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In menopausal women, does fatigue indicate disease?
Though fatigue is a commonly reported symptom, high-quality studies evaluating it as a marker for diseases among menopausal women are lacking. Middle-aged women who report fatigue are more apt to screen positive for clinical depression or anxiety (strength of recommendation [SOR]: B, case series). Fatigue may signal obstructive sleep apnea (SOR: B, retrospective cohort). For menopausal women with cardiac risk factors, extreme fatigue may be a sign of coronary artery disease (SOR: C, review without critical appraisal).
History and exam usually uncover conditions causing fatigue other than menopause
Robert Kynerd, MD
University of Alabama
Remember that menopause is a natural transition in the life of many women, not a medical condition characterized by debilitating fatigue. Symptoms causally associated with the decline in estrogen, which triggers menopause, include hot flashes, night sweats, vaginal dryness, and urethral irritation. For patients complaining of fatigue, a careful history and physical examination usually uncover 1 or more acute or chronic physiological, psychological, and therapeutic conditions that have been shown to be associated with fatigue. Some of the more common ones I have encountered include depression, chronic pain, cardiovascular disease, diabetes, thyroid disease, chronic infections, anemia, insomnia, sleep apnea, restless leg syndrome, medication side effects, and recent surgery.
Evidence summary
Studies evaluating whether menopausal women experience fatigue at higher rates than pre-or perimenopausal women are of variable quality and yield conflicting results.1 Though several studies suggest an association between fatigue among menopausal women and disease states, poor methodology limits the strength of their findings.
In an Internet-based survey, 448 middle-aged women who reported being either perimenopausal or menopausal responded to questions about their symptoms.2 Feeling tired and lacking energy were the 2 most frequently reported symptoms, in 380 (89%) and 355 (83%) of respondents, respectively. These self-selected respondents probably do not represent the menopausal population of women at large.
A prospective cohort study, using a 1-page questionnaire that included 2 fatigue scales, identified 276 (24%) of 1159 primary care patients who indicated fatigue as a major problem.3 The mean age of patients was 57 years and 66% were women. Extensive laboratory testing was not helpful in determining the cause of fatigue. The Beck Depression Inventory, the Modified Somatic Perception Questionnaire, and the Social Readjustment Rating Scale identified depression or anxiety in 80% of patients with fatigue and 12% of controls. There are no similar studies for strictly menopausal women.
The prevalence of obstructive sleep apnea and sleep-disordered breathing increases at the time of menopause and peaks at age 65.4,5 In a retrospective chart review of patients referred for evaluation of snoring, 22 (91%) of the women with studies) were more likely to report daytime fatigue as a presenting symptom than were the 44 (55%) of men with obstructive sleep apnea (P<.01).6 Most striking was a sub-group (40%) of women with documented obstructive sleep apnea who reported only fatigue and morning headache but did not note apnea or restless sleep.
Coronary heart disease is the primary cause of death for women in the United States. A retrospective study of 515 women 4 to 6 months after a myocardial infarction explored self-reported symptoms.7 The mean age was 66±12 years and 93% were white. Unusual fatigue was the most frequent prodromal symptom experienced by 70.7% of women 1 month before a myocardial infarction, with 42.9% reporting fatigue in the acute setting. Though this retrospective study is limited both by its methodological quality and by the narrow population studied, the results suggest a gender difference between men and women in their report of symptoms of coronary artery disease.
A review of 15 studies from 1989 to 2002 reported that some studies found women were more likely to seek medical care for extreme fatigue and dyspnea than they were for chest pain. In acute coronary syndromes, 18% of women (compared with 9% of men) reported fatigue as a presenting symptom (P<.05). This review was limited by small sample sizes, retrospective chart review designs, and lack of explicitly stated critical appraisal criteria.8
Recommendations from others
No recommendations were identified.
1. Nelson HD, Haney E, Humphrey L, et al. Management of menopause-related symptoms. Evidence Report/Technology Assessment No. 120. (Prepared by the Oregon Evidence-Based Practice Center, under Contract No. 290-02-0024.) AHRQ Publication No. 05-E016-2. Rockville, Md: Agency for Healthcare Research and Quality; 2005.
2. Conboy L, Domar A, O’Connell E. Women at mid-life: symptoms, attitudes and choices, an internet based survey. Maturitas 2001;38:129-136.
3. Kroenke K, Wood DR, Mangelsdorff AD, Meier NJ, Powell JB. Chronic fatigue in primary care. Prevalence, patient characteristics and outcomes. JAMA 1988;260:929-934.
4. Bixler EO, Vgontzas AN, Lin HM, et al. Prevalence of sleep-disordered breathing in women: effects of gender. Am J Respir Crit Care Med 2001;163:608-613.
5. Young T, Finn L, Austin D, Peterson A. Menopausal status and sleep-disordered breathing in the Wisconsin Sleep Cohort Study. Am J Respir Crit Care Med 2003;167:1181-1185.
6. Ambrogetti A, Olson LG, Saunders NA. Differences in the symptoms of men and women with obstructive sleep apnoea. Aust NZ J Med 1991;21:863-866.
7. McSweeney JC, Cody M, O’Sullivan P, Elberson K, Moser DK, Garvin BJ. Women’s early warning symptoms of acute myocardial infarction. Circulation 2003;108:2619-2623.
8. Patel H, Rosengren A, Ekman I. Symptoms in acute coronary syndromes: does sex make a difference? Am Heart J 2004;148:27-33.
Though fatigue is a commonly reported symptom, high-quality studies evaluating it as a marker for diseases among menopausal women are lacking. Middle-aged women who report fatigue are more apt to screen positive for clinical depression or anxiety (strength of recommendation [SOR]: B, case series). Fatigue may signal obstructive sleep apnea (SOR: B, retrospective cohort). For menopausal women with cardiac risk factors, extreme fatigue may be a sign of coronary artery disease (SOR: C, review without critical appraisal).
History and exam usually uncover conditions causing fatigue other than menopause
Robert Kynerd, MD
University of Alabama
Remember that menopause is a natural transition in the life of many women, not a medical condition characterized by debilitating fatigue. Symptoms causally associated with the decline in estrogen, which triggers menopause, include hot flashes, night sweats, vaginal dryness, and urethral irritation. For patients complaining of fatigue, a careful history and physical examination usually uncover 1 or more acute or chronic physiological, psychological, and therapeutic conditions that have been shown to be associated with fatigue. Some of the more common ones I have encountered include depression, chronic pain, cardiovascular disease, diabetes, thyroid disease, chronic infections, anemia, insomnia, sleep apnea, restless leg syndrome, medication side effects, and recent surgery.
Evidence summary
Studies evaluating whether menopausal women experience fatigue at higher rates than pre-or perimenopausal women are of variable quality and yield conflicting results.1 Though several studies suggest an association between fatigue among menopausal women and disease states, poor methodology limits the strength of their findings.
In an Internet-based survey, 448 middle-aged women who reported being either perimenopausal or menopausal responded to questions about their symptoms.2 Feeling tired and lacking energy were the 2 most frequently reported symptoms, in 380 (89%) and 355 (83%) of respondents, respectively. These self-selected respondents probably do not represent the menopausal population of women at large.
A prospective cohort study, using a 1-page questionnaire that included 2 fatigue scales, identified 276 (24%) of 1159 primary care patients who indicated fatigue as a major problem.3 The mean age of patients was 57 years and 66% were women. Extensive laboratory testing was not helpful in determining the cause of fatigue. The Beck Depression Inventory, the Modified Somatic Perception Questionnaire, and the Social Readjustment Rating Scale identified depression or anxiety in 80% of patients with fatigue and 12% of controls. There are no similar studies for strictly menopausal women.
The prevalence of obstructive sleep apnea and sleep-disordered breathing increases at the time of menopause and peaks at age 65.4,5 In a retrospective chart review of patients referred for evaluation of snoring, 22 (91%) of the women with studies) were more likely to report daytime fatigue as a presenting symptom than were the 44 (55%) of men with obstructive sleep apnea (P<.01).6 Most striking was a sub-group (40%) of women with documented obstructive sleep apnea who reported only fatigue and morning headache but did not note apnea or restless sleep.
Coronary heart disease is the primary cause of death for women in the United States. A retrospective study of 515 women 4 to 6 months after a myocardial infarction explored self-reported symptoms.7 The mean age was 66±12 years and 93% were white. Unusual fatigue was the most frequent prodromal symptom experienced by 70.7% of women 1 month before a myocardial infarction, with 42.9% reporting fatigue in the acute setting. Though this retrospective study is limited both by its methodological quality and by the narrow population studied, the results suggest a gender difference between men and women in their report of symptoms of coronary artery disease.
A review of 15 studies from 1989 to 2002 reported that some studies found women were more likely to seek medical care for extreme fatigue and dyspnea than they were for chest pain. In acute coronary syndromes, 18% of women (compared with 9% of men) reported fatigue as a presenting symptom (P<.05). This review was limited by small sample sizes, retrospective chart review designs, and lack of explicitly stated critical appraisal criteria.8
Recommendations from others
No recommendations were identified.
Though fatigue is a commonly reported symptom, high-quality studies evaluating it as a marker for diseases among menopausal women are lacking. Middle-aged women who report fatigue are more apt to screen positive for clinical depression or anxiety (strength of recommendation [SOR]: B, case series). Fatigue may signal obstructive sleep apnea (SOR: B, retrospective cohort). For menopausal women with cardiac risk factors, extreme fatigue may be a sign of coronary artery disease (SOR: C, review without critical appraisal).
History and exam usually uncover conditions causing fatigue other than menopause
Robert Kynerd, MD
University of Alabama
Remember that menopause is a natural transition in the life of many women, not a medical condition characterized by debilitating fatigue. Symptoms causally associated with the decline in estrogen, which triggers menopause, include hot flashes, night sweats, vaginal dryness, and urethral irritation. For patients complaining of fatigue, a careful history and physical examination usually uncover 1 or more acute or chronic physiological, psychological, and therapeutic conditions that have been shown to be associated with fatigue. Some of the more common ones I have encountered include depression, chronic pain, cardiovascular disease, diabetes, thyroid disease, chronic infections, anemia, insomnia, sleep apnea, restless leg syndrome, medication side effects, and recent surgery.
Evidence summary
Studies evaluating whether menopausal women experience fatigue at higher rates than pre-or perimenopausal women are of variable quality and yield conflicting results.1 Though several studies suggest an association between fatigue among menopausal women and disease states, poor methodology limits the strength of their findings.
In an Internet-based survey, 448 middle-aged women who reported being either perimenopausal or menopausal responded to questions about their symptoms.2 Feeling tired and lacking energy were the 2 most frequently reported symptoms, in 380 (89%) and 355 (83%) of respondents, respectively. These self-selected respondents probably do not represent the menopausal population of women at large.
A prospective cohort study, using a 1-page questionnaire that included 2 fatigue scales, identified 276 (24%) of 1159 primary care patients who indicated fatigue as a major problem.3 The mean age of patients was 57 years and 66% were women. Extensive laboratory testing was not helpful in determining the cause of fatigue. The Beck Depression Inventory, the Modified Somatic Perception Questionnaire, and the Social Readjustment Rating Scale identified depression or anxiety in 80% of patients with fatigue and 12% of controls. There are no similar studies for strictly menopausal women.
The prevalence of obstructive sleep apnea and sleep-disordered breathing increases at the time of menopause and peaks at age 65.4,5 In a retrospective chart review of patients referred for evaluation of snoring, 22 (91%) of the women with studies) were more likely to report daytime fatigue as a presenting symptom than were the 44 (55%) of men with obstructive sleep apnea (P<.01).6 Most striking was a sub-group (40%) of women with documented obstructive sleep apnea who reported only fatigue and morning headache but did not note apnea or restless sleep.
Coronary heart disease is the primary cause of death for women in the United States. A retrospective study of 515 women 4 to 6 months after a myocardial infarction explored self-reported symptoms.7 The mean age was 66±12 years and 93% were white. Unusual fatigue was the most frequent prodromal symptom experienced by 70.7% of women 1 month before a myocardial infarction, with 42.9% reporting fatigue in the acute setting. Though this retrospective study is limited both by its methodological quality and by the narrow population studied, the results suggest a gender difference between men and women in their report of symptoms of coronary artery disease.
A review of 15 studies from 1989 to 2002 reported that some studies found women were more likely to seek medical care for extreme fatigue and dyspnea than they were for chest pain. In acute coronary syndromes, 18% of women (compared with 9% of men) reported fatigue as a presenting symptom (P<.05). This review was limited by small sample sizes, retrospective chart review designs, and lack of explicitly stated critical appraisal criteria.8
Recommendations from others
No recommendations were identified.
1. Nelson HD, Haney E, Humphrey L, et al. Management of menopause-related symptoms. Evidence Report/Technology Assessment No. 120. (Prepared by the Oregon Evidence-Based Practice Center, under Contract No. 290-02-0024.) AHRQ Publication No. 05-E016-2. Rockville, Md: Agency for Healthcare Research and Quality; 2005.
2. Conboy L, Domar A, O’Connell E. Women at mid-life: symptoms, attitudes and choices, an internet based survey. Maturitas 2001;38:129-136.
3. Kroenke K, Wood DR, Mangelsdorff AD, Meier NJ, Powell JB. Chronic fatigue in primary care. Prevalence, patient characteristics and outcomes. JAMA 1988;260:929-934.
4. Bixler EO, Vgontzas AN, Lin HM, et al. Prevalence of sleep-disordered breathing in women: effects of gender. Am J Respir Crit Care Med 2001;163:608-613.
5. Young T, Finn L, Austin D, Peterson A. Menopausal status and sleep-disordered breathing in the Wisconsin Sleep Cohort Study. Am J Respir Crit Care Med 2003;167:1181-1185.
6. Ambrogetti A, Olson LG, Saunders NA. Differences in the symptoms of men and women with obstructive sleep apnoea. Aust NZ J Med 1991;21:863-866.
7. McSweeney JC, Cody M, O’Sullivan P, Elberson K, Moser DK, Garvin BJ. Women’s early warning symptoms of acute myocardial infarction. Circulation 2003;108:2619-2623.
8. Patel H, Rosengren A, Ekman I. Symptoms in acute coronary syndromes: does sex make a difference? Am Heart J 2004;148:27-33.
1. Nelson HD, Haney E, Humphrey L, et al. Management of menopause-related symptoms. Evidence Report/Technology Assessment No. 120. (Prepared by the Oregon Evidence-Based Practice Center, under Contract No. 290-02-0024.) AHRQ Publication No. 05-E016-2. Rockville, Md: Agency for Healthcare Research and Quality; 2005.
2. Conboy L, Domar A, O’Connell E. Women at mid-life: symptoms, attitudes and choices, an internet based survey. Maturitas 2001;38:129-136.
3. Kroenke K, Wood DR, Mangelsdorff AD, Meier NJ, Powell JB. Chronic fatigue in primary care. Prevalence, patient characteristics and outcomes. JAMA 1988;260:929-934.
4. Bixler EO, Vgontzas AN, Lin HM, et al. Prevalence of sleep-disordered breathing in women: effects of gender. Am J Respir Crit Care Med 2001;163:608-613.
5. Young T, Finn L, Austin D, Peterson A. Menopausal status and sleep-disordered breathing in the Wisconsin Sleep Cohort Study. Am J Respir Crit Care Med 2003;167:1181-1185.
6. Ambrogetti A, Olson LG, Saunders NA. Differences in the symptoms of men and women with obstructive sleep apnoea. Aust NZ J Med 1991;21:863-866.
7. McSweeney JC, Cody M, O’Sullivan P, Elberson K, Moser DK, Garvin BJ. Women’s early warning symptoms of acute myocardial infarction. Circulation 2003;108:2619-2623.
8. Patel H, Rosengren A, Ekman I. Symptoms in acute coronary syndromes: does sex make a difference? Am Heart J 2004;148:27-33.
Evidence-based answers from the Family Physicians Inquiries Network
What illnesses contraindicate immunization?
The Advisory Council on Immunization Practices (ACIP) reports that the only contraindication for all vaccines is a history of severe allergic reaction to a previous vaccine or vaccine constituent (strength of recommendations: C, based predominantly on case series, case reports, and expert opinion).
Vaccination is safe and efficacious in the following situations: during a mild illness (eg, diarrhea, otitis media or other mild upper respiratory infection whether or not the patient has a fever), during antimicrobial therapy, during the convalescent phase of an acute illness, when breastfeeding, and after mild to moderate reactions to a previous dose of vaccine.
Live vaccines (varicella, MMR) should not be used for pregnant women or significantly immunocompromised patients, and may not be effective for patients receiving immunoglobulin therapy. They can be administered to HIV-positive patients who are asymptomatic or not severely immunosuppressed, as determined by age-specific CD4 counts.
