Specialities

Specialities

Bone Disorders
Cardiovascular Risk
COVID-19
Diabetes
Endocrine Oncology
General Endocrinology
Obesity
Paediatric Endocrinology
Pituitary Disorders
Reproductive Endocrinology
Thyroid Disorders
Chronic Kidney Disease
Liver Disorders
Adrenal Disorders
Search

Trending Topic

Stastical analysis indication diabetes mellitus .generative ai
5 mins

Trending Topic
Developed by Touch
Mark CompleteCompleted
BookmarkBookmarked

Forty-four Years of the UK Prospective Diabetes Study: Legacy Effect and Beyond

Saptarshi Bhattacharya, Sanjay Kalra, Lakshmi Nagendra

Very few trials in the history of medical science have altered the treatment landscape as profoundly as the UK Prospective Diabetes Study (UKPDS). Even 44 years after its inception, the trial and post-study follow-up findings continue to fascinate and enlighten the medical community. The study was conceived at a time when there was uncertainty about […]

touchREVIEWS in Endocrinology. 2024;21(1):1–2:Online ahead of journal publication

Connect With Us:

Facebook
X (Twitter)
Instagram
Youtube
Linkedin
Diabetes
13 mins

Controversies in Gestational Diabetes

Chloe A Zera, Ellen W Seely
Share
Facebook
X (formerly Twitter)
LinkedIn
Via Email
Mark CompleteCompleted
BookmarkBookmarked
Copy LinkLink Copied
Download as PDF
Published Online: Aug 6th 2021 touchREVIEWS in Endocrinology. 2021;17(2):102–7 DOI: https://doi.org/10.17925/EE.2021.17.2.102
Select a Section…
1

Abstract

Overview

Gestational diabetes mellitus (GDM) complicates approximately 7% of pregnancies in the USA. Despite recognition of the benefits of diagnosing and treating GDM, there are several areas of controversy that remain unresolved. There is debate as to whether to screen for GDM with the one-step versus the two-step approach. While the former identifies more pregnancies with potential adverse outcomes, data are lacking as to whether treatment of these pregnancies will improve outcomes, while increasing costs by diagnosing more women. Though it is well established that the diagnosis of even mild GDM, and treatment with lifestyle recommendations and insulin, improves pregnancy outcomes, it is controversial as to which type and regimen of insulin is optimal, and whether oral agents can be used safely and effectively to control glucose levels. Finally, it is recommended that women with GDM get tested for type 2 diabetes within several months of delivery; however, many women do not undergo this testing and alternative approaches are needed. These controversies are discussed with data from both sides of the debate to enable clinicians to make patient-centered decisions until more definitive data are available.

Keywords

Gestational diabetes mellitus, screening, treatment, insulin, metformin, glyburide

2

Article

Gestational diabetes mellitus (GDM), defined as hyperglycaemia identified after the first trimester of pregnancy that is not clearly overt diabetes, impacts approximately 7% of births in the USA; a percentage that has increased in parallel with the prevalence of both obesity and type 2 diabetes over the past 20 years.14 The impacts of GDM include hypertensive disorders of pregnancy, abnormal fetal growth and associated difficulties with delivery, as well as longer-term maternal and offspring morbidity.5–11

In the USA, there are significant gaps between the recommended care during and after pregnancy, and what patients actually receive. While it is difficult to estimate the percentage of patients that have morbidity attributable to uncontrolled GDM, the estimated cost of each case of GDM in pregnancy is nearly $5,800, some of which is potentially preventable with good treatment (such as the costs associated with newborn admission to the neonatal intensive care unit, inpatient and emergency department utilization).12,13 There are also well-documented gaps between what is recommended after pregnancy and what actually occurs. As an example, because a substantial proportion of women with GDM will progress to type 2 diabetes after pregnancy, screening for type 2 diabetes is both indicated and recommended.14 Nonetheless, fewer than 40% of patients are screened after pregnancy.15,16 What is at the root of the gap between what is known and what is currently being achieved for patients?

One contributor to the variability in care for GDM may be the lack of clinical consensus that is evident in differing professional society guidelines.1,17–19 While there is broad agreement that providers should screen for GDM,20–22 there is no consensus on optimal screening, diagnostic criteria, treatment, or post-delivery screening. In this review, we will focus on these ongoing controversies. We will discuss screening for GDM in detail, including the benefits and drawbacks of one- and two-step strategies. We will also review treatment options, focusing on the literature for and against oral hypoglycaemic agents as alternative treatments to insulin. Finally, we will highlight limitations in current practice after delivery, with potential solutions, as well as novel approaches to screen for type 2 diabetes after pregnancy with GDM.

Identifying gestational diabetes

GDM is defined as “diabetes diagnosed in the second or third trimester of pregnancy that was not clearly overt diabetes prior to gestation.”1 While all professional organizations agree on this general definition, there is ongoing controversy regarding specific diagnostic strategies. Both one- and two-step testing strategies have been endorsed, with the World Health Organization (WHO), the International Association of Diabetes in Pregnancy Study Groups (IADPSG), and the American Diabetes Association (ADA) endorsing the use of a 75 g oral glucose tolerance test (OGTT) in the late second trimester as the preferred strategy.1,22,23 The American College of Obstetricians and Gynecologists (ACOG) continues to prefer a two-step strategy, recommending universal screening with 50 g glucose-loading test (GLT)followed by targeted diagnostic testing with 100 g OGTT (Table 1).1,18,22,23 Both one-and two-step strategies have benefits, as well as limitations.

