Elizabeth Tweed, MLIS

Evidence summary

Guaifenesin, available in numerous preparations (eg, Mucinex, Robitussin), is one of the most commonly used over-the-counter medications in pregnancy. The National Birth Defects Prevention Study surveyed 2970 pregnant women from 1997 to 2001; 6.2% reported taking guaifenesin during pregnancy.¹ A second survey evaluated 7563 mothers from 1998 to 2004; 9.2% of the mothers reported that they took it during pregnancy.¹

A weak link to inguinal hernias

Guaifenesin use in pregnancy has been associated with inguinal hernias in newborns. From 1958 to 1965, the Collaborative Perinatal Project recruited 132,500 women to participate in a multicenter study; however, selection and exclusion criteria were not consistent. From this initial group, only 50,282 mother-child pairs were studied. Trained examiners interviewed the women at the child’s 4, 8, 12, and 24-month visits, and then annually thereafter to 8 years of age.

The examiners identified 7 children with inguinal hernias among 197 mothers who had used guaifenesin during their first trimester (standardized relative risk [RR] of 2.6; no CI or P value reported). Twenty children had inguinal hernias among the 1337 mothers who had used guaifenesin during any trimester of their pregnancy (RR=1.1; no confidence interval [CI] or P value reported).² The authors acknowledged that reporting bias among the participating centers prevented them from drawing any conclusions from the data.

A possible trend toward neural tube defects?

Guaifenesin use in pregnancy may also be associated with neural tube defects. In a case-control study, researchers identified 538 fetuses and live-born infants with neural tube defects between 1989 and 1991.³ Twelve patients with neural tube defects were exposed to guaifenesin during gestation; 6 in the control group reported exposure.

The authors reported a trend towards increased risk of neural tube defects in offspring of guaifenesin-exposed mothers (odds ratio=2.04; 95% CI, 0.79–5.28).³ However, since the results were not statistically significant, the authors concluded that guaifenesin had not contributed to the occurrence of neural tube defects.

In a study evaluating 6509 women whose pregnancies resulted in live births, 241 women reported first-trimester exposure to guaifenesin.⁴ Five of the guaifenesin-exposed infants (2.1%) had 1 of the birth defects studied (types of disorders not reported). The calculated RR of birth defect after in utero guaifenesin exposure was 1.3 (no CIs or P values reported); the authors concluded that there was no strong association between guaifenesin and the malformations studied.⁴

Interpret results with caution

Because of the significant potential for recall bias, interpret the findings of these case-control studies with caution.⁵ The mother of a child with a birth defect may search her memory more aggressively for potential causes than a mother of a healthy infant, leading to different rates of recalled, rather than actual, exposures. In the absence of confirmatory prospective data, such as medication diaries or pharmacy databases, recall bias accounts for many spurious positive findings in case control studies.

Recommendations from others

Food and Drug Administration. The FDA assigned guaifenesin to category C—that is, its risk cannot be ruled out. Human studies are lacking, and animal studies are either positive for fetal risk or lacking. Guaifenesin is recommended if the benefit to the pregnant woman warrants the risk to the fetus.⁶

ACOG. The American College of Obstetricians and Gynecologists (ACOG) makes no recommendation.⁷ The textbook Drugs in Pregnancy and Lactation reports that guaifenesin use during pregnancy exhibits very low risk to the fetus.⁶ The National Collaborating Centre for Women’s and Children’s Health suggests that guaifenesin be used sparingly during pregnancy.⁸

Evidence summary

Guaifenesin, available in numerous preparations (eg, Mucinex, Robitussin), is one of the most commonly used over-the-counter medications in pregnancy. The National Birth Defects Prevention Study surveyed 2970 pregnant women from 1997 to 2001; 6.2% reported taking guaifenesin during pregnancy.¹ A second survey evaluated 7563 mothers from 1998 to 2004; 9.2% of the mothers reported that they took it during pregnancy.¹

A weak link to inguinal hernias

Guaifenesin use in pregnancy has been associated with inguinal hernias in newborns. From 1958 to 1965, the Collaborative Perinatal Project recruited 132,500 women to participate in a multicenter study; however, selection and exclusion criteria were not consistent. From this initial group, only 50,282 mother-child pairs were studied. Trained examiners interviewed the women at the child’s 4, 8, 12, and 24-month visits, and then annually thereafter to 8 years of age.

