What are the benefits and risks of IUDs in adolescents?

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What are the benefits and risks of IUDs in adolescents?
EVIDENCE-BASED ANSWER

LITTLE AVAILABLE EVIDENCE specifically addresses the benefits and risks of intrauterine devices (IUDs) in adolescents. Most studies have evaluated IUD use in nulliparous adults.

Levonorgestrel IUDs cause less menstrual bleeding than oral contraceptive pills (OCPs) in adult nulliparous women without differences in complications or pregnancy rates (strength of recommendation [SOR]: B, one RCT).

Levonorgestrel IUDs appear to have similar expulsion and continuation rates in adolescents and adults (SOR: B, one prospective study). Adult nulliparous women who discontinue IUDs have subsequent birth rates similar to women who stop using OCPs or barrier methods. (SOR: B, limited quality evidence).

 

Evidence summary

One RCT that compared the levonorgestrel IUD (Mirena) with oral contraceptives in 200 nulliparous women 18 to 25 years of age found the IUD to have equivalent safety and efficacy to OCPs.1 Moreover, the IUD group experienced a significant decrease in bleeding, with a number needed to treat of 4 (P=.001).

Neither group reported any pregnancies or pelvic inflammatory disease at one year. The overall discontinuation rate at one year was 20% for IUDs and 27% for OCPs (P=not significant [NS]).1 Multiple studies show no unintended pregnancies with the IUD.1-3

Study of adolescents finds low complication rate
A prospective cohort study of 179 adolescents 10 to 19 years of age found that the overall incidence of complications with the levonorgestrel IUD was relatively low, with removal rates of 8/179 (4.5%) each for pain and abnormal vaginal bleeding. The cumulative incidence of expulsion was estimated at 8.3% (95% confidence interval [CI], 4.2%-14.3%). No cases of uterine perforation were identified, and the one-year continuation rate was 85% (95% CI, 77%-90%).2 Other studies haven’t evaluated adolescents as a separate group.

IUDs are also well tolerated in an older cohort
A cohort study of 113 nulliparous women 16 to 30 years of age found insertion of a copper or levonorgestrel IUD to be well tolerated; no perforations were observed. At one year, 65 women (58%) still had their original IUD, 15 (13%) had had it removed, 6 (5%) had experienced expulsion, and 27 (24%) were lost to follow-up.3

Abdominal and back pain can be a problem
An RCT of 200 nulliparous women 18 to 25 years of age found that levonorgestrel IUDs were associated with more abdominal and back pain at 12 months than OCPs (54.7% of women with IUDs had pain vs 40% of women with OCPs; number needed to harm=7; P=.007). Pain was the leading cause of discontinuation in the IUD group (6 women with IUDs stopped using them vs no OCP users; P=.012).1

No difference in IUD complications in nulliparous vs parous women
A retrospective cohort study compared 129 nulliparous women with 332 parous women 17 to 52 years of age who had either copper or levonorgestrel IUDs. The researchers found no differences between the 2 groups in rates of perforation, pelvic inflammatory disease, ectopic pregnancy, or expulsion.4

Fertility after IUD removal: An encouraging picture
No studies have evaluated fertility after IUD use exclusively in adolescents. A prospective cohort study of 558 nulliparous women ages 18 to 40 years who stopped using a barrier method, copper IUD, or OCP in order to conceive found the quickest return to fertility among women who used the barrier method. The main outcome, percent of women who delivered within 12 months of discontinuation, was highest in the barrier method cohort and lowest in the OCP cohort (54% vs 32%; P=.002). The difference in delivery rates between the IUD and OCP groups at 12 months wasn’t statistically significant (39% vs 32%). By 18 months after cessation of contraception, the delivery rates in all 3 groups were similar (76%, 67%, and 70% for barrier, OCP, and IUD use, respectively).5

 

 

A retrospective cohort study that compared 36 nulliparous women with 83 parous women 18 to 41 years of age who were trying to conceive after removal of the GyneFix (copper) IUD found no statistical difference in pregnancy rates for age or duration of IUD use. Among women younger than 30 years, nulliparous women conceived earlier than parous women; cumulative pregnancy rates after 12 months were 100% for nulliparous and 80% for parous women (P=.007). No ectopic pregnancies were observed.6

Recommendations

The United Kingdom’s National Institute for Health and Clinical Excellence states that IUD use isn’t contraindicated in nulliparous women of any age, and that women of all ages may use IUDs. The Institute also states that no specific restrictions limit the use of copper or levonorgestrel IUDs by adolescents.

All women at risk for sexually transmitted infections may need to be tested before insertion. No evidence exists for a delay in return to fertility after removal or expulsion of an IUD.7

References

1. Suhonen S, Haukkamaa M, Jakobsson T, et al. Clinical performance of a levonorgestrel releasing intrauterine system and oral contraceptives in young nulliparous women: a comparative study. Contraception. 2004;69:407-412.

2. Paterson H, Ashton J, Harrison-Woolrych M. A nationwide cohort study of the use of the levonorgestrel intrauterine device in New Zealand adolescents. Contraception. 2009;79:433-438.

3. Brockmeyer A, Kishen M, Webb A. Experience of IUD/IUS insertions and clinical performance in nulliparous women—a pilot study. Eur J Contracept Reprod Health Care. 2008;13:248-254.

4. Veldhuis HM, Vos AG, Lagro-Janssen ALM. Complications of the intrauterine device in nulliparous and parous women. Eur J Gen Pract. 2004;10:82-87.

5. Doll H, Vessey M, Painter R. Return of fertility in nulliparous women after discontinuation of the intrauterine device: comparison with women discontinuing other methods of contraception. BJOG. 2001;108:304-314.

6. Delbarge W, Batar I, Bafort M, et al. Return to fertility in nulliparous women after removal of the GyneFix intrauterine contraceptive system. Eur J Contracept Reprod Health Care. 2002;7:24-30.

7. National Collaborating Centre for Women’s and Children’s Health, National Institute for Health and Clinical Excellence. Long-Acting Reversible Contraception: The Effect and Appropriate Use of Long-Acting Reversible Contraception. NICE Clinical Guidelines, No. 30. London, UK: RCOG Press; October 2005. Available at: http://www.ncbi.nlm.nih.gov/books/NBK51051. Accessed October 17, 2012.

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Elizabeth Meza Shih, MD
Department of Family Medicine, University of North Carolina at Chapel Hill

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina at Chapel Hill

Gina Cahoon Firnhaber, RN, MSN, MLS
Laupus Health Sciences Library, East Carolina University at Greenville, NC

ASSISTANT EDITOR
Anne L. Mounsey, MD
University of North Carolina, Chapel Hill

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Elizabeth Meza Shih;MD; Adam J. Zolotor;MD;MPH; Gina Cahoon Firnhaber;RN;MSN;MLS; intrauterine devices; levonorgestrel IUDs; menstrual bleeding; OCPs; expulsion rates; adolescents; nulliparous women
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Elizabeth Meza Shih, MD
Department of Family Medicine, University of North Carolina at Chapel Hill

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina at Chapel Hill

Gina Cahoon Firnhaber, RN, MSN, MLS
Laupus Health Sciences Library, East Carolina University at Greenville, NC

ASSISTANT EDITOR
Anne L. Mounsey, MD
University of North Carolina, Chapel Hill

Author and Disclosure Information

Elizabeth Meza Shih, MD
Department of Family Medicine, University of North Carolina at Chapel Hill

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina at Chapel Hill

Gina Cahoon Firnhaber, RN, MSN, MLS
Laupus Health Sciences Library, East Carolina University at Greenville, NC

ASSISTANT EDITOR
Anne L. Mounsey, MD
University of North Carolina, Chapel Hill

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EVIDENCE-BASED ANSWER

LITTLE AVAILABLE EVIDENCE specifically addresses the benefits and risks of intrauterine devices (IUDs) in adolescents. Most studies have evaluated IUD use in nulliparous adults.

Levonorgestrel IUDs cause less menstrual bleeding than oral contraceptive pills (OCPs) in adult nulliparous women without differences in complications or pregnancy rates (strength of recommendation [SOR]: B, one RCT).

Levonorgestrel IUDs appear to have similar expulsion and continuation rates in adolescents and adults (SOR: B, one prospective study). Adult nulliparous women who discontinue IUDs have subsequent birth rates similar to women who stop using OCPs or barrier methods. (SOR: B, limited quality evidence).

 

Evidence summary

One RCT that compared the levonorgestrel IUD (Mirena) with oral contraceptives in 200 nulliparous women 18 to 25 years of age found the IUD to have equivalent safety and efficacy to OCPs.1 Moreover, the IUD group experienced a significant decrease in bleeding, with a number needed to treat of 4 (P=.001).

Neither group reported any pregnancies or pelvic inflammatory disease at one year. The overall discontinuation rate at one year was 20% for IUDs and 27% for OCPs (P=not significant [NS]).1 Multiple studies show no unintended pregnancies with the IUD.1-3

Study of adolescents finds low complication rate
A prospective cohort study of 179 adolescents 10 to 19 years of age found that the overall incidence of complications with the levonorgestrel IUD was relatively low, with removal rates of 8/179 (4.5%) each for pain and abnormal vaginal bleeding. The cumulative incidence of expulsion was estimated at 8.3% (95% confidence interval [CI], 4.2%-14.3%). No cases of uterine perforation were identified, and the one-year continuation rate was 85% (95% CI, 77%-90%).2 Other studies haven’t evaluated adolescents as a separate group.

IUDs are also well tolerated in an older cohort
A cohort study of 113 nulliparous women 16 to 30 years of age found insertion of a copper or levonorgestrel IUD to be well tolerated; no perforations were observed. At one year, 65 women (58%) still had their original IUD, 15 (13%) had had it removed, 6 (5%) had experienced expulsion, and 27 (24%) were lost to follow-up.3

Abdominal and back pain can be a problem
An RCT of 200 nulliparous women 18 to 25 years of age found that levonorgestrel IUDs were associated with more abdominal and back pain at 12 months than OCPs (54.7% of women with IUDs had pain vs 40% of women with OCPs; number needed to harm=7; P=.007). Pain was the leading cause of discontinuation in the IUD group (6 women with IUDs stopped using them vs no OCP users; P=.012).1

No difference in IUD complications in nulliparous vs parous women
A retrospective cohort study compared 129 nulliparous women with 332 parous women 17 to 52 years of age who had either copper or levonorgestrel IUDs. The researchers found no differences between the 2 groups in rates of perforation, pelvic inflammatory disease, ectopic pregnancy, or expulsion.4

Fertility after IUD removal: An encouraging picture
No studies have evaluated fertility after IUD use exclusively in adolescents. A prospective cohort study of 558 nulliparous women ages 18 to 40 years who stopped using a barrier method, copper IUD, or OCP in order to conceive found the quickest return to fertility among women who used the barrier method. The main outcome, percent of women who delivered within 12 months of discontinuation, was highest in the barrier method cohort and lowest in the OCP cohort (54% vs 32%; P=.002). The difference in delivery rates between the IUD and OCP groups at 12 months wasn’t statistically significant (39% vs 32%). By 18 months after cessation of contraception, the delivery rates in all 3 groups were similar (76%, 67%, and 70% for barrier, OCP, and IUD use, respectively).5

 

 

A retrospective cohort study that compared 36 nulliparous women with 83 parous women 18 to 41 years of age who were trying to conceive after removal of the GyneFix (copper) IUD found no statistical difference in pregnancy rates for age or duration of IUD use. Among women younger than 30 years, nulliparous women conceived earlier than parous women; cumulative pregnancy rates after 12 months were 100% for nulliparous and 80% for parous women (P=.007). No ectopic pregnancies were observed.6

Recommendations

The United Kingdom’s National Institute for Health and Clinical Excellence states that IUD use isn’t contraindicated in nulliparous women of any age, and that women of all ages may use IUDs. The Institute also states that no specific restrictions limit the use of copper or levonorgestrel IUDs by adolescents.

All women at risk for sexually transmitted infections may need to be tested before insertion. No evidence exists for a delay in return to fertility after removal or expulsion of an IUD.7

EVIDENCE-BASED ANSWER

LITTLE AVAILABLE EVIDENCE specifically addresses the benefits and risks of intrauterine devices (IUDs) in adolescents. Most studies have evaluated IUD use in nulliparous adults.

Levonorgestrel IUDs cause less menstrual bleeding than oral contraceptive pills (OCPs) in adult nulliparous women without differences in complications or pregnancy rates (strength of recommendation [SOR]: B, one RCT).

Levonorgestrel IUDs appear to have similar expulsion and continuation rates in adolescents and adults (SOR: B, one prospective study). Adult nulliparous women who discontinue IUDs have subsequent birth rates similar to women who stop using OCPs or barrier methods. (SOR: B, limited quality evidence).

 

Evidence summary

One RCT that compared the levonorgestrel IUD (Mirena) with oral contraceptives in 200 nulliparous women 18 to 25 years of age found the IUD to have equivalent safety and efficacy to OCPs.1 Moreover, the IUD group experienced a significant decrease in bleeding, with a number needed to treat of 4 (P=.001).

Neither group reported any pregnancies or pelvic inflammatory disease at one year. The overall discontinuation rate at one year was 20% for IUDs and 27% for OCPs (P=not significant [NS]).1 Multiple studies show no unintended pregnancies with the IUD.1-3

Study of adolescents finds low complication rate
A prospective cohort study of 179 adolescents 10 to 19 years of age found that the overall incidence of complications with the levonorgestrel IUD was relatively low, with removal rates of 8/179 (4.5%) each for pain and abnormal vaginal bleeding. The cumulative incidence of expulsion was estimated at 8.3% (95% confidence interval [CI], 4.2%-14.3%). No cases of uterine perforation were identified, and the one-year continuation rate was 85% (95% CI, 77%-90%).2 Other studies haven’t evaluated adolescents as a separate group.

IUDs are also well tolerated in an older cohort
A cohort study of 113 nulliparous women 16 to 30 years of age found insertion of a copper or levonorgestrel IUD to be well tolerated; no perforations were observed. At one year, 65 women (58%) still had their original IUD, 15 (13%) had had it removed, 6 (5%) had experienced expulsion, and 27 (24%) were lost to follow-up.3

Abdominal and back pain can be a problem
An RCT of 200 nulliparous women 18 to 25 years of age found that levonorgestrel IUDs were associated with more abdominal and back pain at 12 months than OCPs (54.7% of women with IUDs had pain vs 40% of women with OCPs; number needed to harm=7; P=.007). Pain was the leading cause of discontinuation in the IUD group (6 women with IUDs stopped using them vs no OCP users; P=.012).1

No difference in IUD complications in nulliparous vs parous women
A retrospective cohort study compared 129 nulliparous women with 332 parous women 17 to 52 years of age who had either copper or levonorgestrel IUDs. The researchers found no differences between the 2 groups in rates of perforation, pelvic inflammatory disease, ectopic pregnancy, or expulsion.4

Fertility after IUD removal: An encouraging picture
No studies have evaluated fertility after IUD use exclusively in adolescents. A prospective cohort study of 558 nulliparous women ages 18 to 40 years who stopped using a barrier method, copper IUD, or OCP in order to conceive found the quickest return to fertility among women who used the barrier method. The main outcome, percent of women who delivered within 12 months of discontinuation, was highest in the barrier method cohort and lowest in the OCP cohort (54% vs 32%; P=.002). The difference in delivery rates between the IUD and OCP groups at 12 months wasn’t statistically significant (39% vs 32%). By 18 months after cessation of contraception, the delivery rates in all 3 groups were similar (76%, 67%, and 70% for barrier, OCP, and IUD use, respectively).5

 

 

A retrospective cohort study that compared 36 nulliparous women with 83 parous women 18 to 41 years of age who were trying to conceive after removal of the GyneFix (copper) IUD found no statistical difference in pregnancy rates for age or duration of IUD use. Among women younger than 30 years, nulliparous women conceived earlier than parous women; cumulative pregnancy rates after 12 months were 100% for nulliparous and 80% for parous women (P=.007). No ectopic pregnancies were observed.6

Recommendations

The United Kingdom’s National Institute for Health and Clinical Excellence states that IUD use isn’t contraindicated in nulliparous women of any age, and that women of all ages may use IUDs. The Institute also states that no specific restrictions limit the use of copper or levonorgestrel IUDs by adolescents.

All women at risk for sexually transmitted infections may need to be tested before insertion. No evidence exists for a delay in return to fertility after removal or expulsion of an IUD.7

References

1. Suhonen S, Haukkamaa M, Jakobsson T, et al. Clinical performance of a levonorgestrel releasing intrauterine system and oral contraceptives in young nulliparous women: a comparative study. Contraception. 2004;69:407-412.

2. Paterson H, Ashton J, Harrison-Woolrych M. A nationwide cohort study of the use of the levonorgestrel intrauterine device in New Zealand adolescents. Contraception. 2009;79:433-438.

3. Brockmeyer A, Kishen M, Webb A. Experience of IUD/IUS insertions and clinical performance in nulliparous women—a pilot study. Eur J Contracept Reprod Health Care. 2008;13:248-254.

4. Veldhuis HM, Vos AG, Lagro-Janssen ALM. Complications of the intrauterine device in nulliparous and parous women. Eur J Gen Pract. 2004;10:82-87.

5. Doll H, Vessey M, Painter R. Return of fertility in nulliparous women after discontinuation of the intrauterine device: comparison with women discontinuing other methods of contraception. BJOG. 2001;108:304-314.

6. Delbarge W, Batar I, Bafort M, et al. Return to fertility in nulliparous women after removal of the GyneFix intrauterine contraceptive system. Eur J Contracept Reprod Health Care. 2002;7:24-30.

7. National Collaborating Centre for Women’s and Children’s Health, National Institute for Health and Clinical Excellence. Long-Acting Reversible Contraception: The Effect and Appropriate Use of Long-Acting Reversible Contraception. NICE Clinical Guidelines, No. 30. London, UK: RCOG Press; October 2005. Available at: http://www.ncbi.nlm.nih.gov/books/NBK51051. Accessed October 17, 2012.

References

1. Suhonen S, Haukkamaa M, Jakobsson T, et al. Clinical performance of a levonorgestrel releasing intrauterine system and oral contraceptives in young nulliparous women: a comparative study. Contraception. 2004;69:407-412.

2. Paterson H, Ashton J, Harrison-Woolrych M. A nationwide cohort study of the use of the levonorgestrel intrauterine device in New Zealand adolescents. Contraception. 2009;79:433-438.

3. Brockmeyer A, Kishen M, Webb A. Experience of IUD/IUS insertions and clinical performance in nulliparous women—a pilot study. Eur J Contracept Reprod Health Care. 2008;13:248-254.

4. Veldhuis HM, Vos AG, Lagro-Janssen ALM. Complications of the intrauterine device in nulliparous and parous women. Eur J Gen Pract. 2004;10:82-87.

5. Doll H, Vessey M, Painter R. Return of fertility in nulliparous women after discontinuation of the intrauterine device: comparison with women discontinuing other methods of contraception. BJOG. 2001;108:304-314.

6. Delbarge W, Batar I, Bafort M, et al. Return to fertility in nulliparous women after removal of the GyneFix intrauterine contraceptive system. Eur J Contracept Reprod Health Care. 2002;7:24-30.

7. National Collaborating Centre for Women’s and Children’s Health, National Institute for Health and Clinical Excellence. Long-Acting Reversible Contraception: The Effect and Appropriate Use of Long-Acting Reversible Contraception. NICE Clinical Guidelines, No. 30. London, UK: RCOG Press; October 2005. Available at: http://www.ncbi.nlm.nih.gov/books/NBK51051. Accessed October 17, 2012.

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What are the benefits and risks of IUDs in adolescents?
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What are the benefits and risks of IUDs in adolescents?
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Elizabeth Meza Shih;MD; Adam J. Zolotor;MD;MPH; Gina Cahoon Firnhaber;RN;MSN;MLS; intrauterine devices; levonorgestrel IUDs; menstrual bleeding; OCPs; expulsion rates; adolescents; nulliparous women
Legacy Keywords
Elizabeth Meza Shih;MD; Adam J. Zolotor;MD;MPH; Gina Cahoon Firnhaber;RN;MSN;MLS; intrauterine devices; levonorgestrel IUDs; menstrual bleeding; OCPs; expulsion rates; adolescents; nulliparous women
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PSA testing: When it’s useful, when it’s not

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PSA testing: When it’s useful, when it’s not

 

PRACTICE CHANGER

Do not routinely screen all men over the age of 50 for prostate cancer with the prostate-specific antigen (PSA) test. Consider screening men younger than 75 with no cardiovascular or cancer risk factors—the only patient population for whom PSA testing appears to provide even a small benefit.1,2

STRENGTH OF RECOMMENDATION

B: Based on a meta-analysis of 6 randomized controlled trials (RCTs) with methodological limitations, and a post hoc analysis of a large RCT.

Djulbegovic M, Beyth RJ, Neuberger MM, et al. Screening for prostate cancer: systematic review and meta-analysis of randomized controlled trials. BMJ. 2010;341:c4543.

Crawford ED, Grubb R 3rd, Black A, et al. Comorbidity and mortality results from a randomized prostate cancer screening trial. J Clin Oncol. 2011;29:355-361.

ILLUSTRATIVE CASES

A 65-year-old obese man with high blood pressure comes in for a complete physical and asks if he should have the “blood test for cancer.” He had a normal prostate specific antigen (PSA) the last time he was tested, but that was 10 years ago. What should you tell him?

A 55-year-old man schedules a routine check-up and requests a PSA test. His last test, at age 50, was normal. The patient has no known medical problems and no family history of prostate cancer, and he exercises regularly and doesn’t smoke. How should you respond to his request for a PSA test?