Historically, GDM was defined by risk for long-term adverse maternal outcomes.24 Following several observational studies demonstrating foetal risks associated with varying degrees of glucose intolerance, there was broad agreement that GDM should be defined by glucose thresholds at which the risk for adverse outcomes would increase.25 There was also recognition that level 1 evidence supporting treatment of ‘mild’ GDM with lifestyle counseling and insulin was evident from two randomized controlled trials which used differing diagnostic criteria for study entry. 5,6 Crowther and colleagues studied more than 900 participants in Australia and New Zealand, including participants with GDM diagnosed with a 75 g OGTT at 24–34 weeks by WHO criteria.6 A similar study, performed in the USA, included nearly 900 participants in weeks 24–31 of gestation identified using two-step testing, first screened with 50 g GLT and then using a 100 g OGTT with the Carpenter–Coustan criteria to diagnose GDM.5,26 Both studies excluded participants with elevated fasting glucose or post-load glucose levels consistent with overt diabetes.

The Hyperglycemia and Adverse Pregnancy Outcomes (HAPO) study attempted to define glucose thresholds for adverse pregnancy outcomes.27 In this international, multicenter, observational study of more than 25,000 pregnant participants, investigators administered a 75 g OGTT between 24–32 weeks gestation and blinded clinicians to the results unless the participant was overtly hyperglycaemic (defined as fasting plasma glucose >105 mg/dL or 2-hour plasma glucose >200 mg/dL). The results demonstrated a linear association between maternal glycaemic levels with both maternal and foetal outcomes, leaving a clear diagnostic threshold for GDM uncertain. The IADPSG subsequently proposed diagnostic criteria for GDM based on the glycaemic thresholds that were associated with an increased odds of 1.75 for adverse outcomes, recommendations which were quickly endorsed by the ADA.23,28 The ACOG, however, continued to endorse a two-step strategy, based on concerns regarding the lack of data supporting intervention at these lower cut-offs, as well as healthcare delivery implications of diagnosing more cases of GDM, concerns that were validated and ultimately echoed by the National Institutes of Health (NIH) after a 2013 consensus conference, when it was concluded that there was “insufficient evidence to adopt a one-step approach.”18,29 It is important to note that while GDM prevalence varies across populations, there are consistently more patients identified with a one-step IADPSG testing strategy than with a two-step strategy, in some populations increasing the absolute incidence more than threefold.30,31

Proponents of one-step testing note that two-step testing misses a group of patients who are only identified by using a 75 g OGTT with the IADPSG thresholds and are at similar risk for adverse pregnancy outcomes as those diagnosed using the two-step method.32 A cost-effectiveness analysis estimated that adoption of universal screening using IADPSG thresholds would prevent 85 cases of shoulder dystocia, 262 cases of pre-eclampsia, and 688 cases of future diabetes for every 100,000 pregnancies that were screened.33 Screening and diagnosis can be universally implemented using a one-step approach, avoiding incomplete assessment after abnormal 50 g GLT, and expediting treatment. Those who adopted one-step testing strategies also cite broad acceptance by patients, some of whom prefer a test that is less than 3 hours.34 Of note, the majority of health systems that adopted the IADPSG guidelines are outside the USA.31

Following the NIH consensus conference, obstetric providers in the USA largely continued two-step screening and diagnosis, or returned to this strategy.1,18,29 Arguments for continuing the two-step approach are primarily centered on healthcare delivery considerations. The 50 g GLT can be administered regardless of oral intake prior to visit, while the one-step 75 g OGTT must be administered after a fast; an estimated 15% of women in the USA have inadequate prenatal care, highlighting the need for a test that can be administered at any visit.35 The impact of GDM diagnosis is also not entirely beneficial. While treatment at Carpenter–Coustan thresholds did not change the rate of caesarean delivery in a randomized controlled trial setting, observational data comparing caesarean delivery rates in patients with GDM diagnosed at differing thresholds in a single institution suggest that just the diagnosis of GDM may be associated with morbidity in real-world settings.5,36 There is a substantial burden of diagnosis and treatment to patients, with pain and social isolation identified as themes in qualitative studies.37–39 Finally, the cost of additional cases is significant; universal screening with a one-step strategy utilizing the IADPSG thresholds costs an estimated $20,336 per quality-adjusted life year gained, and is cost effective only when post-delivery care reduces the incidence of type 2 diabetes.33

Therefore, while there is agreement that treatment of GDM has benefits, the lack of a clear threshold for increased risk of adverse pregnancy outcomes, the lack of level 1 evidence supporting treatment at IADPSG thresholds, and the need to balance the additional diagnoses of GDM at IADPSG thresholds with the burden of diagnosis to both patients and the healthcare system, has left providers without consensus guidelines. A recent study compared pregnancy outcomes in over 20,000 pregnant women randomized to diagnosis of GDM by a one-step approach and criteria versus diagnosis by a two-step approach and criteria. This study showed no difference in pregnancy outcomes of the one-step versus the two-step groups, despite about twice as many more women receiving a diagnosis of GDM when the former was used.40 It is too soon to tell if this study will lead to greater consensus in the approach to the diagnosis of GDM.

