HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Kahn, H. S. Articles by Marchbanks, P. A. Search for Related Content PubMed PubMed Citation Articles by Kahn, H. S. Articles by Marchbanks, P. A. Social Bookmarking                What's this?

Effects of Injectable or Implantable Progestin-Only Contraceptives on Insulin-Glucose Metabolism and Diabetes Risk

¹ Division of Diabetes Translation, National Center for Chronic Disease Prevention and Health Promotion, Centers for Disease Control and Prevention, Atlanta, Georgia
² Division of Reproductive Health, National Center for Chronic Disease Prevention and Health Promotion, Centers for Disease Control and Prevention, Atlanta, Georgia

	ABSTRACT

TOP ABSTRACT INTRODUCTION DISCUSSION References

 
Progestin-only contraceptives administered by injection (Depo-Provera) or subcutaneous implant (Norplant) have been available to U.S. women for about a decade. Two epidemiological studies found their use associated with increased incidence of type 2 diabetes. In reviewing publications relating progestin injections and implants to glucose metabolism, 25 studies of various study designs and laboratory methods were identified that reported at least one insulin value in nondiabetic women. Research subjects were usually nonobese and often from developing countries. Of eight studies that performed sequential oral glucose tolerance tests (OGTTs) after at least 6 months of Depo-Provera or Norplant use, seven found significant elevations (approximate doubling) of insulin at 2 or 3 h after glucose challenge; the effects on fasting, half-hour, or 1-h postchallenge insulin values were less consistent. The three studies that performed sequential intravenous glucose tolerance tests (IVGTTs) on injection users all found an increased early-phase insulin response. One study used sequential hyperglycemic-hyperinsulinemic clamps to demonstrate reduced total-body glucose uptake per unit of insulin after 8 weeks of Norplant use. The metabolic studies generally did not show a reduction in the glucose tolerance of their nondiabetic subjects. However, compared with the lean and low-risk women who were usually selected for metabolic research, many U.S. women receiving these injections or implants may start out with increased insulin resistance due to greater weight, sedentary lifestyle, and family or childbearing histories. Additional research could help clarify whether exposure to injectable or implantable contraceptives leads to increased risk of type 2 diabetes and gestational diabetes in women with predisposing factors.

Abbreviations: DMPA, depot injection of medroxyprogesterone acetate (Depo-Provera) • IUD, nonhormonal intrauterine device • IVGTT, intravenous glucose tolerance test • LNG, levonorgestrel • NET-EN, norethisterone enanthate • OGTT, oral glucose tolerance test • OR, odds ratio • RR, relative risk • WHO, World Health Organization

	INTRODUCTION

TOP ABSTRACT INTRODUCTION DISCUSSION References

 
In the early 1990s two new modes of progestin-only hormonal contraception became available to women living in the U.S. The following decade has been notable for the emergence of type 2 diabetes among adolescent girls (more than boys) (1) and a rising prevalence of gestational diabetes (2). The temporal overlap of a diabetes increase among young women and availability of new contraceptive methods has stimulated us to review the published literature on insulin-glucose metabolism in the presence of these hormonal agents.

One new contraceptive mode was a depot injection containing 150 mg medroxyprogesterone acetate (DMPA, "Depo-Provera"). Administered by the intramuscular route, it delivers medroxyprogesterone at a plasma concentration of 1 ng/ml (3). The DMPA injection must be repeated every 3 months for continuing contraceptive benefit. The other new mode was a system of six Silastic capsules, each containing 36 mg of the progestin levonorgestrel (LNG), designed for long-term subcutaneous insertion in the upper arm (LNG implant, "Norplant"). This implant system delivers LNG initially at 85 µg/day, declining gradually to 30 µg/day (4). Serum concentrations of LNG decrease from 0.35 ng/ml at 1 year to 0.29 ng/ml at 5 years, the recommended duration of use.

Both of these new contraceptives are highly effective (0.3% pregnancies with typical use in the first year [5]) and require relatively little active involvement from the patient. In addition, the absence of any estrogenic hormone component makes them theoretically attractive for use by diabetic women who are at advanced risk of vascular complications. For diabetic women free of microvascular or macrovascular disease, the World Health Organization (WHO) acknowledges that progestin-only contraceptives in general (i.e., progestin-only pills as well as injections and implants) may slightly influence carbohydrate metabolism, but the WHO also indicates that the advantages of DMPA or LNG implants generally outweigh their theoretical or proven risks (6). The WHO’s favorable review of the LNG implants extends also to diabetic women with vascular disease, but for these women it considers DMPA to carry theoretical or proven risks that usually outweigh the advantages.

