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Do ACE inhibitors prevent nephropathy in type 2 diabetes without proteinuria?
Angiotensin-converting enzyme (ACE) inhibitors make a significant difference for patients with diabetes as a whole. If patients both with and without microalbuminuria are included together, ACE inhibitors significantly reduce the progression of the albumin excretion rate (strength of recommendation [SOR]: A, based on multiple randomized controlled trials) and the development of overt nephropathy (SOR: A, based on 1 randomized controlled trial).
However, studying diabetes without microalbuminuria separately, the effect of ACE inhibitors on progression to nephropathy does not reach statistical significance. This applies to both type 1 and 2 diabetes (SOR: A, based on randomized controlled trials with heterogenous results). Results are contradictory regarding whether ACE inhibition delays new onset of diabetic microalbuminuria.
Evidence summary
There are 3 prospective randomized controlled trials studying the effect of ACE inhibitors on albumin excretion for patients with diabetes who do not have microalbuminuria. A 2-year randomized controlled trial compared lisinopril (Prinivil; Zestril) 10 mg/d with placebo in 530 normotensive adults (aged 20–59 years) with insulin-dependent diabetes, defined as those diagnosed with diabetes before age 36 and using continuous insulin therapy within 1 year of diagnosis. At the beginning of the study, 90 patients had microalbuminuria—defined as an albumin excretion rate (AER) >29 mg/24 hr—and 440 patients did not. When the results for all patients who had and did not have microalbuminuria were combined, there was a significantly smaller rise in the AER for the lisinopril group vs the placebo group (3.2 mg/24 hr lower; P=.03). However, for the patients without initial microalbuminuria, the reduction in the rise of AER with lisinopril was not significant (1.4 mg/24 hr lower; P=.10). The decreased rate of developing new microalbuminuria was also not significant (relative risk reduction [RRR]=12.7%; P=.10).1
A subsequent trial compared enalapril (Vasotec) 10 mg/d with placebo in 194 normotensive patients (aged 40–60) with type 2 diabetes and without microalbuminuria, defined as AER >30 mg/24 hr. Over the 6-year course of the study, the AER in the placebo group rose from 10.8 mg/24 hr to 26.5 mg/24 hr. The AER of the treatment group dropped from 11.6 mg/24 hr initially to 9.7 mg/24 hr at 2 years, then rose to 15.8 mg/24 hr at 6 years. Enalapril significantly slowed the rise in AER (RRR=0.4; P=.001). Nineteen percent of the placebo group developed microalbuminuria, compared with 6.5% of those taking enalapril (absolute risk reduction[ARR]=12.5%; number needed to treat=8; P=.042). While this study described a modest and statistically significant renal protective effect of enalapril, it did not use an intention-to-treat analysis.2
MICRO-HOPE, a subset of the HOPE trial, studied ramipril (Altace) 10 mg/d vs placebo in 2437 patients with diabetes who did not have clinical proteinuria. Patients were aged 55 years or older and had either a previous cardiovascular event or at least 1 other cardiovascular risk factor. There were 1140 patients with microalbuminuria, defined as an albumin/creatinine ratio 2 mg/mmol, and 2437 patients without. After 4.5 years, 10% of patients had developed overt nephropathy, defined as albumin/creatinine >36 mg/mmol.
When all patients in the study were examined together, ramipril provided significant renal protection over placebo (RRR=24%; ARR=1%; P=.027). It also lowered the risk of MI by 22%, stroke by 33%, and cardiovascular death by 37%. But in a separate analysis of the patients without microalbuminuria, ramipril did not significantly reduce overt nephropathy (P=.50). Ramipril also did not significantly reduce the risk of developing new microalbuminuria in this group (RRR=9%; P=.17). Further, for patients without microalbuminuria, ramipril did not reduce the combined outcomes of myocardial infarction, stroke, or cardiovascular death (odds ratio=0.85; 95% CI, 0.70–1.02).3
Recommendations from others
We could find no guidelines recommending for or against the use of ACE inhibitors for patients with diabetes without microalbuminuria.
ACE inhibitors should still be used in most patients with type 2 diabetes
Joseph Saseen, PharmD, FCCP, BCPS
University of Colorado Health Sciences Center, Denver
ACE inhibitors do not prevent the development of type 2 diabetic nephropathy. In contrast to type 1 diabetes, cardiovascular disease is the primary cause of death in type 2. The HOPE study demonstrated that ACE inhibitor therapy significantly reduces cardiovascular events in type 2 diabetes independent of hypertension status.4 These benefits are so compelling that the American Diabetes Association strongly recommends ACE inhibitor therapy for type 2 diabetics aged ≥55 years with 1 additional risk factor.5 Despite not preventing the development of nephropathy, ACE inhibitors should be used for most patients with type 2 diabetes for cardiovascular risk reduction.
1. Randomised placebo-controlled trial of lisinopril in normotensive patients with insulin-dependent diabetes and normoalbuminuria or microalbuminuria. The EUCLID Study Group. Lancet 1997;349:1787-1792.
2. Ravid M, Brosh D, Levi Z, Bar-Dayan Y, Ravid D, Rachmani R. Use of enalapril to attenuate decline in renal function in normotensive, normoalbuminuric patients with type 2 diabetes mellitus. A randomized, controlled trial. Ann Intern Med 1998;128:982-988.
3. Effects of ramipril on cardiovascular and microvascular outcomes in people with diabetes mellitus: results of the HOPE study and MICRO-HOPE substudy. Heart Outcomes Prevention Evaluation Study Investigators. Lancet 2000;355:253-259.
4. Yusuf S, Sleight P, Pogue J, Bosch J, Davies R, Dagenais G. Effects of an angiotensin-converting-enzyme inhibitor, ramipril, on cardiovascular events in high-risk patients. The Heart Outcomes Prevention Evaluation Study Investigators. N Engl J Med 2000;342:145-153.
5. Arauz-Pacheco C, Parrott MA, Raskin P. American Diabetes Association. Treatment of hypertension in adults with diabetes. Diabetes Care 2003;26 Suppl 1:S80-S82.
Angiotensin-converting enzyme (ACE) inhibitors make a significant difference for patients with diabetes as a whole. If patients both with and without microalbuminuria are included together, ACE inhibitors significantly reduce the progression of the albumin excretion rate (strength of recommendation [SOR]: A, based on multiple randomized controlled trials) and the development of overt nephropathy (SOR: A, based on 1 randomized controlled trial).
However, studying diabetes without microalbuminuria separately, the effect of ACE inhibitors on progression to nephropathy does not reach statistical significance. This applies to both type 1 and 2 diabetes (SOR: A, based on randomized controlled trials with heterogenous results). Results are contradictory regarding whether ACE inhibition delays new onset of diabetic microalbuminuria.
Evidence summary
There are 3 prospective randomized controlled trials studying the effect of ACE inhibitors on albumin excretion for patients with diabetes who do not have microalbuminuria. A 2-year randomized controlled trial compared lisinopril (Prinivil; Zestril) 10 mg/d with placebo in 530 normotensive adults (aged 20–59 years) with insulin-dependent diabetes, defined as those diagnosed with diabetes before age 36 and using continuous insulin therapy within 1 year of diagnosis. At the beginning of the study, 90 patients had microalbuminuria—defined as an albumin excretion rate (AER) >29 mg/24 hr—and 440 patients did not. When the results for all patients who had and did not have microalbuminuria were combined, there was a significantly smaller rise in the AER for the lisinopril group vs the placebo group (3.2 mg/24 hr lower; P=.03). However, for the patients without initial microalbuminuria, the reduction in the rise of AER with lisinopril was not significant (1.4 mg/24 hr lower; P=.10). The decreased rate of developing new microalbuminuria was also not significant (relative risk reduction [RRR]=12.7%; P=.10).1
A subsequent trial compared enalapril (Vasotec) 10 mg/d with placebo in 194 normotensive patients (aged 40–60) with type 2 diabetes and without microalbuminuria, defined as AER >30 mg/24 hr. Over the 6-year course of the study, the AER in the placebo group rose from 10.8 mg/24 hr to 26.5 mg/24 hr. The AER of the treatment group dropped from 11.6 mg/24 hr initially to 9.7 mg/24 hr at 2 years, then rose to 15.8 mg/24 hr at 6 years. Enalapril significantly slowed the rise in AER (RRR=0.4; P=.001). Nineteen percent of the placebo group developed microalbuminuria, compared with 6.5% of those taking enalapril (absolute risk reduction[ARR]=12.5%; number needed to treat=8; P=.042). While this study described a modest and statistically significant renal protective effect of enalapril, it did not use an intention-to-treat analysis.2
MICRO-HOPE, a subset of the HOPE trial, studied ramipril (Altace) 10 mg/d vs placebo in 2437 patients with diabetes who did not have clinical proteinuria. Patients were aged 55 years or older and had either a previous cardiovascular event or at least 1 other cardiovascular risk factor. There were 1140 patients with microalbuminuria, defined as an albumin/creatinine ratio 2 mg/mmol, and 2437 patients without. After 4.5 years, 10% of patients had developed overt nephropathy, defined as albumin/creatinine >36 mg/mmol.
When all patients in the study were examined together, ramipril provided significant renal protection over placebo (RRR=24%; ARR=1%; P=.027). It also lowered the risk of MI by 22%, stroke by 33%, and cardiovascular death by 37%. But in a separate analysis of the patients without microalbuminuria, ramipril did not significantly reduce overt nephropathy (P=.50). Ramipril also did not significantly reduce the risk of developing new microalbuminuria in this group (RRR=9%; P=.17). Further, for patients without microalbuminuria, ramipril did not reduce the combined outcomes of myocardial infarction, stroke, or cardiovascular death (odds ratio=0.85; 95% CI, 0.70–1.02).3
Recommendations from others
We could find no guidelines recommending for or against the use of ACE inhibitors for patients with diabetes without microalbuminuria.
ACE inhibitors should still be used in most patients with type 2 diabetes
Joseph Saseen, PharmD, FCCP, BCPS
University of Colorado Health Sciences Center, Denver
ACE inhibitors do not prevent the development of type 2 diabetic nephropathy. In contrast to type 1 diabetes, cardiovascular disease is the primary cause of death in type 2. The HOPE study demonstrated that ACE inhibitor therapy significantly reduces cardiovascular events in type 2 diabetes independent of hypertension status.4 These benefits are so compelling that the American Diabetes Association strongly recommends ACE inhibitor therapy for type 2 diabetics aged ≥55 years with 1 additional risk factor.5 Despite not preventing the development of nephropathy, ACE inhibitors should be used for most patients with type 2 diabetes for cardiovascular risk reduction.
Angiotensin-converting enzyme (ACE) inhibitors make a significant difference for patients with diabetes as a whole. If patients both with and without microalbuminuria are included together, ACE inhibitors significantly reduce the progression of the albumin excretion rate (strength of recommendation [SOR]: A, based on multiple randomized controlled trials) and the development of overt nephropathy (SOR: A, based on 1 randomized controlled trial).
However, studying diabetes without microalbuminuria separately, the effect of ACE inhibitors on progression to nephropathy does not reach statistical significance. This applies to both type 1 and 2 diabetes (SOR: A, based on randomized controlled trials with heterogenous results). Results are contradictory regarding whether ACE inhibition delays new onset of diabetic microalbuminuria.
Evidence summary
There are 3 prospective randomized controlled trials studying the effect of ACE inhibitors on albumin excretion for patients with diabetes who do not have microalbuminuria. A 2-year randomized controlled trial compared lisinopril (Prinivil; Zestril) 10 mg/d with placebo in 530 normotensive adults (aged 20–59 years) with insulin-dependent diabetes, defined as those diagnosed with diabetes before age 36 and using continuous insulin therapy within 1 year of diagnosis. At the beginning of the study, 90 patients had microalbuminuria—defined as an albumin excretion rate (AER) >29 mg/24 hr—and 440 patients did not. When the results for all patients who had and did not have microalbuminuria were combined, there was a significantly smaller rise in the AER for the lisinopril group vs the placebo group (3.2 mg/24 hr lower; P=.03). However, for the patients without initial microalbuminuria, the reduction in the rise of AER with lisinopril was not significant (1.4 mg/24 hr lower; P=.10). The decreased rate of developing new microalbuminuria was also not significant (relative risk reduction [RRR]=12.7%; P=.10).1
A subsequent trial compared enalapril (Vasotec) 10 mg/d with placebo in 194 normotensive patients (aged 40–60) with type 2 diabetes and without microalbuminuria, defined as AER >30 mg/24 hr. Over the 6-year course of the study, the AER in the placebo group rose from 10.8 mg/24 hr to 26.5 mg/24 hr. The AER of the treatment group dropped from 11.6 mg/24 hr initially to 9.7 mg/24 hr at 2 years, then rose to 15.8 mg/24 hr at 6 years. Enalapril significantly slowed the rise in AER (RRR=0.4; P=.001). Nineteen percent of the placebo group developed microalbuminuria, compared with 6.5% of those taking enalapril (absolute risk reduction[ARR]=12.5%; number needed to treat=8; P=.042). While this study described a modest and statistically significant renal protective effect of enalapril, it did not use an intention-to-treat analysis.2
MICRO-HOPE, a subset of the HOPE trial, studied ramipril (Altace) 10 mg/d vs placebo in 2437 patients with diabetes who did not have clinical proteinuria. Patients were aged 55 years or older and had either a previous cardiovascular event or at least 1 other cardiovascular risk factor. There were 1140 patients with microalbuminuria, defined as an albumin/creatinine ratio 2 mg/mmol, and 2437 patients without. After 4.5 years, 10% of patients had developed overt nephropathy, defined as albumin/creatinine >36 mg/mmol.