Treating gestational diabetes

Insulin remains the pharmacologic agent of first choice to treat hyperglycaemia in women with GDM, as recommended by the ADA, ACOG, and Diabetes Canada, when lifestyle changes fail to achieve glycaemic goals.18,41,42 These recommendations are based on the two trials that established the value of treating mild GDM to improve perinatal outcomes using insulin when lifestyle changes were insufficient to achieve optimal glycaemic control.5,6 Insulin does not cross the placenta and has been used during pregnancy for decades without adverse effects on the neonate/offspring.17,41,43–45 Insulin analogs (including aspart, lispro, detemir, and glargine) have also been used safely in pregnancy, and they are now used more frequently in pregnant women with diabetes than human insulin.4649 Insulin pumps have been safely used in GDM, but are rarely needed in this population.50 To date, there are no head-to-head studies demonstrating the superiority of one insulin regimen or type of insulin over another.51 Some concern has been raised about the use of glargine, which has increased affinity for the insulin-like growth factor (IGF)-1 receptor and increased mitogenicity when compared with other insulins, and therefore might be associated with greater risk of large for gestational age birthweight.52 However, several studies, including a systematic review and meta-analysis, have not supported this concern.53–56

Controversy regarding optimal insulin type or regimen results from a lack of powered head-to-head studies comparing insulin type and insulin regimen. At present, given that the data on insulin analogues support their effectiveness and safety, the type of insulin and regimen used will depend on the ordering clinician and the individual patient, with the goal of achieving optimal glucose goals for pregnancy.

There has been great interest in whether oral medications that reduce glucose levels could be used safely and effectively in women with GDM to avoid the need for insulin injections. The two oral agents used most commonly in the treatment of GDM are metformin and glyburide. In a study of medications for diabetes that looked at initiation in late pregnancy (a surrogate for GDM diagnosis), insulin was the most commonly prescribed drug in international prescription databases derived from seven countries and three continents, but metformin use grew over time. During the study period from 2006 to 2016, metformin was the most common alternative to insulin in every country but the USA, where glyburide was more commonly prescribed as an alternative to insulin.48 A study of USA commercial pharmacy claims in women with GDM found that from 2000 to 2011, glyburide use increased from 7% to 65%, surpassing insulin as the most common treatment as of 2007.57 Large, multicenter, randomized trials have demonstrated that metformin, but not glyburide, is non-inferior to insulin for pregnancy outcomes.58,59 Because of concerns for both the efficacy of and potential for long-term impact on children exposed in utero, insulin remains the recommended first-line agent for many organizations.17,18,42 Others recommend metformin, recognizing that not all women with GDM who need pharmacologic therapy will be able, or willing, to use insulin.19

Metformin

Metformin is a biguanide and decreases hepatic glucose production and promotes glucose uptake by peripheral tissues.60,61 The mechanisms of action in lowering blood glucose remains incompletely understood, but it is one of the few agents used to lower blood glucoses that does not cause hypoglycaemia. Metformin is not recommended for use in individuals with renal or hepatic impairment, due to concern for accumulation leading to lactic acidosis, which is a rare complication, but accordingly, the ADA cautions that metformin should not be used in women with placental insufficiency in such conditions as hypertension, pre-eclampsia, or at risk for intrauterine growth restriction.17,61 Metformin crosses the placenta, with levels in the foetal circulation similar to maternal levels at delivery.62,63 Nonetheless, because of the maternal safety profile, as well as its low cost, the use of metformin in GDM is increasing.

In the Metformin in GDM (MiG) trial, a multicenter study performed in New Zealand and Australia, 751 women with GDM diagnosed by 75 g OGTT who needed pharmacologic treatment between 20 and 33 weeks + 6 days gestation were randomized to insulin or metformin starting at 500 mg, titrated to a maximal dose of 2,500 mg daily.58 The primary outcome, a composite of neonatal complications, was similar in both treatment groups, although 46% of the participants in the metformin group required the addition of insulin to reach glycaemic goals. Participants in the metformin group experienced less hypoglycaemia and gained less weight (0.4 ± 2.9 kg versus 2.0 ± 3.3 kg; p<0.001) over the course of pregnancy than those on insulin. The rate of preterm birth before 37 weeks’ gestation was nearly twofold higher in the metformin group compared with the insulin group (12.1% versus 7.6%; p=0.04), driven primarily by spontaneous, not indicated, preterm delivery. The mechanism by which metformin might lead to spontaneous preterm delivery is not known.

Several meta-analyses have subsequently compared metformin to insulin. Rates of macrosomia were reported to be similar or lower with metformin, with lower rates of neonatal hypoglycaemia than insulin.64,65 In addition, metformin use has been associated with less maternal weight gain and lower risk for preeclampsia than insulin.64,66 As seen in the MiG trial, there was a higher risk for spontaneous preterm birth with metformin than insulin.64,66

A limited number of infants exposed to metformin for treatment of GDM have now been followed up to 9 years of age.67,68 At 7 years of age, there were no differences in body composition or metabolic measures in the offspring of mothers treated with metformin versus insulin. However, at 9 years of age, the metformin-exposed offspring had significantly higher weight, body mass index and waist circumference than those exposed only to insulin.68 Longitudinal studies are ongoing, with concern for adverse metabolic findings in the offspring informing recommendations regarding the use of metformin for the treatment of GDM.69