The American College of Obstetricians and Gynecologists has stated that among diabetic women who have vascular disease or are older than 35 years, the use of progestin-only oral contraceptives, DMPA, or implants may be safer than combination (i.e., estrogen plus progestin) oral contraceptives (7). It adds, however, that "because of its long duration of action and potential for hypoestrogenic effects, DMPA may be less appropriate than other progestin-only contraceptives." The American Diabetes Association offers little contraceptive guidance for diabetic women beyond commenting that "There are no contraceptive methods that are specifically contraindicated in women with diabetes (8)."

For nondiabetic women with previous gestational diabetes, the WHO indicates "no restriction" for the use of injectable or implantable methods (6). On the other hand, experts at the Fourth International Workshop-Conference on Gestational Diabetes Mellitus cautioned that progestin-only contraception should be avoided, if possible, until more data are available on their safety in women with prior gestational diabetes (9).

TOP ABSTRACT INTRODUCTION DISCUSSION References

 
Literature search
This review began with a MEDLINE search for articles on humans published since 1980 that mentioned both contraceptive progestins and an aspect of insulin-glucose metabolism. This search identified 309 citations of which only one article (10) was about an injectable contraceptive and also included a topic related to epidemiology, risk, or odds ratio. In addition, a large prospective cohort study was informally identified that related an implantable contraceptive to many health outcomes, including diabetes (11).

Pertinent metabolic studies were sought by retrieving all articles among the 309 citations for which the keywords or abstracts indicated there might be data reported on at least one insulin value in association with injection or implant use. From these articles, additional bibliographic citations were identified that preceded 1980 or were otherwise missed in the MEDLINE search. After consolidation of multiple reports from the same research program, 15 metabolic studies were found that reported insulin values among nondiabetic women using various progestin-only injections (Table 1) and 10 among nondiabetic women using various progestin-only implants (Table 2). In addition, one study was found of diabetic and prediabetic women who had insulin measurements in connection with their DMPA use (12).

In the other epidemiological study, a cohort of LNG implant initiators (n = 7,977) was prospectively compared with age-matched, nonhormonal intrauterine device (IUD) initiators (n = 6,625) and sterilization users (n = 1,419) (11). Participants came from eight developing countries and were relatively lean (mean weight 55 kg [SD 11]). Compared with the group using IUDs or sterilization, the implant current users had a nonsignificantly increased incidence of diabetes after adjustment for clinic, age, and body weight (relative risk [RR] 2.4 [95% CI 0.7–8.1]). The incidence of diabetes in this young, lean group was 0.2 per 1,000 woman-years of LNG implant use.

Metabolic studies in nondiabetic women
The 15 studies of injectable contraceptives listed in Table 1 include reports with a variety of study designs, sample sizes, laboratory methods, and progestin formulations. The most common design was a time series of contraceptive users, usually without a comparison group or randomization of contraceptive method. Loss to follow-up was generally not addressed. Of the six DMPA studies with insulin values that followed healthy contraceptive users at least 6 months with sequential oral glucose tolerance tests (OGTTs), all showed a significant elevation of insulin concentration (compared with baseline before DMPA) at 2–3 h after the glucose challenge (13–18). The increase in these late postchallenge insulin values was typically about double, but the variation in assay methods and the absence of normative standards make it difficult to interpret these increments. The effects of DMPA on fasting, half-hour, or 1-h postchallenge insulin measurements were varied and inconsistent.

For users of injectable norethisterone enanthate (NET-EN, not currently available in the U.S.), a similar elevation in late postchallenge insulin values was found in one study (18) but not in another (19). Studies of either DMPA or NET-EN that evaluated patients by intravenous glucose tolerance test (IVGTT) all showed increased early-phase insulin responses with injectable contraceptive use (20–22).

Despite the effects noted on insulin values, most of the studies in Table 1 did not find any effect of the injectable contraceptives on glucose concentrations in lean, glucose-tolerant women. Studies that found increased glucose involved DMPA users who were heavier at baseline (mean weight 68 kg) (13,18) or had longer duration of use (at least 48 months) (16).

Of the 10 metabolic studies of progestin implants used by nondiabetic women (Table 2), 7 involved LNG users, and the others involved implantable progestins not currently available in the U.S. (nestorone, nomegestrol, and etonogestrel). Only two studies evaluated LNG users by repeated OGTT after at least 12 months. The first of these reported an increase in the insulin area under the curve along with a doubling of 3-h insulin values (23,24). The investigators also described a decline in postchallenge insulin concentrations at 4 weeks after removal of the LNG implant, but the insulin area under the curve remained greater than it had been before the implant (25). The second study showed a similar increase in the insulin area under the curve but only a nonsignificant increase in the 2-h insulin values (26). Both of these studies identified an increase in glucose (area under the curve) that appeared to increase with greater duration of LNG implant use.