Prostate cancer is the second leading cause of cancer deaths among men in the United States, after lung cancer. One in 6 American men will be diagnosed with prostate cancer; for about 3% of them, the cancer will be fatal.3,4

Widespread testing without evidence of efficacy
The PSA test was approved by the US Food and Drug Administration (FDA) in 1986.5 Its potential to detect early prostate cancer in the hope of decreasing morbidity and mortality led to widespread PSA screening in the 1990s, before data on the efficacy of routine screening existed.

By 2002, only one low-quality RCT that compared screening with no screening had been published. The investigators concluded that screening resulted in lower mortality rates, but a subsequent (and superior) intention-to-treat analysis showed no mortality benefit.6 Two large RCTs, both published in 2009, reported conflicting results.7,8

The European Randomized Study of Screening for Prostate Cancer (ERSPC) enrolled 182,000 men ages 50 to 74 years and randomized them to either PSA screening every 4 years or no screening. Prostate cancer-specific mortality was 20% lower for those in the screening group compared with the no-screening group; however, the absolute risk reduction was only 0.71 deaths per 1000 men.7

The US Prostate, Lung, Colorectal, Ovarian Cancer (PLCO) Screening Trial randomized 77,000 men ages 55 to 74 years to either annual PSA and digital rectal examination (DRE) screening or usual care. After 7 years of follow-up, no significant difference was found in prostate cancer deaths or all-cause mortality in the screening group vs the control group. It is important to note, however, that 52% of the men in the control group had ≥1 PSA screening during the study period, which decreased the researchers’ ability to fully assess the benefits of screening.8

PSA’s limitations and potential harmful effects
The PSA test’s significant limitations and potentially harmful effects counter the potential benefits of screening. About 75% of positive tests are false positives, which are associated with psychological harm in some men for up to a year after the test.6 In addition, diagnostic testing and treatment for what may be nonlife-threatening prostate cancer can cause harm, including erectile dysfunction (ED), urinary incontinence, bowel dysfunction, and death. Rates of ED and incontinence 18 months after radical prostatectomy are an estimated 59.9% and 8.4%, respectively.9

 

Do the benefits of PSA testing outweigh the harms—and for which men? The meta-analysis and post hoc analysis detailed in this PURL help clear up the controversy.

STUDY SUMMARY: Widespread screening doesn’t save lives

Djulbegovic et al examined 6 RCTs, including the ERSPC and PLCO studies described earlier, that compared screening for prostate cancer (PSA with or without DRE) with no screening or usual care.1 Together, the studies included nearly 390,000 men ages 45 to 80 years, and had 4 to 15 years of follow-up. The results showed that routine screening for prostate cancer had no statistically significant effect on all-cause mortality (relative risk [RR]=0.99; 95% confidence interval [CI], 0.97-1.01), death from prostate cancer (RR=0.88; 95% CI, 0.71-1.09), or diagnosis of stage III or IV prostate cancer (RR=0.94; 95% CI, 0.85-1.04). Routine screening did, however, increase the probability of being diagnosed with prostate cancer at any stage, especially at stage I. For every 1000 men screened, on average, 20 more cases of prostate cancer were diagnosed.

 

 

Healthy men may benefit from screening
Crawford et al conducted a post hoc analysis of the PLCO trial, which had found no benefit to annual PSA testing and serial DRE compared with usual care for the general population.2 Their analysis compared the mortality benefits (both prostate cancer–specific and overall) of annual PSA screening for healthy men with no or minimal comorbidities vs the mortality benefits for men with any risk factor for the 2 leading causes of death: cancer and cardiovascular disease.

Annual PSA testing yielded more diagnoses of prostate cancer in both healthy and at-risk men. Deaths from prostate cancer were infrequent in both groups, occurring in 0.22% (164/73,378) of all participants.

Men with ≥1 risk factor had similar prostate cancer–specific deaths with both yearly screening and usual care (62 vs 42 deaths, adjusted hazard ratio [AHR]=1.43; 95% CI, 0.96-2.11); their prostate cancer–specific mortality rate was 0.27% (95% CI, 0.21-0.34) and 0.19% (95% CI, 0.14-0.25), respectively.

However, healthy men younger than 75 years had fewer prostate cancer–specific deaths with annual PSA screenings (22 vs 38; AHR=0.56; 95% CI, 0.33-0.95; P=.03). Specifically, the prostate cancer mortality rate was 0.17% (95% CI, 0.11-0.25) in the group that received screening vs 0.31% (95% CI, 0.22-0.42) in the usual care group. Thus, the absolute risk reduction for prostate cancer-specific mortality in men without comorbidities who received yearly screening instead of usual care was 0.14% (0.31% vs 0.17%, P=.03), with a number needed to screen of 723 to prevent one death from prostate cancer. There was a non-significant reduction in all-cause mortality in the intervention group vs the control group (AHR=0.93; 95% CI, 0.86-1.02; P=.11).

WHAT’S NEW: At best, screening has a small benefit

These trials indicate that only a small group of men will potentially benefit from PSA screening. Prior to this meta-analysis, a Cochrane review published in 2006 had concluded that there was insufficient evidence to support or refute the routine use of mass screening for prostate can-cer.10 The meta-analysis by Djulbegovic et al, which included 4 additional trials, 2 of them large, found no benefit of PSA screening in reducing mortality from prostate cancer for the general population.1

Annual screening does appear to provide a small reduction in prostate cancer deaths but no significant reduction in all-cause mortality in men younger than age 75 who have no risk factors for cancer or cardiovascular disease.

 

CAVEATS: Study limitations, some unknowns

These studies did not address whether certain groups at higher risk of developing prostate cancer, such as African American men and those with a family history of prostate cancer, would benefit from PSA screening. In addition, both of the studies detailed in this PURL had substantive weaknesses.

Methodological limitations of the studies in the meta-analysis included the lack of intention-to-treat analysis and allocation concealment, which favors finding a benefit for the screening arm, and PSA screening in the nonscreening arm, which biases the results toward not finding a screening benefit that might exist. Despite these weaknesses, this meta-analysis brings together the best available evidence of the value of screening for prostate cancer.

In addition, there was no quantitative assessment of complication rates included in the meta-analysis. None of the 6 trials collected data on the effect of screening or treatment on participants’ quality of life.

In the post hoc study showing a benefit for screening healthy men, the decrease in prostate cancer deaths was small in magnitude, did not have an impact on all-cause mortality, and was of marginal statistical significance. Although the data came from the largest multicenter study to date of prostate cancer screening, the results of a post hoc analysis of a single trial should be interpreted with caution. The study was initially designed to test the effect of screening on a general population. Whenever a study deviates from the original hypothesis to evaluate a subset of the study population, the investigators increase the risk of finding a difference where none exists. Thus, it is possible that the findings of benefit for healthy men may not truly be present.

What’s more, the risk factors identified by the authors could be interpreted as arbitrary. They included diverticulosis, which is not known to increase the likelihood of cancer or heart disease, as a risk factor. By the same token, smoking—a known risk factor for both cancer and cardiovascular disease—was not addressed. Finally, potential harms associated with false-positive tests and prostate cancer treatment were not addressed in these studies.

 

 

CHALLENGES TO IMPLEMENTATION: Old habits die hard

Clinicians have recommended PSA screening for men >50 years, and men have requested such screening, for more than 2 decades. Physicians often opt to order a PSA test rather than to take the time to explain potential harms and benefits and listen to the patient’s thoughts and feelings about the value of screening. In addition, physicians who believe the lack of benefit from screening does not apply to their patients will continue to order the PSA test. (See “The perils of PSA screening”.)

Patients may opt to continue to be screened although they have developed a risk factor for cardiovascular disease. Also, a decision not to screen directly contradicts the recommendation of the American Urological Association, which calls for annual PSA testing for asymptomatic men with a life expectancy >10 years starting at 40 years of age.11

Shared decision-making
The US Preventive Services Task Force (USPSTF) provides a basis for shared decision-making between physicians and patients concerning prostate cancer screening. The USPSTF states that there is insufficient evidence to recommend for or against prostate cancer screening for the general male population younger than age 75 and recommends against screening men age 75 and older or those with a life expectancy of less than 10 years.12

Decisions regarding PSA screening should be shared and documented for all men between the ages of 50 and 75 years. Advise patients with risk factors that the evidence shows little value and possible harm from screening. Tell healthier men that PSA testing appears to offer a small benefit, at best.

Acknowledgement

The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center for Research Resources; the grant is a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

References

 

1. Djulbegovic M, Beyth RJ, Neuberger MM, et al. Screening for prostate cancer: systematic review and meta-analysis of randomized controlled trials. BMJ. 2010;341:c4543.-

2. Crawford ED, Grubb R, 3rd, Black A, et al. Comorbidity and mortality results from a randomized prostate cancer screening trial. J Clin Oncol. 2011;29:355-361.

3. American Cancer Society. Cancer facts & figures 2010. Atlanta, Ga: American Cancer Society; 2010. Available at: http://www.cancer.org/acs/groups/content/@nho/documents/document/acspc-024113.pdf. Accessed April 13, 2011.

4. American Cancer Society. Prostate cancer. Last medical review November 22, 2010. Available at: http://www.cancer.org/cancer/prostatecancer/detailedguide/prostate-cancer-key-statistics. Accessed April 13, 2011.

5. National Institutes of Health. Prostate cancer. Last updated February 14, 2011. Available at: http://report.nih.gov/NIHfactsheets/ViewFactSheet.aspx?csid=60. Accessed May 9, 2011.

6. Lin K, Lipsitz R, Miller T, et al. Benefits and harms of prostate-specific antigen screening for prostate cancer: an evidence update for the U.S. Preventive Services Task Force. Ann Intern Med. 2008;149:192-199.

7. Schroder FH, Hugosson J, Roobol MJ, et al. Screening and prostate-cancer mortality in a randomized European study. N Engl J Med. 2009;360:1320-1328.

8. Andriole GL, Crawford ED, Grubb RL, 3rd, et al. Mortality results from a randomized prostate-cancer screening trial. N Engl J Med. 2009;360:1310-1319.

9. Stanford JL, Feng Z, Hamilton AS, et al. Urinary and sexual function after radical prostatectomy for clinically localized prostate cancer: the Prostate Cancer Outcomes Study. JAMA. 2000;283:354-360.

10. Ilic D, O’Connor D, Greens, Wilt T. Screening for prostate cancer. Cochrane Database Syst Rev. 2006;(3):CD004720.-

11. American Urological Association. Prostate-specific antigen best practice statement: 2009 update. Available at: http://www.auanet.org/content/guidelines-and-quality-care/clinical-guidelines/main-reports/psa09.pdf. Accessed March 16, 2011.

12. US Preventive Services Task Force. Screening for prostate cancer: US Preventive Services Task Force recommendation statement. Ann Intern Med. 2008;149:185-191.

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Susan Slatkoff, MD
Department of Family Medicine, University of North Carolina, Chapel Hill

Stephen Gamboa, MD, MPH
Departments of Family Medicine and Emergency Medicine, University of North Carolina, Chapel Hill

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Chapel Hill

Anne L. Mounsey, MD
Department of Family Medicine, University of North Carolina, Chapel Hill

Kohar Jones, MD
Department of Family Medicine, University of Chicago

PURLs EDITORS
John Hickner, MD, MSc
Cleveland Clinic

Kate Rowland, MD
Department of Family Medicine, University of Chicago

Issue
The Journal of Family Practice - 60(6)
Publications
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Page Number
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PSA testing; when it's useful; prostate-specific antigen; digital rectal exam; Kate Rowland; Susan Slatkoff; potential harms; PSA screening
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Susan Slatkoff, MD
Department of Family Medicine, University of North Carolina, Chapel Hill

Stephen Gamboa, MD, MPH
Departments of Family Medicine and Emergency Medicine, University of North Carolina, Chapel Hill

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Chapel Hill

Anne L. Mounsey, MD
Department of Family Medicine, University of North Carolina, Chapel Hill

Kohar Jones, MD
Department of Family Medicine, University of Chicago

PURLs EDITORS
John Hickner, MD, MSc
Cleveland Clinic

Kate Rowland, MD
Department of Family Medicine, University of Chicago

Author and Disclosure Information

 

Susan Slatkoff, MD
Department of Family Medicine, University of North Carolina, Chapel Hill

Stephen Gamboa, MD, MPH
Departments of Family Medicine and Emergency Medicine, University of North Carolina, Chapel Hill

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Chapel Hill

Anne L. Mounsey, MD
Department of Family Medicine, University of North Carolina, Chapel Hill

Kohar Jones, MD
Department of Family Medicine, University of Chicago

PURLs EDITORS
John Hickner, MD, MSc
Cleveland Clinic

Kate Rowland, MD
Department of Family Medicine, University of Chicago

Article PDF
Article PDF

 

PRACTICE CHANGER

Do not routinely screen all men over the age of 50 for prostate cancer with the prostate-specific antigen (PSA) test. Consider screening men younger than 75 with no cardiovascular or cancer risk factors—the only patient population for whom PSA testing appears to provide even a small benefit.1,2

STRENGTH OF RECOMMENDATION

B: Based on a meta-analysis of 6 randomized controlled trials (RCTs) with methodological limitations, and a post hoc analysis of a large RCT.

Djulbegovic M, Beyth RJ, Neuberger MM, et al. Screening for prostate cancer: systematic review and meta-analysis of randomized controlled trials. BMJ. 2010;341:c4543.

Crawford ED, Grubb R 3rd, Black A, et al. Comorbidity and mortality results from a randomized prostate cancer screening trial. J Clin Oncol. 2011;29:355-361.

ILLUSTRATIVE CASES

A 65-year-old obese man with high blood pressure comes in for a complete physical and asks if he should have the “blood test for cancer.” He had a normal prostate specific antigen (PSA) the last time he was tested, but that was 10 years ago. What should you tell him?

A 55-year-old man schedules a routine check-up and requests a PSA test. His last test, at age 50, was normal. The patient has no known medical problems and no family history of prostate cancer, and he exercises regularly and doesn’t smoke. How should you respond to his request for a PSA test?

Prostate cancer is the second leading cause of cancer deaths among men in the United States, after lung cancer. One in 6 American men will be diagnosed with prostate cancer; for about 3% of them, the cancer will be fatal.3,4

Widespread testing without evidence of efficacy
The PSA test was approved by the US Food and Drug Administration (FDA) in 1986.5 Its potential to detect early prostate cancer in the hope of decreasing morbidity and mortality led to widespread PSA screening in the 1990s, before data on the efficacy of routine screening existed.

By 2002, only one low-quality RCT that compared screening with no screening had been published. The investigators concluded that screening resulted in lower mortality rates, but a subsequent (and superior) intention-to-treat analysis showed no mortality benefit.6 Two large RCTs, both published in 2009, reported conflicting results.7,8

The European Randomized Study of Screening for Prostate Cancer (ERSPC) enrolled 182,000 men ages 50 to 74 years and randomized them to either PSA screening every 4 years or no screening. Prostate cancer-specific mortality was 20% lower for those in the screening group compared with the no-screening group; however, the absolute risk reduction was only 0.71 deaths per 1000 men.7

The US Prostate, Lung, Colorectal, Ovarian Cancer (PLCO) Screening Trial randomized 77,000 men ages 55 to 74 years to either annual PSA and digital rectal examination (DRE) screening or usual care. After 7 years of follow-up, no significant difference was found in prostate cancer deaths or all-cause mortality in the screening group vs the control group. It is important to note, however, that 52% of the men in the control group had ≥1 PSA screening during the study period, which decreased the researchers’ ability to fully assess the benefits of screening.8

PSA’s limitations and potential harmful effects
The PSA test’s significant limitations and potentially harmful effects counter the potential benefits of screening. About 75% of positive tests are false positives, which are associated with psychological harm in some men for up to a year after the test.6 In addition, diagnostic testing and treatment for what may be nonlife-threatening prostate cancer can cause harm, including erectile dysfunction (ED), urinary incontinence, bowel dysfunction, and death. Rates of ED and incontinence 18 months after radical prostatectomy are an estimated 59.9% and 8.4%, respectively.9

 

Do the benefits of PSA testing outweigh the harms—and for which men? The meta-analysis and post hoc analysis detailed in this PURL help clear up the controversy.

STUDY SUMMARY: Widespread screening doesn’t save lives

Djulbegovic et al examined 6 RCTs, including the ERSPC and PLCO studies described earlier, that compared screening for prostate cancer (PSA with or without DRE) with no screening or usual care.1 Together, the studies included nearly 390,000 men ages 45 to 80 years, and had 4 to 15 years of follow-up. The results showed that routine screening for prostate cancer had no statistically significant effect on all-cause mortality (relative risk [RR]=0.99; 95% confidence interval [CI], 0.97-1.01), death from prostate cancer (RR=0.88; 95% CI, 0.71-1.09), or diagnosis of stage III or IV prostate cancer (RR=0.94; 95% CI, 0.85-1.04). Routine screening did, however, increase the probability of being diagnosed with prostate cancer at any stage, especially at stage I. For every 1000 men screened, on average, 20 more cases of prostate cancer were diagnosed.

 

 

Healthy men may benefit from screening
Crawford et al conducted a post hoc analysis of the PLCO trial, which had found no benefit to annual PSA testing and serial DRE compared with usual care for the general population.2 Their analysis compared the mortality benefits (both prostate cancer–specific and overall) of annual PSA screening for healthy men with no or minimal comorbidities vs the mortality benefits for men with any risk factor for the 2 leading causes of death: cancer and cardiovascular disease.

Annual PSA testing yielded more diagnoses of prostate cancer in both healthy and at-risk men. Deaths from prostate cancer were infrequent in both groups, occurring in 0.22% (164/73,378) of all participants.

Men with ≥1 risk factor had similar prostate cancer–specific deaths with both yearly screening and usual care (62 vs 42 deaths, adjusted hazard ratio [AHR]=1.43; 95% CI, 0.96-2.11); their prostate cancer–specific mortality rate was 0.27% (95% CI, 0.21-0.34) and 0.19% (95% CI, 0.14-0.25), respectively.

However, healthy men younger than 75 years had fewer prostate cancer–specific deaths with annual PSA screenings (22 vs 38; AHR=0.56; 95% CI, 0.33-0.95; P=.03). Specifically, the prostate cancer mortality rate was 0.17% (95% CI, 0.11-0.25) in the group that received screening vs 0.31% (95% CI, 0.22-0.42) in the usual care group. Thus, the absolute risk reduction for prostate cancer-specific mortality in men without comorbidities who received yearly screening instead of usual care was 0.14% (0.31% vs 0.17%, P=.03), with a number needed to screen of 723 to prevent one death from prostate cancer. There was a non-significant reduction in all-cause mortality in the intervention group vs the control group (AHR=0.93; 95% CI, 0.86-1.02; P=.11).

WHAT’S NEW: At best, screening has a small benefit

These trials indicate that only a small group of men will potentially benefit from PSA screening. Prior to this meta-analysis, a Cochrane review published in 2006 had concluded that there was insufficient evidence to support or refute the routine use of mass screening for prostate can-cer.10 The meta-analysis by Djulbegovic et al, which included 4 additional trials, 2 of them large, found no benefit of PSA screening in reducing mortality from prostate cancer for the general population.1

Annual screening does appear to provide a small reduction in prostate cancer deaths but no significant reduction in all-cause mortality in men younger than age 75 who have no risk factors for cancer or cardiovascular disease.

 

CAVEATS: Study limitations, some unknowns

These studies did not address whether certain groups at higher risk of developing prostate cancer, such as African American men and those with a family history of prostate cancer, would benefit from PSA screening. In addition, both of the studies detailed in this PURL had substantive weaknesses.

Methodological limitations of the studies in the meta-analysis included the lack of intention-to-treat analysis and allocation concealment, which favors finding a benefit for the screening arm, and PSA screening in the nonscreening arm, which biases the results toward not finding a screening benefit that might exist. Despite these weaknesses, this meta-analysis brings together the best available evidence of the value of screening for prostate cancer.

In addition, there was no quantitative assessment of complication rates included in the meta-analysis. None of the 6 trials collected data on the effect of screening or treatment on participants’ quality of life.

In the post hoc study showing a benefit for screening healthy men, the decrease in prostate cancer deaths was small in magnitude, did not have an impact on all-cause mortality, and was of marginal statistical significance. Although the data came from the largest multicenter study to date of prostate cancer screening, the results of a post hoc analysis of a single trial should be interpreted with caution. The study was initially designed to test the effect of screening on a general population. Whenever a study deviates from the original hypothesis to evaluate a subset of the study population, the investigators increase the risk of finding a difference where none exists. Thus, it is possible that the findings of benefit for healthy men may not truly be present.

What’s more, the risk factors identified by the authors could be interpreted as arbitrary. They included diverticulosis, which is not known to increase the likelihood of cancer or heart disease, as a risk factor. By the same token, smoking—a known risk factor for both cancer and cardiovascular disease—was not addressed. Finally, potential harms associated with false-positive tests and prostate cancer treatment were not addressed in these studies.

 

 

CHALLENGES TO IMPLEMENTATION: Old habits die hard

Clinicians have recommended PSA screening for men >50 years, and men have requested such screening, for more than 2 decades. Physicians often opt to order a PSA test rather than to take the time to explain potential harms and benefits and listen to the patient’s thoughts and feelings about the value of screening. In addition, physicians who believe the lack of benefit from screening does not apply to their patients will continue to order the PSA test. (See “The perils of PSA screening”.)