Glyburide

Glyburide, also called glibenclamide, is a second-generation sulfonylurea which lowers glucose levels by stimulation of insulin release by the beta cells in the pancreas.70 Both ACOG and ADA recognize glyburide as an alternative medication for women who cannot, or will not, use insulin and cannot tolerate metformin.17,18

In a large, multicenter, randomized trial performed in France, 914 women with GDM diagnosed by one-step testing were randomized to glyburide (starting at 2.5 mg, titrated up to 20 mg/day as needed) or insulin analogue (starting at 4 U/day, up to 20 U/day) with intermediate-acting insulin as needed, in a non-inferiority study.59 The primary endpoint, which was a composite neonatal outcome that included macrosomia, neonatal hypoglycaemia, and hyperbilirubinaemia, did not differ between the two groups. However, neonatal hypoglycaemia was more common in infants whose mothers were randomized to glyburide than in those who were randomized to insulin (12.2 % versus 7.2%; 95% confidence interval [CI] 0.5–9.5%; p=0.02). As a result, the study concluded that glyburide did not demonstrate non-inferiority to insulin for the treatment of GDM. Additionally, both efficacy and safety were not equivalent; 18% of the women randomized to glyburide had to crossover to insulin after failure to achieve glycaemic control, and maternal hypoglycaemia was more common in the glyburide group than in the insulin group (28.8% versus 3.5%; p<0.001).

Several meta-analyses support the findings of the French trial, including higher risk for both macrosomia and neonatal hypoglycaemia with glyburide or glibenclamide than with insulin.64,66,71 Unlike metformin, longitudinal follow-up data in offspring of pregnancies exposed to glyburide have not been reported. To date, there are no large multicenter randomized trials of metformin versus glyburide that are adequately powered to demonstrate a difference or non-inferiority on pregnancy outcomes in the treatment of GDM. Similar to findings when compared with insulin, both small studies and meta-analyses have demonstrated higher rates of maternal hypoglycaemia and fetal macrosomia associated with glyburide or glibenclamide than with metformin.65,71,72 These studies have also demonstrated less maternal weight gain associated with metformin than with glyburide.65,66,71,73 A major limitation of both agents is the failure to achieve glycaemic control in many women with GDM.74

Other oral hypoglycaemic agents

There are other classes of agents which lower glucose levels and have been approved for use in type 2 diabetes, including dipeptidyl peptidase-4 inhibitors, glucagon-like peptide 1 agonists, and
sodium–glucose cotransporter 2 inhibitors.41 These agents have effects on many organ systems and have not been studied in pregnancy; therefore, they should not be used for the treatment of GDM. In patients with type 2 diabetes outside of pregnancy, the potential benefit of these therapies to reduce the incidence of cardiovascular and renal comorbidities of diabetes guides choice of therapy. These long-term considerations relevant for ongoing management of diabetes do not apply to GDM, in which the benefits of treatment are limited to improving pregnancy outcomes and avoiding adverse offspring effects.

Professional society recommendations for medications to treat gestational diabetes

Based on available data, several professional societies have made recommendations for the treatment of GDM; however, there are differences in approach across organizations, stemming from the ongoing controversy surrounding the efficacy and safety of oral agents (Table 2).1719,21,41 The ACOG, ADA, and Diabetes Canada all recommend insulin as the first-line agent, based on data supporting the ability to achieve glycaemic control and improve pregnancy outcomes, the long history of use without report of adverse offspring effects, and lack of placental transfer.17,18,42 The Society for Maternal-Fetal Medicine (SMFM) recommends that metformin also be considered as a first-line agent for the treatment of GDM.19 Following the SMFM guidelines in particular, a cautionary response from a group of GDM experts highlighted the lack of long-term offspring follow-up data after metformin exposure in utero.69 The National Institute for Health and Care Excellence in the UK recommends metformin as a first-line agent only in the setting of mild fasting hyperglycaemia, with insulin for more severe hyperglycaemia or in the event of obstetric complications.21 Diabetes Canada recommends metformin as an alternative first-line agent, but makes note of the lack of long-term offspring follow-up.41 Other societies recommend metformin only when a patient is unable or unwilling to take insulin.17,18

Screening for type 2 diabetes after pregnancy with gestational diabetes

Women with GDM are at high risk for diabetes, particularly in the first several years following pregnancy.14 The ADA and ACOG recommend diabetes screening at 4–12 weeks postpartum, with repeat screening every 1–3 years thereafter depending on results.17,18 In clinical practice, screening rates are poor. Several groups have identified this gap after pregnancy; despite standardized recommendations for postpartum screening, a recent meta-analysis concluded that fewer than 40% of patients are screened within the recommended time frame, with no change in rates at 6 months or 1 year after pregnancy affected by GDM.16 There have been attempts to mitigate provider barriers to screening, which include fragmented maternal care after delivery; solving the problem will require multi-pronged approaches.7579

Given the suboptimal rates of screening for diabetes after pregnancy complicated by GDM, there is controversy over which test should be performed postpartum, as well as the timing of the testing. Currently, the ADA recommends testing of women with recent GDM with a 75 g OGTT at 4–12 weeks postpartum.17 On the other hand, ACOG recommends either a fasting blood glucose or a 75 g OGTT at 4–12 weeks postpartum, recognizing that a fasting glucose is easier to complete, but that the OGTT provides more information.18 Diabetes Canada recommends a 75 g OGTT after pregnancy, as late as 6 months postpartum.42 There is consensus that although glycated haemoglobin (HbA1c) may identify some women with overt diabetes, it is an insufficient test for postpartum screening.17,18