Evidence summary
Public misperceptions and provider uncertainty about contraindications create missed opportunities for immunization.1-3 The Centers for Disease Control and Prevention (CDC) defines contraindications as conditions that increase the risk of a serious reaction to vaccination. Precautions are conditions that might increase the risk of a serious reaction, or that diminish vaccine efficiency.4 Recommendations about contraindications and precautions for vaccine administration are partially based on studies of adverse effects (see the TABLE for common situations). Complete information on the contraindications and precautions for all common vaccinations can be accessed at www.cdc.gov/mmwr/preview/mmwrhtml/rr5102a1.htm#tab5.4
Data on vaccination risks are limited by a relative lack of experimental studies. Initial recommendations of the Advisory Council on Immunization Practices have been based on the findings of a 14-member Institute of Medicine (IOM) expert committee and are updated regularly.5-7 The IOM committee reported that because vaccine-related adverse events occur infrequently, available randomized controlled trials were too small to detect differences in incidence.6 Much of the data come from adverse effect surveillance systems, such as the Vaccine Adverse Event Reporting System (VAERS), to which health care providers report possible adverse effects of vaccinations.
Updated contraindications by ACIP to the initial IOM recommendations have also been based on observational reports and studies.4 A recent Cochrane review on acellular pertussis vaccines concluded that the acellular vaccine had fewer adverse effects than the whole-cell version, but did not support any changes in contraindications or precautions.8
TABLE
Contraindications and precautions for vaccine administration
| SITUATION | COMMENTS |
|---|---|
| Mild acute illness (with or without fever) (otitis media, diarrhea, etc) | No contraindication |
| Breastfeeding | No contraindication |
| Serious allergic reaction to vaccine or component (anaphylaxis) | Absolute contraindication |
| Pregnancy | Tetanus and influenza should be kept current |
| No contraindication to give indicated inactivated immunizations | |
| Live vaccines are contraindicated, although no reports of adverse reactions reported | |
| Moderate to severe illness | Temporary precaution—hold until patient improved |
| Encephalopathy <1 week after DTP or DtaP | Pertussis immunization contraindicated |
| Fever >40.5° C or Hypotonic, hyporesponsive episode or Persistent, inconsolable crying >3 hours <48 hours after DTP or DTaP or seizure <3 days after DTP or DTaP | Avoid pertussis, but vaccination may be appropriate during an outbreak |
| Recipients of blood, IVIG, and other antibody-containing products | Hold live vaccines for variable timing depending on dose (see CDC Recommendations) |
| Oral typhoid and yellow fever OK | |
| Chemotherapy or radiotherapy | Give influenza |
| Avoid others (decreased immune response) | |
| Antibacterials | Should not be taken with oral (live) typhoid vaccine (decreased effectiveness) |
| Antivirals against herpes spp | Should not be taken with live varicella vaccine (decreased effectiveness) |
| Postpartum anti-Rho(D) | Simultaneous rubella vaccination effective |
| Hematopoietic Stem Cell transplant recipients | See separate CDC Recommendations* |
| Altered immune status (HIV, solid organ transplant recipients, etc) | See separate CDC Recommendations† |
| Inactivated immunizations are safe, may be less effective | |
| Table based on general recommendations on immunization, MMWR Recomm Rep 2002.4 | |
| *Available at: www.cdc.gov/mmwr/preview/mmwrhtml/rr4910a1.htm | |
| † For HIV, www.cdc.gov/mmwr/preview/mmwrhtml/rr5108a1.htm; for others, www.cdc.gov/mmwr/preview/mmwrhtml/00023141.htm. | |
Recommendations from others
The ACIP recommendations serve as national standards and have been adopted by American Academy of Pediatrics and the American Academy of Family Physicians and are included in most standard reference texts.4,9
Know true contraindications; provide clear, factual information to concerned parents
Rebecca Meriwether, MD
Tulane University, New Orleans, La
Immunizations are among the safest and most cost-effective interventions available in modern medicine. Offices should be organized to assist in assuring delivery of immunizations during preventive, sick, and follow-up visits, and to follow recommended and catch-up schedules to reduce the time patients are susceptible to preventable infectious diseases. Failure to vaccinate due to inappropriate contraindications, particularly mild illness, is a missed opportunity and significant contributor to under-immunization. Know and observe true contraindications and provide clear, factual information to parents concerned about vaccine risks. When temporarily delaying vaccination is prudent—eg, with evolving neurologic conditions and moderate to severe illness—scheduling a return visit for immunizations and documenting the intention to vaccinate at the next visit are strategies to reduce the risk that catch-up immunization will be forgotten.
1. Wald ER, Dashefsky B, Byers C, Guerra N, Taylor F. Frequency and severity of infections in day care. J Pediatr 1988;112:540-546.
2. Szilagyi PG, Rodewald LE. Missed opportunities for immunizations: a review of the evidence. J Public Health Manag Pract 1996;2:18-25.
3. Farizo KM, Stehr-Green PA, Markowitz LE, Patriarca PA. Vaccination levels and missed opportunities for measles vaccination: a record audit in a public pediatric clinic. Pediatrics 1992;89:589-592.
4. General recommendations on immunization: recommendations of the Advisory Committee on Immunization Practices and the American Academy of Family Physicians. MMWR Recomm Rep 2002;51(RR-2):1-35.
5. Howson CP, Howe CJ, Fineberg HV, eds. Adverse Effects of Pertussis and Rubella Vaccines. Washington, DC: National Academy Press, last updated 1991. Available at: www.nap.edu/books/0309044995/html/index.html. Accessed on June 10, 2005.
6. Stratton KR, Howe CJ, Johnston RB, eds. Adverse Events Associated with Childhood Vaccines: Evidence Bearing on Causality. Washington, DC: National Academy Press, Last updated 1994. Available at: www.nap.edu/catalog/2138.html. Accessed on June 10, 2005.
7. Update: vaccine side effects, adverse reactions, contraindications, and precautions: recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recomm Rep 1996;45(RR-12):1-35.
8. Tinnion ON, Hanlon M. Acellular vaccines for preventing whooping cough in children. Cochrane Database Syst Rev 2000(2);CD001478.-
9. American Academy of Pediatrics. Active and Passive Immunization. In: Pickering LK, ed. Red Book: 2003 Report of the Committee on Infectious Diseases. 26th ed. Elk Grove Village, Ill: American Academy of Pediatrics; 2003;46-49.
The Advisory Council on Immunization Practices (ACIP) reports that the only contraindication for all vaccines is a history of severe allergic reaction to a previous vaccine or vaccine constituent (strength of recommendations: C, based predominantly on case series, case reports, and expert opinion).
Vaccination is safe and efficacious in the following situations: during a mild illness (eg, diarrhea, otitis media or other mild upper respiratory infection whether or not the patient has a fever), during antimicrobial therapy, during the convalescent phase of an acute illness, when breastfeeding, and after mild to moderate reactions to a previous dose of vaccine.
Live vaccines (varicella, MMR) should not be used for pregnant women or significantly immunocompromised patients, and may not be effective for patients receiving immunoglobulin therapy. They can be administered to HIV-positive patients who are asymptomatic or not severely immunosuppressed, as determined by age-specific CD4 counts.
Evidence summary
Public misperceptions and provider uncertainty about contraindications create missed opportunities for immunization.1-3 The Centers for Disease Control and Prevention (CDC) defines contraindications as conditions that increase the risk of a serious reaction to vaccination. Precautions are conditions that might increase the risk of a serious reaction, or that diminish vaccine efficiency.4 Recommendations about contraindications and precautions for vaccine administration are partially based on studies of adverse effects (see the TABLE for common situations). Complete information on the contraindications and precautions for all common vaccinations can be accessed at www.cdc.gov/mmwr/preview/mmwrhtml/rr5102a1.htm#tab5.4
Data on vaccination risks are limited by a relative lack of experimental studies. Initial recommendations of the Advisory Council on Immunization Practices have been based on the findings of a 14-member Institute of Medicine (IOM) expert committee and are updated regularly.5-7 The IOM committee reported that because vaccine-related adverse events occur infrequently, available randomized controlled trials were too small to detect differences in incidence.6 Much of the data come from adverse effect surveillance systems, such as the Vaccine Adverse Event Reporting System (VAERS), to which health care providers report possible adverse effects of vaccinations.
Updated contraindications by ACIP to the initial IOM recommendations have also been based on observational reports and studies.4 A recent Cochrane review on acellular pertussis vaccines concluded that the acellular vaccine had fewer adverse effects than the whole-cell version, but did not support any changes in contraindications or precautions.8
TABLE
Contraindications and precautions for vaccine administration
| SITUATION | COMMENTS |
|---|---|
| Mild acute illness (with or without fever) (otitis media, diarrhea, etc) | No contraindication |
| Breastfeeding | No contraindication |
| Serious allergic reaction to vaccine or component (anaphylaxis) | Absolute contraindication |
| Pregnancy | Tetanus and influenza should be kept current |
| No contraindication to give indicated inactivated immunizations | |
| Live vaccines are contraindicated, although no reports of adverse reactions reported | |
| Moderate to severe illness | Temporary precaution—hold until patient improved |
| Encephalopathy <1 week after DTP or DtaP | Pertussis immunization contraindicated |
| Fever >40.5° C or Hypotonic, hyporesponsive episode or Persistent, inconsolable crying >3 hours <48 hours after DTP or DTaP or seizure <3 days after DTP or DTaP | Avoid pertussis, but vaccination may be appropriate during an outbreak |
| Recipients of blood, IVIG, and other antibody-containing products | Hold live vaccines for variable timing depending on dose (see CDC Recommendations) |
| Oral typhoid and yellow fever OK | |
| Chemotherapy or radiotherapy | Give influenza |
| Avoid others (decreased immune response) | |
| Antibacterials | Should not be taken with oral (live) typhoid vaccine (decreased effectiveness) |
| Antivirals against herpes spp | Should not be taken with live varicella vaccine (decreased effectiveness) |
| Postpartum anti-Rho(D) | Simultaneous rubella vaccination effective |
| Hematopoietic Stem Cell transplant recipients | See separate CDC Recommendations* |
| Altered immune status (HIV, solid organ transplant recipients, etc) | See separate CDC Recommendations† |
| Inactivated immunizations are safe, may be less effective | |
| Table based on general recommendations on immunization, MMWR Recomm Rep 2002.4 | |
| *Available at: www.cdc.gov/mmwr/preview/mmwrhtml/rr4910a1.htm | |
| † For HIV, www.cdc.gov/mmwr/preview/mmwrhtml/rr5108a1.htm; for others, www.cdc.gov/mmwr/preview/mmwrhtml/00023141.htm. | |
Recommendations from others
The ACIP recommendations serve as national standards and have been adopted by American Academy of Pediatrics and the American Academy of Family Physicians and are included in most standard reference texts.4,9
Know true contraindications; provide clear, factual information to concerned parents
Rebecca Meriwether, MD
Tulane University, New Orleans, La
Immunizations are among the safest and most cost-effective interventions available in modern medicine. Offices should be organized to assist in assuring delivery of immunizations during preventive, sick, and follow-up visits, and to follow recommended and catch-up schedules to reduce the time patients are susceptible to preventable infectious diseases. Failure to vaccinate due to inappropriate contraindications, particularly mild illness, is a missed opportunity and significant contributor to under-immunization. Know and observe true contraindications and provide clear, factual information to parents concerned about vaccine risks. When temporarily delaying vaccination is prudent—eg, with evolving neurologic conditions and moderate to severe illness—scheduling a return visit for immunizations and documenting the intention to vaccinate at the next visit are strategies to reduce the risk that catch-up immunization will be forgotten.
The Advisory Council on Immunization Practices (ACIP) reports that the only contraindication for all vaccines is a history of severe allergic reaction to a previous vaccine or vaccine constituent (strength of recommendations: C, based predominantly on case series, case reports, and expert opinion).
Vaccination is safe and efficacious in the following situations: during a mild illness (eg, diarrhea, otitis media or other mild upper respiratory infection whether or not the patient has a fever), during antimicrobial therapy, during the convalescent phase of an acute illness, when breastfeeding, and after mild to moderate reactions to a previous dose of vaccine.
Live vaccines (varicella, MMR) should not be used for pregnant women or significantly immunocompromised patients, and may not be effective for patients receiving immunoglobulin therapy. They can be administered to HIV-positive patients who are asymptomatic or not severely immunosuppressed, as determined by age-specific CD4 counts.
Evidence summary
Public misperceptions and provider uncertainty about contraindications create missed opportunities for immunization.1-3 The Centers for Disease Control and Prevention (CDC) defines contraindications as conditions that increase the risk of a serious reaction to vaccination. Precautions are conditions that might increase the risk of a serious reaction, or that diminish vaccine efficiency.4 Recommendations about contraindications and precautions for vaccine administration are partially based on studies of adverse effects (see the TABLE for common situations). Complete information on the contraindications and precautions for all common vaccinations can be accessed at www.cdc.gov/mmwr/preview/mmwrhtml/rr5102a1.htm#tab5.4
Data on vaccination risks are limited by a relative lack of experimental studies. Initial recommendations of the Advisory Council on Immunization Practices have been based on the findings of a 14-member Institute of Medicine (IOM) expert committee and are updated regularly.5-7 The IOM committee reported that because vaccine-related adverse events occur infrequently, available randomized controlled trials were too small to detect differences in incidence.6 Much of the data come from adverse effect surveillance systems, such as the Vaccine Adverse Event Reporting System (VAERS), to which health care providers report possible adverse effects of vaccinations.
Updated contraindications by ACIP to the initial IOM recommendations have also been based on observational reports and studies.4 A recent Cochrane review on acellular pertussis vaccines concluded that the acellular vaccine had fewer adverse effects than the whole-cell version, but did not support any changes in contraindications or precautions.8
TABLE
Contraindications and precautions for vaccine administration
| SITUATION | COMMENTS |
|---|---|
| Mild acute illness (with or without fever) (otitis media, diarrhea, etc) | No contraindication |
| Breastfeeding | No contraindication |
| Serious allergic reaction to vaccine or component (anaphylaxis) | Absolute contraindication |
| Pregnancy | Tetanus and influenza should be kept current |
| No contraindication to give indicated inactivated immunizations | |
| Live vaccines are contraindicated, although no reports of adverse reactions reported | |
| Moderate to severe illness | Temporary precaution—hold until patient improved |
| Encephalopathy <1 week after DTP or DtaP | Pertussis immunization contraindicated |
| Fever >40.5° C or Hypotonic, hyporesponsive episode or Persistent, inconsolable crying >3 hours <48 hours after DTP or DTaP or seizure <3 days after DTP or DTaP | Avoid pertussis, but vaccination may be appropriate during an outbreak |
| Recipients of blood, IVIG, and other antibody-containing products | Hold live vaccines for variable timing depending on dose (see CDC Recommendations) |
| Oral typhoid and yellow fever OK | |
| Chemotherapy or radiotherapy | Give influenza |
| Avoid others (decreased immune response) | |
| Antibacterials | Should not be taken with oral (live) typhoid vaccine (decreased effectiveness) |
| Antivirals against herpes spp | Should not be taken with live varicella vaccine (decreased effectiveness) |
| Postpartum anti-Rho(D) | Simultaneous rubella vaccination effective |
| Hematopoietic Stem Cell transplant recipients | See separate CDC Recommendations* |
| Altered immune status (HIV, solid organ transplant recipients, etc) | See separate CDC Recommendations† |
| Inactivated immunizations are safe, may be less effective | |
| Table based on general recommendations on immunization, MMWR Recomm Rep 2002.4 | |
| *Available at: www.cdc.gov/mmwr/preview/mmwrhtml/rr4910a1.htm | |
| † For HIV, www.cdc.gov/mmwr/preview/mmwrhtml/rr5108a1.htm; for others, www.cdc.gov/mmwr/preview/mmwrhtml/00023141.htm. | |
Recommendations from others
The ACIP recommendations serve as national standards and have been adopted by American Academy of Pediatrics and the American Academy of Family Physicians and are included in most standard reference texts.4,9
Know true contraindications; provide clear, factual information to concerned parents
Rebecca Meriwether, MD
Tulane University, New Orleans, La
Immunizations are among the safest and most cost-effective interventions available in modern medicine. Offices should be organized to assist in assuring delivery of immunizations during preventive, sick, and follow-up visits, and to follow recommended and catch-up schedules to reduce the time patients are susceptible to preventable infectious diseases. Failure to vaccinate due to inappropriate contraindications, particularly mild illness, is a missed opportunity and significant contributor to under-immunization. Know and observe true contraindications and provide clear, factual information to parents concerned about vaccine risks. When temporarily delaying vaccination is prudent—eg, with evolving neurologic conditions and moderate to severe illness—scheduling a return visit for immunizations and documenting the intention to vaccinate at the next visit are strategies to reduce the risk that catch-up immunization will be forgotten.