Patients may opt to continue to be screened although they have developed a risk factor for cardiovascular disease. Also, a decision not to screen directly contradicts the recommendation of the American Urological Association, which calls for annual PSA testing for asymptomatic men with a life expectancy >10 years starting at 40 years of age.11

Shared decision-making
The US Preventive Services Task Force (USPSTF) provides a basis for shared decision-making between physicians and patients concerning prostate cancer screening. The USPSTF states that there is insufficient evidence to recommend for or against prostate cancer screening for the general male population younger than age 75 and recommends against screening men age 75 and older or those with a life expectancy of less than 10 years.12

Decisions regarding PSA screening should be shared and documented for all men between the ages of 50 and 75 years. Advise patients with risk factors that the evidence shows little value and possible harm from screening. Tell healthier men that PSA testing appears to offer a small benefit, at best.

Acknowledgement

The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center for Research Resources; the grant is a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

 

PRACTICE CHANGER

Do not routinely screen all men over the age of 50 for prostate cancer with the prostate-specific antigen (PSA) test. Consider screening men younger than 75 with no cardiovascular or cancer risk factors—the only patient population for whom PSA testing appears to provide even a small benefit.1,2

STRENGTH OF RECOMMENDATION

B: Based on a meta-analysis of 6 randomized controlled trials (RCTs) with methodological limitations, and a post hoc analysis of a large RCT.

Djulbegovic M, Beyth RJ, Neuberger MM, et al. Screening for prostate cancer: systematic review and meta-analysis of randomized controlled trials. BMJ. 2010;341:c4543.

Crawford ED, Grubb R 3rd, Black A, et al. Comorbidity and mortality results from a randomized prostate cancer screening trial. J Clin Oncol. 2011;29:355-361.

ILLUSTRATIVE CASES

A 65-year-old obese man with high blood pressure comes in for a complete physical and asks if he should have the “blood test for cancer.” He had a normal prostate specific antigen (PSA) the last time he was tested, but that was 10 years ago. What should you tell him?

A 55-year-old man schedules a routine check-up and requests a PSA test. His last test, at age 50, was normal. The patient has no known medical problems and no family history of prostate cancer, and he exercises regularly and doesn’t smoke. How should you respond to his request for a PSA test?

Prostate cancer is the second leading cause of cancer deaths among men in the United States, after lung cancer. One in 6 American men will be diagnosed with prostate cancer; for about 3% of them, the cancer will be fatal.3,4

Widespread testing without evidence of efficacy
The PSA test was approved by the US Food and Drug Administration (FDA) in 1986.5 Its potential to detect early prostate cancer in the hope of decreasing morbidity and mortality led to widespread PSA screening in the 1990s, before data on the efficacy of routine screening existed.

By 2002, only one low-quality RCT that compared screening with no screening had been published. The investigators concluded that screening resulted in lower mortality rates, but a subsequent (and superior) intention-to-treat analysis showed no mortality benefit.6 Two large RCTs, both published in 2009, reported conflicting results.7,8

The European Randomized Study of Screening for Prostate Cancer (ERSPC) enrolled 182,000 men ages 50 to 74 years and randomized them to either PSA screening every 4 years or no screening. Prostate cancer-specific mortality was 20% lower for those in the screening group compared with the no-screening group; however, the absolute risk reduction was only 0.71 deaths per 1000 men.7

The US Prostate, Lung, Colorectal, Ovarian Cancer (PLCO) Screening Trial randomized 77,000 men ages 55 to 74 years to either annual PSA and digital rectal examination (DRE) screening or usual care. After 7 years of follow-up, no significant difference was found in prostate cancer deaths or all-cause mortality in the screening group vs the control group. It is important to note, however, that 52% of the men in the control group had ≥1 PSA screening during the study period, which decreased the researchers’ ability to fully assess the benefits of screening.8

PSA’s limitations and potential harmful effects
The PSA test’s significant limitations and potentially harmful effects counter the potential benefits of screening. About 75% of positive tests are false positives, which are associated with psychological harm in some men for up to a year after the test.6 In addition, diagnostic testing and treatment for what may be nonlife-threatening prostate cancer can cause harm, including erectile dysfunction (ED), urinary incontinence, bowel dysfunction, and death. Rates of ED and incontinence 18 months after radical prostatectomy are an estimated 59.9% and 8.4%, respectively.9

 

Do the benefits of PSA testing outweigh the harms—and for which men? The meta-analysis and post hoc analysis detailed in this PURL help clear up the controversy.

STUDY SUMMARY: Widespread screening doesn’t save lives

Djulbegovic et al examined 6 RCTs, including the ERSPC and PLCO studies described earlier, that compared screening for prostate cancer (PSA with or without DRE) with no screening or usual care.1 Together, the studies included nearly 390,000 men ages 45 to 80 years, and had 4 to 15 years of follow-up. The results showed that routine screening for prostate cancer had no statistically significant effect on all-cause mortality (relative risk [RR]=0.99; 95% confidence interval [CI], 0.97-1.01), death from prostate cancer (RR=0.88; 95% CI, 0.71-1.09), or diagnosis of stage III or IV prostate cancer (RR=0.94; 95% CI, 0.85-1.04). Routine screening did, however, increase the probability of being diagnosed with prostate cancer at any stage, especially at stage I. For every 1000 men screened, on average, 20 more cases of prostate cancer were diagnosed.

 

 

Healthy men may benefit from screening
Crawford et al conducted a post hoc analysis of the PLCO trial, which had found no benefit to annual PSA testing and serial DRE compared with usual care for the general population.2 Their analysis compared the mortality benefits (both prostate cancer–specific and overall) of annual PSA screening for healthy men with no or minimal comorbidities vs the mortality benefits for men with any risk factor for the 2 leading causes of death: cancer and cardiovascular disease.

Annual PSA testing yielded more diagnoses of prostate cancer in both healthy and at-risk men. Deaths from prostate cancer were infrequent in both groups, occurring in 0.22% (164/73,378) of all participants.

Men with ≥1 risk factor had similar prostate cancer–specific deaths with both yearly screening and usual care (62 vs 42 deaths, adjusted hazard ratio [AHR]=1.43; 95% CI, 0.96-2.11); their prostate cancer–specific mortality rate was 0.27% (95% CI, 0.21-0.34) and 0.19% (95% CI, 0.14-0.25), respectively.

However, healthy men younger than 75 years had fewer prostate cancer–specific deaths with annual PSA screenings (22 vs 38; AHR=0.56; 95% CI, 0.33-0.95; P=.03). Specifically, the prostate cancer mortality rate was 0.17% (95% CI, 0.11-0.25) in the group that received screening vs 0.31% (95% CI, 0.22-0.42) in the usual care group. Thus, the absolute risk reduction for prostate cancer-specific mortality in men without comorbidities who received yearly screening instead of usual care was 0.14% (0.31% vs 0.17%, P=.03), with a number needed to screen of 723 to prevent one death from prostate cancer. There was a non-significant reduction in all-cause mortality in the intervention group vs the control group (AHR=0.93; 95% CI, 0.86-1.02; P=.11).

WHAT’S NEW: At best, screening has a small benefit

These trials indicate that only a small group of men will potentially benefit from PSA screening. Prior to this meta-analysis, a Cochrane review published in 2006 had concluded that there was insufficient evidence to support or refute the routine use of mass screening for prostate can-cer.10 The meta-analysis by Djulbegovic et al, which included 4 additional trials, 2 of them large, found no benefit of PSA screening in reducing mortality from prostate cancer for the general population.1

Annual screening does appear to provide a small reduction in prostate cancer deaths but no significant reduction in all-cause mortality in men younger than age 75 who have no risk factors for cancer or cardiovascular disease.

 

CAVEATS: Study limitations, some unknowns

These studies did not address whether certain groups at higher risk of developing prostate cancer, such as African American men and those with a family history of prostate cancer, would benefit from PSA screening. In addition, both of the studies detailed in this PURL had substantive weaknesses.

Methodological limitations of the studies in the meta-analysis included the lack of intention-to-treat analysis and allocation concealment, which favors finding a benefit for the screening arm, and PSA screening in the nonscreening arm, which biases the results toward not finding a screening benefit that might exist. Despite these weaknesses, this meta-analysis brings together the best available evidence of the value of screening for prostate cancer.

In addition, there was no quantitative assessment of complication rates included in the meta-analysis. None of the 6 trials collected data on the effect of screening or treatment on participants’ quality of life.

In the post hoc study showing a benefit for screening healthy men, the decrease in prostate cancer deaths was small in magnitude, did not have an impact on all-cause mortality, and was of marginal statistical significance. Although the data came from the largest multicenter study to date of prostate cancer screening, the results of a post hoc analysis of a single trial should be interpreted with caution. The study was initially designed to test the effect of screening on a general population. Whenever a study deviates from the original hypothesis to evaluate a subset of the study population, the investigators increase the risk of finding a difference where none exists. Thus, it is possible that the findings of benefit for healthy men may not truly be present.

What’s more, the risk factors identified by the authors could be interpreted as arbitrary. They included diverticulosis, which is not known to increase the likelihood of cancer or heart disease, as a risk factor. By the same token, smoking—a known risk factor for both cancer and cardiovascular disease—was not addressed. Finally, potential harms associated with false-positive tests and prostate cancer treatment were not addressed in these studies.

 

 

CHALLENGES TO IMPLEMENTATION: Old habits die hard

Clinicians have recommended PSA screening for men >50 years, and men have requested such screening, for more than 2 decades. Physicians often opt to order a PSA test rather than to take the time to explain potential harms and benefits and listen to the patient’s thoughts and feelings about the value of screening. In addition, physicians who believe the lack of benefit from screening does not apply to their patients will continue to order the PSA test. (See “The perils of PSA screening”.)

Patients may opt to continue to be screened although they have developed a risk factor for cardiovascular disease. Also, a decision not to screen directly contradicts the recommendation of the American Urological Association, which calls for annual PSA testing for asymptomatic men with a life expectancy >10 years starting at 40 years of age.11

Shared decision-making
The US Preventive Services Task Force (USPSTF) provides a basis for shared decision-making between physicians and patients concerning prostate cancer screening. The USPSTF states that there is insufficient evidence to recommend for or against prostate cancer screening for the general male population younger than age 75 and recommends against screening men age 75 and older or those with a life expectancy of less than 10 years.12

Decisions regarding PSA screening should be shared and documented for all men between the ages of 50 and 75 years. Advise patients with risk factors that the evidence shows little value and possible harm from screening. Tell healthier men that PSA testing appears to offer a small benefit, at best.

Acknowledgement

The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center for Research Resources; the grant is a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

References

 

1. Djulbegovic M, Beyth RJ, Neuberger MM, et al. Screening for prostate cancer: systematic review and meta-analysis of randomized controlled trials. BMJ. 2010;341:c4543.-

2. Crawford ED, Grubb R, 3rd, Black A, et al. Comorbidity and mortality results from a randomized prostate cancer screening trial. J Clin Oncol. 2011;29:355-361.

3. American Cancer Society. Cancer facts & figures 2010. Atlanta, Ga: American Cancer Society; 2010. Available at: http://www.cancer.org/acs/groups/content/@nho/documents/document/acspc-024113.pdf. Accessed April 13, 2011.

4. American Cancer Society. Prostate cancer. Last medical review November 22, 2010. Available at: http://www.cancer.org/cancer/prostatecancer/detailedguide/prostate-cancer-key-statistics. Accessed April 13, 2011.

5. National Institutes of Health. Prostate cancer. Last updated February 14, 2011. Available at: http://report.nih.gov/NIHfactsheets/ViewFactSheet.aspx?csid=60. Accessed May 9, 2011.

6. Lin K, Lipsitz R, Miller T, et al. Benefits and harms of prostate-specific antigen screening for prostate cancer: an evidence update for the U.S. Preventive Services Task Force. Ann Intern Med. 2008;149:192-199.

7. Schroder FH, Hugosson J, Roobol MJ, et al. Screening and prostate-cancer mortality in a randomized European study. N Engl J Med. 2009;360:1320-1328.

8. Andriole GL, Crawford ED, Grubb RL, 3rd, et al. Mortality results from a randomized prostate-cancer screening trial. N Engl J Med. 2009;360:1310-1319.

9. Stanford JL, Feng Z, Hamilton AS, et al. Urinary and sexual function after radical prostatectomy for clinically localized prostate cancer: the Prostate Cancer Outcomes Study. JAMA. 2000;283:354-360.

10. Ilic D, O’Connor D, Greens, Wilt T. Screening for prostate cancer. Cochrane Database Syst Rev. 2006;(3):CD004720.-

11. American Urological Association. Prostate-specific antigen best practice statement: 2009 update. Available at: http://www.auanet.org/content/guidelines-and-quality-care/clinical-guidelines/main-reports/psa09.pdf. Accessed March 16, 2011.

12. US Preventive Services Task Force. Screening for prostate cancer: US Preventive Services Task Force recommendation statement. Ann Intern Med. 2008;149:185-191.

References

 

1. Djulbegovic M, Beyth RJ, Neuberger MM, et al. Screening for prostate cancer: systematic review and meta-analysis of randomized controlled trials. BMJ. 2010;341:c4543.-

2. Crawford ED, Grubb R, 3rd, Black A, et al. Comorbidity and mortality results from a randomized prostate cancer screening trial. J Clin Oncol. 2011;29:355-361.

3. American Cancer Society. Cancer facts & figures 2010. Atlanta, Ga: American Cancer Society; 2010. Available at: http://www.cancer.org/acs/groups/content/@nho/documents/document/acspc-024113.pdf. Accessed April 13, 2011.

4. American Cancer Society. Prostate cancer. Last medical review November 22, 2010. Available at: http://www.cancer.org/cancer/prostatecancer/detailedguide/prostate-cancer-key-statistics. Accessed April 13, 2011.

5. National Institutes of Health. Prostate cancer. Last updated February 14, 2011. Available at: http://report.nih.gov/NIHfactsheets/ViewFactSheet.aspx?csid=60. Accessed May 9, 2011.

6. Lin K, Lipsitz R, Miller T, et al. Benefits and harms of prostate-specific antigen screening for prostate cancer: an evidence update for the U.S. Preventive Services Task Force. Ann Intern Med. 2008;149:192-199.

7. Schroder FH, Hugosson J, Roobol MJ, et al. Screening and prostate-cancer mortality in a randomized European study. N Engl J Med. 2009;360:1320-1328.

8. Andriole GL, Crawford ED, Grubb RL, 3rd, et al. Mortality results from a randomized prostate-cancer screening trial. N Engl J Med. 2009;360:1310-1319.

9. Stanford JL, Feng Z, Hamilton AS, et al. Urinary and sexual function after radical prostatectomy for clinically localized prostate cancer: the Prostate Cancer Outcomes Study. JAMA. 2000;283:354-360.

10. Ilic D, O’Connor D, Greens, Wilt T. Screening for prostate cancer. Cochrane Database Syst Rev. 2006;(3):CD004720.-

11. American Urological Association. Prostate-specific antigen best practice statement: 2009 update. Available at: http://www.auanet.org/content/guidelines-and-quality-care/clinical-guidelines/main-reports/psa09.pdf. Accessed March 16, 2011.

12. US Preventive Services Task Force. Screening for prostate cancer: US Preventive Services Task Force recommendation statement. Ann Intern Med. 2008;149:185-191.

Issue
The Journal of Family Practice - 60(6)
Issue
The Journal of Family Practice - 60(6)
Page Number
357-360
Page Number
357-360
Publications
Publications
Topics
Article Type
Display Headline
PSA testing: When it’s useful, when it’s not
Display Headline
PSA testing: When it’s useful, when it’s not
Legacy Keywords
PSA testing; when it's useful; prostate-specific antigen; digital rectal exam; Kate Rowland; Susan Slatkoff; potential harms; PSA screening
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Which women should we screen for gestational diabetes mellitus?

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EVIDENCE-BASED ANSWER

IT’S UNCLEAR which women we should screen. No randomized controlled trials (RCTs) demonstrate that either universal screening or risk factor screening for gestational diabetes mellitus (GDM) prevents maternal and fetal adverse outcomes.

That said, the common practice of universal screening is more sensitive than screening based on risk factors (strength of recommendation [SOR]: B, 1 randomized trial and 3 retrospective cohort studies without patient-oriented outcomes). Historic risk factors are poor predictors of GDM in a current pregnancy (SOR: C, 1 retrospective cohort study without patient-oriented outcomes).

 

Evidence summary

No RCTs have evaluated the risks, benefits, and clinical outcomes of screening for GDM. A review of universal screening compared with risk factor screening included 2 retrospective studies, 1 observational cohort study, and 1 nonconcurrent cohort study.1-4

Risk factor screening misses women with GDM
All 4 studies clearly show that risk factor screening would miss patients with GDM.1-4 Two studies found that the detection rate of GDM increases when universal screening is performed.1,4

One observational study in a multiethnic cohort concluded that risk factor screening missed 30% of patients with GDM and that universal screening increased the detection rate from 8.3% to 12.6% (P=.001) compared with risk factor screening.1 Similarly, a retrospective study of 147 pregnant women with GDM found that risk factor screening would have missed 23%.2

Universal screening diagnoses GDM earlier than risk factor screening
One prospective randomized study that compared universal screening (using a 50-g 1-hour glucose challenge test) in 1853 women with risk factor screening in 1299 women demonstrated that nearly half of those with GDM had no historical risk factors and would have been missed by risk factor screening in a low-prevalence, mostly Caucasian sample. The prevalence was 2.7% in the universal screening group vs 1.45% in the risk factor screening group (P<.03). Universal screening diagnosed GDM earlier than risk factor screening (mean gestation 30 ± 2.6 weeks vs 33 ± 3.7 weeks; P<.05).3

Need for insulin is similar, with and without GDM risk factors
A retrospective cohort study demonstrated that risk factor screening misses 43% of women with GDM. The study also showed that women with GDM who had identifiable risk factors and women without identifiable risk factors were equally likely to require insulin to control their GDM. Adverse birth outcomes such as macrosomia and shoulder dystocia or cesarean section were similar in patients with and without risk factors for GDM.4

Macrosomia and primary C-section increase along with glucose intolerance
The prospective cohort Hyperglycemia and Adverse Pregnancy Outcome (HAPO) Study of 23,316 women at 15 centers in 9 countries used the 2-hour 75-g oral glucose tolerance test at 24 to 32 weeks’ gestation to clarify the risks of adverse outcomes associated with varying degrees of maternal glucose intolerance. The study found a linear increase in the risk of macrosomia and primary cesarean section as glucose intolerance levels increased from normal to the gestational diabetes range.5

Recommendations

The US Preventive Services Task Force states that evidence is insufficient to advise for or against routine screening for GDM.6

The American College of Obstetricians and Gynecologists considers universal glucose challenge screening for GDM to be the most sensitive approach, but notes that some pregnant women at low risk may be less likely to benefit from testing.7

The Cochrane review protocol states that universally accepted screening is controversial because of a lack of clearly defined, universally accepted screening criteria and uncertainty about the severity of glucose intolerance at which treatment is beneficial.8

References

1. Cosson E, Benchimol M, Carbillon L, et al. Universal rather than selective screening for gestational diabetes mellitus may improve fetal outcomes. Diabetes Metab. 2006;32:140-146.

2. Baliutaviciene D, Petrenko V, Zalinkevicius R. Selective or universal diagnostic testing for gestational diabetes mellitus. Int J Gynaecol Obstet. 2002;78:207-211.

3. Griffin ME, Coffey M, Johnson H, et al. Universal vs. risk factor-based screening for gestational diabetes mellitus: detection rates, gestation at diagnosis and outcome. Diabetes Med. 2000;17:26-32.

4. Weeks JW, Major CA, de Veciana M, et al. Gestational diabetes: does the presence of risk factors influence perinatal outcome? Am J Obstet Gynecol. 1994;171:1003-1007.

5. HAPO Study Cooperative Research Group, Metzger BE, Lowe LP, et al. Hyperglycemia and adverse pregnancy outcomes. N Engl J Med. 2008;358:1991-2002.

6. US Preventive Services Task Force. Screening for gestational diabetes mellitus: US Preventive Services Task Force recommendation statement. Ann Intern Med. 2008;148:759-765.

7. American College of Obstetricians and Gynecologists Committee on Practice Bulletins—Obstetrics. ACOG Practice Bulletin. Clinical management guidelines for obstetrician-gynecologists. Number 30, September 2001 (replaces Technical Bulletin Number 200, December 1994). Gestational diabetes. Obstet Gynecol. 2001;98:525-538.

8. Tieu J, Crowther CA, Middleton P, et al. Screening for gestational diabetes mellitus for improving maternal and infant health (Protocol). Cochrane Database Syst Rev. 2008;(2):CD007222.-

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EVIDENCE-BASED ANSWER

IT’S UNCLEAR which women we should screen. No randomized controlled trials (RCTs) demonstrate that either universal screening or risk factor screening for gestational diabetes mellitus (GDM) prevents maternal and fetal adverse outcomes.

That said, the common practice of universal screening is more sensitive than screening based on risk factors (strength of recommendation [SOR]: B, 1 randomized trial and 3 retrospective cohort studies without patient-oriented outcomes). Historic risk factors are poor predictors of GDM in a current pregnancy (SOR: C, 1 retrospective cohort study without patient-oriented outcomes).