When all patients in the study were examined together, ramipril provided significant renal protection over placebo (RRR=24%; ARR=1%; P=.027). It also lowered the risk of MI by 22%, stroke by 33%, and cardiovascular death by 37%. But in a separate analysis of the patients without microalbuminuria, ramipril did not significantly reduce overt nephropathy (P=.50). Ramipril also did not significantly reduce the risk of developing new microalbuminuria in this group (RRR=9%; P=.17). Further, for patients without microalbuminuria, ramipril did not reduce the combined outcomes of myocardial infarction, stroke, or cardiovascular death (odds ratio=0.85; 95% CI, 0.70–1.02).3
Recommendations from others
We could find no guidelines recommending for or against the use of ACE inhibitors for patients with diabetes without microalbuminuria.
ACE inhibitors should still be used in most patients with type 2 diabetes
Joseph Saseen, PharmD, FCCP, BCPS
University of Colorado Health Sciences Center, Denver
ACE inhibitors do not prevent the development of type 2 diabetic nephropathy. In contrast to type 1 diabetes, cardiovascular disease is the primary cause of death in type 2. The HOPE study demonstrated that ACE inhibitor therapy significantly reduces cardiovascular events in type 2 diabetes independent of hypertension status.4 These benefits are so compelling that the American Diabetes Association strongly recommends ACE inhibitor therapy for type 2 diabetics aged ≥55 years with 1 additional risk factor.5 Despite not preventing the development of nephropathy, ACE inhibitors should be used for most patients with type 2 diabetes for cardiovascular risk reduction.
1. Randomised placebo-controlled trial of lisinopril in normotensive patients with insulin-dependent diabetes and normoalbuminuria or microalbuminuria. The EUCLID Study Group. Lancet 1997;349:1787-1792.
2. Ravid M, Brosh D, Levi Z, Bar-Dayan Y, Ravid D, Rachmani R. Use of enalapril to attenuate decline in renal function in normotensive, normoalbuminuric patients with type 2 diabetes mellitus. A randomized, controlled trial. Ann Intern Med 1998;128:982-988.
3. Effects of ramipril on cardiovascular and microvascular outcomes in people with diabetes mellitus: results of the HOPE study and MICRO-HOPE substudy. Heart Outcomes Prevention Evaluation Study Investigators. Lancet 2000;355:253-259.
4. Yusuf S, Sleight P, Pogue J, Bosch J, Davies R, Dagenais G. Effects of an angiotensin-converting-enzyme inhibitor, ramipril, on cardiovascular events in high-risk patients. The Heart Outcomes Prevention Evaluation Study Investigators. N Engl J Med 2000;342:145-153.
5. Arauz-Pacheco C, Parrott MA, Raskin P. American Diabetes Association. Treatment of hypertension in adults with diabetes. Diabetes Care 2003;26 Suppl 1:S80-S82.
1. Randomised placebo-controlled trial of lisinopril in normotensive patients with insulin-dependent diabetes and normoalbuminuria or microalbuminuria. The EUCLID Study Group. Lancet 1997;349:1787-1792.
2. Ravid M, Brosh D, Levi Z, Bar-Dayan Y, Ravid D, Rachmani R. Use of enalapril to attenuate decline in renal function in normotensive, normoalbuminuric patients with type 2 diabetes mellitus. A randomized, controlled trial. Ann Intern Med 1998;128:982-988.
3. Effects of ramipril on cardiovascular and microvascular outcomes in people with diabetes mellitus: results of the HOPE study and MICRO-HOPE substudy. Heart Outcomes Prevention Evaluation Study Investigators. Lancet 2000;355:253-259.
4. Yusuf S, Sleight P, Pogue J, Bosch J, Davies R, Dagenais G. Effects of an angiotensin-converting-enzyme inhibitor, ramipril, on cardiovascular events in high-risk patients. The Heart Outcomes Prevention Evaluation Study Investigators. N Engl J Med 2000;342:145-153.
5. Arauz-Pacheco C, Parrott MA, Raskin P. American Diabetes Association. Treatment of hypertension in adults with diabetes. Diabetes Care 2003;26 Suppl 1:S80-S82.
Evidence-based answers from the Family Physicians Inquiries Network
What is the best initial treatment of Parkinson’s disease?
No studies clearly demonstrate the best initial treatment for Parkinson’s disease. Levodopa improves motor function in Parkinson’s disease; however, long-term use is associated with irreversible dyskinesias and motor fluctuations. Compared with placebo, selegiline improves the motor symptoms of Parkinson’s disease and allows a physician to delay the introduction of levodopa by 9 to 12 months (strength of recommendation [SOR]: A, based on randomized controlled trials).
Dopamine agonists—alone or combined with levodopa—have fewer associated dyskinesias and other motor complications but produce lower scores on activities of daily living and Unified Parkinson’s Disease Rating Scale (UPDRS) when compared with levodopa alone (SOR: A, based on systematic reviews of randomized controlled trials). Drug choices should be based on each patient’s individual symptoms and response to medication (Table).
TABLE
Medications for Parkinson’s disease
Medication | Starting dose | Usual daily dose | Approx cost/mo |
---|---|---|---|
Selegiline | 5 mg every morning | 5 mg every morning and at noon | $29 for 10 mg/d |
Carbidopa/levodopa | 25/100 mg tab 3 times daily | 25/100 mg 3 times daily | $76 for 75/300 mg/d |
Pergolide | 0.05 mg/d | 2–3 mg/d divided 3 times daily | $223 for 2 mg/d |
Pramipexole | 0.375 mg/d divided 3 times daily | 1.5–4.5 mg/d divided 3 times daily | $177 for 3 mg/d |
Ropinirole | 0.25 mg 3 times daily | 3 mg divided 3 times daily | $185 for 3 mg/d |
Evidence summary
Five randomized controlled trials15 have shown improved motor function and activities of daily living with selegiline vs placebo in early Parkinson’s disease. Two of these trials1,2 found that selegiline delayed the need for levodopa for 9 to 12 months.
One large randomized controlled trial showed no difference in disability scores and an increase in mortality at 5.6 years when comparing selegiline combined with levodopa to levodopa alone.6 A re-analysis of this study, as well as subsequent studies, have not supported this conclusion and found no increase in mortality in patients with a history of selegiline use.7-10
Two Cochrane reviews found that patients who tolerated the dopamine agonist bromocriptine—when administered alone or with levodopa—had delayed dyskinesias and motor complications compared with levodopa alone.11,12 There was no change in off-time with the combination.12 A large randomized controlled trial comparing bromocriptine with levodopa demonstrated that at 3 years, disability scores were lower in the patients initially assigned to bromocriptine, but the difference was no longer significant at 9 years.13
The bromocriptine group in this trial showed a lower incidence of dyskinesias when data from all patient groups were combined. However, when moderate to severe cases were analyzed separately, there was no significant difference.13 There was no difference in mortality between patients initially treated with bromocriptine vs levodopa.13,14
Studies of other dopamine agonists show results comparable with bromocriptine. Lisuride (not available in the US) with rescue levodopa vs levodopa alone had fewer motor complications at 4 years but lower UPDRS and activities of daily living scores.15 Another study comparing lisuride (with or without levodopa) vs levodopa alone found no difference in motor complications at 5 years.16 Studies with cabergoline, pramipexole, and pergolide—alone or combined with levodopa—vs levodopa alone showed a decrease in motor complications with the dopamine agonist but lower activities of daily living and UPDRS scores.17-19
Recommendations from others
In 2002, the American Academy of Neurology published practice parameters for the initiation of treatment for Parkinson’s disease based on literature from 1966 to 1999. The authors concluded:
- selegiline has mild symptomatic benefit and may be tried as initial therapy, but confers no neuroprotective effect
- either levodopa or a dopamine agonist can be used for the initial treatment of symptomatic Parkinson’s disease
- levodopa has a higher risk of dyskinesias than a dopamine agonist but superior motor benefits,20 and is less likely to have other side effects (nausea, hallucinations, somnolence, and edema).
Family physicians play a key role in monitoring Parkinson’s
Randy Ward, MD
Medical College of Wisconsin, Milwaukee
Parkinson’s disease has a profound impact on a patient’s physical and psychological wellbeing. Difficulties with movement, autonomic nervous system abnormalities, neuropsychiatric symptoms, and problems with medication effectiveness and side effects all occur throughout its course. Consultation with a neurologist skilled in this disorder can be quite helpful, particularly in younger patients or when the diagnosis is unclear. The family physician plays a key role in monitoring of the patient’s condition. Active management of symptoms (and comorbidities as they arise) is crucial in helping patients maintain their functional status and quality of life.
1. Myllyla VV, Sotaniemi KA, Vuorinen JA, Heinonen EH. Selegiline as initial treatment in de novo parkinsonian patients. Neurology 1992;42:339-343.
2. Effects of tocopherol and deprenyl on the progression of disability in early Parkinson’s disease. The Parkinson Study Group. N Engl J Med 1993;328:176-183.
3. Olanow CW, Hauser RA, Gauger L, et al. The effect of deprenyl and levodopa on the progression of Parkinson’s disease. Ann Neurol 1995;38:771-777.
4. Larsen JP, Boas J, Erdal JE. Does selegiline modify the progression of early Parkinson’s disease? Results from a five-year study. The Norwegian-Danish Study Group. Eur J Neurol 1999;6:539-547.
5. Przuntek H, Conrad B, Dichgans J, et al. SELEDO: a 5-year long-term trial on the effect of selegiline in early Parkinsonian patients treated with levodopa. Eur J Neurol 1999;6:141-150.
6. Lees AJ. Comparison of therapeutic effects and mortality data of levodopa and levodopa combined with selegiline in people with early, mild Parkinson’s disease. Parkinson’s Disease Research Group of the United Kingdom. BMJ 1995;311:1602-1607.
7. Counsell C. Effect of adding selegiline to levodopa in early, mild Parkinson’s disease. Formal systematic review of data on patients in all relevant trials is required. BMJ 1998;17:1586.-
8. Ben-Shlomo Y, Churchyard A, Head J, et al. Investigation by Parkinson’s Disease Research Group of United Kingdom into excess mortality seen with combined levodopa and selegiline treatment in patients with early, mild Parkinson’s disease: further results of randomised trial and confidential inquiry. BMJ 1998;316:1191-1196.
9. Olanow CW, Myllyla VV, Sotaniemi K, et al. Effect of selegiline on mortality in patients with Parkinson’s disease: a meta-analysis. Neurology 1998;51:825-830.
10. Impact of deprenyl and tocopherol treatment on Parkinson’s disease in DATATOP patients requiring levodopa. Parkinson Study Group. Ann Neurol 1996;39:37-45.
11. Ramaker C, van Hilten JJ. Bromocriptine versus levodopa in early Parkinson’s disease. The Cochrane Library, Issue 3, 2003. Oxford: Update Software, last updated February 2, 2000. Accessed on April 15, 2003.
12. Ramaker C, van Hilten JJ. Bromocriptine/levodopa combined versus levodopa alone for early Parkinson’s disease (Cochrane Review). The Cochrane Library, Issue 3, 2003. Oxford: Update Software, last updated October 21, 2001. Accessed on April 15, 2003.
13. Lees AJ, Katzenschlager R, Head J, Ben-Shlomo Y. Ten-year follow-up of three different initial treatments in de-novo PD: A randomized trial. Neurology 2001;57:1687-1694.
14. Hely MA, Morris JG, Traficante R, et al. The Sydney multicentre study of Parkinson’s disease: progression and mortality at 10 years. J Neurol Neurosurg Psychiatry 1999;67:300-307.
15. Rinne UK. Lisuride, a dopamine agonist in the treatment of early Parkinson’s disease. Neurology 1989;39:336-339.
16. Allain H, Destee A, Petit H, et al. Five-year follow-up of early lisuride and levodopa combination therapy versus levodopa monotherapy in de novo Parkinson’s disease. The French Lisuride Study Group. Eur Neurol 2000;44:22-30.
17. Rinne U. A 5-year double-blind study with cabergoline versus levodopa in the treatment of early Parkinson’s disease. Parkinsonism Relat Disord 1999;5(suppl):84.-
18. Pramipexole vs levodopa as initial treatment for Parkinson disease: A randomized controlled trial. Parkinson Study Group. JAMA 2000;284:1931-1938.
19. Oertel W. Pergolide or levodopa for Parkinson’s therapy? 6th International Congress of Parkinson’s Disease and Movement Disorders, June 11–15, 2000. Available at: http://www.parkinsonsdisease.com/news/N100_arc.HTM #Pergolide. Accessed on April 15, 2003.
20. Miyasaki JM, Martin W, Suchowersky O, Weiner WJ, Lang AE. Practice parameter: initiation of treatment for Parkinson’s disease: An evidence-based review: report of the Quality Standards Subcommittee of the American Academy of Neurology. Neurology 2002;58:11-17.
No studies clearly demonstrate the best initial treatment for Parkinson’s disease. Levodopa improves motor function in Parkinson’s disease; however, long-term use is associated with irreversible dyskinesias and motor fluctuations. Compared with placebo, selegiline improves the motor symptoms of Parkinson’s disease and allows a physician to delay the introduction of levodopa by 9 to 12 months (strength of recommendation [SOR]: A, based on randomized controlled trials).
Dopamine agonists—alone or combined with levodopa—have fewer associated dyskinesias and other motor complications but produce lower scores on activities of daily living and Unified Parkinson’s Disease Rating Scale (UPDRS) when compared with levodopa alone (SOR: A, based on systematic reviews of randomized controlled trials). Drug choices should be based on each patient’s individual symptoms and response to medication (Table).
TABLE
Medications for Parkinson’s disease
Medication | Starting dose | Usual daily dose | Approx cost/mo |
---|---|---|---|
Selegiline | 5 mg every morning | 5 mg every morning and at noon | $29 for 10 mg/d |
Carbidopa/levodopa | 25/100 mg tab 3 times daily | 25/100 mg 3 times daily | $76 for 75/300 mg/d |
Pergolide | 0.05 mg/d | 2–3 mg/d divided 3 times daily | $223 for 2 mg/d |
Pramipexole | 0.375 mg/d divided 3 times daily | 1.5–4.5 mg/d divided 3 times daily | $177 for 3 mg/d |
Ropinirole | 0.25 mg 3 times daily | 3 mg divided 3 times daily | $185 for 3 mg/d |
Evidence summary
Five randomized controlled trials15 have shown improved motor function and activities of daily living with selegiline vs placebo in early Parkinson’s disease. Two of these trials1,2 found that selegiline delayed the need for levodopa for 9 to 12 months.