The examiners identified 7 children with inguinal hernias among 197 mothers who had used guaifenesin during their first trimester (standardized relative risk [RR] of 2.6; no CI or P value reported). Twenty children had inguinal hernias among the 1337 mothers who had used guaifenesin during any trimester of their pregnancy (RR=1.1; no confidence interval [CI] or P value reported).² The authors acknowledged that reporting bias among the participating centers prevented them from drawing any conclusions from the data.

A possible trend toward neural tube defects?

Guaifenesin use in pregnancy may also be associated with neural tube defects. In a case-control study, researchers identified 538 fetuses and live-born infants with neural tube defects between 1989 and 1991.³ Twelve patients with neural tube defects were exposed to guaifenesin during gestation; 6 in the control group reported exposure.

The authors reported a trend towards increased risk of neural tube defects in offspring of guaifenesin-exposed mothers (odds ratio=2.04; 95% CI, 0.79–5.28).³ However, since the results were not statistically significant, the authors concluded that guaifenesin had not contributed to the occurrence of neural tube defects.

In a study evaluating 6509 women whose pregnancies resulted in live births, 241 women reported first-trimester exposure to guaifenesin.⁴ Five of the guaifenesin-exposed infants (2.1%) had 1 of the birth defects studied (types of disorders not reported). The calculated RR of birth defect after in utero guaifenesin exposure was 1.3 (no CIs or P values reported); the authors concluded that there was no strong association between guaifenesin and the malformations studied.⁴

Interpret results with caution

Because of the significant potential for recall bias, interpret the findings of these case-control studies with caution.⁵ The mother of a child with a birth defect may search her memory more aggressively for potential causes than a mother of a healthy infant, leading to different rates of recalled, rather than actual, exposures. In the absence of confirmatory prospective data, such as medication diaries or pharmacy databases, recall bias accounts for many spurious positive findings in case control studies.

Recommendations from others

Food and Drug Administration. The FDA assigned guaifenesin to category C—that is, its risk cannot be ruled out. Human studies are lacking, and animal studies are either positive for fetal risk or lacking. Guaifenesin is recommended if the benefit to the pregnant woman warrants the risk to the fetus.⁶

ACOG. The American College of Obstetricians and Gynecologists (ACOG) makes no recommendation.⁷ The textbook Drugs in Pregnancy and Lactation reports that guaifenesin use during pregnancy exhibits very low risk to the fetus.⁶ The National Collaborating Centre for Women’s and Children’s Health suggests that guaifenesin be used sparingly during pregnancy.⁸

Evidence summary

Guaifenesin, available in numerous preparations (eg, Mucinex, Robitussin), is one of the most commonly used over-the-counter medications in pregnancy. The National Birth Defects Prevention Study surveyed 2970 pregnant women from 1997 to 2001; 6.2% reported taking guaifenesin during pregnancy.¹ A second survey evaluated 7563 mothers from 1998 to 2004; 9.2% of the mothers reported that they took it during pregnancy.¹

A weak link to inguinal hernias

Guaifenesin use in pregnancy has been associated with inguinal hernias in newborns. From 1958 to 1965, the Collaborative Perinatal Project recruited 132,500 women to participate in a multicenter study; however, selection and exclusion criteria were not consistent. From this initial group, only 50,282 mother-child pairs were studied. Trained examiners interviewed the women at the child’s 4, 8, 12, and 24-month visits, and then annually thereafter to 8 years of age.

The examiners identified 7 children with inguinal hernias among 197 mothers who had used guaifenesin during their first trimester (standardized relative risk [RR] of 2.6; no CI or P value reported). Twenty children had inguinal hernias among the 1337 mothers who had used guaifenesin during any trimester of their pregnancy (RR=1.1; no confidence interval [CI] or P value reported).² The authors acknowledged that reporting bias among the participating centers prevented them from drawing any conclusions from the data.

A possible trend toward neural tube defects?

Guaifenesin use in pregnancy may also be associated with neural tube defects. In a case-control study, researchers identified 538 fetuses and live-born infants with neural tube defects between 1989 and 1991.³ Twelve patients with neural tube defects were exposed to guaifenesin during gestation; 6 in the control group reported exposure.

The authors reported a trend towards increased risk of neural tube defects in offspring of guaifenesin-exposed mothers (odds ratio=2.04; 95% CI, 0.79–5.28).³ However, since the results were not statistically significant, the authors concluded that guaifenesin had not contributed to the occurrence of neural tube defects.