 

Evidence summary

No RCTs have evaluated the risks, benefits, and clinical outcomes of screening for GDM. A review of universal screening compared with risk factor screening included 2 retrospective studies, 1 observational cohort study, and 1 nonconcurrent cohort study.1-4

Risk factor screening misses women with GDM
All 4 studies clearly show that risk factor screening would miss patients with GDM.1-4 Two studies found that the detection rate of GDM increases when universal screening is performed.1,4

One observational study in a multiethnic cohort concluded that risk factor screening missed 30% of patients with GDM and that universal screening increased the detection rate from 8.3% to 12.6% (P=.001) compared with risk factor screening.1 Similarly, a retrospective study of 147 pregnant women with GDM found that risk factor screening would have missed 23%.2

Universal screening diagnoses GDM earlier than risk factor screening
One prospective randomized study that compared universal screening (using a 50-g 1-hour glucose challenge test) in 1853 women with risk factor screening in 1299 women demonstrated that nearly half of those with GDM had no historical risk factors and would have been missed by risk factor screening in a low-prevalence, mostly Caucasian sample. The prevalence was 2.7% in the universal screening group vs 1.45% in the risk factor screening group (P<.03). Universal screening diagnosed GDM earlier than risk factor screening (mean gestation 30 ± 2.6 weeks vs 33 ± 3.7 weeks; P<.05).3

Need for insulin is similar, with and without GDM risk factors
A retrospective cohort study demonstrated that risk factor screening misses 43% of women with GDM. The study also showed that women with GDM who had identifiable risk factors and women without identifiable risk factors were equally likely to require insulin to control their GDM. Adverse birth outcomes such as macrosomia and shoulder dystocia or cesarean section were similar in patients with and without risk factors for GDM.4

Macrosomia and primary C-section increase along with glucose intolerance
The prospective cohort Hyperglycemia and Adverse Pregnancy Outcome (HAPO) Study of 23,316 women at 15 centers in 9 countries used the 2-hour 75-g oral glucose tolerance test at 24 to 32 weeks’ gestation to clarify the risks of adverse outcomes associated with varying degrees of maternal glucose intolerance. The study found a linear increase in the risk of macrosomia and primary cesarean section as glucose intolerance levels increased from normal to the gestational diabetes range.5

Recommendations

The US Preventive Services Task Force states that evidence is insufficient to advise for or against routine screening for GDM.6

The American College of Obstetricians and Gynecologists considers universal glucose challenge screening for GDM to be the most sensitive approach, but notes that some pregnant women at low risk may be less likely to benefit from testing.7

The Cochrane review protocol states that universally accepted screening is controversial because of a lack of clearly defined, universally accepted screening criteria and uncertainty about the severity of glucose intolerance at which treatment is beneficial.8

EVIDENCE-BASED ANSWER

IT’S UNCLEAR which women we should screen. No randomized controlled trials (RCTs) demonstrate that either universal screening or risk factor screening for gestational diabetes mellitus (GDM) prevents maternal and fetal adverse outcomes.

That said, the common practice of universal screening is more sensitive than screening based on risk factors (strength of recommendation [SOR]: B, 1 randomized trial and 3 retrospective cohort studies without patient-oriented outcomes). Historic risk factors are poor predictors of GDM in a current pregnancy (SOR: C, 1 retrospective cohort study without patient-oriented outcomes).

 

Evidence summary

No RCTs have evaluated the risks, benefits, and clinical outcomes of screening for GDM. A review of universal screening compared with risk factor screening included 2 retrospective studies, 1 observational cohort study, and 1 nonconcurrent cohort study.1-4

Risk factor screening misses women with GDM
All 4 studies clearly show that risk factor screening would miss patients with GDM.1-4 Two studies found that the detection rate of GDM increases when universal screening is performed.1,4

One observational study in a multiethnic cohort concluded that risk factor screening missed 30% of patients with GDM and that universal screening increased the detection rate from 8.3% to 12.6% (P=.001) compared with risk factor screening.1 Similarly, a retrospective study of 147 pregnant women with GDM found that risk factor screening would have missed 23%.2

Universal screening diagnoses GDM earlier than risk factor screening
One prospective randomized study that compared universal screening (using a 50-g 1-hour glucose challenge test) in 1853 women with risk factor screening in 1299 women demonstrated that nearly half of those with GDM had no historical risk factors and would have been missed by risk factor screening in a low-prevalence, mostly Caucasian sample. The prevalence was 2.7% in the universal screening group vs 1.45% in the risk factor screening group (P<.03). Universal screening diagnosed GDM earlier than risk factor screening (mean gestation 30 ± 2.6 weeks vs 33 ± 3.7 weeks; P<.05).3

Need for insulin is similar, with and without GDM risk factors
A retrospective cohort study demonstrated that risk factor screening misses 43% of women with GDM. The study also showed that women with GDM who had identifiable risk factors and women without identifiable risk factors were equally likely to require insulin to control their GDM. Adverse birth outcomes such as macrosomia and shoulder dystocia or cesarean section were similar in patients with and without risk factors for GDM.4

Macrosomia and primary C-section increase along with glucose intolerance
The prospective cohort Hyperglycemia and Adverse Pregnancy Outcome (HAPO) Study of 23,316 women at 15 centers in 9 countries used the 2-hour 75-g oral glucose tolerance test at 24 to 32 weeks’ gestation to clarify the risks of adverse outcomes associated with varying degrees of maternal glucose intolerance. The study found a linear increase in the risk of macrosomia and primary cesarean section as glucose intolerance levels increased from normal to the gestational diabetes range.5

Recommendations

The US Preventive Services Task Force states that evidence is insufficient to advise for or against routine screening for GDM.6

The American College of Obstetricians and Gynecologists considers universal glucose challenge screening for GDM to be the most sensitive approach, but notes that some pregnant women at low risk may be less likely to benefit from testing.7

The Cochrane review protocol states that universally accepted screening is controversial because of a lack of clearly defined, universally accepted screening criteria and uncertainty about the severity of glucose intolerance at which treatment is beneficial.8

References

1. Cosson E, Benchimol M, Carbillon L, et al. Universal rather than selective screening for gestational diabetes mellitus may improve fetal outcomes. Diabetes Metab. 2006;32:140-146.

2. Baliutaviciene D, Petrenko V, Zalinkevicius R. Selective or universal diagnostic testing for gestational diabetes mellitus. Int J Gynaecol Obstet. 2002;78:207-211.

3. Griffin ME, Coffey M, Johnson H, et al. Universal vs. risk factor-based screening for gestational diabetes mellitus: detection rates, gestation at diagnosis and outcome. Diabetes Med. 2000;17:26-32.

4. Weeks JW, Major CA, de Veciana M, et al. Gestational diabetes: does the presence of risk factors influence perinatal outcome? Am J Obstet Gynecol. 1994;171:1003-1007.

5. HAPO Study Cooperative Research Group, Metzger BE, Lowe LP, et al. Hyperglycemia and adverse pregnancy outcomes. N Engl J Med. 2008;358:1991-2002.

6. US Preventive Services Task Force. Screening for gestational diabetes mellitus: US Preventive Services Task Force recommendation statement. Ann Intern Med. 2008;148:759-765.

7. American College of Obstetricians and Gynecologists Committee on Practice Bulletins—Obstetrics. ACOG Practice Bulletin. Clinical management guidelines for obstetrician-gynecologists. Number 30, September 2001 (replaces Technical Bulletin Number 200, December 1994). Gestational diabetes. Obstet Gynecol. 2001;98:525-538.

8. Tieu J, Crowther CA, Middleton P, et al. Screening for gestational diabetes mellitus for improving maternal and infant health (Protocol). Cochrane Database Syst Rev. 2008;(2):CD007222.-

References

1. Cosson E, Benchimol M, Carbillon L, et al. Universal rather than selective screening for gestational diabetes mellitus may improve fetal outcomes. Diabetes Metab. 2006;32:140-146.

2. Baliutaviciene D, Petrenko V, Zalinkevicius R. Selective or universal diagnostic testing for gestational diabetes mellitus. Int J Gynaecol Obstet. 2002;78:207-211.

3. Griffin ME, Coffey M, Johnson H, et al. Universal vs. risk factor-based screening for gestational diabetes mellitus: detection rates, gestation at diagnosis and outcome. Diabetes Med. 2000;17:26-32.

4. Weeks JW, Major CA, de Veciana M, et al. Gestational diabetes: does the presence of risk factors influence perinatal outcome? Am J Obstet Gynecol. 1994;171:1003-1007.

5. HAPO Study Cooperative Research Group, Metzger BE, Lowe LP, et al. Hyperglycemia and adverse pregnancy outcomes. N Engl J Med. 2008;358:1991-2002.

6. US Preventive Services Task Force. Screening for gestational diabetes mellitus: US Preventive Services Task Force recommendation statement. Ann Intern Med. 2008;148:759-765.

7. American College of Obstetricians and Gynecologists Committee on Practice Bulletins—Obstetrics. ACOG Practice Bulletin. Clinical management guidelines for obstetrician-gynecologists. Number 30, September 2001 (replaces Technical Bulletin Number 200, December 1994). Gestational diabetes. Obstet Gynecol. 2001;98:525-538.

8. Tieu J, Crowther CA, Middleton P, et al. Screening for gestational diabetes mellitus for improving maternal and infant health (Protocol). Cochrane Database Syst Rev. 2008;(2):CD007222.-

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How best to help kids lose weight

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Illustrative case

A 10-year-old boy comes in with his mother for a well-child check-up. His BMI is 40 kg/m2—above the 99th percentile for his age and up from 37 a year ago. His blood pressure is 120/84 mm Hg. What treatment, if any, should you offer for his obesity?

Childhood obesity is a global epidemic. In the United States, 19.6% of children ages 6 through 11 and 18.1% of 12- to 19-year-olds are obese, a 3-fold increase in the last 30 years.3 Without intervention, most obese adolescents will become obese adults, threatening to reverse the progress in slowing cardiovascular morbidity and mortality that has occurred over the past few decades.3

Obese kids get adult diseases
Obesity is a risk factor for a variety of chronic conditions, including cardiovascular disease, cerebrovascular disease, and arthritis. Severe obesity is also associated with higher mortality rates.4 Unfortunately, these comorbidities are not limited to adulthood.

“Adult” diseases, such as obstructive sleep apnea, dyslipidemia, and type 2 diabetes, are increasingly seen in children and adolescents.1 Nutritional deficits such as vitamin D and iron deficiency are often seen in obese children, as well.5 There are also psychological ramifications of childhood obesity, including social isolation and depression.6

The USPSTF recently upgraded its recommendation regarding obesity screening in children ages 6 and older from I (insufficient evidence) to B (a positive grade based on high or moderate certainty of the benefit of the intervention), citing new evidence in favor of screening and treating or referring children when appropriate.2 The systematic review we report on here, which formed the basis for the USPSTF’s upgrade, focused on management options for children identified as overweight or obese.

STUDY SUMMARY: Intense, comprehensive efforts pay off

This systematic review1 included studies of children ages 4 to 18 years who were overweight (defined as a body mass index [BMI] in the 85th to 94th percentile for age and sex) or obese (either a BMI at or above the 95th percentile for age and sex or a BMI >30 kg/m2). The researchers found 25 trials—15 of behavioral interventions alone and 10 that combined behavioral and pharmacologic interventions—that met their criteria: The studies focused on weight loss and/or maintenance, reported outcomes ≥6 months from baseline, and were conducted (or feasible) in a primary care setting.

Behavioral interventions were categorized by treatment intensity (as measured by hours of contact, which ranged from <10 hours to >75) and comprehensiveness (including nutritional counseling, physical activity counseling or participation, and counseling on behavioral management techniques). Weight outcomes were categorized as short-term (6-12 months since treatment initiation) or maintenance (≥12 months after the end of active treatment).

The 15 behavioral intervention trials included 1258 children ages 4 to 18 years, most of whom were obese. Most trials were small and reported high retention rates. All had beneficial effects on weight in the intervention group compared with the controls, but not all changes were statistically significant. Higher intensity and more comprehensive programs had better outcomes.

The largest effects were in 3 moderate- to high-intensity, comprehensive weight management programs with ≥26 hours of contact. These 3 trials demonstrated a difference in BMI of 1.9 to 3.3 in the intervention groups at 12 months compared with the controls. (A 3.3 difference in BMI is equal to approximately 13 lb in an 8-year-old and 17 lb in a 12-year-old.)

Four behavioral intervention studies reported outcomes ≥12 months after completing the intervention (range 15-48 months). Three of the 4 reported continued beneficial effects on weight after the active treatment period, but the effects were markedly attenuated.

The only adverse effect reported in the trials of behavioral interventions was the injury rate among children in an exercise program, but it was minimal: One fracture was reported, vs no injuries for the controls. No differences were reported in height, eating disorders, or depression. However, fewer than half of the behavioral intervention trials reported on adverse effects.

 

 

 

Weight loss drugs have modest effects
Ten trials combining pharmacologic and behavioral interventions involved a total of 1294 obese adolescents ages 12 to 19. All evaluated short-term weight loss effects of either sibutramine (10-15 mg/d) or orlistat (120 mg tid). Trials ranged from 3 to 12 months. Participants in both the control and intervention groups received behavioral counseling.

The trials all favored the treatment groups, although not all of the results were statistically significant. Trials of longer duration (12 months) had more favorable results than those lasting 6 months.

The largest sibutramine trial (n=498) reported a mean BMI reduction of 2.9 in the treatment group, compared with a reduction of 0.3 in the control group (P<.001). This corresponds to an average weight loss of 14 lb in the intervention group, vs 4.2 lb in the control group, after 12 months.

The largest orlistat trial (n=539) reported a mean BMI reduction in the treatment group of 0.6, vs 0.3 in the control group (P<.001)—an average weight loss of 4.2 lb in the intervention group, compared with 2.1 lb among the controls after 12 months. None of the trials evaluated weight change after cessation of the study drug, and none compared orlistat with sibutramine.

Adverse effects in the sibutramine-treated patients were primarily cardiovascular and gastrointestinal. Cardiovascular effects included tachycardia and increases in systolic and diastolic blood pressure. The differences between the intervention and control groups were small, and no differences were observed in discontinuation rates caused by adverse events. Nor were differences reported in growth and maturation between the intervention and control groups.

Adverse effects in the orlistat-treated patients were also low and similar in the intervention and control groups. Gastrointestinal effects were common. The number needed to harm (NNH) for fatty or oily stools was 2,4 and the NNH for fecal incontinence was 12.5

WHAT'S NEW: Clinicians treating obese kids have cause for optimism

Although the trials included in this review were heterogeneous and many were small, this systematic review provides evidence that intensive, comprehensive behavioral weight loss interventions for obese children can be effective up to 12 months after the conclusion of the program. Family physicians should consider referring obese children and adolescents to such programs—or finding ways to provide supportive strategies themselves.

Sibutramine and orlistat may be helpful in the context of comprehensive, intensive behavioral interventions, although there is no follow-up data to demonstrate long-term safety and weight maintenance after the medication is stopped.

CAVEATS: Little is known about long-term safety of the drugs

There have been few randomized trials of pharmacologic interventions in adolescents and none evaluating weight maintenance after 12 months (or discontinuation of treatment), or assessing long-term safety of the medication.

Sibutramine is not approved by the US Food and Drug Administration (FDA) for use in children or adolescents.7 Orlistat is currently approved only for individuals over the age of 12.8

In January 2010, an additional contraindication was added to the sibutramine drug label, stating that it is not to be used in patients with a history of cardiovascular disease.9 And the FDA is currently investigating a rare association between orlistat and liver injury, although no conclusions have been released.10 Children and adolescents are particularly vulnerable to long-term side effects, given their relatively young age at the time of drug initiation, so we urge caution with the use of these drugs in this patient population.

CHALLENGES TO IMPLEMENTATION: Intensive approach may be hard to reproduce

Implementation of high-intensity comprehensive interventions for obese children faces a number of roadblocks, including limited availability of programs, cost, and reimbursement. Most of the intensive interventions in these trials took place in specialty centers rather than in primary care offices. Replicating them could require a referral—or significant resources within the primary care setting itself. Yet many, if not most, insurance policies still do not cover such extensive lifestyle interventions. (For information on weight loss interventions for adults, see “Weight loss strategies that really work”).

None of these trials reported on cost or cost effectiveness. Despite the considerable cost of a comprehensive obesity management program, however, a successful weight-maintenance model could be a worthwhile investment in long-term health.

Lastly, the results of this trial should not negate the importance of obesity prevention efforts by parents, who are in the best position to reverse the childhood obesity epidemic.11

Acknowledgement
The PURLs Surveillance System is supported in part by Grant Number UL1RR024999; awarded by the National Center for Research Resources; the grant is a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

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References

1. Whitlock E, O’Connor E, Williams S, et al. Effectiveness of weight management interventions in children: a targeted systematic review for the USPSTF. Pediatrics. 2010;125:e396-e418.

2. US Preventive Services Task Force. Screening for obesity in children and adolescents: recommendation statement. http://www.ahrq.gov/clinic/uspstf10/childobes/chobesrs.htm. Accessed April 11, 2010.

3. Daniels SR, Arnett DK, Eckel RH, et al. Overweight in children and adolescents: pathophysiology, consequences, prevention, and treatment. Circulation. 2005;111:1999-2012.

4. Flegal KM, Carroll MD, Ogden CL, et al. Prevalence and trends in obesity among US adults, 1999-2008. JAMA. 2010;303:235-241.

5. Han JC, Lawlor DA, Kimm SY. Childhood obesity. Lancet. 2010;375:1737-1748.

6. Strauss RS, Pollack HA. Social marginalization of overweight children. Arch Pediatr Adolesc Med. 2003;157:746-752.

7. US Food and Drug Administration. Meridia approval history. Available at: http://www.accessdata.fda.gov/drugsatfda_docs/label/2009/020632s032lbl.pdf. Accessed June 16, 2010.

8. US Food and Drug Administration. Xenical approval letter. Available at: www.accessdata.fda.gov/drugsatfda_docs/appletter/2003/20766se5-018ltr.pdf. Accessed June 16, 2010.

9. US Food and Drug Administration. Early communication about an ongoing safety review of Meridia (sibutramine hydrochlo-ride). Available at: http://www.fda.gov/Drugs/DrugSafety/PostmarketDrugSafetyInformationfor
PatientsandProviders/ucm180076.htm. Accessed March 29, 2010.

10. US Food and Drug Administration. Early communication about an ongoing safety review of orlistat. Available at: http://www.fda.gov/Drugs/DrugSafety/PostmarketDrugSafetyInformationforPatientsandProviders/ucm180076.htm. Accessed April 11, 2010.

11. Gruber KJ, Haldeman LA. Using the family to combat childhood and adult obesity. Prev Chronic Dis. 2009;6:A106.-

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Illustrative case

A 10-year-old boy comes in with his mother for a well-child check-up. His BMI is 40 kg/m2—above the 99th percentile for his age and up from 37 a year ago. His blood pressure is 120/84 mm Hg. What treatment, if any, should you offer for his obesity?

Childhood obesity is a global epidemic. In the United States, 19.6% of children ages 6 through 11 and 18.1% of 12- to 19-year-olds are obese, a 3-fold increase in the last 30 years.3 Without intervention, most obese adolescents will become obese adults, threatening to reverse the progress in slowing cardiovascular morbidity and mortality that has occurred over the past few decades.3

Obese kids get adult diseases
Obesity is a risk factor for a variety of chronic conditions, including cardiovascular disease, cerebrovascular disease, and arthritis. Severe obesity is also associated with higher mortality rates.4 Unfortunately, these comorbidities are not limited to adulthood.

“Adult” diseases, such as obstructive sleep apnea, dyslipidemia, and type 2 diabetes, are increasingly seen in children and adolescents.1 Nutritional deficits such as vitamin D and iron deficiency are often seen in obese children, as well.5 There are also psychological ramifications of childhood obesity, including social isolation and depression.6

The USPSTF recently upgraded its recommendation regarding obesity screening in children ages 6 and older from I (insufficient evidence) to B (a positive grade based on high or moderate certainty of the benefit of the intervention), citing new evidence in favor of screening and treating or referring children when appropriate.2 The systematic review we report on here, which formed the basis for the USPSTF’s upgrade, focused on management options for children identified as overweight or obese.

STUDY SUMMARY: Intense, comprehensive efforts pay off

This systematic review1 included studies of children ages 4 to 18 years who were overweight (defined as a body mass index [BMI] in the 85th to 94th percentile for age and sex) or obese (either a BMI at or above the 95th percentile for age and sex or a BMI >30 kg/m2). The researchers found 25 trials—15 of behavioral interventions alone and 10 that combined behavioral and pharmacologic interventions—that met their criteria: The studies focused on weight loss and/or maintenance, reported outcomes ≥6 months from baseline, and were conducted (or feasible) in a primary care setting.

Behavioral interventions were categorized by treatment intensity (as measured by hours of contact, which ranged from <10 hours to >75) and comprehensiveness (including nutritional counseling, physical activity counseling or participation, and counseling on behavioral management techniques). Weight outcomes were categorized as short-term (6-12 months since treatment initiation) or maintenance (≥12 months after the end of active treatment).

The 15 behavioral intervention trials included 1258 children ages 4 to 18 years, most of whom were obese. Most trials were small and reported high retention rates. All had beneficial effects on weight in the intervention group compared with the controls, but not all changes were statistically significant. Higher intensity and more comprehensive programs had better outcomes.

The largest effects were in 3 moderate- to high-intensity, comprehensive weight management programs with ≥26 hours of contact. These 3 trials demonstrated a difference in BMI of 1.9 to 3.3 in the intervention groups at 12 months compared with the controls. (A 3.3 difference in BMI is equal to approximately 13 lb in an 8-year-old and 17 lb in a 12-year-old.)

Four behavioral intervention studies reported outcomes ≥12 months after completing the intervention (range 15-48 months). Three of the 4 reported continued beneficial effects on weight after the active treatment period, but the effects were markedly attenuated.

The only adverse effect reported in the trials of behavioral interventions was the injury rate among children in an exercise program, but it was minimal: One fracture was reported, vs no injuries for the controls. No differences were reported in height, eating disorders, or depression. However, fewer than half of the behavioral intervention trials reported on adverse effects.

 

 

 

Weight loss drugs have modest effects
Ten trials combining pharmacologic and behavioral interventions involved a total of 1294 obese adolescents ages 12 to 19. All evaluated short-term weight loss effects of either sibutramine (10-15 mg/d) or orlistat (120 mg tid). Trials ranged from 3 to 12 months. Participants in both the control and intervention groups received behavioral counseling.