In a study of LNG implant users evaluated at baseline and 8 weeks after insertion by hyperglycemic clamp, investigators found increased first- and second-phase insulin responses along with a small increase in total-body glucose uptake; the steady-state rate of glucose uptake per unit of plasma insulin significantly declined, indicating decreased tissue sensitivity to insulin (27).

Metabolic studies in prediabetic women and diabetic patients
A small study of potentially diabetic women (having a history of abnormal glucose tolerance during pregnancy and a newborn infant weighing >9 lbs) evaluated its four participants by repeat OGTT (12). After 1–2 months of DMPA exposure, there was an increase in 1-h and 2-h insulin response to the glucose challenge. After 3–12 months of continuing DMPA use insulin returned to pretreatment levels, whereas 1-h and 2-h glucose concentrations continued to increase. The authors interpreted these observations as showing that the DMPA increased the need for insulin but that, with time, the potentially diabetic women could no longer compensate for this additional insulin requirement.

This same report also described the administration of DMPA to eight patients with frank type 2 diabetes (including five males) who were evaluated by OGTT at baseline and after 1–3 months of DMPA use at two different doses (12). These eight diabetic patients ranged in age from 27 to 62 years, and none of them was treated with hypoglycemic drugs or insulin. For these patients the insulin values at 0.5 and 1 h after glucose challenge declined within 1–3 months after starting DMPA treatment, while their glucose values increased. In the view of the authors, the ß-cells of these patients could not respond, even transiently, to the increased need for insulin induced by DMPA.

For women using contraceptive implants, no studies were found that measured insulin or C-peptide in prediabetic or diabetic patients.

	DISCUSSION

TOP ABSTRACT INTRODUCTION DISCUSSION References

 
Trends in use prevalence of injectable or implantable contraceptives
Data on use prevalence of injectable and implantable contraceptives are necessary to assess any potential public health impact on diabetes risk. In the U.S., use prevalence of these contraceptive methods has generally been low. In 1995, among all U.S. women aged 15–44 years, 1.9% were using injectables and 0.9% were using implants (28). Use prevalence of injectables was slightly higher among younger women: 2.9% among those aged 15–19 years and 3.9% for those aged 20–24 years. With regard to implants, use prevalence was also higher among women aged 20–24 years (2.4%), but not for those aged 15–19 years (0.8%). Approximately half of injectable users and 16% of implant users discontinued use within 12 months (29). Non-Hispanic black women had the highest use prevalence (3.3% for injectables and 1.4% for implants), followed by Hispanic (2.8 and 1.2%, respectively), and Caucasian (1.6 and 0.7%, respectively) women. In some Native American communities, e.g., Navajo (10), use prevalence of injectables is also relatively high.

In the absence of annual, national contraception surveys, trends in use prevalence can be inferred only from limited marketing information or from experience in specific populations. Norplant was approved for the U.S. in 1990, and its use increased until the mid-1990s when the prevalence began to drop as the media focused on its side effects (30). As of August 2000, Norplant System kits for insertion were no longer available in the U.S. (31). DMPA was approved as a contraceptive for the U.S. in 1992 but was used off label as a contraceptive method before its approval (32). The most comprehensive trend data come from the federally funded Title X program, which serves almost 4,000,000 primarily low-income contraceptive users per year in the U.S. These data show an increase in the use of injectables from 12% among contraceptive users in 1995 to 19% in 2000 and a decline in implant users from 2% in 1995 to 0% in 2000 (33). Data from the King County Family Planning Program in Washington state also show an increasing trend in injectable use from 2.7% of contraceptive users in 1992 to 16.6% in 1999 (34).

Given the low use prevalence of implantable and injectable contraceptives among the general population of U.S. women, these contraceptive methods are not likely to have contributed much to the general increase in diabetes incidence over the last decade. However, their possible impact must be considered in specific populations where use prevalence has been relatively high. For example, among U.S. women aged 15–19 years who used any contraceptive in 1995, 19% of non-Hispanic blacks were using injectables compared with only 8% of Caucasians (35). Among adolescents attending a clinic in Baltimore in 1992–1993, 29% chose implants (36). High use prevalence has also been reported among postpartum teens: 50% chose injectables in one study (37) and 48% chose implants in another (38). Another study of postpartum adolescents reported that 43% of African-American, 33% of Mexican-American, and 24% of Caucasian women chose DMPA (39).

Possible mechanisms relating injectable and implantable contraceptives to diabetes risk
The elevations observed in late postchallenge insulin concentrations among nondiabetic injection and implant users (Tables 1 and 2) may reflect compensation for increased insulin resistance. This presumption of increased insulin resistance is supported by a finding of increased free fatty acids after glucose challenge among DMPA users (15). Increased free fatty acids are associated with insulin-resistant states (40) and glucose intolerance (41). Similarly, LNG implant users have been shown to have reduced total-body glucose uptake per unit of insulin (27).