In a study evaluating 6509 women whose pregnancies resulted in live births, 241 women reported first-trimester exposure to guaifenesin.⁴ Five of the guaifenesin-exposed infants (2.1%) had 1 of the birth defects studied (types of disorders not reported). The calculated RR of birth defect after in utero guaifenesin exposure was 1.3 (no CIs or P values reported); the authors concluded that there was no strong association between guaifenesin and the malformations studied.⁴

Interpret results with caution

Because of the significant potential for recall bias, interpret the findings of these case-control studies with caution.⁵ The mother of a child with a birth defect may search her memory more aggressively for potential causes than a mother of a healthy infant, leading to different rates of recalled, rather than actual, exposures. In the absence of confirmatory prospective data, such as medication diaries or pharmacy databases, recall bias accounts for many spurious positive findings in case control studies.

Recommendations from others

Food and Drug Administration. The FDA assigned guaifenesin to category C—that is, its risk cannot be ruled out. Human studies are lacking, and animal studies are either positive for fetal risk or lacking. Guaifenesin is recommended if the benefit to the pregnant woman warrants the risk to the fetus.⁶

ACOG. The American College of Obstetricians and Gynecologists (ACOG) makes no recommendation.⁷ The textbook Drugs in Pregnancy and Lactation reports that guaifenesin use during pregnancy exhibits very low risk to the fetus.⁶ The National Collaborating Centre for Women’s and Children’s Health suggests that guaifenesin be used sparingly during pregnancy.⁸

Evidence summary

Aggregated data from 2 randomized reflux esophagitis trials conducted in the United Kingdom were analyzed with respect to patient age. Comparison of symptom relief and esophageal lesion healing showed that elderly patients treated with omeprazole (Prilosec) fared better than those treated with either cimetidine (Tagamet) or ranitidine (Zantac).² The pooled data involved 555 patients with endoscopically proven reflux esophagitis, 154 of whom were over the age of 65. After 8 weeks, rates of esophageal healing among the elderly were 70% for those receiving omeprazole and 29% for those receiving H2RAs (41% difference; 95% confidence interval [CI], 26–55), while the rate of asymptomatic elderly patients was 79% for the omeprazole group and 51% for the H2RA group (28% difference; 95% CI, 12–44).³ Patients treated with omeprazole healed faster than those taking H2RAs, as shown by endoscopy, and more of them experienced symptom relief.

A multicenter, randomized, double-blind trial of GERD maintenance therapy started with an initial open phase in which elderly patients with GERD and documented esophagitis were treated and then had documented resolution of esophagitis by endoscopy after 6 months. The researchers then randomized 105 of these elderly patients to receive treatment with either low-dose (20 mg/d) pantoprazole or placebo for 6 months. Endoscopy was performed after 12 months for all patients, unless indicated sooner. Intention-to-treat analysis showed a disease-free rate of 79.6% (95% CI, 68.3–90.9) in the treatment group, compared with 30.4% (95% CI, 18.3–42.4) in the placebo group (number needed to treat [NNT]=2). Symptom reports concerning the same patients also suggest a marked drop in symptoms that correlated with healing.⁴

A prospective, nonequivalence, before-after study compared efficacy of, and complications from, laparoscopic surgery for symptomatic GERD between younger and older (≥65 years) patients. The investigators examined postoperative morbidity and mortality for 359 patients referred for laparoscopic surgery, either a partial or Nissen (full) fundoplication. They excluded those requiring more extensive surgery or repair of paraesophageal hernia. The 42 elderly patients had a higher mean American Society of Anesthesiologists score compared with the younger patients, reflecting higher preoperative comorbidity, but were similar with regard to weight and gender.

Before surgery, investigators performed 24-hour ambulatory pH monitoring. Preoperative exposure times to a pH below 4 (TpH <4) were similar for the younger and older patients (median 14.2% and 13.9%, respectively). Postoperative complication rates were similar for both groups. No deaths occurred. Minor postoperative complications involved 7% of the elderly patients and 6% of the younger group. The 24-hour pH monitoring scores showed improvement at 6 weeks after surgery for both groups, with the median TpH <4 at 1.1% (95% CL, 0.5) in the elderly vs a median of 1.8% (95% CL, 1.9) in the younger patients. At 1 year postoperatively, the values were also similar between the two groups; the median TpH <4 (95% CL) were 1.4% (1.5) in the elderly group and 1.2% (0.6) in the younger patient group.