One large randomized controlled trial showed no difference in disability scores and an increase in mortality at 5.6 years when comparing selegiline combined with levodopa to levodopa alone.6 A re-analysis of this study, as well as subsequent studies, have not supported this conclusion and found no increase in mortality in patients with a history of selegiline use.7-10
Two Cochrane reviews found that patients who tolerated the dopamine agonist bromocriptine—when administered alone or with levodopa—had delayed dyskinesias and motor complications compared with levodopa alone.11,12 There was no change in off-time with the combination.12 A large randomized controlled trial comparing bromocriptine with levodopa demonstrated that at 3 years, disability scores were lower in the patients initially assigned to bromocriptine, but the difference was no longer significant at 9 years.13
The bromocriptine group in this trial showed a lower incidence of dyskinesias when data from all patient groups were combined. However, when moderate to severe cases were analyzed separately, there was no significant difference.13 There was no difference in mortality between patients initially treated with bromocriptine vs levodopa.13,14
Studies of other dopamine agonists show results comparable with bromocriptine. Lisuride (not available in the US) with rescue levodopa vs levodopa alone had fewer motor complications at 4 years but lower UPDRS and activities of daily living scores.15 Another study comparing lisuride (with or without levodopa) vs levodopa alone found no difference in motor complications at 5 years.16 Studies with cabergoline, pramipexole, and pergolide—alone or combined with levodopa—vs levodopa alone showed a decrease in motor complications with the dopamine agonist but lower activities of daily living and UPDRS scores.17-19
Recommendations from others
In 2002, the American Academy of Neurology published practice parameters for the initiation of treatment for Parkinson’s disease based on literature from 1966 to 1999. The authors concluded:
- selegiline has mild symptomatic benefit and may be tried as initial therapy, but confers no neuroprotective effect
- either levodopa or a dopamine agonist can be used for the initial treatment of symptomatic Parkinson’s disease
- levodopa has a higher risk of dyskinesias than a dopamine agonist but superior motor benefits,20 and is less likely to have other side effects (nausea, hallucinations, somnolence, and edema).
Family physicians play a key role in monitoring Parkinson’s
Randy Ward, MD
Medical College of Wisconsin, Milwaukee
Parkinson’s disease has a profound impact on a patient’s physical and psychological wellbeing. Difficulties with movement, autonomic nervous system abnormalities, neuropsychiatric symptoms, and problems with medication effectiveness and side effects all occur throughout its course. Consultation with a neurologist skilled in this disorder can be quite helpful, particularly in younger patients or when the diagnosis is unclear. The family physician plays a key role in monitoring of the patient’s condition. Active management of symptoms (and comorbidities as they arise) is crucial in helping patients maintain their functional status and quality of life.
No studies clearly demonstrate the best initial treatment for Parkinson’s disease. Levodopa improves motor function in Parkinson’s disease; however, long-term use is associated with irreversible dyskinesias and motor fluctuations. Compared with placebo, selegiline improves the motor symptoms of Parkinson’s disease and allows a physician to delay the introduction of levodopa by 9 to 12 months (strength of recommendation [SOR]: A, based on randomized controlled trials).
Dopamine agonists—alone or combined with levodopa—have fewer associated dyskinesias and other motor complications but produce lower scores on activities of daily living and Unified Parkinson’s Disease Rating Scale (UPDRS) when compared with levodopa alone (SOR: A, based on systematic reviews of randomized controlled trials). Drug choices should be based on each patient’s individual symptoms and response to medication (Table).
TABLE
Medications for Parkinson’s disease
Medication | Starting dose | Usual daily dose | Approx cost/mo |
---|---|---|---|
Selegiline | 5 mg every morning | 5 mg every morning and at noon | $29 for 10 mg/d |
Carbidopa/levodopa | 25/100 mg tab 3 times daily | 25/100 mg 3 times daily | $76 for 75/300 mg/d |
Pergolide | 0.05 mg/d | 2–3 mg/d divided 3 times daily | $223 for 2 mg/d |
Pramipexole | 0.375 mg/d divided 3 times daily | 1.5–4.5 mg/d divided 3 times daily | $177 for 3 mg/d |
Ropinirole | 0.25 mg 3 times daily | 3 mg divided 3 times daily | $185 for 3 mg/d |
Evidence summary
Five randomized controlled trials15 have shown improved motor function and activities of daily living with selegiline vs placebo in early Parkinson’s disease. Two of these trials1,2 found that selegiline delayed the need for levodopa for 9 to 12 months.
One large randomized controlled trial showed no difference in disability scores and an increase in mortality at 5.6 years when comparing selegiline combined with levodopa to levodopa alone.6 A re-analysis of this study, as well as subsequent studies, have not supported this conclusion and found no increase in mortality in patients with a history of selegiline use.7-10
Two Cochrane reviews found that patients who tolerated the dopamine agonist bromocriptine—when administered alone or with levodopa—had delayed dyskinesias and motor complications compared with levodopa alone.11,12 There was no change in off-time with the combination.12 A large randomized controlled trial comparing bromocriptine with levodopa demonstrated that at 3 years, disability scores were lower in the patients initially assigned to bromocriptine, but the difference was no longer significant at 9 years.13
The bromocriptine group in this trial showed a lower incidence of dyskinesias when data from all patient groups were combined. However, when moderate to severe cases were analyzed separately, there was no significant difference.13 There was no difference in mortality between patients initially treated with bromocriptine vs levodopa.13,14
Studies of other dopamine agonists show results comparable with bromocriptine. Lisuride (not available in the US) with rescue levodopa vs levodopa alone had fewer motor complications at 4 years but lower UPDRS and activities of daily living scores.15 Another study comparing lisuride (with or without levodopa) vs levodopa alone found no difference in motor complications at 5 years.16 Studies with cabergoline, pramipexole, and pergolide—alone or combined with levodopa—vs levodopa alone showed a decrease in motor complications with the dopamine agonist but lower activities of daily living and UPDRS scores.17-19
Recommendations from others
In 2002, the American Academy of Neurology published practice parameters for the initiation of treatment for Parkinson’s disease based on literature from 1966 to 1999. The authors concluded:
- selegiline has mild symptomatic benefit and may be tried as initial therapy, but confers no neuroprotective effect
- either levodopa or a dopamine agonist can be used for the initial treatment of symptomatic Parkinson’s disease
- levodopa has a higher risk of dyskinesias than a dopamine agonist but superior motor benefits,20 and is less likely to have other side effects (nausea, hallucinations, somnolence, and edema).
Family physicians play a key role in monitoring Parkinson’s
Randy Ward, MD
Medical College of Wisconsin, Milwaukee
Parkinson’s disease has a profound impact on a patient’s physical and psychological wellbeing. Difficulties with movement, autonomic nervous system abnormalities, neuropsychiatric symptoms, and problems with medication effectiveness and side effects all occur throughout its course. Consultation with a neurologist skilled in this disorder can be quite helpful, particularly in younger patients or when the diagnosis is unclear. The family physician plays a key role in monitoring of the patient’s condition. Active management of symptoms (and comorbidities as they arise) is crucial in helping patients maintain their functional status and quality of life.
1. Myllyla VV, Sotaniemi KA, Vuorinen JA, Heinonen EH. Selegiline as initial treatment in de novo parkinsonian patients. Neurology 1992;42:339-343.
2. Effects of tocopherol and deprenyl on the progression of disability in early Parkinson’s disease. The Parkinson Study Group. N Engl J Med 1993;328:176-183.
3. Olanow CW, Hauser RA, Gauger L, et al. The effect of deprenyl and levodopa on the progression of Parkinson’s disease. Ann Neurol 1995;38:771-777.
4. Larsen JP, Boas J, Erdal JE. Does selegiline modify the progression of early Parkinson’s disease? Results from a five-year study. The Norwegian-Danish Study Group. Eur J Neurol 1999;6:539-547.
5. Przuntek H, Conrad B, Dichgans J, et al. SELEDO: a 5-year long-term trial on the effect of selegiline in early Parkinsonian patients treated with levodopa. Eur J Neurol 1999;6:141-150.
6. Lees AJ. Comparison of therapeutic effects and mortality data of levodopa and levodopa combined with selegiline in people with early, mild Parkinson’s disease. Parkinson’s Disease Research Group of the United Kingdom. BMJ 1995;311:1602-1607.
7. Counsell C. Effect of adding selegiline to levodopa in early, mild Parkinson’s disease. Formal systematic review of data on patients in all relevant trials is required. BMJ 1998;17:1586.-
8. Ben-Shlomo Y, Churchyard A, Head J, et al. Investigation by Parkinson’s Disease Research Group of United Kingdom into excess mortality seen with combined levodopa and selegiline treatment in patients with early, mild Parkinson’s disease: further results of randomised trial and confidential inquiry. BMJ 1998;316:1191-1196.
9. Olanow CW, Myllyla VV, Sotaniemi K, et al. Effect of selegiline on mortality in patients with Parkinson’s disease: a meta-analysis. Neurology 1998;51:825-830.
10. Impact of deprenyl and tocopherol treatment on Parkinson’s disease in DATATOP patients requiring levodopa. Parkinson Study Group. Ann Neurol 1996;39:37-45.
11. Ramaker C, van Hilten JJ. Bromocriptine versus levodopa in early Parkinson’s disease. The Cochrane Library, Issue 3, 2003. Oxford: Update Software, last updated February 2, 2000. Accessed on April 15, 2003.
12. Ramaker C, van Hilten JJ. Bromocriptine/levodopa combined versus levodopa alone for early Parkinson’s disease (Cochrane Review). The Cochrane Library, Issue 3, 2003. Oxford: Update Software, last updated October 21, 2001. Accessed on April 15, 2003.
13. Lees AJ, Katzenschlager R, Head J, Ben-Shlomo Y. Ten-year follow-up of three different initial treatments in de-novo PD: A randomized trial. Neurology 2001;57:1687-1694.
14. Hely MA, Morris JG, Traficante R, et al. The Sydney multicentre study of Parkinson’s disease: progression and mortality at 10 years. J Neurol Neurosurg Psychiatry 1999;67:300-307.
15. Rinne UK. Lisuride, a dopamine agonist in the treatment of early Parkinson’s disease. Neurology 1989;39:336-339.
16. Allain H, Destee A, Petit H, et al. Five-year follow-up of early lisuride and levodopa combination therapy versus levodopa monotherapy in de novo Parkinson’s disease. The French Lisuride Study Group. Eur Neurol 2000;44:22-30.
17. Rinne U. A 5-year double-blind study with cabergoline versus levodopa in the treatment of early Parkinson’s disease. Parkinsonism Relat Disord 1999;5(suppl):84.-
18. Pramipexole vs levodopa as initial treatment for Parkinson disease: A randomized controlled trial. Parkinson Study Group. JAMA 2000;284:1931-1938.
19. Oertel W. Pergolide or levodopa for Parkinson’s therapy? 6th International Congress of Parkinson’s Disease and Movement Disorders, June 11–15, 2000. Available at: http://www.parkinsonsdisease.com/news/N100_arc.HTM #Pergolide. Accessed on April 15, 2003.
20. Miyasaki JM, Martin W, Suchowersky O, Weiner WJ, Lang AE. Practice parameter: initiation of treatment for Parkinson’s disease: An evidence-based review: report of the Quality Standards Subcommittee of the American Academy of Neurology. Neurology 2002;58:11-17.
1. Myllyla VV, Sotaniemi KA, Vuorinen JA, Heinonen EH. Selegiline as initial treatment in de novo parkinsonian patients. Neurology 1992;42:339-343.
2. Effects of tocopherol and deprenyl on the progression of disability in early Parkinson’s disease. The Parkinson Study Group. N Engl J Med 1993;328:176-183.
3. Olanow CW, Hauser RA, Gauger L, et al. The effect of deprenyl and levodopa on the progression of Parkinson’s disease. Ann Neurol 1995;38:771-777.
4. Larsen JP, Boas J, Erdal JE. Does selegiline modify the progression of early Parkinson’s disease? Results from a five-year study. The Norwegian-Danish Study Group. Eur J Neurol 1999;6:539-547.
5. Przuntek H, Conrad B, Dichgans J, et al. SELEDO: a 5-year long-term trial on the effect of selegiline in early Parkinsonian patients treated with levodopa. Eur J Neurol 1999;6:141-150.
6. Lees AJ. Comparison of therapeutic effects and mortality data of levodopa and levodopa combined with selegiline in people with early, mild Parkinson’s disease. Parkinson’s Disease Research Group of the United Kingdom. BMJ 1995;311:1602-1607.
7. Counsell C. Effect of adding selegiline to levodopa in early, mild Parkinson’s disease. Formal systematic review of data on patients in all relevant trials is required. BMJ 1998;17:1586.-
8. Ben-Shlomo Y, Churchyard A, Head J, et al. Investigation by Parkinson’s Disease Research Group of United Kingdom into excess mortality seen with combined levodopa and selegiline treatment in patients with early, mild Parkinson’s disease: further results of randomised trial and confidential inquiry. BMJ 1998;316:1191-1196.
9. Olanow CW, Myllyla VV, Sotaniemi K, et al. Effect of selegiline on mortality in patients with Parkinson’s disease: a meta-analysis. Neurology 1998;51:825-830.
10. Impact of deprenyl and tocopherol treatment on Parkinson’s disease in DATATOP patients requiring levodopa. Parkinson Study Group. Ann Neurol 1996;39:37-45.