1. Wald ER, Dashefsky B, Byers C, Guerra N, Taylor F. Frequency and severity of infections in day care. J Pediatr 1988;112:540-546.
2. Szilagyi PG, Rodewald LE. Missed opportunities for immunizations: a review of the evidence. J Public Health Manag Pract 1996;2:18-25.
3. Farizo KM, Stehr-Green PA, Markowitz LE, Patriarca PA. Vaccination levels and missed opportunities for measles vaccination: a record audit in a public pediatric clinic. Pediatrics 1992;89:589-592.
4. General recommendations on immunization: recommendations of the Advisory Committee on Immunization Practices and the American Academy of Family Physicians. MMWR Recomm Rep 2002;51(RR-2):1-35.
5. Howson CP, Howe CJ, Fineberg HV, eds. Adverse Effects of Pertussis and Rubella Vaccines. Washington, DC: National Academy Press, last updated 1991. Available at: www.nap.edu/books/0309044995/html/index.html. Accessed on June 10, 2005.
6. Stratton KR, Howe CJ, Johnston RB, eds. Adverse Events Associated with Childhood Vaccines: Evidence Bearing on Causality. Washington, DC: National Academy Press, Last updated 1994. Available at: www.nap.edu/catalog/2138.html. Accessed on June 10, 2005.
7. Update: vaccine side effects, adverse reactions, contraindications, and precautions: recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recomm Rep 1996;45(RR-12):1-35.
8. Tinnion ON, Hanlon M. Acellular vaccines for preventing whooping cough in children. Cochrane Database Syst Rev 2000(2);CD001478.-
9. American Academy of Pediatrics. Active and Passive Immunization. In: Pickering LK, ed. Red Book: 2003 Report of the Committee on Infectious Diseases. 26th ed. Elk Grove Village, Ill: American Academy of Pediatrics; 2003;46-49.
1. Wald ER, Dashefsky B, Byers C, Guerra N, Taylor F. Frequency and severity of infections in day care. J Pediatr 1988;112:540-546.
2. Szilagyi PG, Rodewald LE. Missed opportunities for immunizations: a review of the evidence. J Public Health Manag Pract 1996;2:18-25.
3. Farizo KM, Stehr-Green PA, Markowitz LE, Patriarca PA. Vaccination levels and missed opportunities for measles vaccination: a record audit in a public pediatric clinic. Pediatrics 1992;89:589-592.
4. General recommendations on immunization: recommendations of the Advisory Committee on Immunization Practices and the American Academy of Family Physicians. MMWR Recomm Rep 2002;51(RR-2):1-35.
5. Howson CP, Howe CJ, Fineberg HV, eds. Adverse Effects of Pertussis and Rubella Vaccines. Washington, DC: National Academy Press, last updated 1991. Available at: www.nap.edu/books/0309044995/html/index.html. Accessed on June 10, 2005.
6. Stratton KR, Howe CJ, Johnston RB, eds. Adverse Events Associated with Childhood Vaccines: Evidence Bearing on Causality. Washington, DC: National Academy Press, Last updated 1994. Available at: www.nap.edu/catalog/2138.html. Accessed on June 10, 2005.
7. Update: vaccine side effects, adverse reactions, contraindications, and precautions: recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recomm Rep 1996;45(RR-12):1-35.
8. Tinnion ON, Hanlon M. Acellular vaccines for preventing whooping cough in children. Cochrane Database Syst Rev 2000(2);CD001478.-
9. American Academy of Pediatrics. Active and Passive Immunization. In: Pickering LK, ed. Red Book: 2003 Report of the Committee on Infectious Diseases. 26th ed. Elk Grove Village, Ill: American Academy of Pediatrics; 2003;46-49.
Evidence-based answers from the Family Physicians Inquiries Network
What is the best treatment for analgesic rebound headaches?
Abrupt discontinuation of the offending analgesic(s), and treating rebound headaches with dihydroergotamine (DHE) as needed, results in significant improvement for most patients (strength of recommendation [SOR]: C; based on case series). Amitriptyline does not affect the frequency or severity of rebound headaches, but it may improve quality of life (SOR: B, low-powered randomized controlled trial). Prednisone or naratriptan (Amerge) lessen acute withdrawal symptoms from analgesics and reduce the need for rescue medications during the first 6 days of treatment; however, they do not affect headache frequency or severity (SOR: B, low-quality randomized controlled trial).
Evidence summary
Analgesic rebound headaches are seen in 1% of the population, mostly middle-aged women with underlying migraines.1,2 Also termed analgesic-overuse headaches, they are defined by the International Headache Society guidelines as headaches occurring more than 15 days per month, mild to moderate in intensity, developing or worsening with analgesic overuse, and resolving or reverting to the prior underlying headache pattern within 2 months of discontinuing the analgesic(s).3
A case series studied 50 patients with rebound headaches for 5 or more days a week at baseline.4 Patients were educated regarding analgesic overuse headaches, after which their analgesics were abruptly discontinued, and they were followed up to a year. Subcutaneous DHE was used as needed for symptomatic relief of excruciating headaches. At study completion, 78% of patients had adequately stopped analgesics. The goal of greater than 6 consecutive headache-free days was achieved in 74% patients in an average of 84 days.
A 9-week double-blind, placebo-controlled trial randomized 20 nondepressed patients with analgesic overuse headache to receive amitriptyline or active placebo (trihexyphenidyl).5 Patients were admitted to the hospital for 1 week and withdrawn from all analgesics. The 2 groups had similar baseline characteristics. During the hospitalization, the amitriptyline treatment group received intravenous amitriptyline escalating from 25 to 75 mg. During the following month, oral study medications were continued, and patients took low doses of aspirin or acetaminophen, as needed. There was no significant difference between the 2 groups with regard to analgesic use. At completion of this low-powered study, no difference was found between the 2 groups in headache frequency or analgesic use, although certain components of a quality-of-life scale were better in the amitriptyline group.
An open-label trial of patients with chronic migraine and analgesic overuse in a headache sub-specialty center abruptly withdrew 150 participants from analgesics and quasi-randomized them to 3 groups: prednisone (tapering from 60 to 20 mg over 6 days), naratriptan (Amerge) (2.5 mg twice daily for 6 days), or no prophylactic treatment.6 Patients given the active substances were told it would reduce withdrawal symptoms; patients given placebo were not given this advice. All patients received education about the pathophysiology of rebound headaches, kept a headache diary, and were phoned weekly to ensure compliance. In addition, they all received capsules containing gradually increasing doses of atenolol, nortriptyline, and flunarazine (a calcium channel blocker not FDA-approved.) Indo-methacin and chlorpromazine were used as needed. Results from the first 6 days showed no difference in headaches between the 3 groups; however, significantly more patients used chlorpromazine in the “no pharmacologic treatment” group
By the end of 5 weeks, headache frequency was significantly reduced in all groups from baseline; however, there were no differences between groups in headache frequency or intensity in this small study. Of note, there were statistically fewer withdrawal symptoms and less use of rescue medications among patients who received the initial prophylactic treatments. The indomethacin rescue use was 24%, 18%, and 14% of patients for the no prophylactic treatment, prednisone, and naratriptan groups respectively, while chlorpromazine rescue use was 14%, 0%, and 0%, respectively. The number of patients needed to treat to prevent any withdrawal symptoms (nausea, vomiting, nervousness, dizziness, etc.) was 1 for every 3.5 for naratriptan, and 6.4 for prednisone.
Recommendations from others
The American Council for Headache Education recommends discontinuing all analgesics.7 It notes some patients may need prophylactic medication (although no specific agent is recommended), and hospitalization may be indicated for withdrawal for patients who have abused narcotics. A headache textbook recommends 1 of 2 approaches for patients undergoing outpatient treatment: (1) gradual tapering of the offending medication with substitution of a long-acting nonsteroidal anti-inflammatory drug (NSAID) and initiation of preventive therapy, or (2) abrupt discontinuation of the offending medication and initiation followed by gradual tapering of a “transitional” medication such as NSAIDs, DHE, corticosteroids, or triptans. The authors recommend an intravenous DHE protocol for treatment failures and patients requiring inpatient treatment.8
Consider anxiety, depression, substance abuse, psychosocial stressors as triggers
Lisa Erlanger, MD
Swedish at Providence Family Medicine Residency, Seattle, Wash
Analgesic rebound headaches are clinically challenging. Patients are reluctant to believe that analgesic use is the cause, and good evidence for pharmacologic treatment of the problem is limited. Therefore, the family physician’s unique skills in patient-centered care are invaluable for helping patients comply with the only proven remedy: long-term analgesic abstinence. Even with intense education and support, abstinence rates are low and headache improvement for abstinent patients is relatively slow and not universal.
In discussing options for assisting with detoxification, we must be honest about the limits of our knowledge and clarify that improvement, rather than cure, is the goal. Identification and treatment of concurrent anxiety, depression and substance use is important, as well as identification of psychosocial stressors that may have triggered increased headache frequency. As even moderate amounts of regular analgesic use can cause this difficult to treat syndrome, preventive counseling with migraine patients, particularly those with increasing headache frequency, is essential.
1. Colas R, Munoz P, Temprano R, Gomez C, Pascual J. Chronic daily headache with analgesic overuse: epidemiology and impact on quality of life. Neurology 2004;62:1338-1342.
2. Toth C. Medications and substances as a cause of headache: a systematic review of the literature. Clin Neuropharmacol 2003;26:122-136.
3. Headache Classification Subcommittee of the International Headache Society. The international classification of headache disorders. 2nd ed. Cephalalgia 2004;24(1 Suppl):9-160.
4. Warner JS. The outcome of treating patients with suspected rebound headache. Headache 2001;41:684-692.
5. Descombes S, Brefel-Courbon C, Thalamas C, et al. Amitriptyline treatment in chronic drug-induced headache: a double-blind comparative pilot study. Headache 2001;41:178-182.
6. Krymchantowski AV, Moreira PF. Out-patient detoxification in chronic migraine: comparison of strategies. Cephalalgia 2003;23:982-993.
7. Purdy RA. I have a headache every single day—all about chronic daily headache. Headache (online) 1999. Available at: www.achenet.org/articles/purdy.php/. Accessed on February 7, 2004.
8. Siberstein SD, Lipton RB. Chronic daily headache, including transformed migraine, chronic tension-type headache, and medication overuse. In: Silberstein SD, Lipton RB, Delessio DJ, eds. Wolff’s Headache and Other Head Pain. Oxford: Oxford University Press 2001;247-282.
Abrupt discontinuation of the offending analgesic(s), and treating rebound headaches with dihydroergotamine (DHE) as needed, results in significant improvement for most patients (strength of recommendation [SOR]: C; based on case series). Amitriptyline does not affect the frequency or severity of rebound headaches, but it may improve quality of life (SOR: B, low-powered randomized controlled trial). Prednisone or naratriptan (Amerge) lessen acute withdrawal symptoms from analgesics and reduce the need for rescue medications during the first 6 days of treatment; however, they do not affect headache frequency or severity (SOR: B, low-quality randomized controlled trial).
Evidence summary
Analgesic rebound headaches are seen in 1% of the population, mostly middle-aged women with underlying migraines.1,2 Also termed analgesic-overuse headaches, they are defined by the International Headache Society guidelines as headaches occurring more than 15 days per month, mild to moderate in intensity, developing or worsening with analgesic overuse, and resolving or reverting to the prior underlying headache pattern within 2 months of discontinuing the analgesic(s).3
A case series studied 50 patients with rebound headaches for 5 or more days a week at baseline.4 Patients were educated regarding analgesic overuse headaches, after which their analgesics were abruptly discontinued, and they were followed up to a year. Subcutaneous DHE was used as needed for symptomatic relief of excruciating headaches. At study completion, 78% of patients had adequately stopped analgesics. The goal of greater than 6 consecutive headache-free days was achieved in 74% patients in an average of 84 days.
A 9-week double-blind, placebo-controlled trial randomized 20 nondepressed patients with analgesic overuse headache to receive amitriptyline or active placebo (trihexyphenidyl).5 Patients were admitted to the hospital for 1 week and withdrawn from all analgesics. The 2 groups had similar baseline characteristics. During the hospitalization, the amitriptyline treatment group received intravenous amitriptyline escalating from 25 to 75 mg. During the following month, oral study medications were continued, and patients took low doses of aspirin or acetaminophen, as needed. There was no significant difference between the 2 groups with regard to analgesic use. At completion of this low-powered study, no difference was found between the 2 groups in headache frequency or analgesic use, although certain components of a quality-of-life scale were better in the amitriptyline group.
An open-label trial of patients with chronic migraine and analgesic overuse in a headache sub-specialty center abruptly withdrew 150 participants from analgesics and quasi-randomized them to 3 groups: prednisone (tapering from 60 to 20 mg over 6 days), naratriptan (Amerge) (2.5 mg twice daily for 6 days), or no prophylactic treatment.6 Patients given the active substances were told it would reduce withdrawal symptoms; patients given placebo were not given this advice. All patients received education about the pathophysiology of rebound headaches, kept a headache diary, and were phoned weekly to ensure compliance. In addition, they all received capsules containing gradually increasing doses of atenolol, nortriptyline, and flunarazine (a calcium channel blocker not FDA-approved.) Indo-methacin and chlorpromazine were used as needed. Results from the first 6 days showed no difference in headaches between the 3 groups; however, significantly more patients used chlorpromazine in the “no pharmacologic treatment” group
By the end of 5 weeks, headache frequency was significantly reduced in all groups from baseline; however, there were no differences between groups in headache frequency or intensity in this small study. Of note, there were statistically fewer withdrawal symptoms and less use of rescue medications among patients who received the initial prophylactic treatments. The indomethacin rescue use was 24%, 18%, and 14% of patients for the no prophylactic treatment, prednisone, and naratriptan groups respectively, while chlorpromazine rescue use was 14%, 0%, and 0%, respectively. The number of patients needed to treat to prevent any withdrawal symptoms (nausea, vomiting, nervousness, dizziness, etc.) was 1 for every 3.5 for naratriptan, and 6.4 for prednisone.
Recommendations from others
The American Council for Headache Education recommends discontinuing all analgesics.7 It notes some patients may need prophylactic medication (although no specific agent is recommended), and hospitalization may be indicated for withdrawal for patients who have abused narcotics. A headache textbook recommends 1 of 2 approaches for patients undergoing outpatient treatment: (1) gradual tapering of the offending medication with substitution of a long-acting nonsteroidal anti-inflammatory drug (NSAID) and initiation of preventive therapy, or (2) abrupt discontinuation of the offending medication and initiation followed by gradual tapering of a “transitional” medication such as NSAIDs, DHE, corticosteroids, or triptans. The authors recommend an intravenous DHE protocol for treatment failures and patients requiring inpatient treatment.8
Consider anxiety, depression, substance abuse, psychosocial stressors as triggers
Lisa Erlanger, MD
Swedish at Providence Family Medicine Residency, Seattle, Wash
Analgesic rebound headaches are clinically challenging. Patients are reluctant to believe that analgesic use is the cause, and good evidence for pharmacologic treatment of the problem is limited. Therefore, the family physician’s unique skills in patient-centered care are invaluable for helping patients comply with the only proven remedy: long-term analgesic abstinence. Even with intense education and support, abstinence rates are low and headache improvement for abstinent patients is relatively slow and not universal.
In discussing options for assisting with detoxification, we must be honest about the limits of our knowledge and clarify that improvement, rather than cure, is the goal. Identification and treatment of concurrent anxiety, depression and substance use is important, as well as identification of psychosocial stressors that may have triggered increased headache frequency. As even moderate amounts of regular analgesic use can cause this difficult to treat syndrome, preventive counseling with migraine patients, particularly those with increasing headache frequency, is essential.
Abrupt discontinuation of the offending analgesic(s), and treating rebound headaches with dihydroergotamine (DHE) as needed, results in significant improvement for most patients (strength of recommendation [SOR]: C; based on case series). Amitriptyline does not affect the frequency or severity of rebound headaches, but it may improve quality of life (SOR: B, low-powered randomized controlled trial). Prednisone or naratriptan (Amerge) lessen acute withdrawal symptoms from analgesics and reduce the need for rescue medications during the first 6 days of treatment; however, they do not affect headache frequency or severity (SOR: B, low-quality randomized controlled trial).
Evidence summary
Analgesic rebound headaches are seen in 1% of the population, mostly middle-aged women with underlying migraines.1,2 Also termed analgesic-overuse headaches, they are defined by the International Headache Society guidelines as headaches occurring more than 15 days per month, mild to moderate in intensity, developing or worsening with analgesic overuse, and resolving or reverting to the prior underlying headache pattern within 2 months of discontinuing the analgesic(s).3
A case series studied 50 patients with rebound headaches for 5 or more days a week at baseline.4 Patients were educated regarding analgesic overuse headaches, after which their analgesics were abruptly discontinued, and they were followed up to a year. Subcutaneous DHE was used as needed for symptomatic relief of excruciating headaches. At study completion, 78% of patients had adequately stopped analgesics. The goal of greater than 6 consecutive headache-free days was achieved in 74% patients in an average of 84 days.