The results of this study should be interpreted with caution, however. The study design is prone to bias, the patients had relatively low symptom scores at baseline, and sicker patients may have been excluded during the referral process.⁵

TABLE
Warning signs and symptoms of dyspepsia and GERD that suggest complicated disease or more serious underlying process¹

Recommendations from others

The Veterans Health Affairs/Department of Defense clinical practice guidelines recommend differentiating GERD (feelings of substernal burning associated with acid regurgitation) from dyspepsia (chronic or recurrent discomfort centered in the upper abdomen), of which GERD is a subset.⁶ The guidelines recommend gastroenterology consultation or upper endoscopy to rule out neoplastic or pre-neoplastic lesions if alarm symptoms (TABLE) suggesting complicated GERD are present.⁷

The Institute for Clinical Systems Improvement guidelines on dyspepsia and GERD recommend that all patients aged ≥50 years with symptoms of uncomplicated dyspepsia undergo upper endoscopy non-urgently because of the increased incidence of peptic ulcer disease, pre-neoplastic lesions, malignancy, and increased morbidity out of proportion to symptoms that are more common in an older patient population. The guidelines also recommend endoscopy for patients aged ≥50 years with uncomplicated GERD and the presence of symptoms for greater than 10 years because of the increased risk of pre-neoplastic and neoplastic lesions, including Barrett’s esophagus.⁸

Evidence summary

Aggregated data from 2 randomized reflux esophagitis trials conducted in the United Kingdom were analyzed with respect to patient age. Comparison of symptom relief and esophageal lesion healing showed that elderly patients treated with omeprazole (Prilosec) fared better than those treated with either cimetidine (Tagamet) or ranitidine (Zantac).² The pooled data involved 555 patients with endoscopically proven reflux esophagitis, 154 of whom were over the age of 65. After 8 weeks, rates of esophageal healing among the elderly were 70% for those receiving omeprazole and 29% for those receiving H2RAs (41% difference; 95% confidence interval [CI], 26–55), while the rate of asymptomatic elderly patients was 79% for the omeprazole group and 51% for the H2RA group (28% difference; 95% CI, 12–44).³ Patients treated with omeprazole healed faster than those taking H2RAs, as shown by endoscopy, and more of them experienced symptom relief.

A multicenter, randomized, double-blind trial of GERD maintenance therapy started with an initial open phase in which elderly patients with GERD and documented esophagitis were treated and then had documented resolution of esophagitis by endoscopy after 6 months. The researchers then randomized 105 of these elderly patients to receive treatment with either low-dose (20 mg/d) pantoprazole or placebo for 6 months. Endoscopy was performed after 12 months for all patients, unless indicated sooner. Intention-to-treat analysis showed a disease-free rate of 79.6% (95% CI, 68.3–90.9) in the treatment group, compared with 30.4% (95% CI, 18.3–42.4) in the placebo group (number needed to treat [NNT]=2). Symptom reports concerning the same patients also suggest a marked drop in symptoms that correlated with healing.⁴

A prospective, nonequivalence, before-after study compared efficacy of, and complications from, laparoscopic surgery for symptomatic GERD between younger and older (≥65 years) patients. The investigators examined postoperative morbidity and mortality for 359 patients referred for laparoscopic surgery, either a partial or Nissen (full) fundoplication. They excluded those requiring more extensive surgery or repair of paraesophageal hernia. The 42 elderly patients had a higher mean American Society of Anesthesiologists score compared with the younger patients, reflecting higher preoperative comorbidity, but were similar with regard to weight and gender.

Before surgery, investigators performed 24-hour ambulatory pH monitoring. Preoperative exposure times to a pH below 4 (TpH <4) were similar for the younger and older patients (median 14.2% and 13.9%, respectively). Postoperative complication rates were similar for both groups. No deaths occurred. Minor postoperative complications involved 7% of the elderly patients and 6% of the younger group. The 24-hour pH monitoring scores showed improvement at 6 weeks after surgery for both groups, with the median TpH <4 at 1.1% (95% CL, 0.5) in the elderly vs a median of 1.8% (95% CL, 1.9) in the younger patients. At 1 year postoperatively, the values were also similar between the two groups; the median TpH <4 (95% CL) were 1.4% (1.5) in the elderly group and 1.2% (0.6) in the younger patient group.