11. Ramaker C, van Hilten JJ. Bromocriptine versus levodopa in early Parkinson’s disease. The Cochrane Library, Issue 3, 2003. Oxford: Update Software, last updated February 2, 2000. Accessed on April 15, 2003.
12. Ramaker C, van Hilten JJ. Bromocriptine/levodopa combined versus levodopa alone for early Parkinson’s disease (Cochrane Review). The Cochrane Library, Issue 3, 2003. Oxford: Update Software, last updated October 21, 2001. Accessed on April 15, 2003.
13. Lees AJ, Katzenschlager R, Head J, Ben-Shlomo Y. Ten-year follow-up of three different initial treatments in de-novo PD: A randomized trial. Neurology 2001;57:1687-1694.
14. Hely MA, Morris JG, Traficante R, et al. The Sydney multicentre study of Parkinson’s disease: progression and mortality at 10 years. J Neurol Neurosurg Psychiatry 1999;67:300-307.
15. Rinne UK. Lisuride, a dopamine agonist in the treatment of early Parkinson’s disease. Neurology 1989;39:336-339.
16. Allain H, Destee A, Petit H, et al. Five-year follow-up of early lisuride and levodopa combination therapy versus levodopa monotherapy in de novo Parkinson’s disease. The French Lisuride Study Group. Eur Neurol 2000;44:22-30.
17. Rinne U. A 5-year double-blind study with cabergoline versus levodopa in the treatment of early Parkinson’s disease. Parkinsonism Relat Disord 1999;5(suppl):84.-
18. Pramipexole vs levodopa as initial treatment for Parkinson disease: A randomized controlled trial. Parkinson Study Group. JAMA 2000;284:1931-1938.
19. Oertel W. Pergolide or levodopa for Parkinson’s therapy? 6th International Congress of Parkinson’s Disease and Movement Disorders, June 11–15, 2000. Available at: http://www.parkinsonsdisease.com/news/N100_arc.HTM #Pergolide. Accessed on April 15, 2003.
20. Miyasaki JM, Martin W, Suchowersky O, Weiner WJ, Lang AE. Practice parameter: initiation of treatment for Parkinson’s disease: An evidence-based review: report of the Quality Standards Subcommittee of the American Academy of Neurology. Neurology 2002;58:11-17.
Evidence-based answers from the Family Physicians Inquiries Network
Which infants need lumbar puncture for suspected sepsis?
Evidence from prospective and retrospective clinical trials suggests that for infants <2 months old, only those at high risk for serious bacterial infection by standardized criteria (eg, Rochester classification) require lumbar puncture (strength of recommendation [SOR]: B, based on prospective and retrospective cohort studies). However, expert opinion suggests lumbar puncture on all infants aged 0 to 28 days with suspected sepsis, and all infants aged >2 months who are to receive empiric antibiotics (SOR: C, based on expert opinion).
Evidence summary
Standardized clinical criteria (Table) exist to determine the risk of serious bacterial infection, which includes meningitis; of particular note, these criteria do not require cerebrospinal fluid examination. Infants aged <3 months who fall into the “high-risk” category or appear toxic have 21% probability of a serious bacterial infection, 10% probability of bacteremia, and 2% probability of bacterial meningitis.1 The “low-risk” infants have a correspondingly lower incidence of serious bacterial infection: the negative predictive value of the Rochester classification is 98.9% (95% confidence interval [CI], 97.2–99.6%).2
The negative predictive value for bacterial meningitis (a subset of serious bacterial infection) is even greater. Five studies applied the standardized criteria to febrile infants and monitored them for the development of serious bacterial infection, including meningitis. Two prospective cohort studies of outpatients aged 0 to 2 months used the Rochester criteria to assign infants to risk groups. They studied a total of 1294 infants; 659 (51%) were low-risk. None of the low-risk infants developed bacterial meningitis.2,3
One prospective cohort study of infants aged <1 month hospitalized for fever used a similar method for assessing risk, but added a C-reactive protein value <20 mg/L to criteria for low-risk. Of 250 infants studied, 131 (52%) were low-risk; none of these developed bacterial meningitis.4
A retrospective chart review of 492 infants aged <3 months who were hospitalized due to fever included 108 infants aged <1 month. Thirty percent (114) of the infants aged 1 to 3 months and 67% (72) of the younger infants underwent lumbar puncture at the discretion of the treating physician. All infants were retrospectively assigned to low- or high-risk groups for serious bacterial infection using the Rochester criteria. Of the 296 infants rated “low-risk,” none developed bacterial meningitis. Ten of these infants subsequently developed evidence of another bacterial focus (predominantly urinary tract infection).5
RECOMMENDATIONS FROM OTHERS
The American Academy of Pediatrics has not issued a clinical practice guideline or clinical report addressing this issue. An evidence-based guideline developed at Cincinnati Children’s Hospital Medical Center in 1998 recommends hospitalization and a full sepsis workup (including lumbar puncture) for infants aged <1 month, or infants aged 1 to 2 months who are high-risk.6
A clinical review-based guideline published in 1993 gives the same recommendations.7 The expert panel that devised this guideline emphasized a full sepsis evaluation (including cerebrospinal fluid cultures) for infants <28 days of age “despite the low probability of serious bacterial infections in this age group and the favorable outcome of the children managed to date with careful observation.” For low-risk infants aged 1 to 2 months, lumbar puncture is not necessary unless empiric antibiotics are given; having a cerebrospinal fluid culture prior to empiric antibiotics reduces the concern of partially treated meningitis in the case of clinical deterioration after hospital discharge.6,7
TABLE
How to identify infants at low risk of serious bacterial infection: Rochester Classification
Febrile infants (temperature ≥38°C, 100.4°F) ≥60 days of age who meet all criteria are at low risk of serious bacterial infection: | |
---|---|
General health | Born at ≥37 weeks’ gestation |
Did not receive perinatal or antenatal antibiotics | |
Was not treated for unexplained hyperbilirubinemia | |
Was not hospitalized in the nursery longer than the mother | |
Has had no hospitalization since discharge | |
No diagnosed chronic or underlying illnesses | |
Physical findings | Appears well and nontoxic |
No evidence of skin, soft tissue, bone, or joint abnormalities, or otitis media | |
Laboratory findings | Peripheral total white blood cells 5,000–15,000/mm3 |
Absolute band form leukocytes <1,500/mm3 | |
Spun urine sediment <10 white blood cells per high power field | |
Fresh stool smear <5 white blood cells per high power field |
Evaluating fever in infants: judging the risks
Randy Ward, MD
Family Medicine/Psychiatry Residency, Medical College of Wisconsin, Milwaukee
The evaluation of the febrile infant is often fraught with anxiety. Physicians must balance the potentially devastating consequences of a missed serious bacterial infection with the desire to avoid unnecessary work-ups.
In the past, guidelines have had an extremely conservative viewpoint, essentially grouping all infants by age, and recommended an extensive inpatient work-up regardless of clinical status. The Rochester Criteria have provided guidelines for clinical risk stratification in this age group, allowing a more rational approach to the workup. The above data provide further useful guidance for the appropriate use of lumbar puncture in evaluation of these infants.
1. Baraff LJ, Oslund SA, Schriger DL, Stephen ML. Probability of bacterial infections in febrile infants less than three months of age: a meta-analysis. Pediatr Infect Dis J 1992;11:257-264.
2. Jaskiewicz JA, McCarthy CA, Richardson AC, et al. Febrile infants at low risk for serious bacterial infection—an appraisal of the Rochester criteria and implications for management. Febrile Infant Collaborative Study Group. Pediatrics 1994;94:390-396.
3. Dagan R, Sofer S, Phillip M, Shachak E. Ambulatory care of febrile infants younger than 2 months of age classified as being at low risk for having serious bacterial infections. J Pediatr 1988;112:355-360.
4. Chiu CH, Lin TY, Bullard MJ. Identification of febrile neonates unlikely to have bacterial infection. Pediatr Infect Dis J 1997;16:59-63.
5. Brik R, Hamissah R, Shehada N, Berant M. Evaluation of febrile infants under 3 months of age: is routine lumbar puncture warranted?. Isr J Med Sci 1997;33:93-97.
6. Cincinnati Children’s Hospital Medical Center. Evidence based clinical protocol guideline for fever of uncertain source in infants 60 days of age or less. Cincinnati, Ohio: Cincinnati Children’s Hospital Medical Center; 1998.
7. Baraff LJ, Bass JW, Fleisher GR, et al. Practice guideline for the management of infants and children 0 to 36 months of age with fever without source. Agency for Health Care Policy and Research. Ann Emerg Med 1993;22:1198-1210.
Evidence from prospective and retrospective clinical trials suggests that for infants <2 months old, only those at high risk for serious bacterial infection by standardized criteria (eg, Rochester classification) require lumbar puncture (strength of recommendation [SOR]: B, based on prospective and retrospective cohort studies). However, expert opinion suggests lumbar puncture on all infants aged 0 to 28 days with suspected sepsis, and all infants aged >2 months who are to receive empiric antibiotics (SOR: C, based on expert opinion).
Evidence summary
Standardized clinical criteria (Table) exist to determine the risk of serious bacterial infection, which includes meningitis; of particular note, these criteria do not require cerebrospinal fluid examination. Infants aged <3 months who fall into the “high-risk” category or appear toxic have 21% probability of a serious bacterial infection, 10% probability of bacteremia, and 2% probability of bacterial meningitis.1 The “low-risk” infants have a correspondingly lower incidence of serious bacterial infection: the negative predictive value of the Rochester classification is 98.9% (95% confidence interval [CI], 97.2–99.6%).2
The negative predictive value for bacterial meningitis (a subset of serious bacterial infection) is even greater. Five studies applied the standardized criteria to febrile infants and monitored them for the development of serious bacterial infection, including meningitis. Two prospective cohort studies of outpatients aged 0 to 2 months used the Rochester criteria to assign infants to risk groups. They studied a total of 1294 infants; 659 (51%) were low-risk. None of the low-risk infants developed bacterial meningitis.2,3
One prospective cohort study of infants aged <1 month hospitalized for fever used a similar method for assessing risk, but added a C-reactive protein value <20 mg/L to criteria for low-risk. Of 250 infants studied, 131 (52%) were low-risk; none of these developed bacterial meningitis.4
A retrospective chart review of 492 infants aged <3 months who were hospitalized due to fever included 108 infants aged <1 month. Thirty percent (114) of the infants aged 1 to 3 months and 67% (72) of the younger infants underwent lumbar puncture at the discretion of the treating physician. All infants were retrospectively assigned to low- or high-risk groups for serious bacterial infection using the Rochester criteria. Of the 296 infants rated “low-risk,” none developed bacterial meningitis. Ten of these infants subsequently developed evidence of another bacterial focus (predominantly urinary tract infection).5
RECOMMENDATIONS FROM OTHERS
The American Academy of Pediatrics has not issued a clinical practice guideline or clinical report addressing this issue. An evidence-based guideline developed at Cincinnati Children’s Hospital Medical Center in 1998 recommends hospitalization and a full sepsis workup (including lumbar puncture) for infants aged <1 month, or infants aged 1 to 2 months who are high-risk.6
A clinical review-based guideline published in 1993 gives the same recommendations.7 The expert panel that devised this guideline emphasized a full sepsis evaluation (including cerebrospinal fluid cultures) for infants <28 days of age “despite the low probability of serious bacterial infections in this age group and the favorable outcome of the children managed to date with careful observation.” For low-risk infants aged 1 to 2 months, lumbar puncture is not necessary unless empiric antibiotics are given; having a cerebrospinal fluid culture prior to empiric antibiotics reduces the concern of partially treated meningitis in the case of clinical deterioration after hospital discharge.6,7
TABLE
How to identify infants at low risk of serious bacterial infection: Rochester Classification
Febrile infants (temperature ≥38°C, 100.4°F) ≥60 days of age who meet all criteria are at low risk of serious bacterial infection: | |
---|---|
General health | Born at ≥37 weeks’ gestation |
Did not receive perinatal or antenatal antibiotics | |
Was not treated for unexplained hyperbilirubinemia | |
Was not hospitalized in the nursery longer than the mother | |
Has had no hospitalization since discharge | |
No diagnosed chronic or underlying illnesses | |
Physical findings | Appears well and nontoxic |
No evidence of skin, soft tissue, bone, or joint abnormalities, or otitis media | |
Laboratory findings | Peripheral total white blood cells 5,000–15,000/mm3 |
Absolute band form leukocytes <1,500/mm3 | |
Spun urine sediment <10 white blood cells per high power field | |
Fresh stool smear <5 white blood cells per high power field |
Evaluating fever in infants: judging the risks
Randy Ward, MD
Family Medicine/Psychiatry Residency, Medical College of Wisconsin, Milwaukee
The evaluation of the febrile infant is often fraught with anxiety. Physicians must balance the potentially devastating consequences of a missed serious bacterial infection with the desire to avoid unnecessary work-ups.
In the past, guidelines have had an extremely conservative viewpoint, essentially grouping all infants by age, and recommended an extensive inpatient work-up regardless of clinical status. The Rochester Criteria have provided guidelines for clinical risk stratification in this age group, allowing a more rational approach to the workup. The above data provide further useful guidance for the appropriate use of lumbar puncture in evaluation of these infants.
Evidence from prospective and retrospective clinical trials suggests that for infants <2 months old, only those at high risk for serious bacterial infection by standardized criteria (eg, Rochester classification) require lumbar puncture (strength of recommendation [SOR]: B, based on prospective and retrospective cohort studies). However, expert opinion suggests lumbar puncture on all infants aged 0 to 28 days with suspected sepsis, and all infants aged >2 months who are to receive empiric antibiotics (SOR: C, based on expert opinion).