One strategy to improve screening rates is to test immediately after pregnancy, during the delivery hospitalization. This timing may be important particularly in the USA, where as many as 40% of women do not attend a postpartum visit.80 Several groups have investigated whether screening during the delivery hospitalization might identify patients at highest risk for type 2 diabetes in the postpartum period, and thereby improve efforts to target lifestyle modification.81,82 A combined patient-level analysis of four studies with a total of 319 participants compared results of a 75 g OGTT during delivery hospitalization with results at 4–12 weeks postpartum.83 While only 52% of study subjects returned for follow-up testing, in those who did return, none of the participants with normal initial testing went on to be diagnosed with type 2 diabetes at the postpartum visit. In-hospital glucose testing had 50.0% sensitivity (95% CI 11.8–88.2%) and 95.7% specificity (95% CI 91.3–98.2%), with 98.1% negative predictive value (95% CI 94.5–99.6%). Taken together, these results suggest that in-hospital testing with 75 g OGTT after delivery has the potential for risk stratification, helping to identify those at lowest risk for type 2 diabetes in the immediate postpartum period.

There is broad recognition that a diagnosis of GDM represents a window of opportunity to target interventions aimed at reducing long-term risk for diabetes.8,84,85 Future work should focus on implementation strategies, including local process improvements to achieve optimal rates of postpartum screening.

Conclusions

GDM is one of the most common complications of pregnancy and confers lifelong risks to both women and their children. Nonetheless, there remains a lack of consensus on the best strategies to improve both short- and long-term outcomes. Because rigorous observational data demonstrate a linear association between maternal glycaemic parameters and risks for adverse pregnancy and offspring outcomes, the diagnostic criteria remain controversial. Treatment with insulin is effective, but costs and patient experiences limit use in clinical practice. Glyburide has drawbacks, including both efficacy and safety. While metformin is increasingly used for many indications in reproductive-aged women, use as a first-line agent for GDM remains controversial due to transplacental passage and limited long-term follow-up data. Finally, new approaches are needed for screening for type 2 diabetes after pregnancy to leverage the window of opportunity presented by pregnancy. Future work in the field should include studies of both clinical and implementation outcomes, examining strategies to improve the quality of care delivered to women with GDM.