The results of this study should be interpreted with caution, however. The study design is prone to bias, the patients had relatively low symptom scores at baseline, and sicker patients may have been excluded during the referral process.⁵

TABLE
Warning signs and symptoms of dyspepsia and GERD that suggest complicated disease or more serious underlying process¹

Recommendations from others

The Veterans Health Affairs/Department of Defense clinical practice guidelines recommend differentiating GERD (feelings of substernal burning associated with acid regurgitation) from dyspepsia (chronic or recurrent discomfort centered in the upper abdomen), of which GERD is a subset.⁶ The guidelines recommend gastroenterology consultation or upper endoscopy to rule out neoplastic or pre-neoplastic lesions if alarm symptoms (TABLE) suggesting complicated GERD are present.⁷

The Institute for Clinical Systems Improvement guidelines on dyspepsia and GERD recommend that all patients aged ≥50 years with symptoms of uncomplicated dyspepsia undergo upper endoscopy non-urgently because of the increased incidence of peptic ulcer disease, pre-neoplastic lesions, malignancy, and increased morbidity out of proportion to symptoms that are more common in an older patient population. The guidelines also recommend endoscopy for patients aged ≥50 years with uncomplicated GERD and the presence of symptoms for greater than 10 years because of the increased risk of pre-neoplastic and neoplastic lesions, including Barrett’s esophagus.⁸

Evidence summary

Aggregated data from 2 randomized reflux esophagitis trials conducted in the United Kingdom were analyzed with respect to patient age. Comparison of symptom relief and esophageal lesion healing showed that elderly patients treated with omeprazole (Prilosec) fared better than those treated with either cimetidine (Tagamet) or ranitidine (Zantac).² The pooled data involved 555 patients with endoscopically proven reflux esophagitis, 154 of whom were over the age of 65. After 8 weeks, rates of esophageal healing among the elderly were 70% for those receiving omeprazole and 29% for those receiving H2RAs (41% difference; 95% confidence interval [CI], 26–55), while the rate of asymptomatic elderly patients was 79% for the omeprazole group and 51% for the H2RA group (28% difference; 95% CI, 12–44).³ Patients treated with omeprazole healed faster than those taking H2RAs, as shown by endoscopy, and more of them experienced symptom relief.

A multicenter, randomized, double-blind trial of GERD maintenance therapy started with an initial open phase in which elderly patients with GERD and documented esophagitis were treated and then had documented resolution of esophagitis by endoscopy after 6 months. The researchers then randomized 105 of these elderly patients to receive treatment with either low-dose (20 mg/d) pantoprazole or placebo for 6 months. Endoscopy was performed after 12 months for all patients, unless indicated sooner. Intention-to-treat analysis showed a disease-free rate of 79.6% (95% CI, 68.3–90.9) in the treatment group, compared with 30.4% (95% CI, 18.3–42.4) in the placebo group (number needed to treat [NNT]=2). Symptom reports concerning the same patients also suggest a marked drop in symptoms that correlated with healing.⁴

A prospective, nonequivalence, before-after study compared efficacy of, and complications from, laparoscopic surgery for symptomatic GERD between younger and older (≥65 years) patients. The investigators examined postoperative morbidity and mortality for 359 patients referred for laparoscopic surgery, either a partial or Nissen (full) fundoplication. They excluded those requiring more extensive surgery or repair of paraesophageal hernia. The 42 elderly patients had a higher mean American Society of Anesthesiologists score compared with the younger patients, reflecting higher preoperative comorbidity, but were similar with regard to weight and gender.

Before surgery, investigators performed 24-hour ambulatory pH monitoring. Preoperative exposure times to a pH below 4 (TpH <4) were similar for the younger and older patients (median 14.2% and 13.9%, respectively). Postoperative complication rates were similar for both groups. No deaths occurred. Minor postoperative complications involved 7% of the elderly patients and 6% of the younger group. The 24-hour pH monitoring scores showed improvement at 6 weeks after surgery for both groups, with the median TpH <4 at 1.1% (95% CL, 0.5) in the elderly vs a median of 1.8% (95% CL, 1.9) in the younger patients. At 1 year postoperatively, the values were also similar between the two groups; the median TpH <4 (95% CL) were 1.4% (1.5) in the elderly group and 1.2% (0.6) in the younger patient group.