On the other hand, a study using Bergman minimal-model analysis found no change in insulin sensitivity among women who accepted an LNG implant (42). Thus, the increases observed in postchallenge insulin values may be related to a mechanism other than increased insulin resistance. A direct stimulation of pancreatic ß-cells is conceivable, consistent with metabolic studies showing an increased early-phase insulin response. Primary stimulation of early insulin production, however, would be inconsistent with the epidemiological observation of increased diabetes incidence among these women. Furthermore, the acute insulin response usually declines rather than rises, as patients progress to impaired glucose tolerance and diabetes (43).

Other possible explanations for the increase in peripheral insulin include diminished clearance, less degradation, or increased return to the circulation of cell-associated insulin in an immunoreactive form (44). It is also conceivable that the insulin assays used by earlier investigators were indiscriminately detecting elevations of proinsulin. If this were the case, concerns about an increase in diabetes risk would still be appropriate. Increased levels of peripheral proinsulin are associated with reduced acute insulin response, a defect in insulin secretion, and eventual progression to type 2 diabetes (45). Future studies using better laboratory methods could help to clarify the physiological pathways leading to postchallenge hyperinsulinemia.

If indeed the use of injectable or implantable contraceptives leads to increased insulin resistance among some women, the mechanisms underlying this effect remain to be elucidated. One general mechanism that could tie injectable or implantable contraceptives to insulin resistance is promotion of weight gain. Cross-sectional and longitudinal studies of DMPA users have generally found increased mean weight (46–48) that appears to be associated with changes in adipose mass rather than fluid or lean tissue (49). Among DMPA users attending urban clinics in Texas, weight gain was the most commonly reported side effect, mentioned by 38–46% of recipients at each follow-up contact (50).

Women using LNG implants also tend to gain weight. Among implant users followed in four U.S. academic medical centers, weight gain during 5 years averaged 1 kg per year (51), a larger increase than the mean of 0.3 kg per year typical of U.S. women in a similar age range (52). The large 5-year study in eight developing countries reported that implant users experienced more weight gain (RR 6.9 [95% CI 4.6–10.5]) but also more weight loss (2.6 [1.5–4.7]) (11). For continuing implant users in this international study, the average 5-year weight change was +2.5 kg (SE 0.07) in contrast to +1.5 kg (0.08) for the comparison group (P < 0.001).

Another general mechanism leading to increased insulin resistance could be related to the simulation of a chronically pregnant state by the exogenous progestin. Among older women, a history of multiple pregnancies is associated with increased insulin values and decreased insulin sensitivity, an association that is independent of obesity and fat distribution (53). High parity may also be associated with glucose intolerance (54) and a modestly increased risk of dying from diabetes (55). Among women with previous gestational diabetes, the occurrence of another pregnancy approximately triples the risk of type 2 diabetes after adjustment for multiple other diabetes risk factors (56). Oral progestin-only contraceptives (analogous to injections and implants) may similarly mimic the pregnant state. The use of oral, progestin-only contraceptives among women with previous gestational diabetes almost triples the risk of type 2 diabetes compared with the use of low-dose combination oral contraceptives or nonhormonal contraceptives (57).

These associations between the pregnant state and diabetes risk highlight the long-term disease-reduction benefits of providing contraceptive opportunities for women who desire to avoid pregnancy. At the same time, these associations raise concern that some contraceptive modes might themselves increase disease risk through their simulation of pregnancy or by other mechanisms (e.g., increases in adipose tissue) that contribute to insulin resistance.

Implications in an era of increasing diabetes
Published metabolic studies have generally found no association between women’s use of injectable or implantable progestin-only contraceptives and the development of glucose intolerance. However, recent epidemiological reports suggest a possible increased risk of diabetes among users of DMPA (10) or LNG implants (11). Resolution of this apparent discrepancy may have to consider the increased insulin response among women who adopt these contraceptive injections or implants.

The high insulin concentration of women using progestin-only contraceptives is likely evidence of their increased insulin resistance. The subjects of the published metabolic research were generally lean, so their compensatory hyperinsulinemia was probably sufficient to preserve their glucose tolerance. However, women who are heavier or insulin resistant for other reasons would be less able to respond with complete pancreatic compensation. Thus, injection or implant users with this predisposition might proceed more readily into glucose intolerance.

U.S. women of the 1990s probably had more insulin resistance than the research subjects in whom injectable and implantable contraceptives were first evaluated in earlier decades. The increased insulin resistance of the more recent period was likely associated with women’s greater obesity (58) and more sedentary practices. Among U.S. female adolescents surveyed in 1996, participation in moderate to vigorous physical activity decreased substantially with age; young women who were non-Hispanic blacks or Hispanics (the groups most likely to adopt contraceptive injections or implants) had lower levels of physical activity than women of other racial or ethnic groups (59).