A 9-week double-blind, placebo-controlled trial randomized 20 nondepressed patients with analgesic overuse headache to receive amitriptyline or active placebo (trihexyphenidyl).5 Patients were admitted to the hospital for 1 week and withdrawn from all analgesics. The 2 groups had similar baseline characteristics. During the hospitalization, the amitriptyline treatment group received intravenous amitriptyline escalating from 25 to 75 mg. During the following month, oral study medications were continued, and patients took low doses of aspirin or acetaminophen, as needed. There was no significant difference between the 2 groups with regard to analgesic use. At completion of this low-powered study, no difference was found between the 2 groups in headache frequency or analgesic use, although certain components of a quality-of-life scale were better in the amitriptyline group.
An open-label trial of patients with chronic migraine and analgesic overuse in a headache sub-specialty center abruptly withdrew 150 participants from analgesics and quasi-randomized them to 3 groups: prednisone (tapering from 60 to 20 mg over 6 days), naratriptan (Amerge) (2.5 mg twice daily for 6 days), or no prophylactic treatment.6 Patients given the active substances were told it would reduce withdrawal symptoms; patients given placebo were not given this advice. All patients received education about the pathophysiology of rebound headaches, kept a headache diary, and were phoned weekly to ensure compliance. In addition, they all received capsules containing gradually increasing doses of atenolol, nortriptyline, and flunarazine (a calcium channel blocker not FDA-approved.) Indo-methacin and chlorpromazine were used as needed. Results from the first 6 days showed no difference in headaches between the 3 groups; however, significantly more patients used chlorpromazine in the “no pharmacologic treatment” group
By the end of 5 weeks, headache frequency was significantly reduced in all groups from baseline; however, there were no differences between groups in headache frequency or intensity in this small study. Of note, there were statistically fewer withdrawal symptoms and less use of rescue medications among patients who received the initial prophylactic treatments. The indomethacin rescue use was 24%, 18%, and 14% of patients for the no prophylactic treatment, prednisone, and naratriptan groups respectively, while chlorpromazine rescue use was 14%, 0%, and 0%, respectively. The number of patients needed to treat to prevent any withdrawal symptoms (nausea, vomiting, nervousness, dizziness, etc.) was 1 for every 3.5 for naratriptan, and 6.4 for prednisone.
Recommendations from others
The American Council for Headache Education recommends discontinuing all analgesics.7 It notes some patients may need prophylactic medication (although no specific agent is recommended), and hospitalization may be indicated for withdrawal for patients who have abused narcotics. A headache textbook recommends 1 of 2 approaches for patients undergoing outpatient treatment: (1) gradual tapering of the offending medication with substitution of a long-acting nonsteroidal anti-inflammatory drug (NSAID) and initiation of preventive therapy, or (2) abrupt discontinuation of the offending medication and initiation followed by gradual tapering of a “transitional” medication such as NSAIDs, DHE, corticosteroids, or triptans. The authors recommend an intravenous DHE protocol for treatment failures and patients requiring inpatient treatment.8
Consider anxiety, depression, substance abuse, psychosocial stressors as triggers
Lisa Erlanger, MD
Swedish at Providence Family Medicine Residency, Seattle, Wash
Analgesic rebound headaches are clinically challenging. Patients are reluctant to believe that analgesic use is the cause, and good evidence for pharmacologic treatment of the problem is limited. Therefore, the family physician’s unique skills in patient-centered care are invaluable for helping patients comply with the only proven remedy: long-term analgesic abstinence. Even with intense education and support, abstinence rates are low and headache improvement for abstinent patients is relatively slow and not universal.
In discussing options for assisting with detoxification, we must be honest about the limits of our knowledge and clarify that improvement, rather than cure, is the goal. Identification and treatment of concurrent anxiety, depression and substance use is important, as well as identification of psychosocial stressors that may have triggered increased headache frequency. As even moderate amounts of regular analgesic use can cause this difficult to treat syndrome, preventive counseling with migraine patients, particularly those with increasing headache frequency, is essential.
1. Colas R, Munoz P, Temprano R, Gomez C, Pascual J. Chronic daily headache with analgesic overuse: epidemiology and impact on quality of life. Neurology 2004;62:1338-1342.
2. Toth C. Medications and substances as a cause of headache: a systematic review of the literature. Clin Neuropharmacol 2003;26:122-136.
3. Headache Classification Subcommittee of the International Headache Society. The international classification of headache disorders. 2nd ed. Cephalalgia 2004;24(1 Suppl):9-160.
4. Warner JS. The outcome of treating patients with suspected rebound headache. Headache 2001;41:684-692.
5. Descombes S, Brefel-Courbon C, Thalamas C, et al. Amitriptyline treatment in chronic drug-induced headache: a double-blind comparative pilot study. Headache 2001;41:178-182.
6. Krymchantowski AV, Moreira PF. Out-patient detoxification in chronic migraine: comparison of strategies. Cephalalgia 2003;23:982-993.
7. Purdy RA. I have a headache every single day—all about chronic daily headache. Headache (online) 1999. Available at: www.achenet.org/articles/purdy.php/. Accessed on February 7, 2004.
8. Siberstein SD, Lipton RB. Chronic daily headache, including transformed migraine, chronic tension-type headache, and medication overuse. In: Silberstein SD, Lipton RB, Delessio DJ, eds. Wolff’s Headache and Other Head Pain. Oxford: Oxford University Press 2001;247-282.
1. Colas R, Munoz P, Temprano R, Gomez C, Pascual J. Chronic daily headache with analgesic overuse: epidemiology and impact on quality of life. Neurology 2004;62:1338-1342.
2. Toth C. Medications and substances as a cause of headache: a systematic review of the literature. Clin Neuropharmacol 2003;26:122-136.
3. Headache Classification Subcommittee of the International Headache Society. The international classification of headache disorders. 2nd ed. Cephalalgia 2004;24(1 Suppl):9-160.
4. Warner JS. The outcome of treating patients with suspected rebound headache. Headache 2001;41:684-692.
5. Descombes S, Brefel-Courbon C, Thalamas C, et al. Amitriptyline treatment in chronic drug-induced headache: a double-blind comparative pilot study. Headache 2001;41:178-182.
6. Krymchantowski AV, Moreira PF. Out-patient detoxification in chronic migraine: comparison of strategies. Cephalalgia 2003;23:982-993.
7. Purdy RA. I have a headache every single day—all about chronic daily headache. Headache (online) 1999. Available at: www.achenet.org/articles/purdy.php/. Accessed on February 7, 2004.
8. Siberstein SD, Lipton RB. Chronic daily headache, including transformed migraine, chronic tension-type headache, and medication overuse. In: Silberstein SD, Lipton RB, Delessio DJ, eds. Wolff’s Headache and Other Head Pain. Oxford: Oxford University Press 2001;247-282.
Evidence-based answers from the Family Physicians Inquiries Network
Is methylphenidate useful for treating adolescents with ADHD?
Methylphenidate (Ritalin) is effective in the short-term treatment of attention deficit/hyperactivity disorder (ADHD) (strength of recommendation [SOR]: A, multiple randomized control trials).
Though the immediate-release preparation is the best studied of methylphenidate formulations, extended-release methylphenidate (Concerta) has similar benefits, with a dosing regimen that may better suit an adolescent lifestyle (SOR: B, based on extrapolation of 1 randomized controlled trial and expert opinion).
Evidence Summary
The subjects of most ADHD medication studies have been school-age children. Most children with ADHD will have symptoms persisting into teenage years, and methylphenidate has been increasingly prescribed for them.1,2 Various systematic reviews and meta-analyses have demonstrated the effectiveness of short-term methylphenidate in the treatment of adolescents with ADHD.3-5 Most participants in these studies are males aged <13 years. Therefore, any conclusions about the effectiveness of methylphenidate in older adolescents must be inferred.
The most comprehensive systematic review found 8 well-controlled crossover trials with an average sample size of 24.8 (range, 9–48).6 The average duration of the studies was 6 weeks. The majority of the participants were white males with a mean age of 13 years. Each study showed statistically significant improvement from treatment with methylphenidate. Average effect sizes were calculated for 3 domains: ADHD symptoms (0.94), social behavior (1.06), and academic performance (1.25). Effect sizes were calculated using a modified Cohen’s d, which is the difference between the treated and untreated means divided by the standard deviation in the untreated condition. It is difficult to translate these changes in effect size into clinically meaningful outcome measures, although one rule of thumb estimates an effect size of 0.8 is moderate to large.
Of the 3 studies that reported the proportion of subjects with clinically significant improvement, the modal result was about one half showings improvement with methylphenidate. Of trials assessing dosing levels, <50% found significant differences between “low” and “high” doses. However, the researchers did not give their definition of low and high doses. Also, diminishing clinical improvement was noted with higher methylphenidate doses.
A single study on the once-daily stimulant preparation, extended-release methylphenidate, shows statistically significant improvement in adolescent ADHD.7 In this multicenter, randomized, double-blind, placebo-controlled trial of 177 adolescents, subjects were given placebo (n=87) or extended-release methylphenidate (n=90) at titrated doses from 18 mg/d to 72 mg/d. Following a subsequent 2-week randomization phase, clinical investigators found extended-release methylphenidate significantly superior to placebo (P=.001) on the ADHD scale. Subjects also rated it significantly superior to placebo (P=.001) on the Conners-Wells’ Self-Report Scale. Mean dose and average age were not reported. This study has been presented as an abstract and is not yet published.
Recommendations from others
The American Academy of Child and Adolescent Psychiatry (AACAP) supports the prescribing of methylphenidate in adolescents with ADHD.8 Given the unique psychosocial, environmental, and scheduling challenges of adolescence, the AACAP mentions extended-release methylphenidate as “well-suited for treatment of adolescents.”
Patients with childhood ADHD usually benefit from continuing their medication
Lisa Johnson, MD
Providence St. Peter’s Family Practice Residency, Olympia, Wash
Adolescents must face the challenge of becoming more organized and independent to be successful in middle school and high school. Those with childhood ADHD may have a particularly difficult transition, and will usually benefit from continuing to take their stimulants. Some adolescents, who were not previously identified as having ADHD, may declare themselves at this age due to school performance issues. Careful evaluation and treatment of these patients will contribute to their success.
Physicians should use the lowest effective dose of methylphenidate, as the studies seem to indicate that higher dosages do not improve performance in adolescents. Teens often prefer long-acting preparations, which obviate the need to take medication at school. The studies reviewed do not define long-term academic or vocational success, which is a more important outcome than symptom control for adolescents.
1. Safer DJ, Zito JM, Fine EM. Increased methylphenidate usage for attention deficit disorder in the 1990s. Pediatrics 1996;98:1084-1088.
2. Fischer M, Barkley RA, Edelbrock CS, Smallish L. The adolescent outcome of hyperactive children diagnosed by research criteria: II. Academic, attentional, and neuropsychological status. J Consult Clin Psychol 1990;58:580-588.
3. Klassen A, Miller A, Raina P, Lee SK, Olsen L. Attention-deficit hyperactivity disorder in children and youth: a quantitative systematic review of the efficacy of different management strategies. Can J Psychiatry 1999;44:1007-1016.
4. Schachar R, Jadad AR, Gauld M, et al. Attention-deficit hyperactivity disorder: critical appraisal of extended treatment studies. Can J Psychiatry 2002;47:337-348.
5. Schachter HM, Pham B, King J, Langford S, Moher D. How efficacious and safe is short-acting methylphenidate for the treatment of attention-deficit disorder in children and adolescents? A meta-analysis. CMAJ 2001;165:1475-1488.
6. Smith BH, Waschbusch DA, Willoughby MT, Evans S. The efficacy, safety, and practicality of treatments for adolescents with attention-deficit/hyperactivity disorder (ADHD). Clin Child Fam Psychol Rev 2000;3:243-267.
7. Greenhill LL. Safety and Efficacy of OROS MPH in Adolescents with ADHD. Program and Abstracts of the American Psychiatric Association, 156th Annual Meeting; Scientific and Clinical Reports. May 17-22, 2003; San Francisco, Calif. Abstract S&CR12-37.
8. Greenhill LL, Pliszka S, Dulcan MK, et al. Practice parameter for the use of stimulant medications in the treatment of children, adolescents, and adults. J Am Acad Child Adolesc Psychiatry 2002;41(2 Suppl):26S-49S.
Methylphenidate (Ritalin) is effective in the short-term treatment of attention deficit/hyperactivity disorder (ADHD) (strength of recommendation [SOR]: A, multiple randomized control trials).
Though the immediate-release preparation is the best studied of methylphenidate formulations, extended-release methylphenidate (Concerta) has similar benefits, with a dosing regimen that may better suit an adolescent lifestyle (SOR: B, based on extrapolation of 1 randomized controlled trial and expert opinion).
Evidence Summary
The subjects of most ADHD medication studies have been school-age children. Most children with ADHD will have symptoms persisting into teenage years, and methylphenidate has been increasingly prescribed for them.1,2 Various systematic reviews and meta-analyses have demonstrated the effectiveness of short-term methylphenidate in the treatment of adolescents with ADHD.3-5 Most participants in these studies are males aged <13 years. Therefore, any conclusions about the effectiveness of methylphenidate in older adolescents must be inferred.
The most comprehensive systematic review found 8 well-controlled crossover trials with an average sample size of 24.8 (range, 9–48).6 The average duration of the studies was 6 weeks. The majority of the participants were white males with a mean age of 13 years. Each study showed statistically significant improvement from treatment with methylphenidate. Average effect sizes were calculated for 3 domains: ADHD symptoms (0.94), social behavior (1.06), and academic performance (1.25). Effect sizes were calculated using a modified Cohen’s d, which is the difference between the treated and untreated means divided by the standard deviation in the untreated condition. It is difficult to translate these changes in effect size into clinically meaningful outcome measures, although one rule of thumb estimates an effect size of 0.8 is moderate to large.
Of the 3 studies that reported the proportion of subjects with clinically significant improvement, the modal result was about one half showings improvement with methylphenidate. Of trials assessing dosing levels, <50% found significant differences between “low” and “high” doses. However, the researchers did not give their definition of low and high doses. Also, diminishing clinical improvement was noted with higher methylphenidate doses.
A single study on the once-daily stimulant preparation, extended-release methylphenidate, shows statistically significant improvement in adolescent ADHD.7 In this multicenter, randomized, double-blind, placebo-controlled trial of 177 adolescents, subjects were given placebo (n=87) or extended-release methylphenidate (n=90) at titrated doses from 18 mg/d to 72 mg/d. Following a subsequent 2-week randomization phase, clinical investigators found extended-release methylphenidate significantly superior to placebo (P=.001) on the ADHD scale. Subjects also rated it significantly superior to placebo (P=.001) on the Conners-Wells’ Self-Report Scale. Mean dose and average age were not reported. This study has been presented as an abstract and is not yet published.
Recommendations from others
The American Academy of Child and Adolescent Psychiatry (AACAP) supports the prescribing of methylphenidate in adolescents with ADHD.8 Given the unique psychosocial, environmental, and scheduling challenges of adolescence, the AACAP mentions extended-release methylphenidate as “well-suited for treatment of adolescents.”
Patients with childhood ADHD usually benefit from continuing their medication
Lisa Johnson, MD
Providence St. Peter’s Family Practice Residency, Olympia, Wash
Adolescents must face the challenge of becoming more organized and independent to be successful in middle school and high school. Those with childhood ADHD may have a particularly difficult transition, and will usually benefit from continuing to take their stimulants. Some adolescents, who were not previously identified as having ADHD, may declare themselves at this age due to school performance issues. Careful evaluation and treatment of these patients will contribute to their success.
Physicians should use the lowest effective dose of methylphenidate, as the studies seem to indicate that higher dosages do not improve performance in adolescents. Teens often prefer long-acting preparations, which obviate the need to take medication at school. The studies reviewed do not define long-term academic or vocational success, which is a more important outcome than symptom control for adolescents.
Methylphenidate (Ritalin) is effective in the short-term treatment of attention deficit/hyperactivity disorder (ADHD) (strength of recommendation [SOR]: A, multiple randomized control trials).
Though the immediate-release preparation is the best studied of methylphenidate formulations, extended-release methylphenidate (Concerta) has similar benefits, with a dosing regimen that may better suit an adolescent lifestyle (SOR: B, based on extrapolation of 1 randomized controlled trial and expert opinion).