The trials all favored the treatment groups, although not all of the results were statistically significant. Trials of longer duration (12 months) had more favorable results than those lasting 6 months.

The largest sibutramine trial (n=498) reported a mean BMI reduction of 2.9 in the treatment group, compared with a reduction of 0.3 in the control group (P<.001). This corresponds to an average weight loss of 14 lb in the intervention group, vs 4.2 lb in the control group, after 12 months.

The largest orlistat trial (n=539) reported a mean BMI reduction in the treatment group of 0.6, vs 0.3 in the control group (P<.001)—an average weight loss of 4.2 lb in the intervention group, compared with 2.1 lb among the controls after 12 months. None of the trials evaluated weight change after cessation of the study drug, and none compared orlistat with sibutramine.

Adverse effects in the sibutramine-treated patients were primarily cardiovascular and gastrointestinal. Cardiovascular effects included tachycardia and increases in systolic and diastolic blood pressure. The differences between the intervention and control groups were small, and no differences were observed in discontinuation rates caused by adverse events. Nor were differences reported in growth and maturation between the intervention and control groups.

Adverse effects in the orlistat-treated patients were also low and similar in the intervention and control groups. Gastrointestinal effects were common. The number needed to harm (NNH) for fatty or oily stools was 2,4 and the NNH for fecal incontinence was 12.5

WHAT'S NEW: Clinicians treating obese kids have cause for optimism

Although the trials included in this review were heterogeneous and many were small, this systematic review provides evidence that intensive, comprehensive behavioral weight loss interventions for obese children can be effective up to 12 months after the conclusion of the program. Family physicians should consider referring obese children and adolescents to such programs—or finding ways to provide supportive strategies themselves.

Sibutramine and orlistat may be helpful in the context of comprehensive, intensive behavioral interventions, although there is no follow-up data to demonstrate long-term safety and weight maintenance after the medication is stopped.

CAVEATS: Little is known about long-term safety of the drugs

There have been few randomized trials of pharmacologic interventions in adolescents and none evaluating weight maintenance after 12 months (or discontinuation of treatment), or assessing long-term safety of the medication.

Sibutramine is not approved by the US Food and Drug Administration (FDA) for use in children or adolescents.7 Orlistat is currently approved only for individuals over the age of 12.8

In January 2010, an additional contraindication was added to the sibutramine drug label, stating that it is not to be used in patients with a history of cardiovascular disease.9 And the FDA is currently investigating a rare association between orlistat and liver injury, although no conclusions have been released.10 Children and adolescents are particularly vulnerable to long-term side effects, given their relatively young age at the time of drug initiation, so we urge caution with the use of these drugs in this patient population.

CHALLENGES TO IMPLEMENTATION: Intensive approach may be hard to reproduce

Implementation of high-intensity comprehensive interventions for obese children faces a number of roadblocks, including limited availability of programs, cost, and reimbursement. Most of the intensive interventions in these trials took place in specialty centers rather than in primary care offices. Replicating them could require a referral—or significant resources within the primary care setting itself. Yet many, if not most, insurance policies still do not cover such extensive lifestyle interventions. (For information on weight loss interventions for adults, see “Weight loss strategies that really work”).

None of these trials reported on cost or cost effectiveness. Despite the considerable cost of a comprehensive obesity management program, however, a successful weight-maintenance model could be a worthwhile investment in long-term health.

Lastly, the results of this trial should not negate the importance of obesity prevention efforts by parents, who are in the best position to reverse the childhood obesity epidemic.11

Acknowledgement
The PURLs Surveillance System is supported in part by Grant Number UL1RR024999; awarded by the National Center for Research Resources; the grant is a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

Click here to view PURL METHODOLOGY

 

Illustrative case

A 10-year-old boy comes in with his mother for a well-child check-up. His BMI is 40 kg/m2—above the 99th percentile for his age and up from 37 a year ago. His blood pressure is 120/84 mm Hg. What treatment, if any, should you offer for his obesity?

Childhood obesity is a global epidemic. In the United States, 19.6% of children ages 6 through 11 and 18.1% of 12- to 19-year-olds are obese, a 3-fold increase in the last 30 years.3 Without intervention, most obese adolescents will become obese adults, threatening to reverse the progress in slowing cardiovascular morbidity and mortality that has occurred over the past few decades.3

Obese kids get adult diseases
Obesity is a risk factor for a variety of chronic conditions, including cardiovascular disease, cerebrovascular disease, and arthritis. Severe obesity is also associated with higher mortality rates.4 Unfortunately, these comorbidities are not limited to adulthood.

“Adult” diseases, such as obstructive sleep apnea, dyslipidemia, and type 2 diabetes, are increasingly seen in children and adolescents.1 Nutritional deficits such as vitamin D and iron deficiency are often seen in obese children, as well.5 There are also psychological ramifications of childhood obesity, including social isolation and depression.6

The USPSTF recently upgraded its recommendation regarding obesity screening in children ages 6 and older from I (insufficient evidence) to B (a positive grade based on high or moderate certainty of the benefit of the intervention), citing new evidence in favor of screening and treating or referring children when appropriate.2 The systematic review we report on here, which formed the basis for the USPSTF’s upgrade, focused on management options for children identified as overweight or obese.

STUDY SUMMARY: Intense, comprehensive efforts pay off

This systematic review1 included studies of children ages 4 to 18 years who were overweight (defined as a body mass index [BMI] in the 85th to 94th percentile for age and sex) or obese (either a BMI at or above the 95th percentile for age and sex or a BMI >30 kg/m2). The researchers found 25 trials—15 of behavioral interventions alone and 10 that combined behavioral and pharmacologic interventions—that met their criteria: The studies focused on weight loss and/or maintenance, reported outcomes ≥6 months from baseline, and were conducted (or feasible) in a primary care setting.

Behavioral interventions were categorized by treatment intensity (as measured by hours of contact, which ranged from <10 hours to >75) and comprehensiveness (including nutritional counseling, physical activity counseling or participation, and counseling on behavioral management techniques). Weight outcomes were categorized as short-term (6-12 months since treatment initiation) or maintenance (≥12 months after the end of active treatment).

The 15 behavioral intervention trials included 1258 children ages 4 to 18 years, most of whom were obese. Most trials were small and reported high retention rates. All had beneficial effects on weight in the intervention group compared with the controls, but not all changes were statistically significant. Higher intensity and more comprehensive programs had better outcomes.

The largest effects were in 3 moderate- to high-intensity, comprehensive weight management programs with ≥26 hours of contact. These 3 trials demonstrated a difference in BMI of 1.9 to 3.3 in the intervention groups at 12 months compared with the controls. (A 3.3 difference in BMI is equal to approximately 13 lb in an 8-year-old and 17 lb in a 12-year-old.)

Four behavioral intervention studies reported outcomes ≥12 months after completing the intervention (range 15-48 months). Three of the 4 reported continued beneficial effects on weight after the active treatment period, but the effects were markedly attenuated.

The only adverse effect reported in the trials of behavioral interventions was the injury rate among children in an exercise program, but it was minimal: One fracture was reported, vs no injuries for the controls. No differences were reported in height, eating disorders, or depression. However, fewer than half of the behavioral intervention trials reported on adverse effects.

 

 

 

Weight loss drugs have modest effects
Ten trials combining pharmacologic and behavioral interventions involved a total of 1294 obese adolescents ages 12 to 19. All evaluated short-term weight loss effects of either sibutramine (10-15 mg/d) or orlistat (120 mg tid). Trials ranged from 3 to 12 months. Participants in both the control and intervention groups received behavioral counseling.

The trials all favored the treatment groups, although not all of the results were statistically significant. Trials of longer duration (12 months) had more favorable results than those lasting 6 months.

The largest sibutramine trial (n=498) reported a mean BMI reduction of 2.9 in the treatment group, compared with a reduction of 0.3 in the control group (P<.001). This corresponds to an average weight loss of 14 lb in the intervention group, vs 4.2 lb in the control group, after 12 months.

The largest orlistat trial (n=539) reported a mean BMI reduction in the treatment group of 0.6, vs 0.3 in the control group (P<.001)—an average weight loss of 4.2 lb in the intervention group, compared with 2.1 lb among the controls after 12 months. None of the trials evaluated weight change after cessation of the study drug, and none compared orlistat with sibutramine.

Adverse effects in the sibutramine-treated patients were primarily cardiovascular and gastrointestinal. Cardiovascular effects included tachycardia and increases in systolic and diastolic blood pressure. The differences between the intervention and control groups were small, and no differences were observed in discontinuation rates caused by adverse events. Nor were differences reported in growth and maturation between the intervention and control groups.

Adverse effects in the orlistat-treated patients were also low and similar in the intervention and control groups. Gastrointestinal effects were common. The number needed to harm (NNH) for fatty or oily stools was 2,4 and the NNH for fecal incontinence was 12.5

WHAT'S NEW: Clinicians treating obese kids have cause for optimism

Although the trials included in this review were heterogeneous and many were small, this systematic review provides evidence that intensive, comprehensive behavioral weight loss interventions for obese children can be effective up to 12 months after the conclusion of the program. Family physicians should consider referring obese children and adolescents to such programs—or finding ways to provide supportive strategies themselves.

Sibutramine and orlistat may be helpful in the context of comprehensive, intensive behavioral interventions, although there is no follow-up data to demonstrate long-term safety and weight maintenance after the medication is stopped.

CAVEATS: Little is known about long-term safety of the drugs

There have been few randomized trials of pharmacologic interventions in adolescents and none evaluating weight maintenance after 12 months (or discontinuation of treatment), or assessing long-term safety of the medication.

Sibutramine is not approved by the US Food and Drug Administration (FDA) for use in children or adolescents.7 Orlistat is currently approved only for individuals over the age of 12.8

In January 2010, an additional contraindication was added to the sibutramine drug label, stating that it is not to be used in patients with a history of cardiovascular disease.9 And the FDA is currently investigating a rare association between orlistat and liver injury, although no conclusions have been released.10 Children and adolescents are particularly vulnerable to long-term side effects, given their relatively young age at the time of drug initiation, so we urge caution with the use of these drugs in this patient population.

CHALLENGES TO IMPLEMENTATION: Intensive approach may be hard to reproduce

Implementation of high-intensity comprehensive interventions for obese children faces a number of roadblocks, including limited availability of programs, cost, and reimbursement. Most of the intensive interventions in these trials took place in specialty centers rather than in primary care offices. Replicating them could require a referral—or significant resources within the primary care setting itself. Yet many, if not most, insurance policies still do not cover such extensive lifestyle interventions. (For information on weight loss interventions for adults, see “Weight loss strategies that really work”).

None of these trials reported on cost or cost effectiveness. Despite the considerable cost of a comprehensive obesity management program, however, a successful weight-maintenance model could be a worthwhile investment in long-term health.

Lastly, the results of this trial should not negate the importance of obesity prevention efforts by parents, who are in the best position to reverse the childhood obesity epidemic.11

Acknowledgement
The PURLs Surveillance System is supported in part by Grant Number UL1RR024999; awarded by the National Center for Research Resources; the grant is a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

Click here to view PURL METHODOLOGY

References

1. Whitlock E, O’Connor E, Williams S, et al. Effectiveness of weight management interventions in children: a targeted systematic review for the USPSTF. Pediatrics. 2010;125:e396-e418.

2. US Preventive Services Task Force. Screening for obesity in children and adolescents: recommendation statement. http://www.ahrq.gov/clinic/uspstf10/childobes/chobesrs.htm. Accessed April 11, 2010.

3. Daniels SR, Arnett DK, Eckel RH, et al. Overweight in children and adolescents: pathophysiology, consequences, prevention, and treatment. Circulation. 2005;111:1999-2012.

4. Flegal KM, Carroll MD, Ogden CL, et al. Prevalence and trends in obesity among US adults, 1999-2008. JAMA. 2010;303:235-241.

5. Han JC, Lawlor DA, Kimm SY. Childhood obesity. Lancet. 2010;375:1737-1748.

6. Strauss RS, Pollack HA. Social marginalization of overweight children. Arch Pediatr Adolesc Med. 2003;157:746-752.

7. US Food and Drug Administration. Meridia approval history. Available at: http://www.accessdata.fda.gov/drugsatfda_docs/label/2009/020632s032lbl.pdf. Accessed June 16, 2010.

8. US Food and Drug Administration. Xenical approval letter. Available at: www.accessdata.fda.gov/drugsatfda_docs/appletter/2003/20766se5-018ltr.pdf. Accessed June 16, 2010.

9. US Food and Drug Administration. Early communication about an ongoing safety review of Meridia (sibutramine hydrochlo-ride). Available at: http://www.fda.gov/Drugs/DrugSafety/PostmarketDrugSafetyInformationfor
PatientsandProviders/ucm180076.htm. Accessed March 29, 2010.

10. US Food and Drug Administration. Early communication about an ongoing safety review of orlistat. Available at: http://www.fda.gov/Drugs/DrugSafety/PostmarketDrugSafetyInformationforPatientsandProviders/ucm180076.htm. Accessed April 11, 2010.

11. Gruber KJ, Haldeman LA. Using the family to combat childhood and adult obesity. Prev Chronic Dis. 2009;6:A106.-

References

1. Whitlock E, O’Connor E, Williams S, et al. Effectiveness of weight management interventions in children: a targeted systematic review for the USPSTF. Pediatrics. 2010;125:e396-e418.

2. US Preventive Services Task Force. Screening for obesity in children and adolescents: recommendation statement. http://www.ahrq.gov/clinic/uspstf10/childobes/chobesrs.htm. Accessed April 11, 2010.

3. Daniels SR, Arnett DK, Eckel RH, et al. Overweight in children and adolescents: pathophysiology, consequences, prevention, and treatment. Circulation. 2005;111:1999-2012.

4. Flegal KM, Carroll MD, Ogden CL, et al. Prevalence and trends in obesity among US adults, 1999-2008. JAMA. 2010;303:235-241.

5. Han JC, Lawlor DA, Kimm SY. Childhood obesity. Lancet. 2010;375:1737-1748.

6. Strauss RS, Pollack HA. Social marginalization of overweight children. Arch Pediatr Adolesc Med. 2003;157:746-752.

7. US Food and Drug Administration. Meridia approval history. Available at: http://www.accessdata.fda.gov/drugsatfda_docs/label/2009/020632s032lbl.pdf. Accessed June 16, 2010.

8. US Food and Drug Administration. Xenical approval letter. Available at: www.accessdata.fda.gov/drugsatfda_docs/appletter/2003/20766se5-018ltr.pdf. Accessed June 16, 2010.

9. US Food and Drug Administration. Early communication about an ongoing safety review of Meridia (sibutramine hydrochlo-ride). Available at: http://www.fda.gov/Drugs/DrugSafety/PostmarketDrugSafetyInformationfor
PatientsandProviders/ucm180076.htm. Accessed March 29, 2010.

10. US Food and Drug Administration. Early communication about an ongoing safety review of orlistat. Available at: http://www.fda.gov/Drugs/DrugSafety/PostmarketDrugSafetyInformationforPatientsandProviders/ucm180076.htm. Accessed April 11, 2010.

11. Gruber KJ, Haldeman LA. Using the family to combat childhood and adult obesity. Prev Chronic Dis. 2009;6:A106.-

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Do intercontraction intervals predict when a woman at term should seek evaluation of labor?

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Display Headline
Do intercontraction intervals predict when a woman at term should seek evaluation of labor?
EVIDENCE-BASED ANSWER

NO; HOWEVER, A REDUCTION IN the intercontraction interval is associated with active labor (strength of recommendation [SOR]: B, cohort study).

Most primigravidas who have had regular contractions for 2 hours and multigravidas who have had regular contractions for 1 hour haven’t transitioned into the active phase of labor (SOR: B, cohort study).

 

Evidence summary

Multiple cohort studies demonstrate that the expected events of normal labor form a bell-shaped curve. The range of labor experiences makes predicting when a particular woman will enter active labor difficult.

When does latent labor become active labor?

The first stage of labor includes latent and active phases. The latent phase is defined as the period between onset of labor and cervical dilatation of 3 to 4 cm or the time between onset of regular contractions and escalation in the rate of cervical dilation. Regular contractions must be intense, last 60 seconds, and occur in a predictable pattern. Escalating cervical dilation is marked by a change in the cervical examination over a short period of time (usually 2 hours).1

The World Health Organization defines active labor as cervical dilation between 4 and 9 cm, with dilation usually occurring at 1 cm per hour or faster and accompanied by the beginning of fetal descent.2

Latent labor was initially described in a large prospective cohort of 10,293 term gravidas (including 4175 nulliparas and 5599 multiparas) followed from presentation to delivery.1 Cervical dilation was assessed by examination every 30 to 120 minutes, almost always performed by the same examiner throughout labor. In primigravidas, latent labor averaged 6.4 hours, with 95% of women completing the latent phase in 20.6 hours. In multigravidas, the mean duration of latent labor was 4.8 hours, with 95% of women transitioning to active labor in 13.6 hours.

Shorter intercontraction interval linked to active labor

A recently published cohort study of women presenting to labor and delivery found that a relative decrease in the intercontraction interval was associated with a diagnosis of labor (odds ratio=1.42; 95% confidence interval, 1.06-1.90). The study failed to define either active labor or decrease in the intercontraction interval.3

Earlier admission leads to more interventions and poorer outcomes

Many studies have suggested that admitting women to the hospital during the latent phase of labor is associated with more interventions and poorer outcomes. Two large retrospective cohort studies (N=2697 and 3220) found increased rates of cesarean section in women admitted during the latent phase.4,5 They also reported increased use of oxytocin, epidural analgesia, intrauterine pressure catheters, and fetal scalp electrodes, and increased rates of chorioamnionitis, postpartum infection, and neonatal intubation.4,5 See the TABLE for a summary of the effects of latent-phase admission.

TABLE
Consequences of hospital admission during latent vs active labor

NulliparousParous
ConsequenceLatent (%)Active (%)NNHLatent (%)Active (%)NNH
Oxytocin4 43276*2099*
Epidural4 82615*58406*
Assisted vaginal delivery4 2725508650
Cesarean4 10417*8650
Cesarean5 14714*3150*
pH <7.14 4310032100
Apgar <74 425032100
NNH, number needed to harm.
*Indicates relationship significant at the level <.05.
†Study by Bailit5 also showed significant associations for oxytocin, scalp pH, intrauterine pressure catheter, fetal scalp electrode, epidural, neonatal intubation, amnionitis, and postpartum infection. Raw data are unavailable for abstraction
 

 

 

Labor assessment program reduced time in the labor ward

Labor assessment programs attempt to delay admission during early active labor. One randomized clinical trial (N=209) among low-risk women with reassuring maternal and fetal assessments in early labor divided the women into 2 groups when they presented for labor and delivery. One group received advice, encouragement, and support along with instructions to walk or return home and come back when labor became more active (defined as regular, painful contractions and dilation of at least 3 cm). The other group was admitted directly to the labor and delivery ward. The study found that early labor assessment decreased use of analgesics and oxytocin and reduced time spent in the labor ward.6

Recommendations

The American College of Obstetricians and Gynecologists (ACOG) acknowledges in patient education literature that distinguishing true from false labor is difficult. ACOG lists characteristics of each and recommend that a woman monitor the frequency of contractions for an hour and call the doctor’s office or hospital if she thinks she’s in labor.7

Similarly, a patient handout from the American College of Nurse-Midwives recommends calling the health care provider if contractions are ≤5 minutes apart for more than 1 hour, several contractions are so painful that the woman cannot walk or talk, or her water breaks.8

A standard textbook describes normal uterine contractions during active labor as occurring every 2 to 5 minutes, and as often as every 2 to 3 minutes.9

References

1. Friedman EA, Kroll BH. Computer analysis of labor progression. 3. Pattern variations by parity. J Reprod Med. 1971;6:179-183.

2. World Health Organization. Managing Complications in Pregnancy and Childbirth: A Guide for Midwives and Doctors. Geneva, Switzerland: Department of Reproductive Health and Research, Family and Community Health, World Health Organization; 2003.

3. Ragusa A, Monsur M, Zanini A, et al. Diagnosis of labor: a prospective study. Med Gen Med. 2005;7:61.-

4. Holmes P, Oppenheimer LW, Wen SW. The relationship between cervical dilatation at initial presentation in labour and subsequent intervention. BJOG. 2001;108:1120-1124.

5. Bailit JL, Dierker LR, Blanchard MH, et al. Outcomes of women presenting in active versus latent phase of spontaneous labor. Obstet Gynecol. 2005;105:77-79.

6. McNiven PS, Williams JI, Hodnett E, et al. An early labor assessment program: a randomized, controlled trial. Birth. 1998;25:5-10.

7. How to Tell When Labor Begins. Washington, DC: American College of Obstetricians and Gynecologists; 1999. Available at: www.acog.org/publications/patient_education/bp004.cfm. Accessed November 8, 2008.

8. Am I in Labor? Silver Spring, Md: American College of Nurse-Midwives; 2003. Available at: www.midwife.org/siteFiles/news/sharewithwomen48_4.pdf. Accessed November 7, 2008.

9. Kilpatrick S, Garrison E. Normal labor and delivery. In: Gabbe SG, Niebyl JR, Simpson JL, eds. Obstetrics: Normal and Problem Pregnancies. 5th ed. Philadelphia: Churchill Livingstone/Elsevier; 2007:303–317.