The overall use prevalence in the U.S. of injections and implants appears to have risen during the early 1990s and has since leveled off (DMPA) or declined (LNG implants). However, DMPA or LNG implants may have been preferentially prescribed for U.S. women with prior gestational diabetes or a diabetic family history when their physicians were concerned about vascular disease risk associated with estrogen-containing contraceptives. This recommendation of progestin-only contraceptives in the context of increased insulin resistance in the population may possibly help to explain the recent emergence of type 2 diabetes in some young women (1). Similarly, among women who became pregnant following discontinuation of a progestin injection or implant, a comparable synergism may have contributed to an increase in gestational diabetes (2). Interestingly, the recent rise in gestational diabetes in northern California leveled off after about 1997, a time course that roughly follows the popularity in use of injectable and implantable contraceptives.

Any conclusions about a possible link between contraceptive method and the incidence of diabetes remain speculative and hypothetical. Regardless of how well the time trends associated with diabetes incidence and use of contraceptive injections and implants might (or might not) fit together, any parallel trends could be entirely unrelated. An analysis that compares groups rather than individuals is susceptible to ecological bias (where the effects based on the comparison of groups fail to reflect the biologic effects at an individual level), problems with control of extraneous variables, and temporal ambiguity, e.g., lack of certainty that contraceptive use preceded diabetes (60). Analytic studies that include information on the joint distribution of both exposure (use of contraceptives) and outcome (incident diabetes) in individual women are needed to explore the biologic effects.

It is beyond the scope of this review to specify the contraceptive methods that might be optimal for women who are known to be insulin resistant or frankly diabetic. A comprehensive recommendation would have to consider not only the contraceptives’ effects on insulin and glucose but also other risk variables for chronic disease (e.g., lipids, blood pressure, coagulation factors, liver function) (61), weight changes, and major clinical end points. Toward this end, Diab and Zaki (62) have recently reported prospective experience among diabetic women with hormonal contraceptives (DMPA, LNG implants, and low-dose combination oral contraceptives) and compared numerous chemical changes with those in diabetic women who used copper IUDs. However, their clinical study was small (fewer than 20 women using each of the contraceptive modes) and their participants were primarily women with type 1 diabetes. Expanded clinical studies of this sort, especially with women having type 2 diabetes, would be very useful. Future research and clinical surveillance are needed to clarify appropriate contraceptives for prediabetic and diabetic women and to determine whether contraceptive injections or implants may have a role in increasing the risk of diabetes.

	Footnotes

 
Address correspondence and reprint requests to Henry S. Kahn, K-10, Division of Diabetes Translation/CDC, 4770 Buford Hwy., Atlanta, GA 30341. E-mail: hkahn{at}cdc.gov.

Received for publication 20 March 2002 and accepted in revised form 17 September 2002.

Use of brand names is for identification only and does not imply endorsement by the Centers for Disease Control and Prevention.

A table elsewhere in this issue shows conventional and Système International (SI) units and conversion factors for many substances.

	References

TOP ABSTRACT INTRODUCTION DISCUSSION References

 

1. Fagot-Campagna A, Pettitt DJ, Engelgau MM, Burrows NR, Geiss LS, Valdez R, Beckles GL, Saaddine J, Gregg EW, Williamson DF, Narayan KM: Type 2 diabetes among North American children and adolescents: an epidemiologic review and a public health perspective. J Pediatr 136:664–672, 2000[Medline]
   
2. Ferrara A, Quesenberry CP, Riley C, Hedderson MM, Kahn HS: Changes in prevalence of gestational diabetes mellitus (GDM): Northern California, 1991–1999 (Abstract). Diabetes 50 (Suppl. 2):A5, 2001
   
3. Kaunitz AM: Injectable long-acting contraceptives. Clin Obstet Gynecol 44:73–91, 2001[Medline]
   
4. Croxatto HB: Progestin implants. Steroids 65:681–685, 2000[Medline]
   
5. Hatcher R, Trussell J, Stewart F, Cates W, Stewart G, Guest F, Kowal D: Contraceptive Technology. 17th Ed. New York, Ardent Media, 1998
   
6. World Health Organization: Improving access to quality care in family planning. Medical eligibility criteria for contraceptive use, 2000 (article online). Available from http://www.who.int/reproductive-health/publications/RHR_00_2_medical_eligibility_criteria_second_edition/index.htm. Accessed 15 March 2002
   
7. American College of Obstetricians and Gynecologists: The Use of Hormonal Contraception in Women with Coexisting Medical Conditions. Washington, DC, American College of Obstetricians and Gynecologists, 2000 (Report no. 18)
   