Evidence Summary
The subjects of most ADHD medication studies have been school-age children. Most children with ADHD will have symptoms persisting into teenage years, and methylphenidate has been increasingly prescribed for them.1,2 Various systematic reviews and meta-analyses have demonstrated the effectiveness of short-term methylphenidate in the treatment of adolescents with ADHD.3-5 Most participants in these studies are males aged <13 years. Therefore, any conclusions about the effectiveness of methylphenidate in older adolescents must be inferred.
The most comprehensive systematic review found 8 well-controlled crossover trials with an average sample size of 24.8 (range, 9–48).6 The average duration of the studies was 6 weeks. The majority of the participants were white males with a mean age of 13 years. Each study showed statistically significant improvement from treatment with methylphenidate. Average effect sizes were calculated for 3 domains: ADHD symptoms (0.94), social behavior (1.06), and academic performance (1.25). Effect sizes were calculated using a modified Cohen’s d, which is the difference between the treated and untreated means divided by the standard deviation in the untreated condition. It is difficult to translate these changes in effect size into clinically meaningful outcome measures, although one rule of thumb estimates an effect size of 0.8 is moderate to large.
Of the 3 studies that reported the proportion of subjects with clinically significant improvement, the modal result was about one half showings improvement with methylphenidate. Of trials assessing dosing levels, <50% found significant differences between “low” and “high” doses. However, the researchers did not give their definition of low and high doses. Also, diminishing clinical improvement was noted with higher methylphenidate doses.
A single study on the once-daily stimulant preparation, extended-release methylphenidate, shows statistically significant improvement in adolescent ADHD.7 In this multicenter, randomized, double-blind, placebo-controlled trial of 177 adolescents, subjects were given placebo (n=87) or extended-release methylphenidate (n=90) at titrated doses from 18 mg/d to 72 mg/d. Following a subsequent 2-week randomization phase, clinical investigators found extended-release methylphenidate significantly superior to placebo (P=.001) on the ADHD scale. Subjects also rated it significantly superior to placebo (P=.001) on the Conners-Wells’ Self-Report Scale. Mean dose and average age were not reported. This study has been presented as an abstract and is not yet published.
Recommendations from others
The American Academy of Child and Adolescent Psychiatry (AACAP) supports the prescribing of methylphenidate in adolescents with ADHD.8 Given the unique psychosocial, environmental, and scheduling challenges of adolescence, the AACAP mentions extended-release methylphenidate as “well-suited for treatment of adolescents.”
Patients with childhood ADHD usually benefit from continuing their medication
Lisa Johnson, MD
Providence St. Peter’s Family Practice Residency, Olympia, Wash
Adolescents must face the challenge of becoming more organized and independent to be successful in middle school and high school. Those with childhood ADHD may have a particularly difficult transition, and will usually benefit from continuing to take their stimulants. Some adolescents, who were not previously identified as having ADHD, may declare themselves at this age due to school performance issues. Careful evaluation and treatment of these patients will contribute to their success.
Physicians should use the lowest effective dose of methylphenidate, as the studies seem to indicate that higher dosages do not improve performance in adolescents. Teens often prefer long-acting preparations, which obviate the need to take medication at school. The studies reviewed do not define long-term academic or vocational success, which is a more important outcome than symptom control for adolescents.
1. Safer DJ, Zito JM, Fine EM. Increased methylphenidate usage for attention deficit disorder in the 1990s. Pediatrics 1996;98:1084-1088.
2. Fischer M, Barkley RA, Edelbrock CS, Smallish L. The adolescent outcome of hyperactive children diagnosed by research criteria: II. Academic, attentional, and neuropsychological status. J Consult Clin Psychol 1990;58:580-588.
3. Klassen A, Miller A, Raina P, Lee SK, Olsen L. Attention-deficit hyperactivity disorder in children and youth: a quantitative systematic review of the efficacy of different management strategies. Can J Psychiatry 1999;44:1007-1016.
4. Schachar R, Jadad AR, Gauld M, et al. Attention-deficit hyperactivity disorder: critical appraisal of extended treatment studies. Can J Psychiatry 2002;47:337-348.
5. Schachter HM, Pham B, King J, Langford S, Moher D. How efficacious and safe is short-acting methylphenidate for the treatment of attention-deficit disorder in children and adolescents? A meta-analysis. CMAJ 2001;165:1475-1488.
6. Smith BH, Waschbusch DA, Willoughby MT, Evans S. The efficacy, safety, and practicality of treatments for adolescents with attention-deficit/hyperactivity disorder (ADHD). Clin Child Fam Psychol Rev 2000;3:243-267.
7. Greenhill LL. Safety and Efficacy of OROS MPH in Adolescents with ADHD. Program and Abstracts of the American Psychiatric Association, 156th Annual Meeting; Scientific and Clinical Reports. May 17-22, 2003; San Francisco, Calif. Abstract S&CR12-37.
8. Greenhill LL, Pliszka S, Dulcan MK, et al. Practice parameter for the use of stimulant medications in the treatment of children, adolescents, and adults. J Am Acad Child Adolesc Psychiatry 2002;41(2 Suppl):26S-49S.
1. Safer DJ, Zito JM, Fine EM. Increased methylphenidate usage for attention deficit disorder in the 1990s. Pediatrics 1996;98:1084-1088.
2. Fischer M, Barkley RA, Edelbrock CS, Smallish L. The adolescent outcome of hyperactive children diagnosed by research criteria: II. Academic, attentional, and neuropsychological status. J Consult Clin Psychol 1990;58:580-588.
3. Klassen A, Miller A, Raina P, Lee SK, Olsen L. Attention-deficit hyperactivity disorder in children and youth: a quantitative systematic review of the efficacy of different management strategies. Can J Psychiatry 1999;44:1007-1016.
4. Schachar R, Jadad AR, Gauld M, et al. Attention-deficit hyperactivity disorder: critical appraisal of extended treatment studies. Can J Psychiatry 2002;47:337-348.
5. Schachter HM, Pham B, King J, Langford S, Moher D. How efficacious and safe is short-acting methylphenidate for the treatment of attention-deficit disorder in children and adolescents? A meta-analysis. CMAJ 2001;165:1475-1488.
6. Smith BH, Waschbusch DA, Willoughby MT, Evans S. The efficacy, safety, and practicality of treatments for adolescents with attention-deficit/hyperactivity disorder (ADHD). Clin Child Fam Psychol Rev 2000;3:243-267.
7. Greenhill LL. Safety and Efficacy of OROS MPH in Adolescents with ADHD. Program and Abstracts of the American Psychiatric Association, 156th Annual Meeting; Scientific and Clinical Reports. May 17-22, 2003; San Francisco, Calif. Abstract S&CR12-37.
8. Greenhill LL, Pliszka S, Dulcan MK, et al. Practice parameter for the use of stimulant medications in the treatment of children, adolescents, and adults. J Am Acad Child Adolesc Psychiatry 2002;41(2 Suppl):26S-49S.
Evidence-based answers from the Family Physicians Inquiries Network
Should the varicella vaccine be given to all children to prevent chickenpox?
EVIDENCE-BASED ANSWER
Healthy, unimmunized children who have not had varicella infection should be vaccinated (strength of recommendation: A, based on randomized controlled trials). Use of the vaccine in immunocompromised children is still being studied and has not been approved by the Food and Drug Administration (FDA).
Evidence summary
Before the introduction of the varicella vaccine, almost 4 million cases of chickenpox occurred each year in the United States, resulting in 11,000 hospitalizations and 100 deaths.1 Varicella is the leading cause of vaccine-preventable death in children.2
In a search of the literature from 1966 to 2000, a systematic review identified 24 randomized controlled trials and 18 cohort studies of varicella vaccination.3 In children aged 10 months to 14 years, 1 randomized controlled trial found protective efficacy of 100% over 9 months and 98% over 7 years.4 A second trial showed efficacy of 72% over 29 months.5Cohort studies of children report that the vaccine is 84% to 86% effective in preventing varicella and 100% effective in preventing moderate to severe infections.3
Cumulative results of all studies show the number needed to vaccinate to prevent 1 case of varicella ranges from 5.5 to 11.8, and the number needed to prevent 1 complicated case ranges from 550 to 1180.
No direct evidence supports or refutes a reduction in varicella mortality or rates of hospitalization due to vaccination. Randomized controlled trials show no increase in rates of fever or rash among those receiving vaccine; however, cohort studies report fever (0%–36%), local injection site reactions (7%–30%), and rash (5%).3 No clinical trials have shown transmission of vaccine-related varicella zoster virus in immunocompetent patients, and only 3 proven cases of transmission of vaccine virus to susceptible contacts have been documented.6 Some evidence suggests the incidence of herpes zoster is reduced in immunocompromised vaccine recipients, but long-term observation is needed to assess the effect on healthy recipients.7
One concern about the vaccine is that waning immunity over time could result in increased incidence of varicella infection during adulthood. While existing studies document persistence of antibodies for up to 20 years following immunization,3 long-term effectiveness should continue to be monitored.
The FDA has not approved this live-virus vaccine for use in pregnant women and immunocom-promised persons, including transplant recipients and persons receiving corticosteroid therapy. However, the vaccine has been very well-studied in children with leukemia. A review of these studies found that optimal seroconversion requires 2 sequential vaccine doses (86% efficacy). A rash of varying severity was the predominant adverse event in 20% to 50% of vacinees.7 Study of vaccine use in other immunocompromised children has been limited. Early results from a trial in HIV-infected children who were not severely immunocompromised suggests similar tolerance and efficacy compared with children without HIV.8 A systemic review of cost-effectiveness of varicella vaccine is based predominantly on mathematical models.9These models show societal savings due to decrease in unproductive days for parents, but fail to demonstrate actual healthcare savings.
Recommendations from others
The American Academy of Pediatrics (AAP), Advisory Committee on Immunization Practices (ACIP), and American Academy of Family Medicine all recommend vaccinating unimmunized children aged 12 months and older who have not had varicella infection, and not vaccinating children with cellular immunodeficiencies.2,10,11 The AAP suggests the vaccine could be considered for children with acute lymphocytic leukemia and for HIV-infected children with mild or no signs or symptoms. The ACIP guidelines are similar, with the addition that children with impaired humoral immunity may now be vaccinated.
Encourage varicella vaccination, except for the immunocompromised
Kristen Rundell, MD
University of Colorado Health Sciences Center, Denver
For many parents, vaccination decisions are made based on school district requirements. Varicella zoster vaccine is an exception to that rule. Parents can choose to immunize their child at 12 months or wait and let nature take its course—hopefully before the child starts kindergarten. The major concern with the vaccine has been its long-term efficacy. Although no one knows for sure how long immunity is sustained, studies show that detectable antibodies are present for up to 20 years.
As a parent and physician, my decision to vaccinate my daughter was made after I witnessed an 8-year-old boy in the emergency room with respiratory distress secondary to complications from chickenpox. This experience reinforced for me that chickenpox is a life-threatening disease. The effects of chickenpox include scarring as well as time away from work for parents. I therefore encourage varicella vaccination for my patients, with the only exception being those who are immunocompromised, for whom we have no data.
To the question of whether we should we vaccinate children to prevent chickenpox, I give a resounding “yes.”
1. Arvin AM. Varicella vaccine—the first six years. N Engl J Med 2001;344:1007-1009.
2. Centers for Disease Control and Prevention. Prevention of varicella. Update recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recomm Rep 1999;48(RR-6):1-5.
3. Skull SA, Wang EE. Varicella vaccination—a critical review of the evidence. Arch Dis Child 2001;85:83-90.
4. Weibel RE, Neff BJ, Kuter BJ, et al. Live attenuated varicella vaccine. Efficacy trial in healthy children. N Eng J Med 1984;310:1409-1415.
5. Varis T, Vesikari T. Efficacy of high-titer live attenuated varicella vaccine in healthy young children. J Infect Dis 1996;174(suppl 3):S330-S334.
6. Wise RP, Salive ME, Braun MM, et al. Postlicensure safety surveillance for varicella vaccine. JAMA 2000;284:1271-1279.
7. Gershon AA, LaRussa P, Steinberg S. The varicella vaccine. Clinical trials in immunocompromised individuals. Infect Dis Clin North Am 1996;10:583-594.
8. Levin MJ, Gershon AA, Weinberg A, et al. Immunization of HIV-infected children with varicella vaccine. J Pediatr 2001;139:305-310.
9. Rothberg M, Bennish ML, Kao JS, Wong JB. Do the benefits of varicella vaccination outweigh the risks? A decision-analytical model for policymakers and pediatricians. Clin Infect Dis 2002;34:885-894.
10. American. Academy of Family Practice. Periodic Health Examinations. Revision 5.3. Leawood, Kansas: AAFP; 2002.
11. American Academy of Pediatrics. Committee on Infectious Diseases. Varicella vaccine update. Pediatrics 2000;105:136-141.
EVIDENCE-BASED ANSWER
Healthy, unimmunized children who have not had varicella infection should be vaccinated (strength of recommendation: A, based on randomized controlled trials). Use of the vaccine in immunocompromised children is still being studied and has not been approved by the Food and Drug Administration (FDA).
Evidence summary
Before the introduction of the varicella vaccine, almost 4 million cases of chickenpox occurred each year in the United States, resulting in 11,000 hospitalizations and 100 deaths.1 Varicella is the leading cause of vaccine-preventable death in children.2
In a search of the literature from 1966 to 2000, a systematic review identified 24 randomized controlled trials and 18 cohort studies of varicella vaccination.3 In children aged 10 months to 14 years, 1 randomized controlled trial found protective efficacy of 100% over 9 months and 98% over 7 years.4 A second trial showed efficacy of 72% over 29 months.5Cohort studies of children report that the vaccine is 84% to 86% effective in preventing varicella and 100% effective in preventing moderate to severe infections.3
Cumulative results of all studies show the number needed to vaccinate to prevent 1 case of varicella ranges from 5.5 to 11.8, and the number needed to prevent 1 complicated case ranges from 550 to 1180.
No direct evidence supports or refutes a reduction in varicella mortality or rates of hospitalization due to vaccination. Randomized controlled trials show no increase in rates of fever or rash among those receiving vaccine; however, cohort studies report fever (0%–36%), local injection site reactions (7%–30%), and rash (5%).3 No clinical trials have shown transmission of vaccine-related varicella zoster virus in immunocompetent patients, and only 3 proven cases of transmission of vaccine virus to susceptible contacts have been documented.6 Some evidence suggests the incidence of herpes zoster is reduced in immunocompromised vaccine recipients, but long-term observation is needed to assess the effect on healthy recipients.7
One concern about the vaccine is that waning immunity over time could result in increased incidence of varicella infection during adulthood. While existing studies document persistence of antibodies for up to 20 years following immunization,3 long-term effectiveness should continue to be monitored.
The FDA has not approved this live-virus vaccine for use in pregnant women and immunocom-promised persons, including transplant recipients and persons receiving corticosteroid therapy. However, the vaccine has been very well-studied in children with leukemia. A review of these studies found that optimal seroconversion requires 2 sequential vaccine doses (86% efficacy). A rash of varying severity was the predominant adverse event in 20% to 50% of vacinees.7 Study of vaccine use in other immunocompromised children has been limited. Early results from a trial in HIV-infected children who were not severely immunocompromised suggests similar tolerance and efficacy compared with children without HIV.8 A systemic review of cost-effectiveness of varicella vaccine is based predominantly on mathematical models.9These models show societal savings due to decrease in unproductive days for parents, but fail to demonstrate actual healthcare savings.
Recommendations from others
The American Academy of Pediatrics (AAP), Advisory Committee on Immunization Practices (ACIP), and American Academy of Family Medicine all recommend vaccinating unimmunized children aged 12 months and older who have not had varicella infection, and not vaccinating children with cellular immunodeficiencies.2,10,11 The AAP suggests the vaccine could be considered for children with acute lymphocytic leukemia and for HIV-infected children with mild or no signs or symptoms. The ACIP guidelines are similar, with the addition that children with impaired humoral immunity may now be vaccinated.
Encourage varicella vaccination, except for the immunocompromised
Kristen Rundell, MD
University of Colorado Health Sciences Center, Denver
For many parents, vaccination decisions are made based on school district requirements. Varicella zoster vaccine is an exception to that rule. Parents can choose to immunize their child at 12 months or wait and let nature take its course—hopefully before the child starts kindergarten. The major concern with the vaccine has been its long-term efficacy. Although no one knows for sure how long immunity is sustained, studies show that detectable antibodies are present for up to 20 years.
As a parent and physician, my decision to vaccinate my daughter was made after I witnessed an 8-year-old boy in the emergency room with respiratory distress secondary to complications from chickenpox. This experience reinforced for me that chickenpox is a life-threatening disease. The effects of chickenpox include scarring as well as time away from work for parents. I therefore encourage varicella vaccination for my patients, with the only exception being those who are immunocompromised, for whom we have no data.
To the question of whether we should we vaccinate children to prevent chickenpox, I give a resounding “yes.”