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Courtney Mull, MD;
Vanessa McPherson, MD
Department of Family Medicine, University of North Carolina and Carolinas Medical Center, Charlotte

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Charlotte

Leonora Kaufmann, MLIS
Department of Family Medicine, University of North Carolina and Carolinas Medical Center, Charlotte

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Vanessa McPherson, MD
Department of Family Medicine, University of North Carolina and Carolinas Medical Center, Charlotte

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Charlotte

Leonora Kaufmann, MLIS
Department of Family Medicine, University of North Carolina and Carolinas Medical Center, Charlotte

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Courtney Mull, MD;
Vanessa McPherson, MD
Department of Family Medicine, University of North Carolina and Carolinas Medical Center, Charlotte

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Charlotte

Leonora Kaufmann, MLIS
Department of Family Medicine, University of North Carolina and Carolinas Medical Center, Charlotte

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EVIDENCE-BASED ANSWER

NO; HOWEVER, A REDUCTION IN the intercontraction interval is associated with active labor (strength of recommendation [SOR]: B, cohort study).

Most primigravidas who have had regular contractions for 2 hours and multigravidas who have had regular contractions for 1 hour haven’t transitioned into the active phase of labor (SOR: B, cohort study).

 

Evidence summary

Multiple cohort studies demonstrate that the expected events of normal labor form a bell-shaped curve. The range of labor experiences makes predicting when a particular woman will enter active labor difficult.

When does latent labor become active labor?

The first stage of labor includes latent and active phases. The latent phase is defined as the period between onset of labor and cervical dilatation of 3 to 4 cm or the time between onset of regular contractions and escalation in the rate of cervical dilation. Regular contractions must be intense, last 60 seconds, and occur in a predictable pattern. Escalating cervical dilation is marked by a change in the cervical examination over a short period of time (usually 2 hours).1

The World Health Organization defines active labor as cervical dilation between 4 and 9 cm, with dilation usually occurring at 1 cm per hour or faster and accompanied by the beginning of fetal descent.2

Latent labor was initially described in a large prospective cohort of 10,293 term gravidas (including 4175 nulliparas and 5599 multiparas) followed from presentation to delivery.1 Cervical dilation was assessed by examination every 30 to 120 minutes, almost always performed by the same examiner throughout labor. In primigravidas, latent labor averaged 6.4 hours, with 95% of women completing the latent phase in 20.6 hours. In multigravidas, the mean duration of latent labor was 4.8 hours, with 95% of women transitioning to active labor in 13.6 hours.

Shorter intercontraction interval linked to active labor

A recently published cohort study of women presenting to labor and delivery found that a relative decrease in the intercontraction interval was associated with a diagnosis of labor (odds ratio=1.42; 95% confidence interval, 1.06-1.90). The study failed to define either active labor or decrease in the intercontraction interval.3

Earlier admission leads to more interventions and poorer outcomes

Many studies have suggested that admitting women to the hospital during the latent phase of labor is associated with more interventions and poorer outcomes. Two large retrospective cohort studies (N=2697 and 3220) found increased rates of cesarean section in women admitted during the latent phase.4,5 They also reported increased use of oxytocin, epidural analgesia, intrauterine pressure catheters, and fetal scalp electrodes, and increased rates of chorioamnionitis, postpartum infection, and neonatal intubation.4,5 See the TABLE for a summary of the effects of latent-phase admission.

TABLE
Consequences of hospital admission during latent vs active labor

NulliparousParous
ConsequenceLatent (%)Active (%)NNHLatent (%)Active (%)NNH
Oxytocin4 43276*2099*
Epidural4 82615*58406*
Assisted vaginal delivery4 2725508650
Cesarean4 10417*8650
Cesarean5 14714*3150*
pH <7.14 4310032100
Apgar <74 425032100
NNH, number needed to harm.
*Indicates relationship significant at the level <.05.
†Study by Bailit5 also showed significant associations for oxytocin, scalp pH, intrauterine pressure catheter, fetal scalp electrode, epidural, neonatal intubation, amnionitis, and postpartum infection. Raw data are unavailable for abstraction
 

 

 

Labor assessment program reduced time in the labor ward

Labor assessment programs attempt to delay admission during early active labor. One randomized clinical trial (N=209) among low-risk women with reassuring maternal and fetal assessments in early labor divided the women into 2 groups when they presented for labor and delivery. One group received advice, encouragement, and support along with instructions to walk or return home and come back when labor became more active (defined as regular, painful contractions and dilation of at least 3 cm). The other group was admitted directly to the labor and delivery ward. The study found that early labor assessment decreased use of analgesics and oxytocin and reduced time spent in the labor ward.6

Recommendations

The American College of Obstetricians and Gynecologists (ACOG) acknowledges in patient education literature that distinguishing true from false labor is difficult. ACOG lists characteristics of each and recommend that a woman monitor the frequency of contractions for an hour and call the doctor’s office or hospital if she thinks she’s in labor.7

Similarly, a patient handout from the American College of Nurse-Midwives recommends calling the health care provider if contractions are ≤5 minutes apart for more than 1 hour, several contractions are so painful that the woman cannot walk or talk, or her water breaks.8

A standard textbook describes normal uterine contractions during active labor as occurring every 2 to 5 minutes, and as often as every 2 to 3 minutes.9

EVIDENCE-BASED ANSWER

NO; HOWEVER, A REDUCTION IN the intercontraction interval is associated with active labor (strength of recommendation [SOR]: B, cohort study).

Most primigravidas who have had regular contractions for 2 hours and multigravidas who have had regular contractions for 1 hour haven’t transitioned into the active phase of labor (SOR: B, cohort study).

 

Evidence summary

Multiple cohort studies demonstrate that the expected events of normal labor form a bell-shaped curve. The range of labor experiences makes predicting when a particular woman will enter active labor difficult.

When does latent labor become active labor?

The first stage of labor includes latent and active phases. The latent phase is defined as the period between onset of labor and cervical dilatation of 3 to 4 cm or the time between onset of regular contractions and escalation in the rate of cervical dilation. Regular contractions must be intense, last 60 seconds, and occur in a predictable pattern. Escalating cervical dilation is marked by a change in the cervical examination over a short period of time (usually 2 hours).1

The World Health Organization defines active labor as cervical dilation between 4 and 9 cm, with dilation usually occurring at 1 cm per hour or faster and accompanied by the beginning of fetal descent.2

Latent labor was initially described in a large prospective cohort of 10,293 term gravidas (including 4175 nulliparas and 5599 multiparas) followed from presentation to delivery.1 Cervical dilation was assessed by examination every 30 to 120 minutes, almost always performed by the same examiner throughout labor. In primigravidas, latent labor averaged 6.4 hours, with 95% of women completing the latent phase in 20.6 hours. In multigravidas, the mean duration of latent labor was 4.8 hours, with 95% of women transitioning to active labor in 13.6 hours.

Shorter intercontraction interval linked to active labor

A recently published cohort study of women presenting to labor and delivery found that a relative decrease in the intercontraction interval was associated with a diagnosis of labor (odds ratio=1.42; 95% confidence interval, 1.06-1.90). The study failed to define either active labor or decrease in the intercontraction interval.3

Earlier admission leads to more interventions and poorer outcomes

Many studies have suggested that admitting women to the hospital during the latent phase of labor is associated with more interventions and poorer outcomes. Two large retrospective cohort studies (N=2697 and 3220) found increased rates of cesarean section in women admitted during the latent phase.4,5 They also reported increased use of oxytocin, epidural analgesia, intrauterine pressure catheters, and fetal scalp electrodes, and increased rates of chorioamnionitis, postpartum infection, and neonatal intubation.4,5 See the TABLE for a summary of the effects of latent-phase admission.

TABLE
Consequences of hospital admission during latent vs active labor

NulliparousParous
ConsequenceLatent (%)Active (%)NNHLatent (%)Active (%)NNH
Oxytocin4 43276*2099*
Epidural4 82615*58406*
Assisted vaginal delivery4 2725508650
Cesarean4 10417*8650
Cesarean5 14714*3150*
pH <7.14 4310032100
Apgar <74 425032100
NNH, number needed to harm.
*Indicates relationship significant at the level <.05.
†Study by Bailit5 also showed significant associations for oxytocin, scalp pH, intrauterine pressure catheter, fetal scalp electrode, epidural, neonatal intubation, amnionitis, and postpartum infection. Raw data are unavailable for abstraction
 

 

 

Labor assessment program reduced time in the labor ward

Labor assessment programs attempt to delay admission during early active labor. One randomized clinical trial (N=209) among low-risk women with reassuring maternal and fetal assessments in early labor divided the women into 2 groups when they presented for labor and delivery. One group received advice, encouragement, and support along with instructions to walk or return home and come back when labor became more active (defined as regular, painful contractions and dilation of at least 3 cm). The other group was admitted directly to the labor and delivery ward. The study found that early labor assessment decreased use of analgesics and oxytocin and reduced time spent in the labor ward.6

Recommendations

The American College of Obstetricians and Gynecologists (ACOG) acknowledges in patient education literature that distinguishing true from false labor is difficult. ACOG lists characteristics of each and recommend that a woman monitor the frequency of contractions for an hour and call the doctor’s office or hospital if she thinks she’s in labor.7

Similarly, a patient handout from the American College of Nurse-Midwives recommends calling the health care provider if contractions are ≤5 minutes apart for more than 1 hour, several contractions are so painful that the woman cannot walk or talk, or her water breaks.8

A standard textbook describes normal uterine contractions during active labor as occurring every 2 to 5 minutes, and as often as every 2 to 3 minutes.9

References

1. Friedman EA, Kroll BH. Computer analysis of labor progression. 3. Pattern variations by parity. J Reprod Med. 1971;6:179-183.

2. World Health Organization. Managing Complications in Pregnancy and Childbirth: A Guide for Midwives and Doctors. Geneva, Switzerland: Department of Reproductive Health and Research, Family and Community Health, World Health Organization; 2003.

3. Ragusa A, Monsur M, Zanini A, et al. Diagnosis of labor: a prospective study. Med Gen Med. 2005;7:61.-

4. Holmes P, Oppenheimer LW, Wen SW. The relationship between cervical dilatation at initial presentation in labour and subsequent intervention. BJOG. 2001;108:1120-1124.

5. Bailit JL, Dierker LR, Blanchard MH, et al. Outcomes of women presenting in active versus latent phase of spontaneous labor. Obstet Gynecol. 2005;105:77-79.

6. McNiven PS, Williams JI, Hodnett E, et al. An early labor assessment program: a randomized, controlled trial. Birth. 1998;25:5-10.

7. How to Tell When Labor Begins. Washington, DC: American College of Obstetricians and Gynecologists; 1999. Available at: www.acog.org/publications/patient_education/bp004.cfm. Accessed November 8, 2008.

8. Am I in Labor? Silver Spring, Md: American College of Nurse-Midwives; 2003. Available at: www.midwife.org/siteFiles/news/sharewithwomen48_4.pdf. Accessed November 7, 2008.

9. Kilpatrick S, Garrison E. Normal labor and delivery. In: Gabbe SG, Niebyl JR, Simpson JL, eds. Obstetrics: Normal and Problem Pregnancies. 5th ed. Philadelphia: Churchill Livingstone/Elsevier; 2007:303–317.

References

1. Friedman EA, Kroll BH. Computer analysis of labor progression. 3. Pattern variations by parity. J Reprod Med. 1971;6:179-183.

2. World Health Organization. Managing Complications in Pregnancy and Childbirth: A Guide for Midwives and Doctors. Geneva, Switzerland: Department of Reproductive Health and Research, Family and Community Health, World Health Organization; 2003.

3. Ragusa A, Monsur M, Zanini A, et al. Diagnosis of labor: a prospective study. Med Gen Med. 2005;7:61.-

4. Holmes P, Oppenheimer LW, Wen SW. The relationship between cervical dilatation at initial presentation in labour and subsequent intervention. BJOG. 2001;108:1120-1124.

5. Bailit JL, Dierker LR, Blanchard MH, et al. Outcomes of women presenting in active versus latent phase of spontaneous labor. Obstet Gynecol. 2005;105:77-79.

6. McNiven PS, Williams JI, Hodnett E, et al. An early labor assessment program: a randomized, controlled trial. Birth. 1998;25:5-10.

7. How to Tell When Labor Begins. Washington, DC: American College of Obstetricians and Gynecologists; 1999. Available at: www.acog.org/publications/patient_education/bp004.cfm. Accessed November 8, 2008.

8. Am I in Labor? Silver Spring, Md: American College of Nurse-Midwives; 2003. Available at: www.midwife.org/siteFiles/news/sharewithwomen48_4.pdf. Accessed November 7, 2008.

9. Kilpatrick S, Garrison E. Normal labor and delivery. In: Gabbe SG, Niebyl JR, Simpson JL, eds. Obstetrics: Normal and Problem Pregnancies. 5th ed. Philadelphia: Churchill Livingstone/Elsevier; 2007:303–317.

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Glucose control: How low should you go with the critically ill?

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Display Headline
Glucose control: How low should you go with the critically ill?
Practice changer

For hyperglycemic patients admitted to an intensive care unit (ICU), the target blood glucose level should be ≤180 mg/dL, not 81 to 108 mg/dL. More aggressive glucose lowering is associated with a higher mortality rate.1

Strength of recommendation

B: Based on a single, high-quality randomized clinical trial.

Finfer S, Chittock DR, Su SY, et al; NICE-SUGAR Study Investigators. Intensive versus conventional glucose control in critically ill patients. N Engl J Med. 2009;360:1283-1297.

 

ILLUSTRATIVE CASE

A 71-year-old woman with diabetes and coronary artery disease has just been admitted to the ICU, where she’ll receive treatment for sepsis, multilobar pneumonia, and respiratory failure requiring mechanical ventilation. Her blood sugar is 253 mg/dL. In writing her admission orders, you contemplate targets for glycemic control. How low should you go?

Hyperglycemia is common in patients admitted to intensive care, whether or not they have diabetes. Elevated blood sugar is associated with stress and trauma and affects both postoperative and critically ill medical patients. A wealth of evidence has demonstrated that hyperglycemia is associated with poorer outcomes and increased mortality in this patient population, including those with myocardial infarction, stroke, trauma, and other medical conditions.2-5 Thus, intensive glucose control is the standard of care in the ICU, based on consensus guidelines from such groups as the American Diabetes Association (ADA) and the Surviving Sepsis Campaign—an initiative developed by 3 critical care organizations and endorsed by 16 specialty groups.6-8

Is intense therapy better? Study results differ
The association between hyperglycemia and an increased risk of death led investigators to study the effectiveness of aggressive treatment with insulin in decreasing morbidity and mortality. A 2004 meta-analysis of 35 trials comparing insulin vs no insulin in critically ill hospitalized patients demonstrated a 15% reduction in short-term mortality among patients treated with insulin.9 A 2008 meta-analysis of 29 randomized trials, including data from 8432 adult ICU patients, compared intensive insulin therapy with conventional therapy—and found that intensive therapy did not lower hospital mortality rates compared with conventional therapy. In addition, this meta-analysis revealed a marked increase in severe hypoglycemia (blood sugar ≤40 mg/dL) in the intensive therapy group.10 (The intensive therapy group included studies with glucose goals of ≤110 mg/dL and <150 mg/dL in about equal numbers; conventional therapy goals were generally between 180 and 200 mg/dL.)

The studies included in both the meta-analyses, however, were mostly small, single-center trials, and of low-to-medium quality. In addition, methods for achieving glycemic control varied. Nonetheless, current consensus guidelines set a goal for glucose levels of 80 to 110 mg/dL for all critically ill hospitalized patients.6-8 But because of the lack of sufficient high-quality evidence from a single large RCT, Finfer et al conducted the large study described here to clearly establish that intensive glycemic control decreases all-cause mortality. Given their hypothesis, the results were surprising.

STUDY SUMMARY: Intensive therapy does more harm than help

NICE-SUGAR (Normoglycaemia in Intensive Care Evaluation-Survival Using Glucose Algorithm Regulation) was a large-scale, multicenter, multinational trial comparing aggressive blood sugar control (goal 81-108 mg/dL) with conventional therapy (goal ≤180 mg/dL) in 6104 critically ill hospitalized patients with hyperglycemia. Patients were followed for 90 days. The primary end point was death from any cause 90 days after randomization. Secondary outcomes included survival time during the first 90 days, specific cause of death, duration of mechanical ventilation, renal replacement therapy, and length of stays in the ICU and in the hospital. Other outcomes included death from any cause within 28 days, place of death, new organ failure, positive blood culture, blood transfusion, and units of blood transfused.

The study was conducted in 42 hospitals in Canada, Australia, and New Zealand. Patients had to have an anticipated ICU admission of 3 days or more and randomization had to occur within 24 hours of admission. The study protocol was discontinued when patients began eating or were discharged from the ICU; if they were readmitted to the ICU within 90 days of randomization, the study protocol was resumed.

Treatment assignment was revealed to clinical staff after randomization, and was determined by a specific algorithm ( https://studies.thegeorgeinstitute.org/nice/ ). Blood sugar levels were managed with insulin infusions.

In the conventional group, insulin was started at 1 unit/h for glucose levels >180 mg/dL, and decreased or stopped when levels were <144 mg/dL, depending on previous glucose value and current rate of drip. In the intensive therapy group, insulin was initiated for lower levels (blood sugar >109 mg/dL) and at a higher rate (2 units/h). The insulin rate was decreased or maintained for glucose levels from 64 to 80 mg/dL, depending on previous glucose value and current rate of drip. Insulin was withheld for blood sugar levels of <64 mg/dL.

Contrary to the hypothesis, intensive therapy spelled trouble. Patients with intensive glycemic control had an all-cause mortality rate of 27.5%, compared with a rate of 24.9% for patients in the conventional therapy group (P=.04, number needed to harm [NNH]=38). Severe hypoglycemia (glucose ≤40 mg/dL) occurred in 6.8% of those in the intensive therapy group, compared with 0.5% in the conventional therapy group (P=.03, NNH=16).

Most of the deaths in both groups occurred in the ICU or in the hospital. Deaths from cardiovascular causes were more common among those in the intensive therapy group. There were no significant differences in any other outcomes. The mean glucose level in the intensive therapy group was 118, vs 145 mg/dL in the conventional therapy group.

For multivariate and subgroup analyses, the patients were assigned strata (Canada or Australia/New Zealand; operative vs nonoperative admission) or classified into groups (traumatic vs atraumatic; diabetes vs no diabetes; corticosteroids in previous 72 hours or not; high vs low critical illness symptom severity) based on predefined characteristics. No subgroups had significantly improved outcomes with intensive therapy.1

 

 

 

WHAT’S NEW: Now we know: Don’t go too low

This study, in contrast to a number of smaller studies of lower quality, demonstrates a higher all-cause mortality rate at 90 days for critically ill patients receiving intensive glucose therapy. It is now clear that, among critically ill hospitalized patients, aiming for intensive glucose control (81-108 mg/dL) is associated with an increased rate of severe hypoglycemic events and all-cause mortality at 90 days. The previously used goal of conventional therapy (≤180 mg/dL) is safer.

CAVEATS: Study population may not reflect primary care

There are 2 caveats to this study. The first is that because of the nature of the research, it was impossible to maintain blinding of the clinical staff to patient assignments. The second important caveat pertains to the severity of illness among participants in this multicenter study: Most of these patients were in ICUs at tertiary care medical centers and had an expected ICU length of stay of 3 or more days. Although many family physicians manage patients in ICUs, the patients randomized in this study may represent a sicker than average patient population for some hospitals.

CHALLENGES TO IMPLEMENTATION: Some may doubt validity of this outcome

Less aggressive glycemic control for critically ill patients should be easier to achieve, not more difficult. However, a change in glucose targets may require new admission order sets and, notably, reeducation of physicians and nurses who have been convinced by earlier studies that more intensive glucose control is superior.

Acknowledgments

The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center for Research Resources, a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

PURLs methodology

This study was selected and evaluated using FPIN’s Priority Updates from the Research Literature (PURL) Surveillance System methodology. The criteria and findings leading to the selection of this study as a PURL can be accessed at www.jfponline.com/purls.

Files
References

1. Finfer S, Chittock DR, Su SY, et al. NICE-SUGAR Study Investigators. Intensive versus conventional glucose control in critically ill patients. N Engl J Med. 2009;360:1283-1297.

2. Capes SE, Hunt D, Malmberg K, et al. Stress hyperglycaemia and increased risk of death after myocardial infarction in patients with and without diabetes: a systematic overview. Lancet. 2000;355:773-778.

3. Capes SE, Hunt D, Malmberg K, et al. Stress hyperglycemia and prognosis of stroke in nondiabetic and diabetic patients: a systematic overview. Stroke. 2001;32:2426-2432.

4. Gale SC, Sicoutris C, Reilly PM, et al. Poor glycemic control is associated with increased mortality in critically ill trauma patients. Am Surg. 2007;73:454-460.

5. Krinsley JS. Association between hyperglycemia and increased hospital mortality in a heterogeneous population of critically ill patients. Mayo Clin Proc. 2003;78:1471-1478.

6. Standards of medical care in diabetes—2008. Diabetes Care. 2008;31(suppl 1):S12-S54.

7. Rodbard HW, Blonde L, Braithwaite SS, et al. American Association of Clinical Endocrinologists medical guidelines for clinical practice for the management of diabetes mellitus. Endocr Pract. 2007;13(suppl 1):1-68.

8. Dellinger RP, Levy MM, Carlet JM, et al. Surviving Sepsis Campaign: international guidelines for management of severe sepsis and septic shock: 2008. Crit Care Med. 2008;36:296-327.

9. Pittas AG, Siegel RD, Lau J. Insulin therapy for critically ill hospitalized patients: a meta-analysis of randomized controlled trials. Arch Intern Med. 2004;164:2005-2011.

10. Wiener RS, Wiener DC, Larson RJ. Benefits and risks of tight glucose control in critically ill adults: a meta-analysis. JAMA. 2008;300:933-944.