8. American Diabetes Association: Preconception care of women with diabetes. Diabetes Care 25 (Suppl. 1):S82–S89, 2002
   
9. Kjos SL, Peters RK, Xiang A, Schaefer U, Buchanan TA: Hormonal choices after gestational diabetes: subsequent pregnancy, contraception, and hormone replacement. Diabetes Care 21 (Suppl. 2):B50–B57, 1998
   
10. Kim C, Seidel KW, Begier EA, Kwok YS: Diabetes and depot medroxyprogesterone contraception in Navajo women. Arch Intern Med 161:1766–1771, 2001[Abstract/Free Full Text]
    
11. International Collaborative Post-Marketing Surveillance of Norplant: Post-marketing surveillance of Norplant contraceptive implants. II. Non-reproductive health. Contraception 63:187–209, 2001[Medline]
    
12. Gershberg H, Zorrilla E, Hernandez A, Hulse M: Effects of medroxyprogesterone acetate on serum insulin and growth hormone levels in diabetics and potential diabetics. Obstet Gynecol 33:383–389, 1969[Free Full Text]
    
13. Spellacy WN, McLeod AG, Buhi WC, Birk SA: The effects of medroxyprogesterone acetate on carbohydrate metabolism: measurements of glucose, insulin, and growth hormone after twelve months’ use. Fertil Steril 23:239–244, 1972[Medline]
    
14. Vermeulen A, Thiery M: Hormonal contraceptives and carbohydrate tolerance. II. Influence of medroxyprogesterone acetate and chronic oral contraceptives. Diabetologia 10:253–259, 1974[Medline]
    
15. Tuttle S, Turkington VE: Effects of medroxyprogesterone acetate on carbohydrate metabolism. Obstet Gynecol 43:685–692, 1974[Abstract/Free Full Text]
    
16. Liew DF, Ng CS, Yong YM, Ratnam SS: Long-term effects of Depo-Provera on carbohydrate and lipid metabolism. Contraception 31:51–64, 1985[Medline]
    
17. Virutamasen P, Wongsrichanalai C, Tangkeo P, Nitichai Y, Rienprayoon D: Metabolic effects of depot-medroxyprogesterone acetate in long-term users: a cross-sectional study. Int J Gynaecol Obstet 24:291–296, 1986[Medline]
    
18. Fahmy K, Abdel-Razik M, Shaaraway M, al-Kholy G, Saad S, Wagdi A, al-Azzony M: Effect of long-acting progestagen-only injectable contraceptives on carbohydrate metabolism and its hormonal profile. Contraception 44:419–430, 1991[Medline]
    
19. Griffin M, Heaton DA, McEwan JA: Long-term use of an injectable contraceptive: effect of depot-norethisterone oenanthate on carbohydrate metabolism. Contraception 37:53–60, 1988[Medline]
    
20. Tankeyoon M, Dusitsin N, Poshyachinda V, Larsson-Cohn U: A study of glucose tolerance, serum transaminase and lipids in women using depot-medroxyprogesterone acetate and a combination-type oral contraceptive. Contraception 14:199–214, 1976[Medline]
    
21. Amatayakul K, Sivassomboon B, Singkamani R: Effects of medroxyprogesterone acetate on serum lipids, protein, glucose tolerance and liver function in Thai women. Contraception 21:283–297, 1980[Medline]
    
22. Amatayakul K, Suriyanon V: The effects of long-acting injectable contraceptives on carbohydrate metabolism. Int J Gynaecol Obstet 23:361–368, 1985[Medline]
    
23. Konje JC, Otolorin EO, Ladipo OA: Changes in carbohydrate metabolism during 30 months on Norplant. Contraception 44:163–172, 1991[Medline]
    
24. Konje JC, Otolorin EO, Ladipo OA: The effect of continuous subdermal levonorgestrel (Norplant) on carbohydrate metabolism. Am J Obstet Gynecol 166:15–19, 1992[Medline]
    
25. Konje JC, Odukoya OA, Otolorin EO, Ewings PD, Ladipo OA: Carbohydrate metabolism before and after Norplant removal. Contraception 46:61–69, 1992[Medline]
    
26. Biswas A, Viegas OA, Coeling Bennink HJ, Korver T, Ratnam SS: Implanon contraceptive implants: effects on carbohydrate metabolism. Contraception 63:137–141, 2001[Medline]
    
27. Shamma FN, Rossi G, HajHassan L, Penzias AS, Connoly-Diamond M, Jones E, Diamond MP: The effect of Norplant on glucose metabolism under hyperglycemic hyperinsulinemic conditions. Fertil Steril 63:767–772, 1995[Medline]
    
28. Abma JC, Chandra A, Mosher WD, Peterson LS, Piccinino LJ: Fertility, family planning, and women’s health: new data from the 1995 National Survey of Family Growth. Vital Health Stat 23:1–114, 1997
    