EVIDENCE-BASED ANSWER
Healthy, unimmunized children who have not had varicella infection should be vaccinated (strength of recommendation: A, based on randomized controlled trials). Use of the vaccine in immunocompromised children is still being studied and has not been approved by the Food and Drug Administration (FDA).
Evidence summary
Before the introduction of the varicella vaccine, almost 4 million cases of chickenpox occurred each year in the United States, resulting in 11,000 hospitalizations and 100 deaths.1 Varicella is the leading cause of vaccine-preventable death in children.2
In a search of the literature from 1966 to 2000, a systematic review identified 24 randomized controlled trials and 18 cohort studies of varicella vaccination.3 In children aged 10 months to 14 years, 1 randomized controlled trial found protective efficacy of 100% over 9 months and 98% over 7 years.4 A second trial showed efficacy of 72% over 29 months.5Cohort studies of children report that the vaccine is 84% to 86% effective in preventing varicella and 100% effective in preventing moderate to severe infections.3
Cumulative results of all studies show the number needed to vaccinate to prevent 1 case of varicella ranges from 5.5 to 11.8, and the number needed to prevent 1 complicated case ranges from 550 to 1180.
No direct evidence supports or refutes a reduction in varicella mortality or rates of hospitalization due to vaccination. Randomized controlled trials show no increase in rates of fever or rash among those receiving vaccine; however, cohort studies report fever (0%–36%), local injection site reactions (7%–30%), and rash (5%).3 No clinical trials have shown transmission of vaccine-related varicella zoster virus in immunocompetent patients, and only 3 proven cases of transmission of vaccine virus to susceptible contacts have been documented.6 Some evidence suggests the incidence of herpes zoster is reduced in immunocompromised vaccine recipients, but long-term observation is needed to assess the effect on healthy recipients.7
One concern about the vaccine is that waning immunity over time could result in increased incidence of varicella infection during adulthood. While existing studies document persistence of antibodies for up to 20 years following immunization,3 long-term effectiveness should continue to be monitored.
The FDA has not approved this live-virus vaccine for use in pregnant women and immunocom-promised persons, including transplant recipients and persons receiving corticosteroid therapy. However, the vaccine has been very well-studied in children with leukemia. A review of these studies found that optimal seroconversion requires 2 sequential vaccine doses (86% efficacy). A rash of varying severity was the predominant adverse event in 20% to 50% of vacinees.7 Study of vaccine use in other immunocompromised children has been limited. Early results from a trial in HIV-infected children who were not severely immunocompromised suggests similar tolerance and efficacy compared with children without HIV.8 A systemic review of cost-effectiveness of varicella vaccine is based predominantly on mathematical models.9These models show societal savings due to decrease in unproductive days for parents, but fail to demonstrate actual healthcare savings.
Recommendations from others
The American Academy of Pediatrics (AAP), Advisory Committee on Immunization Practices (ACIP), and American Academy of Family Medicine all recommend vaccinating unimmunized children aged 12 months and older who have not had varicella infection, and not vaccinating children with cellular immunodeficiencies.2,10,11 The AAP suggests the vaccine could be considered for children with acute lymphocytic leukemia and for HIV-infected children with mild or no signs or symptoms. The ACIP guidelines are similar, with the addition that children with impaired humoral immunity may now be vaccinated.
Encourage varicella vaccination, except for the immunocompromised
Kristen Rundell, MD
University of Colorado Health Sciences Center, Denver
For many parents, vaccination decisions are made based on school district requirements. Varicella zoster vaccine is an exception to that rule. Parents can choose to immunize their child at 12 months or wait and let nature take its course—hopefully before the child starts kindergarten. The major concern with the vaccine has been its long-term efficacy. Although no one knows for sure how long immunity is sustained, studies show that detectable antibodies are present for up to 20 years.
As a parent and physician, my decision to vaccinate my daughter was made after I witnessed an 8-year-old boy in the emergency room with respiratory distress secondary to complications from chickenpox. This experience reinforced for me that chickenpox is a life-threatening disease. The effects of chickenpox include scarring as well as time away from work for parents. I therefore encourage varicella vaccination for my patients, with the only exception being those who are immunocompromised, for whom we have no data.
To the question of whether we should we vaccinate children to prevent chickenpox, I give a resounding “yes.”
1. Arvin AM. Varicella vaccine—the first six years. N Engl J Med 2001;344:1007-1009.
2. Centers for Disease Control and Prevention. Prevention of varicella. Update recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recomm Rep 1999;48(RR-6):1-5.
3. Skull SA, Wang EE. Varicella vaccination—a critical review of the evidence. Arch Dis Child 2001;85:83-90.
4. Weibel RE, Neff BJ, Kuter BJ, et al. Live attenuated varicella vaccine. Efficacy trial in healthy children. N Eng J Med 1984;310:1409-1415.
5. Varis T, Vesikari T. Efficacy of high-titer live attenuated varicella vaccine in healthy young children. J Infect Dis 1996;174(suppl 3):S330-S334.
6. Wise RP, Salive ME, Braun MM, et al. Postlicensure safety surveillance for varicella vaccine. JAMA 2000;284:1271-1279.
7. Gershon AA, LaRussa P, Steinberg S. The varicella vaccine. Clinical trials in immunocompromised individuals. Infect Dis Clin North Am 1996;10:583-594.
8. Levin MJ, Gershon AA, Weinberg A, et al. Immunization of HIV-infected children with varicella vaccine. J Pediatr 2001;139:305-310.
9. Rothberg M, Bennish ML, Kao JS, Wong JB. Do the benefits of varicella vaccination outweigh the risks? A decision-analytical model for policymakers and pediatricians. Clin Infect Dis 2002;34:885-894.
10. American. Academy of Family Practice. Periodic Health Examinations. Revision 5.3. Leawood, Kansas: AAFP; 2002.
11. American Academy of Pediatrics. Committee on Infectious Diseases. Varicella vaccine update. Pediatrics 2000;105:136-141.
1. Arvin AM. Varicella vaccine—the first six years. N Engl J Med 2001;344:1007-1009.
2. Centers for Disease Control and Prevention. Prevention of varicella. Update recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recomm Rep 1999;48(RR-6):1-5.
3. Skull SA, Wang EE. Varicella vaccination—a critical review of the evidence. Arch Dis Child 2001;85:83-90.
4. Weibel RE, Neff BJ, Kuter BJ, et al. Live attenuated varicella vaccine. Efficacy trial in healthy children. N Eng J Med 1984;310:1409-1415.
5. Varis T, Vesikari T. Efficacy of high-titer live attenuated varicella vaccine in healthy young children. J Infect Dis 1996;174(suppl 3):S330-S334.
6. Wise RP, Salive ME, Braun MM, et al. Postlicensure safety surveillance for varicella vaccine. JAMA 2000;284:1271-1279.
7. Gershon AA, LaRussa P, Steinberg S. The varicella vaccine. Clinical trials in immunocompromised individuals. Infect Dis Clin North Am 1996;10:583-594.
8. Levin MJ, Gershon AA, Weinberg A, et al. Immunization of HIV-infected children with varicella vaccine. J Pediatr 2001;139:305-310.
9. Rothberg M, Bennish ML, Kao JS, Wong JB. Do the benefits of varicella vaccination outweigh the risks? A decision-analytical model for policymakers and pediatricians. Clin Infect Dis 2002;34:885-894.
10. American. Academy of Family Practice. Periodic Health Examinations. Revision 5.3. Leawood, Kansas: AAFP; 2002.
11. American Academy of Pediatrics. Committee on Infectious Diseases. Varicella vaccine update. Pediatrics 2000;105:136-141.
Evidence-based answers from the Family Physicians Inquiries Network
Which blood tests are most helpful in evaluating pelvic inflammatory disease?
No individual or combination of blood tests can reliably diagnose pelvic inflammatory disease (PID) (strength of recommendation [SOR]: A, meta-analysis). The combination of white blood cell count, Creactive protein (CRP), erythrocyte sedimentation rate (ESR), and vaginal white blood cells can reliably exclude PID if results for all 4 tests are normal (sensitivity=100%) (SOR: B, cohort study, reference standard not uniformly applied).
The combination of CRP and ESR is helpful in excluding PID (sensitivity=91%) and may be especially useful in distinguishing mild from complicated cases (SOR: B, small cohort study). Individual tests do not appear to significantly improve diagnostic accuracy, although the CRP and ESR are somewhat useful to rule out PID (SOR: B, small cohort study).
Evidence summary
Because of the significant inflammatory sequelae of PID, it is the standard of care to treat women with suggestive signs and symptoms. Clinical diagnosis has a positive predictive value of 65% to 90% compared with laparoscopy.1 While no single test is both sensitive and specific, a combination of biochemical tests for inflammation may improve the ability to rule out PID.
A prospective cohort study of 120 women presenting to an ambulatory center with symptoms of PID evaluated the tests commonly used to support the clinical diagnosis of PID.2 The objective criteria used for diagnosis included histologic evidence of acute endometritis via endometrial biopsy, purulent exudates in the pelvis on laparoscopy, or microbiologic evidence of Neisseris gonorrhea or Chlamydia trachomatis from the upper genital tract. The Table shows the sensitivities, specificities, and predictive values for an elevated white blood cells (>10,000/mm), ESR (>15 mm/hr), CRP (>5 mg/dL), and increased vaginal white blood cells (>3 white blood cells/high-power field) for detection of PID. If all 4 test results are negative, PID is reliably ruled out with a sensitivity of 100%. These results may be an overestimate, as the gold standard was not uniformly applied.
The role of CRP and ESR in the diagnosis of acute PID was studied in 41 women with clinically suspected acute PID who presented to a university department of obstetrics and gynecology.3 Women underwent laparoscopy, endometrial sampling, and cultures of the upper genital tract to confirm the diagnosis. When considered together, a positive value in either the ESR (cutoff level of 15 mm/hr) or CRP (cutoff >20 mg/dL) had a sensitivity of 91% and a specificity of 50%.
Another report looked at the ability of ESR and CRP to differentiate between mild, moderate, and severe PID in 72 women undergoing laparoscopy at a university department of gynecology.4 The cutoff levels were ESR >40 mm/hr and CRP >60 mg/dL. If either test was abnormal, the sensitivity and the negative predictive value for severe disease were 97% and 96%, respectively ( Table). All patients with tuboovarian abscess or perihepatitis and 6 of 7 patients who had anaerobic bacteria isolated from the fallopian tubes tested positive with these cutoff levels.
A meta-analysis from 1991 found 12 studies, not including any of the above studies, and assessed the laboratory criteria for the diagnosis of PID. No single or combination diagnostic indicator was found to reliably predict PID. However, the CRP and the ESR were useful in ruling out PID, with good sensitivities for CRP in 4 of 4 studies analyzed (74%–93%) and for the ESR in 4 of 6 studies (64%–81%). Ten of 12 studies used laparoscopy as the gold standard.5
TABLE
Diagnostic performance of blood tests for pelvic inflammatory disease
| Sn (%) | Sp (%) | PPV (%)* | NPV (%)* | |
|---|---|---|---|---|
| WBC (>10,000/mm 3)2 | 57 | 88 | 88 | 58 |
| ESR (>15 mm/hr) 2 | 70 | 52 | 69 | 54 |
| CRP (>5 mg/dL) 2 | 71 | 66 | 76 | 60 |
| Vaginal WBCs 2 | 78 | 39 | 66 | 54 |
| 0 of 4 of the above positive 2 | 100 | 18 | 100 | 65 |
| 4 of 4 of the above positive 2 | 29 | 95 | 90 | 47 |
| CRP >20 or ESR >15 3 | 91 | 50 | N/A | N/A |
| CRP >60 or ESR >40 4 | 97 | 61 | 70 | 96 |
| CRP (metaanalysis)5 | 74%–93% | 50%–90% | ||
| ESR (metaanalysis)5 | 64%–81% | 43%–69% | ||
| *Prevalence=60%. SN, sensitivity; Sp, specificity; PPV, positive predictive value; NPV, negative predictive value; WBC, white blood cells; ESR, erythrocyte sedimentation rate; CRP, C-reactive protein. | ||||
Recommendations from others
The Centers for Disease Control and Prevention makes no specific recommendation for the use of specific blood tests in the diagnosis of PID.1 The Association for Genitourinary Medicine states that an elevated ESR or CRP supports the diagnosis of PID.6
When diagnosing PID, a clinician must have a high index of suspicion
Ellen Beck, MD
University of California– San Diego
PID is a difficult diagnosis to make, without clear-cut diagnostic guideposts. The sequelae of PID can be so serious that clinicians must not miss this diagnosis. If results of all 4 tests described above are negative, this can reliably rule out the diagnosis.
Unfortunately, no set of tests can reliably confirm the diagnosis in all cases. The traditional triad of lower abdominal pain, cervical motion tenderness, and adnexal pain are still taught as the classic findings for diagnosing PID. The clinician must also have a high index of suspicion, particularly with teen-agers with abdominal pain, and when the pain is indolent and lingering.
Nonetheless, a recent study concludes there is insufficient evidence to support existing clinical diagnostic criteria and recommends that the clinical criteria for PID be redefined. In a group of patients with laparoscopically confirmed PID, no variable (abnormal vaginal discharge, fever >38°C, vomiting, menstrual irregularity, ongoing bleeding, symptoms of urethritis, rectal temperature >38°C, marked tenderness of pelvic organs on bimanual examination, adnexal mass, and ESR >15 mm) reliably predicted the disease, and found, rather, that most had low specificity and sensitivity. The chance of having PID based on the presence of lower abdominal pain was 79%. Three variables predicted 65% of the cases of PID: elevated ESR, fever, and adnexal tenderness. When evaluating patients for admission, some authors add “the desire to bear children” to the standard admission criteria, which include severity of sickness, pregnancy, possible need for surgical intervention, lack of response to oral medications, or immunosuppression.
1. Sexually transmitted diseases treatment guidelines. MMWR Recomm Rep 2002;51(RR-6):48-52.
2. Peipert JF, Boardman L, Hogan JW, Sung J, Mayer KH. Laboratory evaluation of acute upper genital tract infection. Obstet Gynecol 1996;87:730-736.
3. Lehtinen M, Laine S, Heinonen PK, et al. Serum C-reactive protein determination in acute pelvic inflammatory disease. Am J Obstet Gynecol 1986;154:158-159.
4. Miettinen AK, Heinonen PK, Laippala P, Paavonen J. Test performance of erythrocyte sedimentation rate and C-reactive protein in assessing the severity of acute pelvic inflammatory disease. Am J Obstet Gynecol 1993;169:1143-1149.
5. Kahn JG, Walker CK, Washington AE, Landers DV, Sweet RL. Diagnosing pelvic inflammatory disease. A comprehensive analysis and considerations for developing a new model. JAMA 1991;266:2594-2604.
6. 2002 Guidelines for the management of pelvic infection and perihepatitis. London: Association for Genitourinary Medicine (AGUM); Medical Society for the Study of Venereal Disease (MSSVD); 2002. Available at: www.agum.org.uk/ceg2002/pid0601.htm. Accessed on March 5, 2004.
No individual or combination of blood tests can reliably diagnose pelvic inflammatory disease (PID) (strength of recommendation [SOR]: A, meta-analysis). The combination of white blood cell count, Creactive protein (CRP), erythrocyte sedimentation rate (ESR), and vaginal white blood cells can reliably exclude PID if results for all 4 tests are normal (sensitivity=100%) (SOR: B, cohort study, reference standard not uniformly applied).
The combination of CRP and ESR is helpful in excluding PID (sensitivity=91%) and may be especially useful in distinguishing mild from complicated cases (SOR: B, small cohort study). Individual tests do not appear to significantly improve diagnostic accuracy, although the CRP and ESR are somewhat useful to rule out PID (SOR: B, small cohort study).
Evidence summary
Because of the significant inflammatory sequelae of PID, it is the standard of care to treat women with suggestive signs and symptoms. Clinical diagnosis has a positive predictive value of 65% to 90% compared with laparoscopy.1 While no single test is both sensitive and specific, a combination of biochemical tests for inflammation may improve the ability to rule out PID.
A prospective cohort study of 120 women presenting to an ambulatory center with symptoms of PID evaluated the tests commonly used to support the clinical diagnosis of PID.2 The objective criteria used for diagnosis included histologic evidence of acute endometritis via endometrial biopsy, purulent exudates in the pelvis on laparoscopy, or microbiologic evidence of Neisseris gonorrhea or Chlamydia trachomatis from the upper genital tract. The Table shows the sensitivities, specificities, and predictive values for an elevated white blood cells (>10,000/mm), ESR (>15 mm/hr), CRP (>5 mg/dL), and increased vaginal white blood cells (>3 white blood cells/high-power field) for detection of PID. If all 4 test results are negative, PID is reliably ruled out with a sensitivity of 100%. These results may be an overestimate, as the gold standard was not uniformly applied.