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Sarah-Anne Schumann, MD;
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Department of Family Medicine, The University of Chicago

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John Hickner, MD, MSc
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Sarah-Anne Schumann, MD;
Lisa Vargish, MD, MS
Department of Family Medicine, The University of Chicago

PURLs EDITOR
John Hickner, MD, MSc
Department of Family Medicine, Cleveland Clinic
The University of Chicago

Author and Disclosure Information

Adam J. Zolotor, MD, MPH
Department of Family Medicine, University of North Carolina, Chapel Hill

Sarah-Anne Schumann, MD;
Lisa Vargish, MD, MS
Department of Family Medicine, The University of Chicago

PURLs EDITOR
John Hickner, MD, MSc
Department of Family Medicine, Cleveland Clinic
The University of Chicago

Article PDF
Article PDF
Practice changer

For hyperglycemic patients admitted to an intensive care unit (ICU), the target blood glucose level should be ≤180 mg/dL, not 81 to 108 mg/dL. More aggressive glucose lowering is associated with a higher mortality rate.1

Strength of recommendation

B: Based on a single, high-quality randomized clinical trial.

Finfer S, Chittock DR, Su SY, et al; NICE-SUGAR Study Investigators. Intensive versus conventional glucose control in critically ill patients. N Engl J Med. 2009;360:1283-1297.

 

ILLUSTRATIVE CASE

A 71-year-old woman with diabetes and coronary artery disease has just been admitted to the ICU, where she’ll receive treatment for sepsis, multilobar pneumonia, and respiratory failure requiring mechanical ventilation. Her blood sugar is 253 mg/dL. In writing her admission orders, you contemplate targets for glycemic control. How low should you go?

Hyperglycemia is common in patients admitted to intensive care, whether or not they have diabetes. Elevated blood sugar is associated with stress and trauma and affects both postoperative and critically ill medical patients. A wealth of evidence has demonstrated that hyperglycemia is associated with poorer outcomes and increased mortality in this patient population, including those with myocardial infarction, stroke, trauma, and other medical conditions.2-5 Thus, intensive glucose control is the standard of care in the ICU, based on consensus guidelines from such groups as the American Diabetes Association (ADA) and the Surviving Sepsis Campaign—an initiative developed by 3 critical care organizations and endorsed by 16 specialty groups.6-8

Is intense therapy better? Study results differ
The association between hyperglycemia and an increased risk of death led investigators to study the effectiveness of aggressive treatment with insulin in decreasing morbidity and mortality. A 2004 meta-analysis of 35 trials comparing insulin vs no insulin in critically ill hospitalized patients demonstrated a 15% reduction in short-term mortality among patients treated with insulin.9 A 2008 meta-analysis of 29 randomized trials, including data from 8432 adult ICU patients, compared intensive insulin therapy with conventional therapy—and found that intensive therapy did not lower hospital mortality rates compared with conventional therapy. In addition, this meta-analysis revealed a marked increase in severe hypoglycemia (blood sugar ≤40 mg/dL) in the intensive therapy group.10 (The intensive therapy group included studies with glucose goals of ≤110 mg/dL and <150 mg/dL in about equal numbers; conventional therapy goals were generally between 180 and 200 mg/dL.)

The studies included in both the meta-analyses, however, were mostly small, single-center trials, and of low-to-medium quality. In addition, methods for achieving glycemic control varied. Nonetheless, current consensus guidelines set a goal for glucose levels of 80 to 110 mg/dL for all critically ill hospitalized patients.6-8 But because of the lack of sufficient high-quality evidence from a single large RCT, Finfer et al conducted the large study described here to clearly establish that intensive glycemic control decreases all-cause mortality. Given their hypothesis, the results were surprising.

STUDY SUMMARY: Intensive therapy does more harm than help

NICE-SUGAR (Normoglycaemia in Intensive Care Evaluation-Survival Using Glucose Algorithm Regulation) was a large-scale, multicenter, multinational trial comparing aggressive blood sugar control (goal 81-108 mg/dL) with conventional therapy (goal ≤180 mg/dL) in 6104 critically ill hospitalized patients with hyperglycemia. Patients were followed for 90 days. The primary end point was death from any cause 90 days after randomization. Secondary outcomes included survival time during the first 90 days, specific cause of death, duration of mechanical ventilation, renal replacement therapy, and length of stays in the ICU and in the hospital. Other outcomes included death from any cause within 28 days, place of death, new organ failure, positive blood culture, blood transfusion, and units of blood transfused.

The study was conducted in 42 hospitals in Canada, Australia, and New Zealand. Patients had to have an anticipated ICU admission of 3 days or more and randomization had to occur within 24 hours of admission. The study protocol was discontinued when patients began eating or were discharged from the ICU; if they were readmitted to the ICU within 90 days of randomization, the study protocol was resumed.

Treatment assignment was revealed to clinical staff after randomization, and was determined by a specific algorithm ( https://studies.thegeorgeinstitute.org/nice/ ). Blood sugar levels were managed with insulin infusions.

In the conventional group, insulin was started at 1 unit/h for glucose levels >180 mg/dL, and decreased or stopped when levels were <144 mg/dL, depending on previous glucose value and current rate of drip. In the intensive therapy group, insulin was initiated for lower levels (blood sugar >109 mg/dL) and at a higher rate (2 units/h). The insulin rate was decreased or maintained for glucose levels from 64 to 80 mg/dL, depending on previous glucose value and current rate of drip. Insulin was withheld for blood sugar levels of <64 mg/dL.

Contrary to the hypothesis, intensive therapy spelled trouble. Patients with intensive glycemic control had an all-cause mortality rate of 27.5%, compared with a rate of 24.9% for patients in the conventional therapy group (P=.04, number needed to harm [NNH]=38). Severe hypoglycemia (glucose ≤40 mg/dL) occurred in 6.8% of those in the intensive therapy group, compared with 0.5% in the conventional therapy group (P=.03, NNH=16).

Most of the deaths in both groups occurred in the ICU or in the hospital. Deaths from cardiovascular causes were more common among those in the intensive therapy group. There were no significant differences in any other outcomes. The mean glucose level in the intensive therapy group was 118, vs 145 mg/dL in the conventional therapy group.

For multivariate and subgroup analyses, the patients were assigned strata (Canada or Australia/New Zealand; operative vs nonoperative admission) or classified into groups (traumatic vs atraumatic; diabetes vs no diabetes; corticosteroids in previous 72 hours or not; high vs low critical illness symptom severity) based on predefined characteristics. No subgroups had significantly improved outcomes with intensive therapy.1

 

 

 

WHAT’S NEW: Now we know: Don’t go too low

This study, in contrast to a number of smaller studies of lower quality, demonstrates a higher all-cause mortality rate at 90 days for critically ill patients receiving intensive glucose therapy. It is now clear that, among critically ill hospitalized patients, aiming for intensive glucose control (81-108 mg/dL) is associated with an increased rate of severe hypoglycemic events and all-cause mortality at 90 days. The previously used goal of conventional therapy (≤180 mg/dL) is safer.

CAVEATS: Study population may not reflect primary care

There are 2 caveats to this study. The first is that because of the nature of the research, it was impossible to maintain blinding of the clinical staff to patient assignments. The second important caveat pertains to the severity of illness among participants in this multicenter study: Most of these patients were in ICUs at tertiary care medical centers and had an expected ICU length of stay of 3 or more days. Although many family physicians manage patients in ICUs, the patients randomized in this study may represent a sicker than average patient population for some hospitals.

CHALLENGES TO IMPLEMENTATION: Some may doubt validity of this outcome

Less aggressive glycemic control for critically ill patients should be easier to achieve, not more difficult. However, a change in glucose targets may require new admission order sets and, notably, reeducation of physicians and nurses who have been convinced by earlier studies that more intensive glucose control is superior.

Acknowledgments

The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center for Research Resources, a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

PURLs methodology

This study was selected and evaluated using FPIN’s Priority Updates from the Research Literature (PURL) Surveillance System methodology. The criteria and findings leading to the selection of this study as a PURL can be accessed at www.jfponline.com/purls.

Practice changer

For hyperglycemic patients admitted to an intensive care unit (ICU), the target blood glucose level should be ≤180 mg/dL, not 81 to 108 mg/dL. More aggressive glucose lowering is associated with a higher mortality rate.1

Strength of recommendation

B: Based on a single, high-quality randomized clinical trial.

Finfer S, Chittock DR, Su SY, et al; NICE-SUGAR Study Investigators. Intensive versus conventional glucose control in critically ill patients. N Engl J Med. 2009;360:1283-1297.

 

ILLUSTRATIVE CASE

A 71-year-old woman with diabetes and coronary artery disease has just been admitted to the ICU, where she’ll receive treatment for sepsis, multilobar pneumonia, and respiratory failure requiring mechanical ventilation. Her blood sugar is 253 mg/dL. In writing her admission orders, you contemplate targets for glycemic control. How low should you go?

Hyperglycemia is common in patients admitted to intensive care, whether or not they have diabetes. Elevated blood sugar is associated with stress and trauma and affects both postoperative and critically ill medical patients. A wealth of evidence has demonstrated that hyperglycemia is associated with poorer outcomes and increased mortality in this patient population, including those with myocardial infarction, stroke, trauma, and other medical conditions.2-5 Thus, intensive glucose control is the standard of care in the ICU, based on consensus guidelines from such groups as the American Diabetes Association (ADA) and the Surviving Sepsis Campaign—an initiative developed by 3 critical care organizations and endorsed by 16 specialty groups.6-8

Is intense therapy better? Study results differ
The association between hyperglycemia and an increased risk of death led investigators to study the effectiveness of aggressive treatment with insulin in decreasing morbidity and mortality. A 2004 meta-analysis of 35 trials comparing insulin vs no insulin in critically ill hospitalized patients demonstrated a 15% reduction in short-term mortality among patients treated with insulin.9 A 2008 meta-analysis of 29 randomized trials, including data from 8432 adult ICU patients, compared intensive insulin therapy with conventional therapy—and found that intensive therapy did not lower hospital mortality rates compared with conventional therapy. In addition, this meta-analysis revealed a marked increase in severe hypoglycemia (blood sugar ≤40 mg/dL) in the intensive therapy group.10 (The intensive therapy group included studies with glucose goals of ≤110 mg/dL and <150 mg/dL in about equal numbers; conventional therapy goals were generally between 180 and 200 mg/dL.)

The studies included in both the meta-analyses, however, were mostly small, single-center trials, and of low-to-medium quality. In addition, methods for achieving glycemic control varied. Nonetheless, current consensus guidelines set a goal for glucose levels of 80 to 110 mg/dL for all critically ill hospitalized patients.6-8 But because of the lack of sufficient high-quality evidence from a single large RCT, Finfer et al conducted the large study described here to clearly establish that intensive glycemic control decreases all-cause mortality. Given their hypothesis, the results were surprising.

STUDY SUMMARY: Intensive therapy does more harm than help

NICE-SUGAR (Normoglycaemia in Intensive Care Evaluation-Survival Using Glucose Algorithm Regulation) was a large-scale, multicenter, multinational trial comparing aggressive blood sugar control (goal 81-108 mg/dL) with conventional therapy (goal ≤180 mg/dL) in 6104 critically ill hospitalized patients with hyperglycemia. Patients were followed for 90 days. The primary end point was death from any cause 90 days after randomization. Secondary outcomes included survival time during the first 90 days, specific cause of death, duration of mechanical ventilation, renal replacement therapy, and length of stays in the ICU and in the hospital. Other outcomes included death from any cause within 28 days, place of death, new organ failure, positive blood culture, blood transfusion, and units of blood transfused.

The study was conducted in 42 hospitals in Canada, Australia, and New Zealand. Patients had to have an anticipated ICU admission of 3 days or more and randomization had to occur within 24 hours of admission. The study protocol was discontinued when patients began eating or were discharged from the ICU; if they were readmitted to the ICU within 90 days of randomization, the study protocol was resumed.

Treatment assignment was revealed to clinical staff after randomization, and was determined by a specific algorithm ( https://studies.thegeorgeinstitute.org/nice/ ). Blood sugar levels were managed with insulin infusions.

In the conventional group, insulin was started at 1 unit/h for glucose levels >180 mg/dL, and decreased or stopped when levels were <144 mg/dL, depending on previous glucose value and current rate of drip. In the intensive therapy group, insulin was initiated for lower levels (blood sugar >109 mg/dL) and at a higher rate (2 units/h). The insulin rate was decreased or maintained for glucose levels from 64 to 80 mg/dL, depending on previous glucose value and current rate of drip. Insulin was withheld for blood sugar levels of <64 mg/dL.

Contrary to the hypothesis, intensive therapy spelled trouble. Patients with intensive glycemic control had an all-cause mortality rate of 27.5%, compared with a rate of 24.9% for patients in the conventional therapy group (P=.04, number needed to harm [NNH]=38). Severe hypoglycemia (glucose ≤40 mg/dL) occurred in 6.8% of those in the intensive therapy group, compared with 0.5% in the conventional therapy group (P=.03, NNH=16).

Most of the deaths in both groups occurred in the ICU or in the hospital. Deaths from cardiovascular causes were more common among those in the intensive therapy group. There were no significant differences in any other outcomes. The mean glucose level in the intensive therapy group was 118, vs 145 mg/dL in the conventional therapy group.

For multivariate and subgroup analyses, the patients were assigned strata (Canada or Australia/New Zealand; operative vs nonoperative admission) or classified into groups (traumatic vs atraumatic; diabetes vs no diabetes; corticosteroids in previous 72 hours or not; high vs low critical illness symptom severity) based on predefined characteristics. No subgroups had significantly improved outcomes with intensive therapy.1

 

 

 

WHAT’S NEW: Now we know: Don’t go too low

This study, in contrast to a number of smaller studies of lower quality, demonstrates a higher all-cause mortality rate at 90 days for critically ill patients receiving intensive glucose therapy. It is now clear that, among critically ill hospitalized patients, aiming for intensive glucose control (81-108 mg/dL) is associated with an increased rate of severe hypoglycemic events and all-cause mortality at 90 days. The previously used goal of conventional therapy (≤180 mg/dL) is safer.

CAVEATS: Study population may not reflect primary care

There are 2 caveats to this study. The first is that because of the nature of the research, it was impossible to maintain blinding of the clinical staff to patient assignments. The second important caveat pertains to the severity of illness among participants in this multicenter study: Most of these patients were in ICUs at tertiary care medical centers and had an expected ICU length of stay of 3 or more days. Although many family physicians manage patients in ICUs, the patients randomized in this study may represent a sicker than average patient population for some hospitals.

CHALLENGES TO IMPLEMENTATION: Some may doubt validity of this outcome

Less aggressive glycemic control for critically ill patients should be easier to achieve, not more difficult. However, a change in glucose targets may require new admission order sets and, notably, reeducation of physicians and nurses who have been convinced by earlier studies that more intensive glucose control is superior.

Acknowledgments

The PURLs Surveillance System is supported in part by Grant Number UL1RR024999 from the National Center for Research Resources, a Clinical Translational Science Award to the University of Chicago. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Center for Research Resources or the National Institutes of Health.

PURLs methodology

This study was selected and evaluated using FPIN’s Priority Updates from the Research Literature (PURL) Surveillance System methodology. The criteria and findings leading to the selection of this study as a PURL can be accessed at www.jfponline.com/purls.

References

1. Finfer S, Chittock DR, Su SY, et al. NICE-SUGAR Study Investigators. Intensive versus conventional glucose control in critically ill patients. N Engl J Med. 2009;360:1283-1297.

2. Capes SE, Hunt D, Malmberg K, et al. Stress hyperglycaemia and increased risk of death after myocardial infarction in patients with and without diabetes: a systematic overview. Lancet. 2000;355:773-778.

3. Capes SE, Hunt D, Malmberg K, et al. Stress hyperglycemia and prognosis of stroke in nondiabetic and diabetic patients: a systematic overview. Stroke. 2001;32:2426-2432.

4. Gale SC, Sicoutris C, Reilly PM, et al. Poor glycemic control is associated with increased mortality in critically ill trauma patients. Am Surg. 2007;73:454-460.

5. Krinsley JS. Association between hyperglycemia and increased hospital mortality in a heterogeneous population of critically ill patients. Mayo Clin Proc. 2003;78:1471-1478.

6. Standards of medical care in diabetes—2008. Diabetes Care. 2008;31(suppl 1):S12-S54.

7. Rodbard HW, Blonde L, Braithwaite SS, et al. American Association of Clinical Endocrinologists medical guidelines for clinical practice for the management of diabetes mellitus. Endocr Pract. 2007;13(suppl 1):1-68.

8. Dellinger RP, Levy MM, Carlet JM, et al. Surviving Sepsis Campaign: international guidelines for management of severe sepsis and septic shock: 2008. Crit Care Med. 2008;36:296-327.

9. Pittas AG, Siegel RD, Lau J. Insulin therapy for critically ill hospitalized patients: a meta-analysis of randomized controlled trials. Arch Intern Med. 2004;164:2005-2011.

10. Wiener RS, Wiener DC, Larson RJ. Benefits and risks of tight glucose control in critically ill adults: a meta-analysis. JAMA. 2008;300:933-944.

References

1. Finfer S, Chittock DR, Su SY, et al. NICE-SUGAR Study Investigators. Intensive versus conventional glucose control in critically ill patients. N Engl J Med. 2009;360:1283-1297.

2. Capes SE, Hunt D, Malmberg K, et al. Stress hyperglycaemia and increased risk of death after myocardial infarction in patients with and without diabetes: a systematic overview. Lancet. 2000;355:773-778.

3. Capes SE, Hunt D, Malmberg K, et al. Stress hyperglycemia and prognosis of stroke in nondiabetic and diabetic patients: a systematic overview. Stroke. 2001;32:2426-2432.

4. Gale SC, Sicoutris C, Reilly PM, et al. Poor glycemic control is associated with increased mortality in critically ill trauma patients. Am Surg. 2007;73:454-460.

5. Krinsley JS. Association between hyperglycemia and increased hospital mortality in a heterogeneous population of critically ill patients. Mayo Clin Proc. 2003;78:1471-1478.

6. Standards of medical care in diabetes—2008. Diabetes Care. 2008;31(suppl 1):S12-S54.

7. Rodbard HW, Blonde L, Braithwaite SS, et al. American Association of Clinical Endocrinologists medical guidelines for clinical practice for the management of diabetes mellitus. Endocr Pract. 2007;13(suppl 1):1-68.

8. Dellinger RP, Levy MM, Carlet JM, et al. Surviving Sepsis Campaign: international guidelines for management of severe sepsis and septic shock: 2008. Crit Care Med. 2008;36:296-327.

9. Pittas AG, Siegel RD, Lau J. Insulin therapy for critically ill hospitalized patients: a meta-analysis of randomized controlled trials. Arch Intern Med. 2004;164:2005-2011.

10. Wiener RS, Wiener DC, Larson RJ. Benefits and risks of tight glucose control in critically ill adults: a meta-analysis. JAMA. 2008;300:933-944.

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Does a short symptom checklist accurately diagnose ADHD?

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Does a short symptom checklist accurately diagnose ADHD?
EVIDENCE-BASED ANSWER

Several abbreviated checklists perform well in distinguishing children with attention deficit/hyperactivity disorder (ADHD) from those without ADHD under ideal conditions and in research settings. While many guidelines and experts recommend using these checklists as an efficient method to collect data from multiple sources (strength of recommendation: B, based on extrapolation from cohort studies to define test characteristics and consensus opinion), experts point out the subjective nature of responses on behavior rating scales, and the limitations in using checklists as the sole source of information.

The Swanson, Nolan, and Pelham (SNAP) checklist from the Diagnostic and Statistical Manual of Mental Disorders, revised 3rd edition (DSM-III-R) has been shown to have a sensitivity and specificity in excess of 94% to distinguish hyperactive, inattentive, and impulsive children with ADHD from those without ADHD. This was based on criteria in the DSM-III-R. The DSM-IV SNAP checklist (available at www.adhd.net/snap-iv-form.pdf; scoring at www.adhd.net/snap-iv-instructions.pdf), based on the newer diagnostic criteria, has not been adequately evaluated. The ADHD Rating Scale-IV (in DuPaul et al, ADHD Rating Scale IV—Checklists, Norms, and Clinical Interpretations, available from Guilford Press) and the ADD-H Comprehensive Teacher/Parent Rating Scale (ACTeRS; available from MetriTech, Inc at www.metritech.com) are useful for their brevity, but they do not perform as well in differentiating children with ADHD from those without ADHD.

 

Evidence summary

A variety of brief ADHD-specific rating scales are used for both parent and teacher assessment of child behavior. Rating scales are generally evaluated to establish mean scores for affected and unaffected children. Many scales publish such normative data in commercially available manuals. Some scales have been evaluated by 1 or more independent studies to compare children with and without ADHD. Rating scales have not been evaluated as a sole tool for the diagnosis of ADHD.

The test characteristics of a particular scale depend on the cut points for a positive or negative test. The usefulness of psychological tests in discriminating normal from abnormal behavior is often reported as “effect size.” The effect size is the difference in mean scores between 2 populations divided by an estimate of the individual standard deviation.1 An effect size of 4.0 means that abnormal subjects and normal controls are separated 4 standard deviations and thus almost completely separated. An effect size of 1.0 shows significant overlap between the 2 populations. An effect size of 4.0 is roughly equivalent to a sensitivity and specificity of 97%. An effect size of 1.0 is roughly equal to a sensitivity and specificity of 71%.

Table 1 outlines the characteristics and effect size of several available brief ADHD-specific checklists.2-4,6,11-13 Typically, the gold standard was a clinical diagnostic interview, usually conducted by a clinical psychologist, as well as supporting data from schools and parents.