The results of this study should be interpreted with caution, however. The study design is prone to bias, the patients had relatively low symptom scores at baseline, and sicker patients may have been excluded during the referral process.⁵

TABLE
Warning signs and symptoms of dyspepsia and GERD that suggest complicated disease or more serious underlying process¹

Recommendations from others

The Veterans Health Affairs/Department of Defense clinical practice guidelines recommend differentiating GERD (feelings of substernal burning associated with acid regurgitation) from dyspepsia (chronic or recurrent discomfort centered in the upper abdomen), of which GERD is a subset.⁶ The guidelines recommend gastroenterology consultation or upper endoscopy to rule out neoplastic or pre-neoplastic lesions if alarm symptoms (TABLE) suggesting complicated GERD are present.⁷

The Institute for Clinical Systems Improvement guidelines on dyspepsia and GERD recommend that all patients aged ≥50 years with symptoms of uncomplicated dyspepsia undergo upper endoscopy non-urgently because of the increased incidence of peptic ulcer disease, pre-neoplastic lesions, malignancy, and increased morbidity out of proportion to symptoms that are more common in an older patient population. The guidelines also recommend endoscopy for patients aged ≥50 years with uncomplicated GERD and the presence of symptoms for greater than 10 years because of the increased risk of pre-neoplastic and neoplastic lesions, including Barrett’s esophagus.⁸

Evidence summary

Gestational diabetes mellitus is diagnosed when at least 2 of 4 values measured in a 3-hour glucose tolerance test are elevated; 2 different definitions of “elevated” are accepted (TABLE 1). White’s classification stratifies the risk of various types of diabetes during pregnancy (TABLE 2): Class A includes patients without a diagnosis of diabetes before pregnancy; classes B, C, and D include patients with pre-existing diabetes of increasing duration; and classes F, H, R, and T include patients with diabetes with various vascular complications.

Infants of mothers with pre-existing diabetes are at increased risk of pre- and neonatal complications (including stillbirth); it has been commonly assumed that type A1 gestational diabetes confers similar risks. However, 2 observational studies call this assumption into question. One study evaluated antepartum predictors of fetal distress requiring a cesarean delivery among 2134 pregnant women with gestational diabetes.⁴ Antepartum surveillance consisted of biweekly nonstress testing with amniotic fluid index determination starting at 34 weeks gestation. Of the 1501 eligible participants, the study included 810 and 580 class A1 and A2 patients, respectively; the remaining 111 were classes B–T. They considered women with A1 gestational diabetes with fasting plasma glucose levels <105 mg/dL to be well-controlled. Results of antepartum surveillance did not significantly differ among the different diabetic classes.

In univariate and multivariate analyses, the greatest indicator for cesarean section due to fetal distress was a nonreactive non-stress test with decelerations (odds ratio [OR]=5.63; 95% confidence interval [CI], 2.67–11.9). Routine amniotic fluid measurement was not significantly related to either the classification of diabetes or to cesarean delivery for fetal distress. No patients with normal surveillance testing within 4 days of delivery had a stillbirth. However, all 5 stillbirths in the study population occurred among those with A2 diabetes whose last non-stress test was >4 days prior.

An earlier retrospective study followed 97 pregnant patients with gestational diabetes, 69 of whom were diet-controlled (class A1, fasting glucose <105 mg/dL).⁵ Antepartum surveillance consisted of maternal monitoring and non-stress testing. At 28 weeks, pregnant patients assessed daily fetal activity; reassuring fetal well-being was defined as 10 fetal movements in a 12-hour period. At 40 weeks, a non-stress test was performed weekly. Contraction stress testing was performed for those with nonreactive non-stress tests. To observe for macrosomia, serial ultrasonography was performed every 4 to 6 weeks, starting at 28 weeks. Forty-four patients (64%) had spontaneous labors without intervention, while the rest required induction of labor or cesarean section (primary or failed induction). Five patients had primary cesarean section for suspected macrosomia, 3 patients had intervention for suspected intrauterine growth restriction, and only 4 (5.7%) patients were delivered due to fetal indications, defined as decreased fetal movement or a nonreactive nonstress test. No stillbirths or neonatal deaths occurred. Perinatal complications included hypoglycemia (n=13; 19%), hyperbilirubinemia (n=12; 17%), and macrosomia (n=11; 16%). The study did not compare complication rates between diet-controlled and insulin-requiring patients (SOR: B, retrospective study).