Evidence summary
Standardized clinical criteria (Table) exist to determine the risk of serious bacterial infection, which includes meningitis; of particular note, these criteria do not require cerebrospinal fluid examination. Infants aged <3 months who fall into the “high-risk” category or appear toxic have 21% probability of a serious bacterial infection, 10% probability of bacteremia, and 2% probability of bacterial meningitis.1 The “low-risk” infants have a correspondingly lower incidence of serious bacterial infection: the negative predictive value of the Rochester classification is 98.9% (95% confidence interval [CI], 97.2–99.6%).2
The negative predictive value for bacterial meningitis (a subset of serious bacterial infection) is even greater. Five studies applied the standardized criteria to febrile infants and monitored them for the development of serious bacterial infection, including meningitis. Two prospective cohort studies of outpatients aged 0 to 2 months used the Rochester criteria to assign infants to risk groups. They studied a total of 1294 infants; 659 (51%) were low-risk. None of the low-risk infants developed bacterial meningitis.2,3
One prospective cohort study of infants aged <1 month hospitalized for fever used a similar method for assessing risk, but added a C-reactive protein value <20 mg/L to criteria for low-risk. Of 250 infants studied, 131 (52%) were low-risk; none of these developed bacterial meningitis.4
A retrospective chart review of 492 infants aged <3 months who were hospitalized due to fever included 108 infants aged <1 month. Thirty percent (114) of the infants aged 1 to 3 months and 67% (72) of the younger infants underwent lumbar puncture at the discretion of the treating physician. All infants were retrospectively assigned to low- or high-risk groups for serious bacterial infection using the Rochester criteria. Of the 296 infants rated “low-risk,” none developed bacterial meningitis. Ten of these infants subsequently developed evidence of another bacterial focus (predominantly urinary tract infection).5
RECOMMENDATIONS FROM OTHERS
The American Academy of Pediatrics has not issued a clinical practice guideline or clinical report addressing this issue. An evidence-based guideline developed at Cincinnati Children’s Hospital Medical Center in 1998 recommends hospitalization and a full sepsis workup (including lumbar puncture) for infants aged <1 month, or infants aged 1 to 2 months who are high-risk.6
A clinical review-based guideline published in 1993 gives the same recommendations.7 The expert panel that devised this guideline emphasized a full sepsis evaluation (including cerebrospinal fluid cultures) for infants <28 days of age “despite the low probability of serious bacterial infections in this age group and the favorable outcome of the children managed to date with careful observation.” For low-risk infants aged 1 to 2 months, lumbar puncture is not necessary unless empiric antibiotics are given; having a cerebrospinal fluid culture prior to empiric antibiotics reduces the concern of partially treated meningitis in the case of clinical deterioration after hospital discharge.6,7
TABLE
How to identify infants at low risk of serious bacterial infection: Rochester Classification
Febrile infants (temperature ≥38°C, 100.4°F) ≥60 days of age who meet all criteria are at low risk of serious bacterial infection: | |
---|---|
General health | Born at ≥37 weeks’ gestation |
Did not receive perinatal or antenatal antibiotics | |
Was not treated for unexplained hyperbilirubinemia | |
Was not hospitalized in the nursery longer than the mother | |
Has had no hospitalization since discharge | |
No diagnosed chronic or underlying illnesses | |
Physical findings | Appears well and nontoxic |
No evidence of skin, soft tissue, bone, or joint abnormalities, or otitis media | |
Laboratory findings | Peripheral total white blood cells 5,000–15,000/mm3 |
Absolute band form leukocytes <1,500/mm3 | |
Spun urine sediment <10 white blood cells per high power field | |
Fresh stool smear <5 white blood cells per high power field |
Evaluating fever in infants: judging the risks
Randy Ward, MD
Family Medicine/Psychiatry Residency, Medical College of Wisconsin, Milwaukee
The evaluation of the febrile infant is often fraught with anxiety. Physicians must balance the potentially devastating consequences of a missed serious bacterial infection with the desire to avoid unnecessary work-ups.
In the past, guidelines have had an extremely conservative viewpoint, essentially grouping all infants by age, and recommended an extensive inpatient work-up regardless of clinical status. The Rochester Criteria have provided guidelines for clinical risk stratification in this age group, allowing a more rational approach to the workup. The above data provide further useful guidance for the appropriate use of lumbar puncture in evaluation of these infants.
1. Baraff LJ, Oslund SA, Schriger DL, Stephen ML. Probability of bacterial infections in febrile infants less than three months of age: a meta-analysis. Pediatr Infect Dis J 1992;11:257-264.
2. Jaskiewicz JA, McCarthy CA, Richardson AC, et al. Febrile infants at low risk for serious bacterial infection—an appraisal of the Rochester criteria and implications for management. Febrile Infant Collaborative Study Group. Pediatrics 1994;94:390-396.
3. Dagan R, Sofer S, Phillip M, Shachak E. Ambulatory care of febrile infants younger than 2 months of age classified as being at low risk for having serious bacterial infections. J Pediatr 1988;112:355-360.
4. Chiu CH, Lin TY, Bullard MJ. Identification of febrile neonates unlikely to have bacterial infection. Pediatr Infect Dis J 1997;16:59-63.
5. Brik R, Hamissah R, Shehada N, Berant M. Evaluation of febrile infants under 3 months of age: is routine lumbar puncture warranted?. Isr J Med Sci 1997;33:93-97.
6. Cincinnati Children’s Hospital Medical Center. Evidence based clinical protocol guideline for fever of uncertain source in infants 60 days of age or less. Cincinnati, Ohio: Cincinnati Children’s Hospital Medical Center; 1998.
7. Baraff LJ, Bass JW, Fleisher GR, et al. Practice guideline for the management of infants and children 0 to 36 months of age with fever without source. Agency for Health Care Policy and Research. Ann Emerg Med 1993;22:1198-1210.
1. Baraff LJ, Oslund SA, Schriger DL, Stephen ML. Probability of bacterial infections in febrile infants less than three months of age: a meta-analysis. Pediatr Infect Dis J 1992;11:257-264.
2. Jaskiewicz JA, McCarthy CA, Richardson AC, et al. Febrile infants at low risk for serious bacterial infection—an appraisal of the Rochester criteria and implications for management. Febrile Infant Collaborative Study Group. Pediatrics 1994;94:390-396.
3. Dagan R, Sofer S, Phillip M, Shachak E. Ambulatory care of febrile infants younger than 2 months of age classified as being at low risk for having serious bacterial infections. J Pediatr 1988;112:355-360.
4. Chiu CH, Lin TY, Bullard MJ. Identification of febrile neonates unlikely to have bacterial infection. Pediatr Infect Dis J 1997;16:59-63.
5. Brik R, Hamissah R, Shehada N, Berant M. Evaluation of febrile infants under 3 months of age: is routine lumbar puncture warranted?. Isr J Med Sci 1997;33:93-97.
6. Cincinnati Children’s Hospital Medical Center. Evidence based clinical protocol guideline for fever of uncertain source in infants 60 days of age or less. Cincinnati, Ohio: Cincinnati Children’s Hospital Medical Center; 1998.
7. Baraff LJ, Bass JW, Fleisher GR, et al. Practice guideline for the management of infants and children 0 to 36 months of age with fever without source. Agency for Health Care Policy and Research. Ann Emerg Med 1993;22:1198-1210.
Evidence-based answers from the Family Physicians Inquiries Network
Does a knee brace decrease recurrent ACL injuries?
After surgical anterior cruciate ligament (ACL) reconstruction, knee bracing does not significantly protect against injury during recovery or afterwards (strength of recommendation [SOR]: C, based on expert opinion). In addition, the use of a knee brace following ACL reconstruction does not improve stability or hasten rehabilitation, either immediately or for up to 2 years (SOR: A, based on randomized controlled trials with heterogenous results).
Patients wearing a knee brace after ACL reconstruction may report subjective enhanced performance, but measured performance is better without the brace (SOR: B, based on an individual case-control study).
We found no information specifically about functional bracing following ACL injuries that have been managed conservatively.
Evidence summary
Functional braces are designed to provide stability for the unstable knee, but few trials report re-injury rates as an outcome. Cadaver studies show that braces limit tibial rotation and anteroposterior translation. However, the mechanical effects of knee bracing in vivo are controversial.
A study involving 5 patients with chronic unstable ACL injuries showed some limitation of movement with functional bracing, but it was accompanied by slowed muscle performance and used only low-stress forces.1 Objective findings during physiologic stress loads are inconclusive.2
Three recent randomized controlled trials compared functional bracing with no bracing in rehabilitation after ACL reconstruction. In a prospective study of 62 patients, researchers found no benefit from using a postoperative knee brace at any stage (2 and 6 weeks; 3, 6, and 24 months) after surgery. Moreover, the brace did not contribute to a more stable knee during rehabilitation or 2-year follow-up.3
A similar study of 50 patients demonstrated no significant difference in function or laxity at 2 years.4 A 2-year study comparing 30 braced with 30 nonbraced patients showed improved functional stability (P<.05) but increased thigh muscle atrophy (P<.0001) at 3-month follow-up in the braced group. However, no significant differences were seen at other follow-up intervals up to 2 years.5
One study evaluated running, jumping, and turning performance with and without a functional brace in 31 patients who had had an ACL reconstruction 5 to 26 months previously. They measured significantly better performance without bracing; however, more than half the group perceived enhanced performance with the brace.6
RECOMMENDATIONS FROM OTHERS
The American Association of Orthopaedic Surgeons believes that rehabilitative and functional knee braces can be effective in many treatment programs. Rehabilitative braces are more effective in protecting against excessive flexion and extension than against anterior and posterior motion. Functional braces reduce abnormal movement under low load conditions but do not restore normal knee stability under high forces related to certain athletic activities. Physician and patient must guard against a false sense of security.7
The American Academy of Pediatrics says that functional braces may help prevent further injury to a previously injured knee. Their use is accepted clinically on the basis of subjective performance. If used, knee braces should complement rehabilitative therapy and required surgery.8
Knee braces no substitute for rehabilitation, but patients say they help
James L. Lord, MD
Sports Medicine Director, Mercy Family Medicine, St. John’s Mercy Medical Center, St. Louis, Mo
A key question all clinicians must ask is who is being treated—the patient, yourself, or some third-party payer. While multiple studies on knee bracing after ACL reconstruction have not demonstrated improved knee stability or faster recovery times, many patients have reported subjective improvement in function.
As long as patients understand that a brace does not substitute for vigorous rehabilitation to improve strength, flexibility, and proprioception, I find no compelling reason to discourage its use after a patient is allowed to return to unrestricted activities.
Cost may then become the major deciding factor, but even off-the-shelf braces or neoprene sleeves may be sufficient to provide the subjective benefit.
1. Wojtys EM, Kothari SU, Huston LJ. Anterior cruciate ligament functional brace use in sports. Am J Sports Med 1996;24:539-546.
2. Paluska SA, McKeag DB. Knee braces: current evidence and clinical recommendations for their use. Am Fam Physician 2000;61:411–18, 423-424.
3. Moller E, Forssblad M, Hansson L, Wange P, Weidenhielm L. Bracing versus nonbracing in rehabilitation after anterior cruciate ligament reconstruction: a randomized prospective study with 2-year follow-up. Knee Surg Sports Traumatol Arthrosc 2001;9:102-108.
4. Brandsson S, Faxen E, Kartus J, Eriksson BI, Karlsson J. Is a knee brace advantageous after anterior cruciate ligament surgery? A prospective, randomised study with a two year follow-up. Scand J Med Sci Sports 2001;11:110-114.
5. Risberg MA, Holm I, Steen H, Eriksson J, Ekeland A. The effect of knee bracing after anterior cruciate ligament reconstruction. A prospective, randomized study with two years’ follow-up. Am J Sports Med 1999;27:76-83.
6. Wu GK, Ng GY, Mak AF. Effects of knee bracing on the functional performance of patients with anterior cruciate ligament reconstruction. Arch Phys Med Rehabil 2001;82:282-285.
7. American Academy of Orthopaedic Surgeons. Position Statement on the use of knee braces. Document number 1124, October 1997. Available at: www.aaos.org/ wordhtml/papers/position/1124.htm. Accessed on September 5, 2003.
8. Martin TJ. Committee on Sports Medicine and Fitness. American Academy of Pediatrics. Technical Report: knee brace use in the young athlete. Policy Statement. Pediatrics 2001;108:503-507.
After surgical anterior cruciate ligament (ACL) reconstruction, knee bracing does not significantly protect against injury during recovery or afterwards (strength of recommendation [SOR]: C, based on expert opinion). In addition, the use of a knee brace following ACL reconstruction does not improve stability or hasten rehabilitation, either immediately or for up to 2 years (SOR: A, based on randomized controlled trials with heterogenous results).
Patients wearing a knee brace after ACL reconstruction may report subjective enhanced performance, but measured performance is better without the brace (SOR: B, based on an individual case-control study).
We found no information specifically about functional bracing following ACL injuries that have been managed conservatively.
Evidence summary
Functional braces are designed to provide stability for the unstable knee, but few trials report re-injury rates as an outcome. Cadaver studies show that braces limit tibial rotation and anteroposterior translation. However, the mechanical effects of knee bracing in vivo are controversial.