The role of CRP and ESR in the diagnosis of acute PID was studied in 41 women with clinically suspected acute PID who presented to a university department of obstetrics and gynecology.3 Women underwent laparoscopy, endometrial sampling, and cultures of the upper genital tract to confirm the diagnosis. When considered together, a positive value in either the ESR (cutoff level of 15 mm/hr) or CRP (cutoff >20 mg/dL) had a sensitivity of 91% and a specificity of 50%.
Another report looked at the ability of ESR and CRP to differentiate between mild, moderate, and severe PID in 72 women undergoing laparoscopy at a university department of gynecology.4 The cutoff levels were ESR >40 mm/hr and CRP >60 mg/dL. If either test was abnormal, the sensitivity and the negative predictive value for severe disease were 97% and 96%, respectively ( Table). All patients with tuboovarian abscess or perihepatitis and 6 of 7 patients who had anaerobic bacteria isolated from the fallopian tubes tested positive with these cutoff levels.
A meta-analysis from 1991 found 12 studies, not including any of the above studies, and assessed the laboratory criteria for the diagnosis of PID. No single or combination diagnostic indicator was found to reliably predict PID. However, the CRP and the ESR were useful in ruling out PID, with good sensitivities for CRP in 4 of 4 studies analyzed (74%–93%) and for the ESR in 4 of 6 studies (64%–81%). Ten of 12 studies used laparoscopy as the gold standard.5
TABLE
Diagnostic performance of blood tests for pelvic inflammatory disease
| Sn (%) | Sp (%) | PPV (%)* | NPV (%)* | |
|---|---|---|---|---|
| WBC (>10,000/mm 3)2 | 57 | 88 | 88 | 58 |
| ESR (>15 mm/hr) 2 | 70 | 52 | 69 | 54 |
| CRP (>5 mg/dL) 2 | 71 | 66 | 76 | 60 |
| Vaginal WBCs 2 | 78 | 39 | 66 | 54 |
| 0 of 4 of the above positive 2 | 100 | 18 | 100 | 65 |
| 4 of 4 of the above positive 2 | 29 | 95 | 90 | 47 |
| CRP >20 or ESR >15 3 | 91 | 50 | N/A | N/A |
| CRP >60 or ESR >40 4 | 97 | 61 | 70 | 96 |
| CRP (metaanalysis)5 | 74%–93% | 50%–90% | ||
| ESR (metaanalysis)5 | 64%–81% | 43%–69% | ||
| *Prevalence=60%. SN, sensitivity; Sp, specificity; PPV, positive predictive value; NPV, negative predictive value; WBC, white blood cells; ESR, erythrocyte sedimentation rate; CRP, C-reactive protein. | ||||
Recommendations from others
The Centers for Disease Control and Prevention makes no specific recommendation for the use of specific blood tests in the diagnosis of PID.1 The Association for Genitourinary Medicine states that an elevated ESR or CRP supports the diagnosis of PID.6
When diagnosing PID, a clinician must have a high index of suspicion
Ellen Beck, MD
University of California– San Diego
PID is a difficult diagnosis to make, without clear-cut diagnostic guideposts. The sequelae of PID can be so serious that clinicians must not miss this diagnosis. If results of all 4 tests described above are negative, this can reliably rule out the diagnosis.
Unfortunately, no set of tests can reliably confirm the diagnosis in all cases. The traditional triad of lower abdominal pain, cervical motion tenderness, and adnexal pain are still taught as the classic findings for diagnosing PID. The clinician must also have a high index of suspicion, particularly with teen-agers with abdominal pain, and when the pain is indolent and lingering.
Nonetheless, a recent study concludes there is insufficient evidence to support existing clinical diagnostic criteria and recommends that the clinical criteria for PID be redefined. In a group of patients with laparoscopically confirmed PID, no variable (abnormal vaginal discharge, fever >38°C, vomiting, menstrual irregularity, ongoing bleeding, symptoms of urethritis, rectal temperature >38°C, marked tenderness of pelvic organs on bimanual examination, adnexal mass, and ESR >15 mm) reliably predicted the disease, and found, rather, that most had low specificity and sensitivity. The chance of having PID based on the presence of lower abdominal pain was 79%. Three variables predicted 65% of the cases of PID: elevated ESR, fever, and adnexal tenderness. When evaluating patients for admission, some authors add “the desire to bear children” to the standard admission criteria, which include severity of sickness, pregnancy, possible need for surgical intervention, lack of response to oral medications, or immunosuppression.
No individual or combination of blood tests can reliably diagnose pelvic inflammatory disease (PID) (strength of recommendation [SOR]: A, meta-analysis). The combination of white blood cell count, Creactive protein (CRP), erythrocyte sedimentation rate (ESR), and vaginal white blood cells can reliably exclude PID if results for all 4 tests are normal (sensitivity=100%) (SOR: B, cohort study, reference standard not uniformly applied).
The combination of CRP and ESR is helpful in excluding PID (sensitivity=91%) and may be especially useful in distinguishing mild from complicated cases (SOR: B, small cohort study). Individual tests do not appear to significantly improve diagnostic accuracy, although the CRP and ESR are somewhat useful to rule out PID (SOR: B, small cohort study).
Evidence summary
Because of the significant inflammatory sequelae of PID, it is the standard of care to treat women with suggestive signs and symptoms. Clinical diagnosis has a positive predictive value of 65% to 90% compared with laparoscopy.1 While no single test is both sensitive and specific, a combination of biochemical tests for inflammation may improve the ability to rule out PID.
A prospective cohort study of 120 women presenting to an ambulatory center with symptoms of PID evaluated the tests commonly used to support the clinical diagnosis of PID.2 The objective criteria used for diagnosis included histologic evidence of acute endometritis via endometrial biopsy, purulent exudates in the pelvis on laparoscopy, or microbiologic evidence of Neisseris gonorrhea or Chlamydia trachomatis from the upper genital tract. The Table shows the sensitivities, specificities, and predictive values for an elevated white blood cells (>10,000/mm), ESR (>15 mm/hr), CRP (>5 mg/dL), and increased vaginal white blood cells (>3 white blood cells/high-power field) for detection of PID. If all 4 test results are negative, PID is reliably ruled out with a sensitivity of 100%. These results may be an overestimate, as the gold standard was not uniformly applied.
The role of CRP and ESR in the diagnosis of acute PID was studied in 41 women with clinically suspected acute PID who presented to a university department of obstetrics and gynecology.3 Women underwent laparoscopy, endometrial sampling, and cultures of the upper genital tract to confirm the diagnosis. When considered together, a positive value in either the ESR (cutoff level of 15 mm/hr) or CRP (cutoff >20 mg/dL) had a sensitivity of 91% and a specificity of 50%.
Another report looked at the ability of ESR and CRP to differentiate between mild, moderate, and severe PID in 72 women undergoing laparoscopy at a university department of gynecology.4 The cutoff levels were ESR >40 mm/hr and CRP >60 mg/dL. If either test was abnormal, the sensitivity and the negative predictive value for severe disease were 97% and 96%, respectively ( Table). All patients with tuboovarian abscess or perihepatitis and 6 of 7 patients who had anaerobic bacteria isolated from the fallopian tubes tested positive with these cutoff levels.
A meta-analysis from 1991 found 12 studies, not including any of the above studies, and assessed the laboratory criteria for the diagnosis of PID. No single or combination diagnostic indicator was found to reliably predict PID. However, the CRP and the ESR were useful in ruling out PID, with good sensitivities for CRP in 4 of 4 studies analyzed (74%–93%) and for the ESR in 4 of 6 studies (64%–81%). Ten of 12 studies used laparoscopy as the gold standard.5
TABLE
Diagnostic performance of blood tests for pelvic inflammatory disease
| Sn (%) | Sp (%) | PPV (%)* | NPV (%)* | |
|---|---|---|---|---|
| WBC (>10,000/mm 3)2 | 57 | 88 | 88 | 58 |
| ESR (>15 mm/hr) 2 | 70 | 52 | 69 | 54 |
| CRP (>5 mg/dL) 2 | 71 | 66 | 76 | 60 |
| Vaginal WBCs 2 | 78 | 39 | 66 | 54 |
| 0 of 4 of the above positive 2 | 100 | 18 | 100 | 65 |
| 4 of 4 of the above positive 2 | 29 | 95 | 90 | 47 |
| CRP >20 or ESR >15 3 | 91 | 50 | N/A | N/A |
| CRP >60 or ESR >40 4 | 97 | 61 | 70 | 96 |
| CRP (metaanalysis)5 | 74%–93% | 50%–90% | ||
| ESR (metaanalysis)5 | 64%–81% | 43%–69% | ||
| *Prevalence=60%. SN, sensitivity; Sp, specificity; PPV, positive predictive value; NPV, negative predictive value; WBC, white blood cells; ESR, erythrocyte sedimentation rate; CRP, C-reactive protein. | ||||
Recommendations from others
The Centers for Disease Control and Prevention makes no specific recommendation for the use of specific blood tests in the diagnosis of PID.1 The Association for Genitourinary Medicine states that an elevated ESR or CRP supports the diagnosis of PID.6
When diagnosing PID, a clinician must have a high index of suspicion
Ellen Beck, MD
University of California– San Diego
PID is a difficult diagnosis to make, without clear-cut diagnostic guideposts. The sequelae of PID can be so serious that clinicians must not miss this diagnosis. If results of all 4 tests described above are negative, this can reliably rule out the diagnosis.
Unfortunately, no set of tests can reliably confirm the diagnosis in all cases. The traditional triad of lower abdominal pain, cervical motion tenderness, and adnexal pain are still taught as the classic findings for diagnosing PID. The clinician must also have a high index of suspicion, particularly with teen-agers with abdominal pain, and when the pain is indolent and lingering.
Nonetheless, a recent study concludes there is insufficient evidence to support existing clinical diagnostic criteria and recommends that the clinical criteria for PID be redefined. In a group of patients with laparoscopically confirmed PID, no variable (abnormal vaginal discharge, fever >38°C, vomiting, menstrual irregularity, ongoing bleeding, symptoms of urethritis, rectal temperature >38°C, marked tenderness of pelvic organs on bimanual examination, adnexal mass, and ESR >15 mm) reliably predicted the disease, and found, rather, that most had low specificity and sensitivity. The chance of having PID based on the presence of lower abdominal pain was 79%. Three variables predicted 65% of the cases of PID: elevated ESR, fever, and adnexal tenderness. When evaluating patients for admission, some authors add “the desire to bear children” to the standard admission criteria, which include severity of sickness, pregnancy, possible need for surgical intervention, lack of response to oral medications, or immunosuppression.
1. Sexually transmitted diseases treatment guidelines. MMWR Recomm Rep 2002;51(RR-6):48-52.
2. Peipert JF, Boardman L, Hogan JW, Sung J, Mayer KH. Laboratory evaluation of acute upper genital tract infection. Obstet Gynecol 1996;87:730-736.
3. Lehtinen M, Laine S, Heinonen PK, et al. Serum C-reactive protein determination in acute pelvic inflammatory disease. Am J Obstet Gynecol 1986;154:158-159.
4. Miettinen AK, Heinonen PK, Laippala P, Paavonen J. Test performance of erythrocyte sedimentation rate and C-reactive protein in assessing the severity of acute pelvic inflammatory disease. Am J Obstet Gynecol 1993;169:1143-1149.
5. Kahn JG, Walker CK, Washington AE, Landers DV, Sweet RL. Diagnosing pelvic inflammatory disease. A comprehensive analysis and considerations for developing a new model. JAMA 1991;266:2594-2604.
6. 2002 Guidelines for the management of pelvic infection and perihepatitis. London: Association for Genitourinary Medicine (AGUM); Medical Society for the Study of Venereal Disease (MSSVD); 2002. Available at: www.agum.org.uk/ceg2002/pid0601.htm. Accessed on March 5, 2004.
1. Sexually transmitted diseases treatment guidelines. MMWR Recomm Rep 2002;51(RR-6):48-52.
2. Peipert JF, Boardman L, Hogan JW, Sung J, Mayer KH. Laboratory evaluation of acute upper genital tract infection. Obstet Gynecol 1996;87:730-736.
3. Lehtinen M, Laine S, Heinonen PK, et al. Serum C-reactive protein determination in acute pelvic inflammatory disease. Am J Obstet Gynecol 1986;154:158-159.
4. Miettinen AK, Heinonen PK, Laippala P, Paavonen J. Test performance of erythrocyte sedimentation rate and C-reactive protein in assessing the severity of acute pelvic inflammatory disease. Am J Obstet Gynecol 1993;169:1143-1149.
5. Kahn JG, Walker CK, Washington AE, Landers DV, Sweet RL. Diagnosing pelvic inflammatory disease. A comprehensive analysis and considerations for developing a new model. JAMA 1991;266:2594-2604.
6. 2002 Guidelines for the management of pelvic infection and perihepatitis. London: Association for Genitourinary Medicine (AGUM); Medical Society for the Study of Venereal Disease (MSSVD); 2002. Available at: www.agum.org.uk/ceg2002/pid0601.htm. Accessed on March 5, 2004.
Evidence-based answers from the Family Physicians Inquiries Network
Does stimulant therapy help adult ADHD?
Central nervous system stimulants improve symptoms of attention deficit–hyperactivity disorder (ADHD) in adults (strength of recommendation: B, based on an older, inconclusive systematic review, a lesser-quality systematic review, and several newer small randomized controlled trials).
Although not the focus of this question, nonstimulant medications (including buproprion, modafinil, and guanfacine) have also been studied in the treatment of ADHD in adults. Recently, atomoxetine became the only nonstimulant medication to receive approval by the US Food and Drug Administration for the treatment of ADHD.
Evidence summary
A well-done systematic review of 12 trials assessing the efficacy of stimulant therapy in the treatment of adult ADHD did not find sufficient evidence that stimulants were effective.1 Significant heterogeneity and poor reporting of methodology was seen among the studies.
The 1 study rated as high-quality was a 7-week randomized controlled trial using a crossover comparison of methylphenidate and placebo.2 There was a favorable response in 78% (18/23) of subjects while takin methylphenidate, in contrast to 4% (1/23) while taking placebo (number needed to treat [NNT]=1.4; P<.0001). A favorable response was assessed by the Clinical Global Impression Scale, a measure of illness severity and improvement, and a >30% reduction in symptoms as measured by the ADHD Rating Scale. A more recent, but less rigorous, systematic review identified 15 studies of stimulant efficacy in adults.3 Researchers concluded that under controlled conditions, stimulants are efficacious in the treatment of ADHD in adults. The rate of response among the studies ranged from 25% to 78%.
One of the better studies in this review was a randomized, double-blind, 3-phase crossover study of dextroamphetamine, modafinil (a drug used to treat narcolepsy), and placebo.4 Each phase was 2 weeks long, with a 4-day washout in between. A favorable response was defined as a reduction of ADHD symptoms by at least 30% on the DSM-IV ADHD Behavior Checklist for Adults. Dextroamphetamine and modafinil showed the same response rate in 10 of 21 patients. Both treatments had a significant improvement over placebo (P<.001). It was unclear from the study what percentage of subjects responded to placebo.
A similar study compared dextroamphetamine, guanfacine (an antihypertensive agent), and placebo in 17 patients.5 On the DSM-IV ADHD Behavior Checklist for Adults, subjects taking dextroamphetamine or guanfacine reported similar decreases in mean ADHD scores compared with placebo (24 vs 22 vs 30; P<.05). They did not report the number of subjects who had a 30% reduction in symptoms. Of note: at the end of the study but prior to unblinding, subjects were asked which medication they preferred. Twelve subjects chose dextroamphetamine, 4 chose guanfacine, and 1 chose placebo. Subjects’ stated reason for choosing dextroamphetamine was the positive effect it had on their motivation.
Another study included in this review was a randomized controlled trial of mixed amphetamine salts. Of the 27 adults who completed the study, 19 (70%) responded favorably to mixed amphetamine salts compared with 2 (7.4%) receiving placebo (NNT=1.6; P<.001).6 Favorable response was defined as more than a 30% reduction of symptoms on the ADHD Rating Scale. Not included in either review was a 7-week randomized controlled trial comparing methylphenidate with sustained-release buproprion.7 Thirty out of 37 subjects completed at least 1 week of the study. The primary indicator of a favorable response was the Clinical Global Impression Scale. The rate of response was 50% for methylphenidate, 64% for sustained-release buproprion, and 27% for placebo (P<.14).
Recommendations from others
The American Academy of Child and Adolescent Psychiatry8 concluded that stimulant medication can be used to treat adults who have been carefully evaluated. They recommend starting methylphenidate, dextroamphetamine, or mixed amphetamine salts according to patient and clinician preference (Table). They do not recommend the use of pemoline due to the potential for hepatic failure.