A Cochrane review found no evidence for or against increased surveillance in A1 gestational diabetes: “A lack of conclusive evidence has lead clinicians to equate the risk of adverse perinatal outcome with pre-existing diabetes. Consequently women are often managed with increased obstetrical monitoring, dietary regulation, and [pharmacological] treatment. However, no sound evidence base supports such intensive treatment.”⁶

TABLE
At least 2 of 4 measurements over 3 hours must be higher than these values to diagnose gestational diabetes mellitus

TABLE
White’s classification for gestational diabetes mellitus

Recommendations from others

The American College of Obstetricians and Gynecologists’ practice bulletin on gestational diabetes states that there is no consensus regarding fetal surveillance for women with diet-controlled gestational diabetes. However, local practice may include non-stress and contraction stress testing, amniotic fluid determination, and biophysical profile; this may start as early as 32 weeks to or as late as 40 weeks, based upon the total cumulative risk to the fetus from all potential complications.² The American Diabetes Association states that increased fetal surveillance is appropriate but is not any more specific with this recommendation.¹

Evidence summary

Gestational diabetes mellitus is diagnosed when at least 2 of 4 values measured in a 3-hour glucose tolerance test are elevated; 2 different definitions of “elevated” are accepted (TABLE 1). White’s classification stratifies the risk of various types of diabetes during pregnancy (TABLE 2): Class A includes patients without a diagnosis of diabetes before pregnancy; classes B, C, and D include patients with pre-existing diabetes of increasing duration; and classes F, H, R, and T include patients with diabetes with various vascular complications.

Infants of mothers with pre-existing diabetes are at increased risk of pre- and neonatal complications (including stillbirth); it has been commonly assumed that type A1 gestational diabetes confers similar risks. However, 2 observational studies call this assumption into question. One study evaluated antepartum predictors of fetal distress requiring a cesarean delivery among 2134 pregnant women with gestational diabetes.⁴ Antepartum surveillance consisted of biweekly nonstress testing with amniotic fluid index determination starting at 34 weeks gestation. Of the 1501 eligible participants, the study included 810 and 580 class A1 and A2 patients, respectively; the remaining 111 were classes B–T. They considered women with A1 gestational diabetes with fasting plasma glucose levels <105 mg/dL to be well-controlled. Results of antepartum surveillance did not significantly differ among the different diabetic classes.

In univariate and multivariate analyses, the greatest indicator for cesarean section due to fetal distress was a nonreactive non-stress test with decelerations (odds ratio [OR]=5.63; 95% confidence interval [CI], 2.67–11.9). Routine amniotic fluid measurement was not significantly related to either the classification of diabetes or to cesarean delivery for fetal distress. No patients with normal surveillance testing within 4 days of delivery had a stillbirth. However, all 5 stillbirths in the study population occurred among those with A2 diabetes whose last non-stress test was >4 days prior.

An earlier retrospective study followed 97 pregnant patients with gestational diabetes, 69 of whom were diet-controlled (class A1, fasting glucose <105 mg/dL).⁵ Antepartum surveillance consisted of maternal monitoring and non-stress testing. At 28 weeks, pregnant patients assessed daily fetal activity; reassuring fetal well-being was defined as 10 fetal movements in a 12-hour period. At 40 weeks, a non-stress test was performed weekly. Contraction stress testing was performed for those with nonreactive non-stress tests. To observe for macrosomia, serial ultrasonography was performed every 4 to 6 weeks, starting at 28 weeks. Forty-four patients (64%) had spontaneous labors without intervention, while the rest required induction of labor or cesarean section (primary or failed induction). Five patients had primary cesarean section for suspected macrosomia, 3 patients had intervention for suspected intrauterine growth restriction, and only 4 (5.7%) patients were delivered due to fetal indications, defined as decreased fetal movement or a nonreactive nonstress test. No stillbirths or neonatal deaths occurred. Perinatal complications included hypoglycemia (n=13; 19%), hyperbilirubinemia (n=12; 17%), and macrosomia (n=11; 16%). The study did not compare complication rates between diet-controlled and insulin-requiring patients (SOR: B, retrospective study).

A Cochrane review found no evidence for or against increased surveillance in A1 gestational diabetes: “A lack of conclusive evidence has lead clinicians to equate the risk of adverse perinatal outcome with pre-existing diabetes. Consequently women are often managed with increased obstetrical monitoring, dietary regulation, and [pharmacological] treatment. However, no sound evidence base supports such intensive treatment.”⁶

TABLE
At least 2 of 4 measurements over 3 hours must be higher than these values to diagnose gestational diabetes mellitus