A study involving 5 patients with chronic unstable ACL injuries showed some limitation of movement with functional bracing, but it was accompanied by slowed muscle performance and used only low-stress forces.1 Objective findings during physiologic stress loads are inconclusive.2
Three recent randomized controlled trials compared functional bracing with no bracing in rehabilitation after ACL reconstruction. In a prospective study of 62 patients, researchers found no benefit from using a postoperative knee brace at any stage (2 and 6 weeks; 3, 6, and 24 months) after surgery. Moreover, the brace did not contribute to a more stable knee during rehabilitation or 2-year follow-up.3
A similar study of 50 patients demonstrated no significant difference in function or laxity at 2 years.4 A 2-year study comparing 30 braced with 30 nonbraced patients showed improved functional stability (P<.05) but increased thigh muscle atrophy (P<.0001) at 3-month follow-up in the braced group. However, no significant differences were seen at other follow-up intervals up to 2 years.5
One study evaluated running, jumping, and turning performance with and without a functional brace in 31 patients who had had an ACL reconstruction 5 to 26 months previously. They measured significantly better performance without bracing; however, more than half the group perceived enhanced performance with the brace.6
RECOMMENDATIONS FROM OTHERS
The American Association of Orthopaedic Surgeons believes that rehabilitative and functional knee braces can be effective in many treatment programs. Rehabilitative braces are more effective in protecting against excessive flexion and extension than against anterior and posterior motion. Functional braces reduce abnormal movement under low load conditions but do not restore normal knee stability under high forces related to certain athletic activities. Physician and patient must guard against a false sense of security.7
The American Academy of Pediatrics says that functional braces may help prevent further injury to a previously injured knee. Their use is accepted clinically on the basis of subjective performance. If used, knee braces should complement rehabilitative therapy and required surgery.8
Knee braces no substitute for rehabilitation, but patients say they help
James L. Lord, MD
Sports Medicine Director, Mercy Family Medicine, St. John’s Mercy Medical Center, St. Louis, Mo
A key question all clinicians must ask is who is being treated—the patient, yourself, or some third-party payer. While multiple studies on knee bracing after ACL reconstruction have not demonstrated improved knee stability or faster recovery times, many patients have reported subjective improvement in function.
As long as patients understand that a brace does not substitute for vigorous rehabilitation to improve strength, flexibility, and proprioception, I find no compelling reason to discourage its use after a patient is allowed to return to unrestricted activities.
Cost may then become the major deciding factor, but even off-the-shelf braces or neoprene sleeves may be sufficient to provide the subjective benefit.
After surgical anterior cruciate ligament (ACL) reconstruction, knee bracing does not significantly protect against injury during recovery or afterwards (strength of recommendation [SOR]: C, based on expert opinion). In addition, the use of a knee brace following ACL reconstruction does not improve stability or hasten rehabilitation, either immediately or for up to 2 years (SOR: A, based on randomized controlled trials with heterogenous results).
Patients wearing a knee brace after ACL reconstruction may report subjective enhanced performance, but measured performance is better without the brace (SOR: B, based on an individual case-control study).
We found no information specifically about functional bracing following ACL injuries that have been managed conservatively.
Evidence summary
Functional braces are designed to provide stability for the unstable knee, but few trials report re-injury rates as an outcome. Cadaver studies show that braces limit tibial rotation and anteroposterior translation. However, the mechanical effects of knee bracing in vivo are controversial.
A study involving 5 patients with chronic unstable ACL injuries showed some limitation of movement with functional bracing, but it was accompanied by slowed muscle performance and used only low-stress forces.1 Objective findings during physiologic stress loads are inconclusive.2
Three recent randomized controlled trials compared functional bracing with no bracing in rehabilitation after ACL reconstruction. In a prospective study of 62 patients, researchers found no benefit from using a postoperative knee brace at any stage (2 and 6 weeks; 3, 6, and 24 months) after surgery. Moreover, the brace did not contribute to a more stable knee during rehabilitation or 2-year follow-up.3
A similar study of 50 patients demonstrated no significant difference in function or laxity at 2 years.4 A 2-year study comparing 30 braced with 30 nonbraced patients showed improved functional stability (P<.05) but increased thigh muscle atrophy (P<.0001) at 3-month follow-up in the braced group. However, no significant differences were seen at other follow-up intervals up to 2 years.5
One study evaluated running, jumping, and turning performance with and without a functional brace in 31 patients who had had an ACL reconstruction 5 to 26 months previously. They measured significantly better performance without bracing; however, more than half the group perceived enhanced performance with the brace.6
RECOMMENDATIONS FROM OTHERS
The American Association of Orthopaedic Surgeons believes that rehabilitative and functional knee braces can be effective in many treatment programs. Rehabilitative braces are more effective in protecting against excessive flexion and extension than against anterior and posterior motion. Functional braces reduce abnormal movement under low load conditions but do not restore normal knee stability under high forces related to certain athletic activities. Physician and patient must guard against a false sense of security.7
The American Academy of Pediatrics says that functional braces may help prevent further injury to a previously injured knee. Their use is accepted clinically on the basis of subjective performance. If used, knee braces should complement rehabilitative therapy and required surgery.8
Knee braces no substitute for rehabilitation, but patients say they help
James L. Lord, MD
Sports Medicine Director, Mercy Family Medicine, St. John’s Mercy Medical Center, St. Louis, Mo
A key question all clinicians must ask is who is being treated—the patient, yourself, or some third-party payer. While multiple studies on knee bracing after ACL reconstruction have not demonstrated improved knee stability or faster recovery times, many patients have reported subjective improvement in function.
As long as patients understand that a brace does not substitute for vigorous rehabilitation to improve strength, flexibility, and proprioception, I find no compelling reason to discourage its use after a patient is allowed to return to unrestricted activities.
Cost may then become the major deciding factor, but even off-the-shelf braces or neoprene sleeves may be sufficient to provide the subjective benefit.
1. Wojtys EM, Kothari SU, Huston LJ. Anterior cruciate ligament functional brace use in sports. Am J Sports Med 1996;24:539-546.
2. Paluska SA, McKeag DB. Knee braces: current evidence and clinical recommendations for their use. Am Fam Physician 2000;61:411–18, 423-424.
3. Moller E, Forssblad M, Hansson L, Wange P, Weidenhielm L. Bracing versus nonbracing in rehabilitation after anterior cruciate ligament reconstruction: a randomized prospective study with 2-year follow-up. Knee Surg Sports Traumatol Arthrosc 2001;9:102-108.
4. Brandsson S, Faxen E, Kartus J, Eriksson BI, Karlsson J. Is a knee brace advantageous after anterior cruciate ligament surgery? A prospective, randomised study with a two year follow-up. Scand J Med Sci Sports 2001;11:110-114.
5. Risberg MA, Holm I, Steen H, Eriksson J, Ekeland A. The effect of knee bracing after anterior cruciate ligament reconstruction. A prospective, randomized study with two years’ follow-up. Am J Sports Med 1999;27:76-83.
6. Wu GK, Ng GY, Mak AF. Effects of knee bracing on the functional performance of patients with anterior cruciate ligament reconstruction. Arch Phys Med Rehabil 2001;82:282-285.
7. American Academy of Orthopaedic Surgeons. Position Statement on the use of knee braces. Document number 1124, October 1997. Available at: www.aaos.org/ wordhtml/papers/position/1124.htm. Accessed on September 5, 2003.
8. Martin TJ. Committee on Sports Medicine and Fitness. American Academy of Pediatrics. Technical Report: knee brace use in the young athlete. Policy Statement. Pediatrics 2001;108:503-507.
1. Wojtys EM, Kothari SU, Huston LJ. Anterior cruciate ligament functional brace use in sports. Am J Sports Med 1996;24:539-546.
2. Paluska SA, McKeag DB. Knee braces: current evidence and clinical recommendations for their use. Am Fam Physician 2000;61:411–18, 423-424.
3. Moller E, Forssblad M, Hansson L, Wange P, Weidenhielm L. Bracing versus nonbracing in rehabilitation after anterior cruciate ligament reconstruction: a randomized prospective study with 2-year follow-up. Knee Surg Sports Traumatol Arthrosc 2001;9:102-108.
4. Brandsson S, Faxen E, Kartus J, Eriksson BI, Karlsson J. Is a knee brace advantageous after anterior cruciate ligament surgery? A prospective, randomised study with a two year follow-up. Scand J Med Sci Sports 2001;11:110-114.
5. Risberg MA, Holm I, Steen H, Eriksson J, Ekeland A. The effect of knee bracing after anterior cruciate ligament reconstruction. A prospective, randomized study with two years’ follow-up. Am J Sports Med 1999;27:76-83.
6. Wu GK, Ng GY, Mak AF. Effects of knee bracing on the functional performance of patients with anterior cruciate ligament reconstruction. Arch Phys Med Rehabil 2001;82:282-285.
7. American Academy of Orthopaedic Surgeons. Position Statement on the use of knee braces. Document number 1124, October 1997. Available at: www.aaos.org/ wordhtml/papers/position/1124.htm. Accessed on September 5, 2003.
8. Martin TJ. Committee on Sports Medicine and Fitness. American Academy of Pediatrics. Technical Report: knee brace use in the young athlete. Policy Statement. Pediatrics 2001;108:503-507.
Evidence-based answers from the Family Physicians Inquiries Network
Do nasal decongestants relieve symptoms?
Oral and topical nasal decongestants result in a statistically significant improvement in subjective symptoms of nasal congestion and objective nasal airway resistance in adults’ common colds (strength of recommendation [SOR]: A, based on randomized controlled trials). Evidence is lacking to support the use of decongestants in acute sinusitis.
Evidence summary
Nasal congestion is the most common symptom of the common cold, and hundreds of millions of dollars are spent annually on decongestants. A Cochrane review of 4 randomized controlled trials compared single doses of oxymetazoline, pseudoephedrine, and phenylpropanolamine.1 Included studies involved from 30 to 106 participants, were double-blinded and placebo-controlled, used either topical or oral decongestants for symptoms of less than 5 days’ duration, and measured either subjective or objective relief or adverse events. All 4 studies used nasal airway resistance as an objective measure of nasal congestion, and a combined symptom score as a subjective measure of relief. One study also administered a side-effect questionnaire.
In all studies, topical and oral decongestants were equally efficacious, producing a 13% reduction in subjective symptoms and a significant decrease in nasal airway resistance after 1 dose of decongestant. Only 1 study investigated repeated doses of decongestants and found no significant additional improvement from repeated doses over a 5-day period.
More studies are needed to evaluate efficacy of multiple doses. Clinical interpretation of these results must take into consideration that quality-of-life measures were not evaluated and that none of the studies included children under 12.
Limited data are available on decongestants in sinusitis. Most studies focused on the use of nasal corticosteroids. One placebo-controlled, randomized controlled trial evaluated the effect on mucociliary clearance from adding nasal saline, nasal steroids, or oxymetazoline to antibiotics in acute bacterial sinusitis.2 The group using oxymetazoline increased mucociliary clearance immediately (within 20 minutes). However, at 3 weeks, the improvement in mucociliary clearance in the oxymetazoline group was not significantly different than in the other groups.
An additional prospective, placebo-controlled study evaluated improvement in x-ray findings as well as subjective symptoms in acute sinusitis using phenoxymethyl-penicillin (penicillin V) in combination with oxymetazoline or placebo administered via a variety of nasal delivery systems.3 Oxymetazoline was not significantly different from placebo. Controlled prospective studies are lacking to support the use of decongestants in acute sinusitis.
Recommendations from others
Expert opinion from Current Clinical Topics in Infectious Diseases does not recommend the use of decongestants in sinusitis or the common cold in the absence of concurrent allergic rhinosinusitis.4 This recommendation is based on the lack of evidence regarding efficacy and the known rebound congestion associated with topical decongestants. If a decongestant is prescribed, the oral route is preferred, with the understanding of potential significant side effects of nervousness, insomnia, tachycardia, and hypertension.
Decongestants can do more harm than good
Russell W. Roberts, MD
Louisiana State University Health Sciences Center, Shreveport
Never one to have been impressed with most of the current symptomatic treatments available for the common cold, I have for years been amazed at how quick the public is to purchase and repeatedly use these products.
While a judicious course of decongestants can ease the congestion, when misused they often cause significant harm and discomfort that is difficult to resolve. Patients whom I have assisted through successful discontinuance of topical nasal decongestants are among the most appreciative in my practice.
1. Taverner D, Bickford L, Draper M. Nasal decongestants for the common cold. Cochrane Database Syst Rev 2000;(2):CD001953. Updated quarterly.
2. Inanli S, Ozturk O, Korkmaz M, Tutkun A, Batman C. The effects of topical agents of fluticasone propionate, oxymetazoline, and 3% and 0.9% sodium chloride solutions on mucociliary clearance in the therapy of acute bacterial rhinosinusitis in vivo. Laryngoscope 2002;112:320-325.
3. Wiklund L, Stierna P, Berglund R, Westrin KM, Tonnesson M. The efficacy of oxymetazoline administered with a nasal bellows container and combined with oral phenoxymethyl-penicillin in the treatment of acute maxillary sinusitis. Acta Otolaryngol Suppl 1994;515:57-64.
4. Chow AW. Acute sinusitis: current status of etiologies, diagnosis, and treatment. Curr Clin Top Infect Dis 2001;21:31-63.
Oral and topical nasal decongestants result in a statistically significant improvement in subjective symptoms of nasal congestion and objective nasal airway resistance in adults’ common colds (strength of recommendation [SOR]: A, based on randomized controlled trials). Evidence is lacking to support the use of decongestants in acute sinusitis.
Evidence summary
Nasal congestion is the most common symptom of the common cold, and hundreds of millions of dollars are spent annually on decongestants. A Cochrane review of 4 randomized controlled trials compared single doses of oxymetazoline, pseudoephedrine, and phenylpropanolamine.1 Included studies involved from 30 to 106 participants, were double-blinded and placebo-controlled, used either topical or oral decongestants for symptoms of less than 5 days’ duration, and measured either subjective or objective relief or adverse events. All 4 studies used nasal airway resistance as an objective measure of nasal congestion, and a combined symptom score as a subjective measure of relief. One study also administered a side-effect questionnaire.
In all studies, topical and oral decongestants were equally efficacious, producing a 13% reduction in subjective symptoms and a significant decrease in nasal airway resistance after 1 dose of decongestant. Only 1 study investigated repeated doses of decongestants and found no significant additional improvement from repeated doses over a 5-day period.
More studies are needed to evaluate efficacy of multiple doses. Clinical interpretation of these results must take into consideration that quality-of-life measures were not evaluated and that none of the studies included children under 12.