2

References

  1. American Diabetes Association. 2. Classification and diagnosis of diabetes: Standards of medical care in diabetes-2020. Diabetes Care. 2020;43(Suppl. 1):S14–31.
  2. Bardenheier BH, Elixhauser A, Imperatore G, et al. Variation in prevalence of gestational diabetes mellitus among hospital discharges for obstetric delivery across 23 states in the United States. Diabetes Care. 2013;36:1209–14.
  3. Hales CM, Carroll MD, Fryar CD, Ogden CL. Prevalence of obesity and severe obesity among adults: United States, 2017–2018. NCHS Data Brief. 2020;(360):1–8.
  4. Centers for Disease Control and Prevention. National Diabetes Statistics Report 2020. Available at: cdc.gov/diabetes/data/statistics-report/index.html(accessed 22 March 2021).
  5. Landon MB, Spong CY, Thom E, et al. A multicenter, randomized trial of treatment for mild gestational diabetes. N Engl J Med. 2009;361:1339–48.
  6. Crowther CA, Hiller JE, Moss JR, Effect of treatment of gestational diabetes mellitus on pregnancy outcomes. N Engl J Med. 2005;352:2477–86.
  7. Lowe WL, Scholtens DM, Lowe LP, et al. Association of gestational diabetes with maternal disorders of glucose metabolism and childhood adiposity. JAMA. 2018;320:1005–16.
  8. Ratner RE, Christophi CA, Metzger BE, et al. Prevention of diabetes in women with a history of gestational diabetes: Effects of metformin and lifestyle interventions. J Clin Endocrinol Metab2008;93:4774–9.
  9. Gomes D, von Kries R, Delius M, et al. Late-pregnancy dysglycemia in obese pregnancies after negative testing for gestational diabetes and risk of future childhood overweight: An interim analysis from a longitudinal mother–child cohort study. PLoS Med. 2018;15:e1002681.
  10. Josefson JL, Catalano PM, Lowe WL, et al. The Joint Associations of Maternal BMI and Glycemia with Childhood Adiposity. J Clin Endocrinol Metab. 2020;105:2177–88.
  11. Dabelea D, Hanson RL, Lindsay RS, et al. Intrauterine exposure to diabetes conveys risks for type 2 diabetes and obesity: A study of discordant sibships. Diabetes. 2000;49:2208–11.
  12. Dall TM, Yang W, Gillespie K, et al. The economic burden of elevated blood glucose levels in 2017: Diagnosed and undiagnosed diabetes, gestational diabetes mellitus, and prediabetes. Diabetes Care2019;42:1661–8.
  13. American Diabetes Association. Economic costs of diabetes in the U.S. in 2017. Diabetes Care. 2018;41:917–28.
  14. Kim C, Newton KM, Knopp RH. Gestational diabetes and the incidence of type 2 diabetes: A systematic review. Diabetes Care2002;25:1862–8.
  15. Eggleston EM, Lecates RF, Zhang F, et al. Variation in postpartum glycemic screening in women with a history of gestational diabetes mellitus. Obstet Gynecol. 2016;128:159–67.
  16. Carson MP, Frank MI, Keely E. Original research: Postpartum testing rates among women with a history of gestational diabetes–systematic review. Prim Care Diabetes.2013;7:177–86.
  17. American Diabetes Association. 14. Management of diabetes in pregnancy: Standards of medical care in diabetes-2020. Diabetes Care.2020;43(Suppl. 1):S183–92.
  18. ACOG Practice Bulletin No. 190: Gestational diabetes mellitus. Obstet Gynecol2018;131:e49–64.
  19. Society of Maternal-Fetal Medicine Publications Committee. SMFM Statement: Pharmacological treatment of gestational diabetes. Am J Obstet Gynecol.2018;218:B2– 4.
  20. Hartling L, Dryden DM, Guthrie A, et al. Benefits and harms of treating gestational diabetes mellitus: A systematic review and meta-analysis for the U.S. Preventive Services Task Force and the National Institutes of Health Office of Medical Applications of Research. Ann Intern Med. 2013;159:123–9.
  21. National Institute for Health and Care Excellence. Diabetes in pregnancy: Management from preconception to the postnatal period. 2015. Available at: www.nice.org.uk/guidance/ng3 (accessed 22 March 2021).
  22. World Health Organization. Diagnostic criteria and classification of hyperglycaemia first detected in pregnancy. 2013. Available at: https://apps.who.int/iris/handle/10665/85975(accessed 27 April 2021).
  23. International Association of Diabetes and Pregnancy Study Groups Consensus Panel, Metzger BE, Gabbe SG, et al. International association of diabetes and pregnancy
    study groups recommendations on the diagnosis and classification of hyperglycemia in pregnancy. Diabetes Care. 2010;33:676–82.
  24. O’Sullivan JB, Mahan CM. Criteria for the oral glucose tolerance test in pregnancy. Diabetes. 1964;13:278–85.
  25. Metzger BE, Buchanan TA, Coustan DR, et al. Summary and recommendations of the Fifth International Workshop-Conference on Gestational Diabetes Mellitus. Diabetes Care. 2007;30(Suppl. 2):S251–60.
  26. Carpenter MW, Coustan DR. Criteria for screening tests for gestational diabetes. Am J Obstet Gynecol.1982;144:768–73.
  27. HAPO Study Cooperative Research Group. Hyperglycemia and Adverse Pregnancy Outcome (HAPO) Study: Associations with neonatal anthropometrics. Diabetes. 2009;58:453–9.
  28. American Diabetes Association. 2. Classification and Diagnosis of Diabetes: Standards of Medical Care in Diabetes-2019. Diabetes Care. 2019;42(Suppl. 1):S13–28.
  29. Vandorsten JP, Dodson WC, Espeland MA, et al. NIH consensus development conference: Diagnosing gestational diabetes mellitus. NIH Consens State Sci Statements2013;29:1–31.
  30. Sacks DA, Hadden DR, Maresh M, et al. Frequency of gestational diabetes mellitus at collaborating centers based on IADPSG consensus panel-recommended criteria: The Hyperglycemia and Adverse Pregnancy Outcome (HAPO) Study. Diabetes Care. 2012;35:526–8.
  31. Brown FM, Wyckoff J. Application of one-step IADPSG versus two-step diagnostic criteria for gestational diabetes in the real world: Impact on health services, clinical care, and outcomes. Curr Diab Rep. 2017;17:85.
  32. Mayo K, Melamed N, Vandenberghe H, Berger H. The impact of adoption of the International Association of Diabetes in Pregnancy Study Group criteria for the screening and diagnosis of gestational diabetes. Am J Obstet Gynecol2015;212:224.e1–9.
  33. Werner EF, Pettker CM, Zuckerwise L, et al. Screening for gestational diabetes mellitus: Are the criteria proposed by the International Association of the Diabetes and Pregnancy Study Groups cost-effective? Diabetes Care. 2012;35:529–35.
  34. Berghella V, Caissutti C, Saccone G, Khalifeh A. The one step approach for diagnosing gestational diabetes is associated with better perinatal outcomes than the two step approach: Evidence of randomized clinical trials. Am J Obstet Gynecol2019;220:562–4.
  35. Osterman MJK, Martin JA. Timing and adequacy of prenatal care in the United States, 2016. Natl Vital Stat Rep. 2018;67:1–14.
  36. Palatnik A, Swanson K, Churchill T, et al. Association between type of screening for gestational diabetes mellitus and cesarean delivery. Obstet Gynecol.2017;130:539–44.
  37. Craig L, Sims R, Glasziou P, Thomas R. Women’s experiences of a diagnosis of gestational diabetes mellitus: A systematic review. BMC Pregnancy Childbirth. 2020;20:76.
  38. Devsam BU, Bogossian FE, Peacock AS. An interpretive review of women’s experiences of gestational diabetes mellitus: Proposing a framework to enhance midwifery assessment. Women Birth. 2013;26:e69–76.
  39. Kaptein S, Evans M, McTavish S, et al. The subjective impact of a diagnosis of gestational diabetes among ethnically diverse pregnant women: A qualitative study. Can J Diabetes. 2015;39:117–22.
  40. Hillier TA, Pedula KL, Ogasawara KK, et al. A pragmatic, randomized clinical trial of gestational diabetes screening. N Engl J Med. 2021;384:895–904.