29. Trussell J, Vaughan B: Contraceptive failure, method-related discontinuation and resumption of use: results from the 1995 National Survey of Family Growth. Fam Plann Perspect 31:64–72, 93, 1999[Medline]
    
30. Berenson AB, Wiemann CM, McCombs SL, Somma-Garcia A: The rise and fall of levonorgestrel implants: 1992–1996. Obstet Gynecol 92:790–794, 1998[Abstract]
    
31. de Vane PJ (Wyeth-Ayerst Pharmaceuticals): Letter to Norplant Providers (10 August). Philadelphia, PA, Wyeth-Ayerst Pharmaceuticals 2000
    
32. Pinkston Koenigs LM, Miller NH: The contraceptive use of Depo-Provera in U.S. adolescents. J Adolesc Health 16:347–349, 1995[Medline]
    
33. Alan Guttmacher Institute: Family Planning Annual Report: 2000 Summary. New York, 2001
    
34. Margulies R, Miller L: Increased depot medroxyprogesterone acetate use increases family planning program pharmaceutical supply costs. Contraception 63:147–149, 2001[Medline]
    
35. Piccinino LJ, Mosher WD: Trends in contraceptive use in the United States: 1982–1995. Fam Plann Perspect 30:4–10, 46, 1998[Medline]
    
36. Dinerman LM, Wilson MD, Duggan AK, Joffe A: Outcomes of adolescents using levonorgestrel implants vs oral contraceptives or other contraceptive methods. Arch Pediatr Adolesc Med 149:967–972, 1995[Abstract]
    
37. O’Dell CM, Forke CM, Polaneczky MM, Sondheimer SJ, Slap GB: Depot medroxyprogesterone acetate or oral contraception in postpartum adolescents. Obstet Gynecol 91:609–614, 1998[Abstract]
    
38. Polaneczky M, Slap G, Forke C, Rappaport A, Sondheimer S: The use of levonorgestrel implants (Norplant) for contraception in adolescent mothers. N Engl J Med 331:1201–1206, 1994[Abstract/Free Full Text]
    
39. Berenson AB, Wiemann CM: Contraceptive use among adolescent mothers at 6 months postpartum. Obstet Gynecol 89:999–1005, 1997[Abstract]
    
40. Bergman RN, Ader M: Free fatty acids and pathogenesis of type 2 diabetes mellitus. Trends Endocrinol Metab 11:351–356, 2000[Medline]
    
41. Pouliot MC, Despres JP, Nadeau A, Tremblay A, Moorjani S, Lupien PJ, Theriault G, Bouchard C: Associations between regional body fat distribution, fasting plasma free fatty acid levels and glucose tolerance in premenopausal women. Int J Obes 14:293–302, 1990[Medline]
    
42. Harper MA, Meis PJ, Steele L: A prospective study of insulin sensitivity and glucose metabolism in women using a continuous subdermal levonorgestrel implant system. J Soc Gynecol Investig 4:86–89, 1997
    
43. Pratley RE, Weyer C: The role of impaired early insulin secretion in the pathogenesis of type II diabetes mellitus. Diabetologia 44:929–945, 2001[Medline]
    
44. Duckworth WC, Bennett RG, Hamel FG: Insulin degradation: progress and potential. Endocr Rev 19:608–624, 1998[Abstract/Free Full Text]
    
45. Mykkanen L, Zaccaro DJ, Hales CN, Festa A, Haffner SM: The relation of proinsulin and insulin to insulin sensitivity and acute insulin response in subjects with newly diagnosed type II diabetes: the Insulin Resistance Atherosclerosis Study. Diabetologia 42:1060–1066, 1999[Medline]
    
46. Westhoff C: Depot medroxyprogesterone acetate contraception: metabolic parameters and mood changes. J Reprod Med 41 (Suppl. 5):401–406, 1996[Medline]
    
47. Risser WL, Gefter LR, Barratt MS, Risser JM: Weight change in adolescents who used hormonal contraception. J Adolesc Health 24:433–436, 1999[Medline]
    
48. Espey E, Steinhart J, Ogburn T, Qualls C: Depo-provera associated with weight gain in Navajo women. Contraception 62:55–58, 2000[Medline]
    
49. Amatayakul K, Sivasomboon B, Thanangkul O: A study of the mechanism of weight gain in medroxyprogesterone acetate users. Contraception 22:605–622, 1980[Medline]
    
50. Sangi-Haghpeykar H, Poindexter AN 3rd, Bateman L, Ditmore JR: Experiences of injectable contraceptive users in an urban setting. Obstet Gynecol 88:227–233, 1996[Abstract]
    
51. Sivin I, Mishell DR Jr, Darney P, Wan L, Christ M: Levonorgestrel capsule implants in the United States: a 5-year study. Obstet Gynecol 92:337–344, 1998[Abstract]
    