TABLE
White’s classification for gestational diabetes mellitus

Recommendations from others

The American College of Obstetricians and Gynecologists’ practice bulletin on gestational diabetes states that there is no consensus regarding fetal surveillance for women with diet-controlled gestational diabetes. However, local practice may include non-stress and contraction stress testing, amniotic fluid determination, and biophysical profile; this may start as early as 32 weeks to or as late as 40 weeks, based upon the total cumulative risk to the fetus from all potential complications.² The American Diabetes Association states that increased fetal surveillance is appropriate but is not any more specific with this recommendation.¹

Evidence summary

Gestational diabetes mellitus is diagnosed when at least 2 of 4 values measured in a 3-hour glucose tolerance test are elevated; 2 different definitions of “elevated” are accepted (TABLE 1). White’s classification stratifies the risk of various types of diabetes during pregnancy (TABLE 2): Class A includes patients without a diagnosis of diabetes before pregnancy; classes B, C, and D include patients with pre-existing diabetes of increasing duration; and classes F, H, R, and T include patients with diabetes with various vascular complications.

Infants of mothers with pre-existing diabetes are at increased risk of pre- and neonatal complications (including stillbirth); it has been commonly assumed that type A1 gestational diabetes confers similar risks. However, 2 observational studies call this assumption into question. One study evaluated antepartum predictors of fetal distress requiring a cesarean delivery among 2134 pregnant women with gestational diabetes.⁴ Antepartum surveillance consisted of biweekly nonstress testing with amniotic fluid index determination starting at 34 weeks gestation. Of the 1501 eligible participants, the study included 810 and 580 class A1 and A2 patients, respectively; the remaining 111 were classes B–T. They considered women with A1 gestational diabetes with fasting plasma glucose levels <105 mg/dL to be well-controlled. Results of antepartum surveillance did not significantly differ among the different diabetic classes.

In univariate and multivariate analyses, the greatest indicator for cesarean section due to fetal distress was a nonreactive non-stress test with decelerations (odds ratio [OR]=5.63; 95% confidence interval [CI], 2.67–11.9). Routine amniotic fluid measurement was not significantly related to either the classification of diabetes or to cesarean delivery for fetal distress. No patients with normal surveillance testing within 4 days of delivery had a stillbirth. However, all 5 stillbirths in the study population occurred among those with A2 diabetes whose last non-stress test was >4 days prior.

An earlier retrospective study followed 97 pregnant patients with gestational diabetes, 69 of whom were diet-controlled (class A1, fasting glucose <105 mg/dL).⁵ Antepartum surveillance consisted of maternal monitoring and non-stress testing. At 28 weeks, pregnant patients assessed daily fetal activity; reassuring fetal well-being was defined as 10 fetal movements in a 12-hour period. At 40 weeks, a non-stress test was performed weekly. Contraction stress testing was performed for those with nonreactive non-stress tests. To observe for macrosomia, serial ultrasonography was performed every 4 to 6 weeks, starting at 28 weeks. Forty-four patients (64%) had spontaneous labors without intervention, while the rest required induction of labor or cesarean section (primary or failed induction). Five patients had primary cesarean section for suspected macrosomia, 3 patients had intervention for suspected intrauterine growth restriction, and only 4 (5.7%) patients were delivered due to fetal indications, defined as decreased fetal movement or a nonreactive nonstress test. No stillbirths or neonatal deaths occurred. Perinatal complications included hypoglycemia (n=13; 19%), hyperbilirubinemia (n=12; 17%), and macrosomia (n=11; 16%). The study did not compare complication rates between diet-controlled and insulin-requiring patients (SOR: B, retrospective study).

A Cochrane review found no evidence for or against increased surveillance in A1 gestational diabetes: “A lack of conclusive evidence has lead clinicians to equate the risk of adverse perinatal outcome with pre-existing diabetes. Consequently women are often managed with increased obstetrical monitoring, dietary regulation, and [pharmacological] treatment. However, no sound evidence base supports such intensive treatment.”⁶

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At least 2 of 4 measurements over 3 hours must be higher than these values to diagnose gestational diabetes mellitus

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White’s classification for gestational diabetes mellitus

Recommendations from others

The American College of Obstetricians and Gynecologists’ practice bulletin on gestational diabetes states that there is no consensus regarding fetal surveillance for women with diet-controlled gestational diabetes. However, local practice may include non-stress and contraction stress testing, amniotic fluid determination, and biophysical profile; this may start as early as 32 weeks to or as late as 40 weeks, based upon the total cumulative risk to the fetus from all potential complications.² The American Diabetes Association states that increased fetal surveillance is appropriate but is not any more specific with this recommendation.¹