TABLE
Descriptive characteristics of abbreviated symptom checklists for ADHD

    Effect size
ScaleMinutes#ItemsAgeHyperactivityInattentionImpulsivity
ACTeRS Parent Version5–10255–121.52.0NA
ACTeRS Teacher Version5–10245–12NANANA
DSM-IV SNAP5–10406–12NANANA
DSM-III–R SNAP5–10386–123.1–5.13.5–4.24.0–5.5
ADHD Rating Scale-IV5185–181.11.21.1
Conners RatingScale,Revised (1997, Short Version)11,12,135–10273–17NANANA
Numbers reported in ranges indicate multiple studies.
ACTeRS, ADD-H Comprehensive Teacher Rating Scales; DSM, Diagnostic and Statistical Manual of Mental Disorders; SNAP,
Swanson, Nolan, and Pelham; ADHD, attention deficit/hyperactivity disorder; NA, not available.

Recommendations from others

The American Academy of Pediatrics states that the use of ADHD-specific checklists is a clinical option when evaluating children for ADHD. They caution that the ADHD scales may function less well in clinicians’ offices than suggested by reported effect size and, in addition, rating scales are subject to bias and may convey a false sense of validity. They also state that it is not known if these scales provide additional information beyond a careful clinical assessment.7

The Institute for Clinical Systems Improvement recommends use of at least 1 ADHD-specific rating scale to be administered to parents and teachers. This information should be used as part of the overall historical database for the child and should not be used as the sole criteria for diagnosis of ADHD.8

Many sources agree that ADHD-specific rating scales allow a rapid and consistent collection of information from multiple sources. However, the information they provide is necessary, but not sufficient, to make a definitive diagnosis of ADHD. In addition to assisting in diagnosis, checklists can be helpful in monitoring treatment changes once a diagnosis has been established.

CLINICAL COMMENTARY:

Gather data from multiple sources
John Hill, MD
Rose Family Medicine Residency/University of Colorado Health Sciences Center, Denver

Sorting out children with ADHD, bipolar disorder, or learning disabilities from lively or distractible children is not a simple matter. Often the objective rating scales miss the more passive, less disruptive, inattentive ADHD children while overdiagnosing high-energy children as having ADHD. Perhaps the new DSM-IV SNAP will provide the objective sensitivity and specificity we desire as clinicians. However, this checklist requires further evaluation.

Information from ACTeRS scales has helped me treat these children, but I prefer to have both parents, if possible, independently complete the form. Obtaining scales from a Special Education teacher or psychologist, when available, in addition to the primary classroom teacher, is invaluable. Still, it often comes down to how a child responds to medication. Proceed with caution if there is a family history of bipolar disorder, as these children often do worse on stimulants and are better treated by our colleagues in child psychiatry.

References

1. Hedges LV, Olkin I. Statistical Methods for Meta-analysis. Orlando, Fla: Academic Press; 1985.

2. Diagnosis of Attention-Deficit/Hyperactivity Disorder. Technical Review #3. Rockville, Md: Agency for Health Care Policy and Research; 1999 August. Available at: www.ahrq.gov/clinic/epcsums/adhdsutr.htm. Accessed on March 31, 2004.

3. DuPaul GJ. ADHD Rating Scale-IV: Checklists, Norms, and Clinical Interpretation. New York, NY: Guilford Press, 1998.

4. Atkins MS, Pelham WE, Licht MH. A comparison of objective classroom measures and teacher ratings of Attention Deficit Disorder. J Abnorm Child Psychol 1985;13:155-167.

5. Tarnowski KJ, Prinz RJ, Nay SM. Comparative analysis of attentional deficits in hyperactive and learning-disabled children. J Abnorm Psychol 1986;95:341-345.

6. Ullmann RK, Sleator EK, Sprague RL, MetriTech Staff. ACTeRS Teacher and Parent Forms Manual. Champaign, Ill: MetriTech; 1997.

7. Clinical practice guideline: diagnosis and evaluation of the child with attention-deficit/hyperactivity disorder Pediatrics 2000;105:1158-1170.

8. Diagnosis and Management of Attention Deficit Hyperactivity Disorder in Primary Care for School Age Children and Adolescents. Bloomington, Minn: Institute for Clinical Systems Improvement; 2003. Available at: www.icsi.org/knowledge/detail.asp?catID=29&itemID=163. Accessed on March 31, 2004.

9. Dulcan M. Practice parameters for the assessment and treatment of children, adolescents, and adults with attention-deficit/hyperactivity disorder. American Academy of Child and Adolescent Psychiatry. J Am Acad Child Adolesc Psychiatry 1997;36(10 Suppl):85S-121S.

10. Goldman LS, Genel M, Bezman RJ, Slanetz PJ. Diagnosis and treatment of attention-deficit/hyperactivity disorder in children and adolescents. Council on Scientific Affairs. American Medical Association. JAMA 1998;279:1100-1107.

11. Conners CK, Parker JD, Sitarenios G, Epstein JN. The revised Conners’ Parent Rating Scale (CPRS-R): factor structure, reliability, and criterion validity. J Abnorm Child Psychol 1998;26:257-268.

12. Conners CK, Sitarenios G, Parker JD, Epstein JN. Revision and restandardization of the Conners Teacher Rating Scale (CTRS-R): factor structure, reliability, and criterion validity. J Abnorm Child Psychol 1998;26:279-291.

13. Conners CK, Wells KC, Parker JD, Sitarenios G, Diamond JM, Powell JW. A new self-report scale for the assessment of adolescent psychopathology: factor structure, reliability, validity and diagnostic sensitivity. J Abnorm Child Psychol 1997;25:487-497.

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EVIDENCE-BASED ANSWER

Several abbreviated checklists perform well in distinguishing children with attention deficit/hyperactivity disorder (ADHD) from those without ADHD under ideal conditions and in research settings. While many guidelines and experts recommend using these checklists as an efficient method to collect data from multiple sources (strength of recommendation: B, based on extrapolation from cohort studies to define test characteristics and consensus opinion), experts point out the subjective nature of responses on behavior rating scales, and the limitations in using checklists as the sole source of information.

The Swanson, Nolan, and Pelham (SNAP) checklist from the Diagnostic and Statistical Manual of Mental Disorders, revised 3rd edition (DSM-III-R) has been shown to have a sensitivity and specificity in excess of 94% to distinguish hyperactive, inattentive, and impulsive children with ADHD from those without ADHD. This was based on criteria in the DSM-III-R. The DSM-IV SNAP checklist (available at www.adhd.net/snap-iv-form.pdf; scoring at www.adhd.net/snap-iv-instructions.pdf), based on the newer diagnostic criteria, has not been adequately evaluated. The ADHD Rating Scale-IV (in DuPaul et al, ADHD Rating Scale IV—Checklists, Norms, and Clinical Interpretations, available from Guilford Press) and the ADD-H Comprehensive Teacher/Parent Rating Scale (ACTeRS; available from MetriTech, Inc at www.metritech.com) are useful for their brevity, but they do not perform as well in differentiating children with ADHD from those without ADHD.

 

Evidence summary

A variety of brief ADHD-specific rating scales are used for both parent and teacher assessment of child behavior. Rating scales are generally evaluated to establish mean scores for affected and unaffected children. Many scales publish such normative data in commercially available manuals. Some scales have been evaluated by 1 or more independent studies to compare children with and without ADHD. Rating scales have not been evaluated as a sole tool for the diagnosis of ADHD.

The test characteristics of a particular scale depend on the cut points for a positive or negative test. The usefulness of psychological tests in discriminating normal from abnormal behavior is often reported as “effect size.” The effect size is the difference in mean scores between 2 populations divided by an estimate of the individual standard deviation.1 An effect size of 4.0 means that abnormal subjects and normal controls are separated 4 standard deviations and thus almost completely separated. An effect size of 1.0 shows significant overlap between the 2 populations. An effect size of 4.0 is roughly equivalent to a sensitivity and specificity of 97%. An effect size of 1.0 is roughly equal to a sensitivity and specificity of 71%.

Table 1 outlines the characteristics and effect size of several available brief ADHD-specific checklists.2-4,6,11-13 Typically, the gold standard was a clinical diagnostic interview, usually conducted by a clinical psychologist, as well as supporting data from schools and parents.

TABLE
Descriptive characteristics of abbreviated symptom checklists for ADHD

    Effect size
ScaleMinutes#ItemsAgeHyperactivityInattentionImpulsivity
ACTeRS Parent Version5–10255–121.52.0NA
ACTeRS Teacher Version5–10245–12NANANA
DSM-IV SNAP5–10406–12NANANA
DSM-III–R SNAP5–10386–123.1–5.13.5–4.24.0–5.5
ADHD Rating Scale-IV5185–181.11.21.1
Conners RatingScale,Revised (1997, Short Version)11,12,135–10273–17NANANA
Numbers reported in ranges indicate multiple studies.
ACTeRS, ADD-H Comprehensive Teacher Rating Scales; DSM, Diagnostic and Statistical Manual of Mental Disorders; SNAP,
Swanson, Nolan, and Pelham; ADHD, attention deficit/hyperactivity disorder; NA, not available.

Recommendations from others

The American Academy of Pediatrics states that the use of ADHD-specific checklists is a clinical option when evaluating children for ADHD. They caution that the ADHD scales may function less well in clinicians’ offices than suggested by reported effect size and, in addition, rating scales are subject to bias and may convey a false sense of validity. They also state that it is not known if these scales provide additional information beyond a careful clinical assessment.7

The Institute for Clinical Systems Improvement recommends use of at least 1 ADHD-specific rating scale to be administered to parents and teachers. This information should be used as part of the overall historical database for the child and should not be used as the sole criteria for diagnosis of ADHD.8

Many sources agree that ADHD-specific rating scales allow a rapid and consistent collection of information from multiple sources. However, the information they provide is necessary, but not sufficient, to make a definitive diagnosis of ADHD. In addition to assisting in diagnosis, checklists can be helpful in monitoring treatment changes once a diagnosis has been established.

CLINICAL COMMENTARY:

Gather data from multiple sources
John Hill, MD
Rose Family Medicine Residency/University of Colorado Health Sciences Center, Denver

Sorting out children with ADHD, bipolar disorder, or learning disabilities from lively or distractible children is not a simple matter. Often the objective rating scales miss the more passive, less disruptive, inattentive ADHD children while overdiagnosing high-energy children as having ADHD. Perhaps the new DSM-IV SNAP will provide the objective sensitivity and specificity we desire as clinicians. However, this checklist requires further evaluation.

Information from ACTeRS scales has helped me treat these children, but I prefer to have both parents, if possible, independently complete the form. Obtaining scales from a Special Education teacher or psychologist, when available, in addition to the primary classroom teacher, is invaluable. Still, it often comes down to how a child responds to medication. Proceed with caution if there is a family history of bipolar disorder, as these children often do worse on stimulants and are better treated by our colleagues in child psychiatry.

EVIDENCE-BASED ANSWER

Several abbreviated checklists perform well in distinguishing children with attention deficit/hyperactivity disorder (ADHD) from those without ADHD under ideal conditions and in research settings. While many guidelines and experts recommend using these checklists as an efficient method to collect data from multiple sources (strength of recommendation: B, based on extrapolation from cohort studies to define test characteristics and consensus opinion), experts point out the subjective nature of responses on behavior rating scales, and the limitations in using checklists as the sole source of information.

The Swanson, Nolan, and Pelham (SNAP) checklist from the Diagnostic and Statistical Manual of Mental Disorders, revised 3rd edition (DSM-III-R) has been shown to have a sensitivity and specificity in excess of 94% to distinguish hyperactive, inattentive, and impulsive children with ADHD from those without ADHD. This was based on criteria in the DSM-III-R. The DSM-IV SNAP checklist (available at www.adhd.net/snap-iv-form.pdf; scoring at www.adhd.net/snap-iv-instructions.pdf), based on the newer diagnostic criteria, has not been adequately evaluated. The ADHD Rating Scale-IV (in DuPaul et al, ADHD Rating Scale IV—Checklists, Norms, and Clinical Interpretations, available from Guilford Press) and the ADD-H Comprehensive Teacher/Parent Rating Scale (ACTeRS; available from MetriTech, Inc at www.metritech.com) are useful for their brevity, but they do not perform as well in differentiating children with ADHD from those without ADHD.

 

Evidence summary

A variety of brief ADHD-specific rating scales are used for both parent and teacher assessment of child behavior. Rating scales are generally evaluated to establish mean scores for affected and unaffected children. Many scales publish such normative data in commercially available manuals. Some scales have been evaluated by 1 or more independent studies to compare children with and without ADHD. Rating scales have not been evaluated as a sole tool for the diagnosis of ADHD.

The test characteristics of a particular scale depend on the cut points for a positive or negative test. The usefulness of psychological tests in discriminating normal from abnormal behavior is often reported as “effect size.” The effect size is the difference in mean scores between 2 populations divided by an estimate of the individual standard deviation.1 An effect size of 4.0 means that abnormal subjects and normal controls are separated 4 standard deviations and thus almost completely separated. An effect size of 1.0 shows significant overlap between the 2 populations. An effect size of 4.0 is roughly equivalent to a sensitivity and specificity of 97%. An effect size of 1.0 is roughly equal to a sensitivity and specificity of 71%.

Table 1 outlines the characteristics and effect size of several available brief ADHD-specific checklists.2-4,6,11-13 Typically, the gold standard was a clinical diagnostic interview, usually conducted by a clinical psychologist, as well as supporting data from schools and parents.

TABLE
Descriptive characteristics of abbreviated symptom checklists for ADHD

    Effect size
ScaleMinutes#ItemsAgeHyperactivityInattentionImpulsivity
ACTeRS Parent Version5–10255–121.52.0NA
ACTeRS Teacher Version5–10245–12NANANA
DSM-IV SNAP5–10406–12NANANA
DSM-III–R SNAP5–10386–123.1–5.13.5–4.24.0–5.5
ADHD Rating Scale-IV5185–181.11.21.1
Conners RatingScale,Revised (1997, Short Version)11,12,135–10273–17NANANA
Numbers reported in ranges indicate multiple studies.
ACTeRS, ADD-H Comprehensive Teacher Rating Scales; DSM, Diagnostic and Statistical Manual of Mental Disorders; SNAP,
Swanson, Nolan, and Pelham; ADHD, attention deficit/hyperactivity disorder; NA, not available.

Recommendations from others

The American Academy of Pediatrics states that the use of ADHD-specific checklists is a clinical option when evaluating children for ADHD. They caution that the ADHD scales may function less well in clinicians’ offices than suggested by reported effect size and, in addition, rating scales are subject to bias and may convey a false sense of validity. They also state that it is not known if these scales provide additional information beyond a careful clinical assessment.7

The Institute for Clinical Systems Improvement recommends use of at least 1 ADHD-specific rating scale to be administered to parents and teachers. This information should be used as part of the overall historical database for the child and should not be used as the sole criteria for diagnosis of ADHD.8

Many sources agree that ADHD-specific rating scales allow a rapid and consistent collection of information from multiple sources. However, the information they provide is necessary, but not sufficient, to make a definitive diagnosis of ADHD. In addition to assisting in diagnosis, checklists can be helpful in monitoring treatment changes once a diagnosis has been established.

CLINICAL COMMENTARY:

Gather data from multiple sources
John Hill, MD
Rose Family Medicine Residency/University of Colorado Health Sciences Center, Denver

Sorting out children with ADHD, bipolar disorder, or learning disabilities from lively or distractible children is not a simple matter. Often the objective rating scales miss the more passive, less disruptive, inattentive ADHD children while overdiagnosing high-energy children as having ADHD. Perhaps the new DSM-IV SNAP will provide the objective sensitivity and specificity we desire as clinicians. However, this checklist requires further evaluation.

Information from ACTeRS scales has helped me treat these children, but I prefer to have both parents, if possible, independently complete the form. Obtaining scales from a Special Education teacher or psychologist, when available, in addition to the primary classroom teacher, is invaluable. Still, it often comes down to how a child responds to medication. Proceed with caution if there is a family history of bipolar disorder, as these children often do worse on stimulants and are better treated by our colleagues in child psychiatry.

References

1. Hedges LV, Olkin I. Statistical Methods for Meta-analysis. Orlando, Fla: Academic Press; 1985.

2. Diagnosis of Attention-Deficit/Hyperactivity Disorder. Technical Review #3. Rockville, Md: Agency for Health Care Policy and Research; 1999 August. Available at: www.ahrq.gov/clinic/epcsums/adhdsutr.htm. Accessed on March 31, 2004.

3. DuPaul GJ. ADHD Rating Scale-IV: Checklists, Norms, and Clinical Interpretation. New York, NY: Guilford Press, 1998.

4. Atkins MS, Pelham WE, Licht MH. A comparison of objective classroom measures and teacher ratings of Attention Deficit Disorder. J Abnorm Child Psychol 1985;13:155-167.

5. Tarnowski KJ, Prinz RJ, Nay SM. Comparative analysis of attentional deficits in hyperactive and learning-disabled children. J Abnorm Psychol 1986;95:341-345.

6. Ullmann RK, Sleator EK, Sprague RL, MetriTech Staff. ACTeRS Teacher and Parent Forms Manual. Champaign, Ill: MetriTech; 1997.

7. Clinical practice guideline: diagnosis and evaluation of the child with attention-deficit/hyperactivity disorder Pediatrics 2000;105:1158-1170.

8. Diagnosis and Management of Attention Deficit Hyperactivity Disorder in Primary Care for School Age Children and Adolescents. Bloomington, Minn: Institute for Clinical Systems Improvement; 2003. Available at: www.icsi.org/knowledge/detail.asp?catID=29&itemID=163. Accessed on March 31, 2004.

9. Dulcan M. Practice parameters for the assessment and treatment of children, adolescents, and adults with attention-deficit/hyperactivity disorder. American Academy of Child and Adolescent Psychiatry. J Am Acad Child Adolesc Psychiatry 1997;36(10 Suppl):85S-121S.

10. Goldman LS, Genel M, Bezman RJ, Slanetz PJ. Diagnosis and treatment of attention-deficit/hyperactivity disorder in children and adolescents. Council on Scientific Affairs. American Medical Association. JAMA 1998;279:1100-1107.

11. Conners CK, Parker JD, Sitarenios G, Epstein JN. The revised Conners’ Parent Rating Scale (CPRS-R): factor structure, reliability, and criterion validity. J Abnorm Child Psychol 1998;26:257-268.

12. Conners CK, Sitarenios G, Parker JD, Epstein JN. Revision and restandardization of the Conners Teacher Rating Scale (CTRS-R): factor structure, reliability, and criterion validity. J Abnorm Child Psychol 1998;26:279-291.

13. Conners CK, Wells KC, Parker JD, Sitarenios G, Diamond JM, Powell JW. A new self-report scale for the assessment of adolescent psychopathology: factor structure, reliability, validity and diagnostic sensitivity. J Abnorm Child Psychol 1997;25:487-497.

References

1. Hedges LV, Olkin I. Statistical Methods for Meta-analysis. Orlando, Fla: Academic Press; 1985.

2. Diagnosis of Attention-Deficit/Hyperactivity Disorder. Technical Review #3. Rockville, Md: Agency for Health Care Policy and Research; 1999 August. Available at: www.ahrq.gov/clinic/epcsums/adhdsutr.htm. Accessed on March 31, 2004.

3. DuPaul GJ. ADHD Rating Scale-IV: Checklists, Norms, and Clinical Interpretation. New York, NY: Guilford Press, 1998.

4. Atkins MS, Pelham WE, Licht MH. A comparison of objective classroom measures and teacher ratings of Attention Deficit Disorder. J Abnorm Child Psychol 1985;13:155-167.

5. Tarnowski KJ, Prinz RJ, Nay SM. Comparative analysis of attentional deficits in hyperactive and learning-disabled children. J Abnorm Psychol 1986;95:341-345.

6. Ullmann RK, Sleator EK, Sprague RL, MetriTech Staff. ACTeRS Teacher and Parent Forms Manual. Champaign, Ill: MetriTech; 1997.

7. Clinical practice guideline: diagnosis and evaluation of the child with attention-deficit/hyperactivity disorder Pediatrics 2000;105:1158-1170.

8. Diagnosis and Management of Attention Deficit Hyperactivity Disorder in Primary Care for School Age Children and Adolescents. Bloomington, Minn: Institute for Clinical Systems Improvement; 2003. Available at: www.icsi.org/knowledge/detail.asp?catID=29&itemID=163. Accessed on March 31, 2004.

9. Dulcan M. Practice parameters for the assessment and treatment of children, adolescents, and adults with attention-deficit/hyperactivity disorder. American Academy of Child and Adolescent Psychiatry. J Am Acad Child Adolesc Psychiatry 1997;36(10 Suppl):85S-121S.

10. Goldman LS, Genel M, Bezman RJ, Slanetz PJ. Diagnosis and treatment of attention-deficit/hyperactivity disorder in children and adolescents. Council on Scientific Affairs. American Medical Association. JAMA 1998;279:1100-1107.

11. Conners CK, Parker JD, Sitarenios G, Epstein JN. The revised Conners’ Parent Rating Scale (CPRS-R): factor structure, reliability, and criterion validity. J Abnorm Child Psychol 1998;26:257-268.

12. Conners CK, Sitarenios G, Parker JD, Epstein JN. Revision and restandardization of the Conners Teacher Rating Scale (CTRS-R): factor structure, reliability, and criterion validity. J Abnorm Child Psychol 1998;26:279-291.

13. Conners CK, Wells KC, Parker JD, Sitarenios G, Diamond JM, Powell JW. A new self-report scale for the assessment of adolescent psychopathology: factor structure, reliability, validity and diagnostic sensitivity. J Abnorm Child Psychol 1997;25:487-497.

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