellitus".)
•Those with a normal GTT are counseled about their future risk of developing type 2 diabetes and cardiovascular disease, encouraged to adopt lifestyle changes for risk reduction (eg, healthy diet, weight loss, exercise), and informed about the importance of close follow-up with their primary care provider and rescreening at appropriate intervals. These issues are discussed in detail separately. (See "Gestational diabetes mellitus: Glucose management and maternal prognosis", section on 'Follow-up' and "Screening for type 2 diabetes mellitus".)
Screening for depression — Although screening for depression is indicated in all postpartum patients, clinicians should be aware that postpartum depression is more common among patients with diabetes (pregestational or gestational) than in postpartum patients without diabetes [92]. (See "Postpartum unipolar major depression: Epidemiology, clinical features, assessment, and diagnosis", section on 'Screening'.)
SOCIETY GUIDELINE LINKS — Links to society and government-sponsored guidelines from selected countries and regions around the world are provided separately. (See "Society guideline links: Diabetes mellitus in pregnancy" and "Society guideline links: Shoulder dystocia and macrosomia".)
INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.
Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)
●Basics topics (see "Patient education: Gestational diabetes (diabetes that starts during pregnancy) (The Basics)")
●Beyond the Basics topics (see "Patient education: Gestational diabetes (Beyond the Basics)")
SUMMARY AND RECOMMENDATIONS
●Screening for and birth of the macrosomic fetus
•Ultrasound – We perform a single third-trimester ultrasound at 36 to 39 weeks to screen for macrosomia in all patients with gestational diabetes mellitus (GDM). (See 'Monitoring fetal growth' above.)
•Scheduled cesarean birth – Scheduled cesarean birth to avoid birth trauma is typically offered at 39+0 weeks to patients with GDM (any class) and an estimated fetal weight ≥4500 grams. These patients should be counseled about the poor predictive ability of ultrasound estimates of fetal weight and the risks and benefits of cesarean birth in the current and future pregnancies. (See 'Route of birth' above.)
●Fetal surveillance and timing of birth in patients with A1 GDM well controlled with nutritional medical therapy alone – These patients are not at increased risk for stillbirth.
•Antenatal fetal surveillance – We do not order antenatal fetal testing (nonstress test, biophysical profile) in these patients unless they have a standard obstetric indication for fetal surveillance (eg, growth restriction). (See 'Fetal surveillance' above.)
•Timing of induction – For candidates for vaginal birth, we offer induction of labor at 39+0 weeks of gestation and suggest performing induction by 41+0 weeks of gestation (Grade 2C), as with other late term pregnancies. (See 'Timing of birth' above and "Postterm pregnancy".)
●Fetal surveillance and timing of birth in patients with A2 GDM (ie, on pharmacologic therapy) or A1 GDM with suboptimal glucose control – These patients may be at increased risk for stillbirth.
•Antenatal fetal surveillance – We suggest a standard form of antenatal fetal testing. The optimal testing regimen has not been established from rigorous studies. We order twice weekly antenatal testing, using a nonstress test with an amniotic fluid index, starting at 32 weeks of gestation. Ideally, patients with suboptimal glucose control will be brought under better control with diet and/or medication. (See 'Fetal surveillance' above.)
•Timing of induction – For candidates for vaginal birth, we suggest induction of labor at 39+0 weeks of gestation (Grade 2C). Potential benefits include lower rates of: macrosomia and large for gestational age infants, shoulder dystocia, cesarean birth, and stillbirth. If a concomitant medical condition (eg, hypertension) is present or glycemic control is suboptimal on pharmacologic therapy, birth should be undertaken as clinically indicated prior to 39+0 weeks of gestation. (See 'Timing of birth' above.)
The American College of Obstetricians and Gynecologists suggests birth at 39+0 to 39+6 weeks of gestation for patients with A2 GDM that is well controlled with medication. For patients with suboptimal glycemic control on pharmacologic therapy, birth at 37+0 to 38+6 weeks may be reasonable, but that birth prior to 37+0 weeks should only be done when more aggressive efforts to control blood sugars, such as hospitalization, have failed.
●Postpartum care
•Breastfeeding – All patients should be encouraged to breastfeed. A potential benefit of breastfeeding is that it improves glucose metabolism in the short term. (See 'Breastfeeding' above.)
•Contraception – While any type of contraception is acceptable as long as the usual medical contraindications to use are absent, long-acting reversible contraception is convenient and has minimal risk of unplanned pregnancy. (See 'Contraception' above.)
•Postpartum testing for diabetes – All patients with GDM should have a two-hour 75 gram oral glucose tolerance test between 4 and 12 weeks postpartum (see 'Postpartum management and follow-up' above):
-Those with a normal test should be informed of their future increased risk for diabetes and cardiovascular disease, counseled about preventive measures that they can adopt, and informed of the need for rescreening at periodic intervals.
-Those with diabetes are managed as medically appropriate.
ACKNOWLEDGMENT — The UpToDate editorial staff acknowledges Michael F Greene, MD, who contributed to an earlier version of this topic review.
13 : Fetal macrosomia: risk factors and outcome. A study of the outcome concerning 100 cases>4500 g.
73 : Medically Indicated Late-Preterm and Early-Term Deliveries: ACOG Committee Opinion, Number 831.