  41. American Diabetes Association. 9. Pharmacologic approaches to glycemic treatment: Standards of medical care in diabetes-2020. Diabetes Care. 2020;43:S98–110.
  42. Diabetes Canada Clinical Practice Guidelines Expert Committee, Feig DS, Berger H, et al. Diabetes and pregnancy. Can J Diabetes. 2018;42(Suppl. 1):S255–82.
  43. Suffecool K, Rosenn B, Niederkofler EE, et al. Insulin detemir does not cross the human placenta. Diabetes Care.2015;38:e20–1.
  44. Pollex EK, Feig DS, Lubetsky A, et al. Insulin glargine safety in pregnancy: A transplacental transfer study. Diabetes Care2010;33:29–33.
  45. Boskovic R, Feig DS, Derewlany L, et al. Transfer of insulin lispro across the human placenta: In vitro perfusion studies. Diabetes Care. 2003;26:1390–4.
  46. Lv SS, Wang JY, Xu Y. Safety of insulin analogs during pregnancy: A meta-analysis. Arch Gynecol Obstet.2015;292:749–56.
  47. Lepercq J, Lin J, Hall GC, et al. Meta-analysis of maternal and neonatal outcomes associated with the use of insulin glargine versus NPH insulin during pregnancy. Obstet Gynecol Int. 2012;2012:649070.
  48. Cesta CE, Cohen JM, Pazzagli L, et al. Antidiabetic medication use during pregnancy: An international utilization study. BMJ Open Diabetes Res Care.2019;7:e000759.
  49. Charlton RA, Klungsøyr K, Neville AJ, et al. Prescribing of antidiabetic medicines before, during and after pregnancy: A study in seven European regions. PLoS One. 2016;11:e0155737.
  50. Simmons D, Thompson CF, Conroy C, Scott DJ. Use of insulin pumps in pregnancies complicated by type 2 diabetes and gestational diabetes in a multiethnic community. Diabetes Care. 2001;24:2078–82.
  51. O’Neill SM, Kenny LC, Khashan AS, et al. Different insulin types and regimens for pregnant women with pre-existing diabetes. Cochrane Database Syst Rev. 2017;2:CD011880.
  52. Kurtzhals P, Schäffer L, Sørensen A, et al. Correlations of receptor binding and metabolic and mitogenic potencies of insulin analogs designed for clinical use. Diabetes. 2000;49:999–1005.
  53. Pollex E, Moretti ME, Koren G, Feig DS. Safety of insulin glargine use in pregnancy: A systematic review and meta-analysis. Ann Pharmacother.2011;45:9–16.
  54. Bolli GB, Owens DR. Insulin glargine. Lancet. 2000;356:443–5.
  55. Egerman RS, Ramsey RD, Kao LW, et al. Perinatal outcomes in pregnancies managed with antenatal insulin glargine. Am J Perinatol. 2009;26:591–5.
  56. Pöyhönen-Alho M, Rönnemaa T, Saltevo J, et al. Use of insulin glargine during pregnancy. Acta Obstet Gynecol Scand. 2007;86:1171–4.
  57. Camelo Castillo W, Boggess K, Stürmer T, et al. Trends in glyburide compared with insulin use for gestational diabetes treatment in the United States, 2000-2011. Obstet Gynecol2014;123:1177–84.
  58. Rowan JA, Hague WM, Gao W, et al. Metformin versus insulin for the treatment of gestational diabetes. N Engl J Med. 2008;358:2003–15.
  59. Sénat MV, Affres H, Letourneau A, et al. Effect of glyburide vs subcutaneous insulin on perinatal complications among women with gestational diabetes a randomized clinical trial. JAMA. 2018;319:1773–80.
  60. Rena G, Hardie DG, Pearson ER. The mechanisms of action of metformin. Diabetologia. 2017;60:1577–85.
  61. Flory J, Lipska K. Metformin in 2019. JAMA. 2019;321:1926–7.
  62. Eyal S, Easterling TR, Carr D, et al. Pharmacokinetics of metformin during pregnancy. Drug Metab Dispos.2010;38:833–40.
  63. Vanky E, Zahlsen K, Spigset O, Carlsen SM. Placental passage of metformin in women with polycystic ovary syndrome.
    Fertil Steril    2005;83:1575–8.
  64. Poolsup N, Suksomboon N, Amin M. Efficacy and safety of oral antidiabetic drugs in comparison to insulin in treating gestational diabetes mellitus: A meta-analysis. PLoS One. 2014;9:e109985.
  65. Guo L, Ma J, Tang J, et al. Comparative efficacy and safety of metformin, glyburide, and insulin in treating gestational diabetes mellitus: A meta-analysis. J Diabetes Res. 2019;2019:9804708.
  66. Jiang YF, Chen XY, Ding T, et al. Comparative efficacy and safety of OADs in management of GDM: Network meta-analysis of randomized controlled trials. J Clin Endocrinol Metab. 2015;100:2071–80.
  67. Rowan JA, Rush EC, Obolonkin V, et al. Metformin in gestational diabetes: the offspring follow-up (MiG TOFU): Body composition at 2 years of age. Diabetes Care. 2011;34:2279–84.
  68. Rowan JA, Rush EC, Plank LD, et al. Metformin in gestational diabetes: The offspring follow-up (MiG TOFU): Body composition and metabolic outcomes at 7-9 years of age. BMJ Open Diabetes Res Care. 2018;6:e000456.
  69. Barbour LA, Scifres C, Valent AM, et al. A cautionary response to SMFM statement: Pharmacological treatment of gestational diabetes. Am J Obstet Gynecol. 2018;219:367.e1-367.e7.
  70. Simonson DC, Ferrannini E, Bevilacqua S, et al. Mechanism of improvement in glucose metabolism after chronic glyburide therapy. Diabetes. 1984;33:838–45.
  71. Balsells M, García-Patterson A, Solà I, et al. Glibenclamide, metformin, and insulin for the treatment of gestational diabetes: A systematic review and meta-analysis. BMJ. 2015;350:h102.
  72. George A, Mathews JE, Sam D, et al. Comparison of neonatal outcomes in women with gestational diabetes with moderate hyperglycaemia on metformin or glibenclamide–a randomised controlled trial. Aust New Zeal J Obstet Gynaecol.2015;55:47–52.
  73. Silva JC, Pacheco C, Bizato J, et al. Metformin compared with glyburide for the management of gestational diabetes. Int J Gynecol Obstet. 2010;111:37–40.
  74. Nachum Z, Zafran N, Salim R, et al. Glyburide versus metformin and their combination for the treatment of gestational diabetes mellitus: A randomized controlled study. Diabetes Care. 2017;40:332–7.
  75. Zera CA, Bates DW, Stuebe AM, et al. Diabetes screening reminder for women with prior gestational diabetes. Obstet Gynecol.2015;126:109–14.
  76. Hamel MS, Werner EF. Interventions to improve rate of diabetes testing postpartum in women with gestational diabetes mellitus. Curr Diab Rep. 2017;17:7.
  77. Middleton P, Crowther CA. Reminder systems for women with previous gestational diabetes mellitus to increase uptake of testing for type 2 diabetes or impaired glucose tolerance. Cochrane database Syst Rev2014;2014:CD009578.
  78. Stuebe A, Ecker J, Bates DW, et al. Barriers to follow-up for women with a history of gestational diabetes. Am J Perinatol2010;27:705–10.
  79. Yarrington C, Zera C. Health systems approaches to diabetes screening and prevention in women with a history of gestational diabetes. Curr Diab Rep. 2015;15:114.
  80. ACOG Committee Opinion No. 736: Optimizing postpartum care. Obstet Gynecol. 2018;131:e140–50.
  81. Werner EF, Has P, Tarabulsi G, et al. Early postpartum glucose testing in women with gestational diabetes mellitus. Am J Perinatol.2016;33:966–71.
  82. Carter EB, Martin S, Temming LA, et al. Early versus 6–12 week postpartum glucose tolerance testing for women with gestational diabetes. J Perinatol. 2018;38:118–21.
  83. Waters TP, Kim SY, Werner E, et al. Should women with gestational diabetes be screened at delivery hospitalization for type 2 diabetes? Am J Obstet Gynecol.2020;222:73.e1-73.e11.
  84. Nicklas JM, Zera CA, England LJ, et al. A web-based lifestyle intervention for women with recent gestational diabetes mellitus: A randomized controlled trial. Obstet Gynecol. 2014;124:563–70.
  85. Ferrara A, Hedderson MM, Brown SD, et al. The comparative effectiveness of diabetes prevention strategies to reduce postpartum weight retention in women with gestational diabetes mellitus: The Gestational Diabetes’ Effects on Moms (GEM) cluster randomized controlled trial. Diabetes Care. 2016;39:65–74.
3