Limited data are available on decongestants in sinusitis. Most studies focused on the use of nasal corticosteroids. One placebo-controlled, randomized controlled trial evaluated the effect on mucociliary clearance from adding nasal saline, nasal steroids, or oxymetazoline to antibiotics in acute bacterial sinusitis.2 The group using oxymetazoline increased mucociliary clearance immediately (within 20 minutes). However, at 3 weeks, the improvement in mucociliary clearance in the oxymetazoline group was not significantly different than in the other groups.
An additional prospective, placebo-controlled study evaluated improvement in x-ray findings as well as subjective symptoms in acute sinusitis using phenoxymethyl-penicillin (penicillin V) in combination with oxymetazoline or placebo administered via a variety of nasal delivery systems.3 Oxymetazoline was not significantly different from placebo. Controlled prospective studies are lacking to support the use of decongestants in acute sinusitis.
Recommendations from others
Expert opinion from Current Clinical Topics in Infectious Diseases does not recommend the use of decongestants in sinusitis or the common cold in the absence of concurrent allergic rhinosinusitis.4 This recommendation is based on the lack of evidence regarding efficacy and the known rebound congestion associated with topical decongestants. If a decongestant is prescribed, the oral route is preferred, with the understanding of potential significant side effects of nervousness, insomnia, tachycardia, and hypertension.
Decongestants can do more harm than good
Russell W. Roberts, MD
Louisiana State University Health Sciences Center, Shreveport
Never one to have been impressed with most of the current symptomatic treatments available for the common cold, I have for years been amazed at how quick the public is to purchase and repeatedly use these products.
While a judicious course of decongestants can ease the congestion, when misused they often cause significant harm and discomfort that is difficult to resolve. Patients whom I have assisted through successful discontinuance of topical nasal decongestants are among the most appreciative in my practice.
Oral and topical nasal decongestants result in a statistically significant improvement in subjective symptoms of nasal congestion and objective nasal airway resistance in adults’ common colds (strength of recommendation [SOR]: A, based on randomized controlled trials). Evidence is lacking to support the use of decongestants in acute sinusitis.
Evidence summary
Nasal congestion is the most common symptom of the common cold, and hundreds of millions of dollars are spent annually on decongestants. A Cochrane review of 4 randomized controlled trials compared single doses of oxymetazoline, pseudoephedrine, and phenylpropanolamine.1 Included studies involved from 30 to 106 participants, were double-blinded and placebo-controlled, used either topical or oral decongestants for symptoms of less than 5 days’ duration, and measured either subjective or objective relief or adverse events. All 4 studies used nasal airway resistance as an objective measure of nasal congestion, and a combined symptom score as a subjective measure of relief. One study also administered a side-effect questionnaire.
In all studies, topical and oral decongestants were equally efficacious, producing a 13% reduction in subjective symptoms and a significant decrease in nasal airway resistance after 1 dose of decongestant. Only 1 study investigated repeated doses of decongestants and found no significant additional improvement from repeated doses over a 5-day period.
More studies are needed to evaluate efficacy of multiple doses. Clinical interpretation of these results must take into consideration that quality-of-life measures were not evaluated and that none of the studies included children under 12.
Limited data are available on decongestants in sinusitis. Most studies focused on the use of nasal corticosteroids. One placebo-controlled, randomized controlled trial evaluated the effect on mucociliary clearance from adding nasal saline, nasal steroids, or oxymetazoline to antibiotics in acute bacterial sinusitis.2 The group using oxymetazoline increased mucociliary clearance immediately (within 20 minutes). However, at 3 weeks, the improvement in mucociliary clearance in the oxymetazoline group was not significantly different than in the other groups.
An additional prospective, placebo-controlled study evaluated improvement in x-ray findings as well as subjective symptoms in acute sinusitis using phenoxymethyl-penicillin (penicillin V) in combination with oxymetazoline or placebo administered via a variety of nasal delivery systems.3 Oxymetazoline was not significantly different from placebo. Controlled prospective studies are lacking to support the use of decongestants in acute sinusitis.
Recommendations from others
Expert opinion from Current Clinical Topics in Infectious Diseases does not recommend the use of decongestants in sinusitis or the common cold in the absence of concurrent allergic rhinosinusitis.4 This recommendation is based on the lack of evidence regarding efficacy and the known rebound congestion associated with topical decongestants. If a decongestant is prescribed, the oral route is preferred, with the understanding of potential significant side effects of nervousness, insomnia, tachycardia, and hypertension.
Decongestants can do more harm than good
Russell W. Roberts, MD
Louisiana State University Health Sciences Center, Shreveport
Never one to have been impressed with most of the current symptomatic treatments available for the common cold, I have for years been amazed at how quick the public is to purchase and repeatedly use these products.
While a judicious course of decongestants can ease the congestion, when misused they often cause significant harm and discomfort that is difficult to resolve. Patients whom I have assisted through successful discontinuance of topical nasal decongestants are among the most appreciative in my practice.
1. Taverner D, Bickford L, Draper M. Nasal decongestants for the common cold. Cochrane Database Syst Rev 2000;(2):CD001953. Updated quarterly.
2. Inanli S, Ozturk O, Korkmaz M, Tutkun A, Batman C. The effects of topical agents of fluticasone propionate, oxymetazoline, and 3% and 0.9% sodium chloride solutions on mucociliary clearance in the therapy of acute bacterial rhinosinusitis in vivo. Laryngoscope 2002;112:320-325.
3. Wiklund L, Stierna P, Berglund R, Westrin KM, Tonnesson M. The efficacy of oxymetazoline administered with a nasal bellows container and combined with oral phenoxymethyl-penicillin in the treatment of acute maxillary sinusitis. Acta Otolaryngol Suppl 1994;515:57-64.
4. Chow AW. Acute sinusitis: current status of etiologies, diagnosis, and treatment. Curr Clin Top Infect Dis 2001;21:31-63.
1. Taverner D, Bickford L, Draper M. Nasal decongestants for the common cold. Cochrane Database Syst Rev 2000;(2):CD001953. Updated quarterly.
2. Inanli S, Ozturk O, Korkmaz M, Tutkun A, Batman C. The effects of topical agents of fluticasone propionate, oxymetazoline, and 3% and 0.9% sodium chloride solutions on mucociliary clearance in the therapy of acute bacterial rhinosinusitis in vivo. Laryngoscope 2002;112:320-325.
3. Wiklund L, Stierna P, Berglund R, Westrin KM, Tonnesson M. The efficacy of oxymetazoline administered with a nasal bellows container and combined with oral phenoxymethyl-penicillin in the treatment of acute maxillary sinusitis. Acta Otolaryngol Suppl 1994;515:57-64.
4. Chow AW. Acute sinusitis: current status of etiologies, diagnosis, and treatment. Curr Clin Top Infect Dis 2001;21:31-63.
Evidence-based answers from the Family Physicians Inquiries Network
Heat or ice for acute ankle sprain?
For grade 3 and 4 ankle sprains, ice works better than heat to speed recovery (return to play) (strength of recommendation [SOR]: B, based on a single retrospective cohort study). No studies support faster return to play with the application of heat at any time after injury (SOR: B, based on head-to-head randomized trials). Ice therapy also reduces edema, but the clinical significance of this finding is unclear.
Evidence summary
Studies of ankle sprain use variable diagnostic criteria for sprain and definition of recovery (return to play). They often report indirect outcomes such as edema. The effect of decreased edema on recovery time is not addressed.
Only 1 study has directly compared heat vs ice therapy and recovery time for ankle sprains. A retrospective cohort study of 32 patients in a sports medicine clinic demonstrated that early cryotherapy (within 36 hours of injury) for grades 3 and 4 ankle sprains, when compared with early heat therapy, resulted in earlier return to activity, as defined by ability to walk, climb stairs, run, and jump without pain.1 Grade 3 sprains treated with ice recovered in 11.0 days vs 14.8 days with heat. Grade 4 sprains treated with ice recovered in 13.2 days vs 30.4 days with heat. This study also showed that early application of ice (within 36 hours) decreased time to recovery compared with late application of ice.
However, evidence is heterogeneous about the effect of ice on return to play. In 2 of 3 randomized controlled trials, early application of ice vs placebo did not significantly speed return to play.
One randomized controlled trial compared ice therapy (in the form of a cooling anklet applied upon presentation) with placebo in 143 patients presenting within 24 hours of injury to a university emergency department in England.2 All patients received high-dose nonsteroidal anti-inflammatory agents. Though a trend was found in favor of ice therapy, no statistically significant difference was found in recovery time, as defined by pain relief and ability to bear weight. The grade of sprain was not specifically accounted for in this study.
Another randomized controlled trial compared ice with placebo in 30 patients with grade 3 and 4 sprains referred to a physiotherapy department within 2 days of ankle injury. No statistical difference was found in recovery time, defined as ability to bear weight with only mild to moderate pain.3
However, a randomized controlled trial of 60 patients with acute ankle sprains of all grades presenting to an emergency department compared cryogel plus bandaging with bandaging alone (cooling vs no cooling). This study found the mean time to recovery—defined as decreased pain—was reduced from 14.8 days to 9.7 days with constant cooling for the first 48 hours.4
The application of ice—but not heat—within 24 to 48 hours of acute ankle sprain also reduced edema. Several studies looked at reduction of edema with cooling. One study measured edema in 30 patients with grade 1 and 2 sprains treated with cold, heat, or contrast baths during the third, fourth, and fifth days.5 Only ice therapy alone significantly reduced edema.
Recommendations from others
The American Academy of Orthopaedic Surgeons recommends initial treatment of stable ankle sprains with rest, ice, gentle compression, and elevation (RICE).6 These guidelines are echoed by the American Academy of Family Physicians. In addition, the Institute for Clinical Systems Improvement and the National Guidelines Clearinghouse recommend PRICE, where protecting the ankle is explicitly added to RICE therapy.7
Sourav Poddar, MD
Team Physician, University of Colorado Buffaloes; Department of Family Medicine, University of Colorado
Ice should be the first choice for all acute ankle sprains. The immediate goals of treating an ankle sprain are reducing edema, stabilizing the ankle, and enabling early weight-bearing. Applying heat may increase swelling and subsequently slow recovery. Once the initial phase of recovery is achieved through cryotherapy, compression, and elevation, the injured patient may initiate work to increase strength, flexibility, and range of motion of the injured ankle. As a result, icing an ankle sprain facilitates an earlier return to full activity and sports participation by speeding the first phase of recovery.
1. Sloan JP, Hain R, Pownall R. Clinical benefits of early cold therapy in accident and emergency following ankle sprain. Arch Emerg Med 1989;6:1-6.
2. Laba E, Roestenburg M. Clinical evaluation of ice therapy for acute ankle sprain injuries. N Z J Physiother 1989;17:7-9.
3. Basur RL, Shephard E, Mouzas GL. A cooling method in the treatment of ankle sprains. Practitioner 1976;216:708-711.
4. Hocutt JE, Jr, Jaffee R, Rylander CR, Beebe JK. Cryotherapy in ankle sprains. Am J Sports Med 1982;10:316-319.
5. Cote DJ, Prentice WE, Jr, Hooker DN, Shields EW. Comparison of three treatment procedures for minimizing ankle sprain swelling. Phys Ther 1988;68:1072-1076.
6. American Academy of Orthopaedic Surgeons. Clinical Guideline on Ankle Injury. Rosemont, Ill: American Academy of Orthopaedic Surgeons; 1997:7.
7. Institute for Clinical Systems Improvement (ICSI). Ankle Sprain. Bloomington, Minn: Institute for Clinical Systems Improvement (ICSI); 2002:24.
For grade 3 and 4 ankle sprains, ice works better than heat to speed recovery (return to play) (strength of recommendation [SOR]: B, based on a single retrospective cohort study). No studies support faster return to play with the application of heat at any time after injury (SOR: B, based on head-to-head randomized trials). Ice therapy also reduces edema, but the clinical significance of this finding is unclear.
Evidence summary
Studies of ankle sprain use variable diagnostic criteria for sprain and definition of recovery (return to play). They often report indirect outcomes such as edema. The effect of decreased edema on recovery time is not addressed.
Only 1 study has directly compared heat vs ice therapy and recovery time for ankle sprains. A retrospective cohort study of 32 patients in a sports medicine clinic demonstrated that early cryotherapy (within 36 hours of injury) for grades 3 and 4 ankle sprains, when compared with early heat therapy, resulted in earlier return to activity, as defined by ability to walk, climb stairs, run, and jump without pain.1 Grade 3 sprains treated with ice recovered in 11.0 days vs 14.8 days with heat. Grade 4 sprains treated with ice recovered in 13.2 days vs 30.4 days with heat. This study also showed that early application of ice (within 36 hours) decreased time to recovery compared with late application of ice.
However, evidence is heterogeneous about the effect of ice on return to play. In 2 of 3 randomized controlled trials, early application of ice vs placebo did not significantly speed return to play.
One randomized controlled trial compared ice therapy (in the form of a cooling anklet applied upon presentation) with placebo in 143 patients presenting within 24 hours of injury to a university emergency department in England.2 All patients received high-dose nonsteroidal anti-inflammatory agents. Though a trend was found in favor of ice therapy, no statistically significant difference was found in recovery time, as defined by pain relief and ability to bear weight. The grade of sprain was not specifically accounted for in this study.
Another randomized controlled trial compared ice with placebo in 30 patients with grade 3 and 4 sprains referred to a physiotherapy department within 2 days of ankle injury. No statistical difference was found in recovery time, defined as ability to bear weight with only mild to moderate pain.3
However, a randomized controlled trial of 60 patients with acute ankle sprains of all grades presenting to an emergency department compared cryogel plus bandaging with bandaging alone (cooling vs no cooling). This study found the mean time to recovery—defined as decreased pain—was reduced from 14.8 days to 9.7 days with constant cooling for the first 48 hours.4
The application of ice—but not heat—within 24 to 48 hours of acute ankle sprain also reduced edema. Several studies looked at reduction of edema with cooling. One study measured edema in 30 patients with grade 1 and 2 sprains treated with cold, heat, or contrast baths during the third, fourth, and fifth days.5 Only ice therapy alone significantly reduced edema.