52. Kahn HS, Williamson DF, Stevens JA: Race and weight change in US women: the roles of socioeconomic and marital status. Am J Public Health 81:319–323, 1991[Abstract/Free Full Text]
    
53. Kritz-Silverstein D, Barrett-Connor E, Wingard DL, Friedlander NJ: Relation of pregnancy history to insulin levels in older, nondiabetic women. Am J Epidemiol 140:375–382, 1994[Abstract/Free Full Text]
    
54. Boyko EJ, Alderman BW, Keane EM, Baron AE: Effects of childbearing on glucose tolerance and NIDDM prevalence. Diabetes Care 13:848–854, 1990[Abstract]
    
55. Beral V: Long term effects of childbearing on health. J Epidemiol Community Health 39:343–346, 1985[Abstract]
    
56. Peters RK, Kjos SL, Xiang A, Buchanan TA: Long-term diabetogenic effect of single pregnancy in women with previous gestational diabetes mellitus. Lancet 347:227–230, 1996[Medline]
    
57. Kjos SL, Peters RK, Xiang A, Thomas D, Schaefer U, Buchanan TA: Contraception and the risk of type 2 diabetes mellitus in Latina women with prior gestational diabetes mellitus. JAMA 280:533–538, 1998[Abstract/Free Full Text]
    
58. Flegal KM, Troiano RP: Changes in the distribution of body mass index of adults and children in the US population. Int J Obes Relat Metab Disord 24:807–818, 2000[Medline]
    
59. Gordon-Larsen P, McMurray RG, Popkin BM: Adolescent physical activity and inactivity vary by ethnicity: the National Longitudinal Study of Adolescent Health. J Pediatr 135:301–306, 1999[Medline]
    
60. Morgenstern H: Ecologic studies. In Modern Epidemiology. 2nd ed. Rothman K, Greenland S, Eds. Philadelphia, Lippincott, 1998, p. 459–480
    
61. Dorflinger LJ: Metabolic effects of implantable steroid contraceptives for women. Contraception 65:47–62, 2002[Medline]
    
62. Diab KM, Zaki MM: Contraception in diabetic women: comparative metabolic study of Norplant, depot medroxyprogesterone acetate, low dose oral contraceptive pill and CuT380A. J Obstet Gynaecol Res 26:17–26, 2000[Medline]
    
63. Dhall K, Kumar M, Rastogi GK, Devi PK: Short-term effects of norethisterone oenanthate and medroxyprogesterone acetate on glucose, insulin, growth hormone, and lipids. Fertil Steril 28:156–158, 1977[Medline]
    
64. Andino N: Phase I clinical trial of two contraceptive preparations. Norethisterone enanthate (NEN) and norethisterone acetate (NET). Contraception 23:141–155, 1981[Medline]
    
65. Lithell H, Weiner E, Vessby B, Johansson ED: Effects of continuous levonorgestrel treatment (subcutaneous capsules) on the lipoprotein and carbohydrate metabolism in fertile women. Ups J Med Sci 88:103–108, 1983[Medline]
    
66. Koopersmith TB, Lobo RA: Insulin sensitivity is unaltered by the use of the Norplant subdermal implant contraceptive. Contraception 51:197–200, 1995[Medline]
    
67. Odlind V, Lithell H, Selinus I, Vessby B: Unaltered lipoprotein and carbohydrate metabolism during treatment with contraceptive subdermal implants containing ST-1435. Ups J Med Sci 89:151–158, 1984[Medline]
    
68. Barbosa I, Coutinho E, Athayde C, Ladipo O, Olsson SE, Ulmsten U: The effects of nomegestrol acetate subdermal implant (Uniplant) on carbohydrate metabolism, serum lipoproteins and on hepatic function in women. Contraception 52:111–114, 1995[Medline]
    

CiteULike

Del.icio.us

Digg

Reddit

Technorati

This article has been cited by other articles:

				P. Damm, E. R. Mathiesen, K. R. Petersen, and S. Kjos Contraception After Gestational Diabetes Diabetes Care, July 1, 2007; 30(Supplement_2): S236 - S241. [Full Text] [PDF]

				M. R. Batista, M. S. Smith, W. L. Snead, C. C. Connolly, D. B. Lacy, and M. C. Moore Chronic estradiol and progesterone treatment in conscious dogs: effects on insulin sensitivity and response to hypoglycemia Am J Physiol Regulatory Integrative Comp Physiol, October 1, 2005; 289(4): R1064 - R1073. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Kahn, H. S. Articles by Marchbanks, P. A. Search for Related Content PubMed PubMed Citation Articles by Kahn, H. S. Articles by Marchbanks, P. A. Social Bookmarking                What's this?