TABLE
Stimulants used to treat ADHD in adults
| Drug | Starting dose | Maximum daily dose |
|---|---|---|
| Methylphenidate | ||
| Ritalin, Methylin | 5 mg twice daily | 65 mg* |
| Ritalin-SR, Methylin ER, Metadate ER, Metadate CR | 20 mg every morning | 65 mg* |
| Concerta | 18 mg every morning | 54 mg |
| Dextroamphetamine sulfate | ||
| Dexedrine | 2.5 mg twice daily | 45 mg* |
| Dexedrine spansules | 5 mg every morning | 45 mg* |
| Mixed amphetamine salts | ||
| Adderall | 5 mg | 40 mg |
| Adderall XR | 10 mg every morning | 30 mg |
| *American Academy of Child and Adolescent Psychiatry Practice Parameter | ||
Medication can help even well-adapted adults with ADHD
Daniel Triezenberg, MD
Family Practice Residency, Saint Joseph Regional Medical Center, South Bend, Ind
Stimulant therapy benefits many adult patients with ADHD. While some adults need scheduled dosing, others do well with as-needed dosing.
Adults with ADHD often have made behavioral adaptations that allow success without medication. Drugs help these patients when focused attention is critical for specific tasks. A salesman doing a month-end report may find the improvement in attention helpful, but not needed for most daily tasks. A college student may need medication only for a specific class or project. Physicians can help patients with ADHD through anticipatory guidance in choosing a program of study or career goal and then collaborating in choosing appropriate behavioral and medication therapies.
1. Jadad AR, Boyle M, Cunningham C, Kim M, Schachar R. Treatment of attention-deficit/hyperactivity disorder. Evid Rep Technol Assess (Summ) 1999;11:i-viii,1-341.
2. Spencer T, Wilens T, Biederman J, Faraone S, Ablon S, Lapey K. A double-blind, crossover comparison of methylphenidate and placebo in adults with childhoodonset attention-deficit hyperactivity disorder. Arch Gen Psychiatry 1995;52:434-443.
3. Wilens T, Spencer J, Biederman J. A review of the pharmacotherapy of adults with attention-deficit/hyperactivity disorder. J Atten Disord 2002;5:189-202.
4. Taylor F, Russo J. Efficacy of modafinil compared to dextroamphetamine for the treatment of attention deficit hyperactivity disorder in adults. J Child Adolesc Psychopharmacol 2000;10:311-320.
5. Taylor F, Russo J. Comparing guanfacine and dextroamphetamine for the treatment of adult attention-deficit/hyperactivity disorder. J Clin Psychopharmacol 2001;21:223-228.
6. Spencer T, Biederman J, Wilens T, et al. Efficacy of mixed amphetamine salts compound in adults with attention-deficit/hyperactivity disorder. Arch Gen Psychiatry 2001;58:775-782.
7. Kuperman S, Perry P, Gaffney G, et al. Buproprion SR vs. methylphenidate vs. placebo for attention deficit hyperactivity disorder in adults. Ann Clin Psychiatry 2001;13:129-134.
8. American Academy of Child and Adolescent Psychiatry. Practice parameter for the use of stimulant medications in the treatment of children, adolescents and adults. J Am Acad Chil Adolesc Psychiatry 2001;41:26S-49S.
Central nervous system stimulants improve symptoms of attention deficit–hyperactivity disorder (ADHD) in adults (strength of recommendation: B, based on an older, inconclusive systematic review, a lesser-quality systematic review, and several newer small randomized controlled trials).
Although not the focus of this question, nonstimulant medications (including buproprion, modafinil, and guanfacine) have also been studied in the treatment of ADHD in adults. Recently, atomoxetine became the only nonstimulant medication to receive approval by the US Food and Drug Administration for the treatment of ADHD.
Evidence summary
A well-done systematic review of 12 trials assessing the efficacy of stimulant therapy in the treatment of adult ADHD did not find sufficient evidence that stimulants were effective.1 Significant heterogeneity and poor reporting of methodology was seen among the studies.
The 1 study rated as high-quality was a 7-week randomized controlled trial using a crossover comparison of methylphenidate and placebo.2 There was a favorable response in 78% (18/23) of subjects while takin methylphenidate, in contrast to 4% (1/23) while taking placebo (number needed to treat [NNT]=1.4; P<.0001). A favorable response was assessed by the Clinical Global Impression Scale, a measure of illness severity and improvement, and a >30% reduction in symptoms as measured by the ADHD Rating Scale. A more recent, but less rigorous, systematic review identified 15 studies of stimulant efficacy in adults.3 Researchers concluded that under controlled conditions, stimulants are efficacious in the treatment of ADHD in adults. The rate of response among the studies ranged from 25% to 78%.
One of the better studies in this review was a randomized, double-blind, 3-phase crossover study of dextroamphetamine, modafinil (a drug used to treat narcolepsy), and placebo.4 Each phase was 2 weeks long, with a 4-day washout in between. A favorable response was defined as a reduction of ADHD symptoms by at least 30% on the DSM-IV ADHD Behavior Checklist for Adults. Dextroamphetamine and modafinil showed the same response rate in 10 of 21 patients. Both treatments had a significant improvement over placebo (P<.001). It was unclear from the study what percentage of subjects responded to placebo.
A similar study compared dextroamphetamine, guanfacine (an antihypertensive agent), and placebo in 17 patients.5 On the DSM-IV ADHD Behavior Checklist for Adults, subjects taking dextroamphetamine or guanfacine reported similar decreases in mean ADHD scores compared with placebo (24 vs 22 vs 30; P<.05). They did not report the number of subjects who had a 30% reduction in symptoms. Of note: at the end of the study but prior to unblinding, subjects were asked which medication they preferred. Twelve subjects chose dextroamphetamine, 4 chose guanfacine, and 1 chose placebo. Subjects’ stated reason for choosing dextroamphetamine was the positive effect it had on their motivation.
Another study included in this review was a randomized controlled trial of mixed amphetamine salts. Of the 27 adults who completed the study, 19 (70%) responded favorably to mixed amphetamine salts compared with 2 (7.4%) receiving placebo (NNT=1.6; P<.001).6 Favorable response was defined as more than a 30% reduction of symptoms on the ADHD Rating Scale. Not included in either review was a 7-week randomized controlled trial comparing methylphenidate with sustained-release buproprion.7 Thirty out of 37 subjects completed at least 1 week of the study. The primary indicator of a favorable response was the Clinical Global Impression Scale. The rate of response was 50% for methylphenidate, 64% for sustained-release buproprion, and 27% for placebo (P<.14).
Recommendations from others
The American Academy of Child and Adolescent Psychiatry8 concluded that stimulant medication can be used to treat adults who have been carefully evaluated. They recommend starting methylphenidate, dextroamphetamine, or mixed amphetamine salts according to patient and clinician preference (Table). They do not recommend the use of pemoline due to the potential for hepatic failure.
TABLE
Stimulants used to treat ADHD in adults
| Drug | Starting dose | Maximum daily dose |
|---|---|---|
| Methylphenidate | ||
| Ritalin, Methylin | 5 mg twice daily | 65 mg* |
| Ritalin-SR, Methylin ER, Metadate ER, Metadate CR | 20 mg every morning | 65 mg* |
| Concerta | 18 mg every morning | 54 mg |
| Dextroamphetamine sulfate | ||
| Dexedrine | 2.5 mg twice daily | 45 mg* |
| Dexedrine spansules | 5 mg every morning | 45 mg* |
| Mixed amphetamine salts | ||
| Adderall | 5 mg | 40 mg |
| Adderall XR | 10 mg every morning | 30 mg |
| *American Academy of Child and Adolescent Psychiatry Practice Parameter | ||
Medication can help even well-adapted adults with ADHD
Daniel Triezenberg, MD
Family Practice Residency, Saint Joseph Regional Medical Center, South Bend, Ind
Stimulant therapy benefits many adult patients with ADHD. While some adults need scheduled dosing, others do well with as-needed dosing.
Adults with ADHD often have made behavioral adaptations that allow success without medication. Drugs help these patients when focused attention is critical for specific tasks. A salesman doing a month-end report may find the improvement in attention helpful, but not needed for most daily tasks. A college student may need medication only for a specific class or project. Physicians can help patients with ADHD through anticipatory guidance in choosing a program of study or career goal and then collaborating in choosing appropriate behavioral and medication therapies.
Central nervous system stimulants improve symptoms of attention deficit–hyperactivity disorder (ADHD) in adults (strength of recommendation: B, based on an older, inconclusive systematic review, a lesser-quality systematic review, and several newer small randomized controlled trials).
Although not the focus of this question, nonstimulant medications (including buproprion, modafinil, and guanfacine) have also been studied in the treatment of ADHD in adults. Recently, atomoxetine became the only nonstimulant medication to receive approval by the US Food and Drug Administration for the treatment of ADHD.
Evidence summary
A well-done systematic review of 12 trials assessing the efficacy of stimulant therapy in the treatment of adult ADHD did not find sufficient evidence that stimulants were effective.1 Significant heterogeneity and poor reporting of methodology was seen among the studies.
The 1 study rated as high-quality was a 7-week randomized controlled trial using a crossover comparison of methylphenidate and placebo.2 There was a favorable response in 78% (18/23) of subjects while takin methylphenidate, in contrast to 4% (1/23) while taking placebo (number needed to treat [NNT]=1.4; P<.0001). A favorable response was assessed by the Clinical Global Impression Scale, a measure of illness severity and improvement, and a >30% reduction in symptoms as measured by the ADHD Rating Scale. A more recent, but less rigorous, systematic review identified 15 studies of stimulant efficacy in adults.3 Researchers concluded that under controlled conditions, stimulants are efficacious in the treatment of ADHD in adults. The rate of response among the studies ranged from 25% to 78%.
One of the better studies in this review was a randomized, double-blind, 3-phase crossover study of dextroamphetamine, modafinil (a drug used to treat narcolepsy), and placebo.4 Each phase was 2 weeks long, with a 4-day washout in between. A favorable response was defined as a reduction of ADHD symptoms by at least 30% on the DSM-IV ADHD Behavior Checklist for Adults. Dextroamphetamine and modafinil showed the same response rate in 10 of 21 patients. Both treatments had a significant improvement over placebo (P<.001). It was unclear from the study what percentage of subjects responded to placebo.
A similar study compared dextroamphetamine, guanfacine (an antihypertensive agent), and placebo in 17 patients.5 On the DSM-IV ADHD Behavior Checklist for Adults, subjects taking dextroamphetamine or guanfacine reported similar decreases in mean ADHD scores compared with placebo (24 vs 22 vs 30; P<.05). They did not report the number of subjects who had a 30% reduction in symptoms. Of note: at the end of the study but prior to unblinding, subjects were asked which medication they preferred. Twelve subjects chose dextroamphetamine, 4 chose guanfacine, and 1 chose placebo. Subjects’ stated reason for choosing dextroamphetamine was the positive effect it had on their motivation.
Another study included in this review was a randomized controlled trial of mixed amphetamine salts. Of the 27 adults who completed the study, 19 (70%) responded favorably to mixed amphetamine salts compared with 2 (7.4%) receiving placebo (NNT=1.6; P<.001).6 Favorable response was defined as more than a 30% reduction of symptoms on the ADHD Rating Scale. Not included in either review was a 7-week randomized controlled trial comparing methylphenidate with sustained-release buproprion.7 Thirty out of 37 subjects completed at least 1 week of the study. The primary indicator of a favorable response was the Clinical Global Impression Scale. The rate of response was 50% for methylphenidate, 64% for sustained-release buproprion, and 27% for placebo (P<.14).
Recommendations from others
The American Academy of Child and Adolescent Psychiatry8 concluded that stimulant medication can be used to treat adults who have been carefully evaluated. They recommend starting methylphenidate, dextroamphetamine, or mixed amphetamine salts according to patient and clinician preference (Table). They do not recommend the use of pemoline due to the potential for hepatic failure.
TABLE
Stimulants used to treat ADHD in adults
| Drug | Starting dose | Maximum daily dose |
|---|---|---|
| Methylphenidate | ||
| Ritalin, Methylin | 5 mg twice daily | 65 mg* |
| Ritalin-SR, Methylin ER, Metadate ER, Metadate CR | 20 mg every morning | 65 mg* |
| Concerta | 18 mg every morning | 54 mg |
| Dextroamphetamine sulfate | ||
| Dexedrine | 2.5 mg twice daily | 45 mg* |
| Dexedrine spansules | 5 mg every morning | 45 mg* |
| Mixed amphetamine salts | ||
| Adderall | 5 mg | 40 mg |
| Adderall XR | 10 mg every morning | 30 mg |
| *American Academy of Child and Adolescent Psychiatry Practice Parameter | ||
Medication can help even well-adapted adults with ADHD
Daniel Triezenberg, MD
Family Practice Residency, Saint Joseph Regional Medical Center, South Bend, Ind
Stimulant therapy benefits many adult patients with ADHD. While some adults need scheduled dosing, others do well with as-needed dosing.
Adults with ADHD often have made behavioral adaptations that allow success without medication. Drugs help these patients when focused attention is critical for specific tasks. A salesman doing a month-end report may find the improvement in attention helpful, but not needed for most daily tasks. A college student may need medication only for a specific class or project. Physicians can help patients with ADHD through anticipatory guidance in choosing a program of study or career goal and then collaborating in choosing appropriate behavioral and medication therapies.
1. Jadad AR, Boyle M, Cunningham C, Kim M, Schachar R. Treatment of attention-deficit/hyperactivity disorder. Evid Rep Technol Assess (Summ) 1999;11:i-viii,1-341.
2. Spencer T, Wilens T, Biederman J, Faraone S, Ablon S, Lapey K. A double-blind, crossover comparison of methylphenidate and placebo in adults with childhoodonset attention-deficit hyperactivity disorder. Arch Gen Psychiatry 1995;52:434-443.
3. Wilens T, Spencer J, Biederman J. A review of the pharmacotherapy of adults with attention-deficit/hyperactivity disorder. J Atten Disord 2002;5:189-202.
4. Taylor F, Russo J. Efficacy of modafinil compared to dextroamphetamine for the treatment of attention deficit hyperactivity disorder in adults. J Child Adolesc Psychopharmacol 2000;10:311-320.
5. Taylor F, Russo J. Comparing guanfacine and dextroamphetamine for the treatment of adult attention-deficit/hyperactivity disorder. J Clin Psychopharmacol 2001;21:223-228.
6. Spencer T, Biederman J, Wilens T, et al. Efficacy of mixed amphetamine salts compound in adults with attention-deficit/hyperactivity disorder. Arch Gen Psychiatry 2001;58:775-782.
7. Kuperman S, Perry P, Gaffney G, et al. Buproprion SR vs. methylphenidate vs. placebo for attention deficit hyperactivity disorder in adults. Ann Clin Psychiatry 2001;13:129-134.
8. American Academy of Child and Adolescent Psychiatry. Practice parameter for the use of stimulant medications in the treatment of children, adolescents and adults. J Am Acad Chil Adolesc Psychiatry 2001;41:26S-49S.
1. Jadad AR, Boyle M, Cunningham C, Kim M, Schachar R. Treatment of attention-deficit/hyperactivity disorder. Evid Rep Technol Assess (Summ) 1999;11:i-viii,1-341.
2. Spencer T, Wilens T, Biederman J, Faraone S, Ablon S, Lapey K. A double-blind, crossover comparison of methylphenidate and placebo in adults with childhoodonset attention-deficit hyperactivity disorder. Arch Gen Psychiatry 1995;52:434-443.
3. Wilens T, Spencer J, Biederman J. A review of the pharmacotherapy of adults with attention-deficit/hyperactivity disorder. J Atten Disord 2002;5:189-202.
4. Taylor F, Russo J. Efficacy of modafinil compared to dextroamphetamine for the treatment of attention deficit hyperactivity disorder in adults. J Child Adolesc Psychopharmacol 2000;10:311-320.
5. Taylor F, Russo J. Comparing guanfacine and dextroamphetamine for the treatment of adult attention-deficit/hyperactivity disorder. J Clin Psychopharmacol 2001;21:223-228.
6. Spencer T, Biederman J, Wilens T, et al. Efficacy of mixed amphetamine salts compound in adults with attention-deficit/hyperactivity disorder. Arch Gen Psychiatry 2001;58:775-782.
7. Kuperman S, Perry P, Gaffney G, et al. Buproprion SR vs. methylphenidate vs. placebo for attention deficit hyperactivity disorder in adults. Ann Clin Psychiatry 2001;13:129-134.
8. American Academy of Child and Adolescent Psychiatry. Practice parameter for the use of stimulant medications in the treatment of children, adolescents and adults. J Am Acad Chil Adolesc Psychiatry 2001;41:26S-49S.
Evidence-based answers from the Family Physicians Inquiries Network