Article Information

Disclosure

Chloe A Zera and Ellen W Seely have no financial or non-financial relationships or activities to declare in relation to this article.

Compliance With Ethics

This study involves a review of the literature and did not involve any studies with human or animal subjects performed by any of the authors.

Review Process

Double-blind peer review.

Authorship

The named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship of this manuscript, take responsibility for the integrity of the work as a whole, and have given final approval for the version to be published.

Correspondence

Ellen W Seely, Division of Endocrinology, Diabetes and Hypertension Brigham and Women’s Hospital, 221 Longwood Ave, Boston, MA 02115, USA. E: eseely@bwh.harvard.edu

Support

No funding was received in the publication of this article.

Access

This article is freely accessible at touchENDOCRINOLOGY.com © Touch Medical Media 2021

Received

2020-09-01

4

Further Resources

Share
Facebook
X (formerly Twitter)
LinkedIn
Via Email
Mark CompleteCompleted
BookmarkBookmarked
Copy LinkLink Copied
Download as PDF
Stastical analysis indication diabetes mellitus .generative ai
5 mins

Trending Topic
Developed by Touch
Mark CompleteCompleted
BookmarkBookmarked

Forty-four Years of the UK Prospective Diabetes Study: Legacy Effect and Beyond

Saptarshi Bhattacharya, Sanjay Kalra, Lakshmi Nagendra

Very few trials in the history of medical science have altered the treatment landscape as profoundly as the UK Prospective Diabetes Study (UKPDS). Even 44 years after its inception, the trial and post-study follow-up findings continue to fascinate and enlighten the medical community. The study was conceived at a time when there was uncertainty about […]

touchREVIEWS in Endocrinology. 2024;21(1):1–2:Online ahead of journal publication
Advertisement
    • 5

    Related Content in Diabetes

    Latest articles videos and clinical updates - straight to your inbox

    Close Popup