Recommendations from others
The American Academy of Orthopaedic Surgeons recommends initial treatment of stable ankle sprains with rest, ice, gentle compression, and elevation (RICE).6 These guidelines are echoed by the American Academy of Family Physicians. In addition, the Institute for Clinical Systems Improvement and the National Guidelines Clearinghouse recommend PRICE, where protecting the ankle is explicitly added to RICE therapy.7
Sourav Poddar, MD
Team Physician, University of Colorado Buffaloes; Department of Family Medicine, University of Colorado
Ice should be the first choice for all acute ankle sprains. The immediate goals of treating an ankle sprain are reducing edema, stabilizing the ankle, and enabling early weight-bearing. Applying heat may increase swelling and subsequently slow recovery. Once the initial phase of recovery is achieved through cryotherapy, compression, and elevation, the injured patient may initiate work to increase strength, flexibility, and range of motion of the injured ankle. As a result, icing an ankle sprain facilitates an earlier return to full activity and sports participation by speeding the first phase of recovery.
For grade 3 and 4 ankle sprains, ice works better than heat to speed recovery (return to play) (strength of recommendation [SOR]: B, based on a single retrospective cohort study). No studies support faster return to play with the application of heat at any time after injury (SOR: B, based on head-to-head randomized trials). Ice therapy also reduces edema, but the clinical significance of this finding is unclear.
Evidence summary
Studies of ankle sprain use variable diagnostic criteria for sprain and definition of recovery (return to play). They often report indirect outcomes such as edema. The effect of decreased edema on recovery time is not addressed.
Only 1 study has directly compared heat vs ice therapy and recovery time for ankle sprains. A retrospective cohort study of 32 patients in a sports medicine clinic demonstrated that early cryotherapy (within 36 hours of injury) for grades 3 and 4 ankle sprains, when compared with early heat therapy, resulted in earlier return to activity, as defined by ability to walk, climb stairs, run, and jump without pain.1 Grade 3 sprains treated with ice recovered in 11.0 days vs 14.8 days with heat. Grade 4 sprains treated with ice recovered in 13.2 days vs 30.4 days with heat. This study also showed that early application of ice (within 36 hours) decreased time to recovery compared with late application of ice.
However, evidence is heterogeneous about the effect of ice on return to play. In 2 of 3 randomized controlled trials, early application of ice vs placebo did not significantly speed return to play.
One randomized controlled trial compared ice therapy (in the form of a cooling anklet applied upon presentation) with placebo in 143 patients presenting within 24 hours of injury to a university emergency department in England.2 All patients received high-dose nonsteroidal anti-inflammatory agents. Though a trend was found in favor of ice therapy, no statistically significant difference was found in recovery time, as defined by pain relief and ability to bear weight. The grade of sprain was not specifically accounted for in this study.
Another randomized controlled trial compared ice with placebo in 30 patients with grade 3 and 4 sprains referred to a physiotherapy department within 2 days of ankle injury. No statistical difference was found in recovery time, defined as ability to bear weight with only mild to moderate pain.3
However, a randomized controlled trial of 60 patients with acute ankle sprains of all grades presenting to an emergency department compared cryogel plus bandaging with bandaging alone (cooling vs no cooling). This study found the mean time to recovery—defined as decreased pain—was reduced from 14.8 days to 9.7 days with constant cooling for the first 48 hours.4
The application of ice—but not heat—within 24 to 48 hours of acute ankle sprain also reduced edema. Several studies looked at reduction of edema with cooling. One study measured edema in 30 patients with grade 1 and 2 sprains treated with cold, heat, or contrast baths during the third, fourth, and fifth days.5 Only ice therapy alone significantly reduced edema.
Recommendations from others
The American Academy of Orthopaedic Surgeons recommends initial treatment of stable ankle sprains with rest, ice, gentle compression, and elevation (RICE).6 These guidelines are echoed by the American Academy of Family Physicians. In addition, the Institute for Clinical Systems Improvement and the National Guidelines Clearinghouse recommend PRICE, where protecting the ankle is explicitly added to RICE therapy.7
Sourav Poddar, MD
Team Physician, University of Colorado Buffaloes; Department of Family Medicine, University of Colorado
Ice should be the first choice for all acute ankle sprains. The immediate goals of treating an ankle sprain are reducing edema, stabilizing the ankle, and enabling early weight-bearing. Applying heat may increase swelling and subsequently slow recovery. Once the initial phase of recovery is achieved through cryotherapy, compression, and elevation, the injured patient may initiate work to increase strength, flexibility, and range of motion of the injured ankle. As a result, icing an ankle sprain facilitates an earlier return to full activity and sports participation by speeding the first phase of recovery.
1. Sloan JP, Hain R, Pownall R. Clinical benefits of early cold therapy in accident and emergency following ankle sprain. Arch Emerg Med 1989;6:1-6.
2. Laba E, Roestenburg M. Clinical evaluation of ice therapy for acute ankle sprain injuries. N Z J Physiother 1989;17:7-9.
3. Basur RL, Shephard E, Mouzas GL. A cooling method in the treatment of ankle sprains. Practitioner 1976;216:708-711.
4. Hocutt JE, Jr, Jaffee R, Rylander CR, Beebe JK. Cryotherapy in ankle sprains. Am J Sports Med 1982;10:316-319.
5. Cote DJ, Prentice WE, Jr, Hooker DN, Shields EW. Comparison of three treatment procedures for minimizing ankle sprain swelling. Phys Ther 1988;68:1072-1076.
6. American Academy of Orthopaedic Surgeons. Clinical Guideline on Ankle Injury. Rosemont, Ill: American Academy of Orthopaedic Surgeons; 1997:7.
7. Institute for Clinical Systems Improvement (ICSI). Ankle Sprain. Bloomington, Minn: Institute for Clinical Systems Improvement (ICSI); 2002:24.
1. Sloan JP, Hain R, Pownall R. Clinical benefits of early cold therapy in accident and emergency following ankle sprain. Arch Emerg Med 1989;6:1-6.
2. Laba E, Roestenburg M. Clinical evaluation of ice therapy for acute ankle sprain injuries. N Z J Physiother 1989;17:7-9.
3. Basur RL, Shephard E, Mouzas GL. A cooling method in the treatment of ankle sprains. Practitioner 1976;216:708-711.
4. Hocutt JE, Jr, Jaffee R, Rylander CR, Beebe JK. Cryotherapy in ankle sprains. Am J Sports Med 1982;10:316-319.
5. Cote DJ, Prentice WE, Jr, Hooker DN, Shields EW. Comparison of three treatment procedures for minimizing ankle sprain swelling. Phys Ther 1988;68:1072-1076.
6. American Academy of Orthopaedic Surgeons. Clinical Guideline on Ankle Injury. Rosemont, Ill: American Academy of Orthopaedic Surgeons; 1997:7.
7. Institute for Clinical Systems Improvement (ICSI). Ankle Sprain. Bloomington, Minn: Institute for Clinical Systems Improvement (ICSI); 2002:24.
Evidence-based answers from the Family Physicians Inquiries Network
How accurate is the clinical diagnosis of pneumonia?
No element or combination of elements from the clinical history and physical examination are sufficiently sensitive or specific to confirm or exclude acute community-acquired pneumonia (CAP). A chest x-ray is recommended to make the diagnosis (Grade of Recommendation: A, based on well-designed cohort studies). No studies specifically demonstrate improved patient outcomes through use of chest x-ray in adults; however, accurate diagnosis is expected to reduce the number of unnecessary antibiotic prescriptions (Grade of Recommendation: D, based on expert opinion).
Evidence summary
Metlay and colleagues1 found only 4 high-quality, prospective cohort trials evaluating the sensitivity and specificity of the clinical history and physical examination in pneumonia. In each of the 4 studies, the reference standard for the diagnosis of pneumonia was a new infiltrate on chest radiograph. Subjects were community-dwelling adults with acute cough who were seen in ambulatory settings, and who had an average pneumonia prevalence of 7% (range, 3%–38%).1 Although no study specifically addressed the interobserver reliability of the history and physical examination findings in pneumonia, other studies of chest findings typically found variable reproducibility. In a study by Spiteri and associates,2 24 physicians examined 24 patients with a variety of respiratory conditions: only 4 had pneumonia on chest x-ray. The most reliable findings (dullness to percussion and wheezing) had only fair agreement among examiners (kappa approximately 0.5).
Nine symptoms (cough, dyspnea, sputum production, subjective fever, chills, night sweats, myalgias, sore throat, and rhinorrhea) and 3 items in the past medical history (asthma, immunosuppression, and dementia) were associated with pneumonia. For most elements of history, both the positive and negative likelihood ratios (LR+, LR−) were in the indeterminate range of 0.5 to 2.0. No single feature was sufficient to either rule in or rule out the diagnosis.1
Regarding the physical examination, tachypnea, tachycardia, and fever had LR+s between 1.5 and 2.4 in an ambulatory setting. In one study, the absence of any vital sign abnormalities reduced the likelihood of pneumonia substantially (LR− = 0.18), but did not rule out the diagnosis completely.1 Egophony had an LR+ of 5.3. Other physical findings (rhonchi, crackles, decreased breath sounds, dullness to percussion, and bronchial breath sounds) yielded LR+s from 1.5 to 3.5, respectively. Most individual findings were insufficient to diagnose pneumonia. For example, if the baseline prevalence of pneumonia was 5%, the presence of crackles raised the probability to 10% and their absence decreased the probability to 3%.
The sensitivity and specificity of clinical diagnosis varied with the prevalence of pneumonia. In a general practice setting, 20 of 402 patients with cough were diagnosed with pneumonia by chest x-ray.3 Physicians correctly diagnosed 7 patients clinically, and incorrectly diagnosed pneumonia in 22 additional patients.3 At a Veterans Administration hospital, a prospective cohort of 52 men with acute cough and change in sputum production underwent sequential blinded examination by 3 physicians. Rales and bronchial breath sounds were common, and chest x-ray confirmed pneumonia in 28 patients. Sensitivity of clinical diagnosis ranged from 47% to 69%, and specificity from 58% to 75%.4
Several researchers improved diagnostic accuracy by combining multiple elements from the history and physical examination. For example, according to Metlay and colleagues,1 Heckerling et al calculated the probability of pneumonia if up to 5 predictors were present. However, if the prevalence of pneumonia in a primary care population is 5%, the presence of all 5 predictors raises the probability of pneumonia only to 53%.1 The absence of 4 of the 5 findings (fever >37.8°C, heart rate >100 beats per minute, decreased breath sounds, crackles) reduces the risk of pneumonia to 1%, thus eliminating the need for radiography or antibiotics in most situations. If the patient also has asthma, the risk drops even further.
Recommendations from others
The Infectious Diseases Society of North America states that a chest x-ray is necessary for accurate diagnosis. In otherwise healthy adults with acute cough illness, antibiotic therapy is indicated only for pneumonia. A normal chest x-ray obviates the need for antibiotics.5,6
John W. Ely, MD, MSPH
University of Iowa Iowa City
john-ely@uiowa.ed.
The immediate question for clinicians is “Can you treat pneumonia based on clinical findings alone?” Apparently, the answer is “no” unless the radiograph would be unacceptably difficult to obtain (eg, certain nursing home or homebound patients). Can the patient have pneumonia even if the chest radiograph is negative? Subtle early pneumonias sometimes blossom on chest film after a day or two. The diagnosis of pneumonia can be just as much a subjective “call” for the radiologist as “a few crackles” can be for the clinician, so the bottom line is: If you suspect pneumonia, order a chest film.
1. Metlay JP, Kapoor WN, Fine MJ. Does this patient have community-acquired pneumonia? Diagnosing pneumonia by history and physical examination. JAMA 1997;278:1440-5.
2. Spiteri MA, Cook DG, Clarke SW. Reliability of eliciting physical signs in examination of the chest. Lancet 1988;1:873-5.
3. Melbye H, Straume B, Aasebo U, Dale K. Diagnosis of pneumonia in adults in general practice. Relative importance of typical symptoms and abnormal chest signs evaluated against a radiographic reference standard. Scand J Prim Health Care 1992;10:226-33.
4. Wipf JE, Lipsky BA, Hirschmann JV, et al. Diagnosing pneumonia by physical examination: relevant or relic? Arch Intern Med 1999;159:1082-7.
5. Gonzales R, Bartlett JG, Besser RE, et al. Principles of appropriate antibiotic use for treatment of uncomplicated acute bronchitis: background. Ann Intern Med 2001;134:521-9.
6. Bartlett JG, Dowell SF, Mandell LA, et al. Practice guidelines for the management of community-acquired pneumonia in adults.Infectious Diseases Society of America. Clin Infect Dis 2000;31:347-82.
No element or combination of elements from the clinical history and physical examination are sufficiently sensitive or specific to confirm or exclude acute community-acquired pneumonia (CAP). A chest x-ray is recommended to make the diagnosis (Grade of Recommendation: A, based on well-designed cohort studies). No studies specifically demonstrate improved patient outcomes through use of chest x-ray in adults; however, accurate diagnosis is expected to reduce the number of unnecessary antibiotic prescriptions (Grade of Recommendation: D, based on expert opinion).
Evidence summary
Metlay and colleagues1 found only 4 high-quality, prospective cohort trials evaluating the sensitivity and specificity of the clinical history and physical examination in pneumonia. In each of the 4 studies, the reference standard for the diagnosis of pneumonia was a new infiltrate on chest radiograph. Subjects were community-dwelling adults with acute cough who were seen in ambulatory settings, and who had an average pneumonia prevalence of 7% (range, 3%–38%).1 Although no study specifically addressed the interobserver reliability of the history and physical examination findings in pneumonia, other studies of chest findings typically found variable reproducibility. In a study by Spiteri and associates,2 24 physicians examined 24 patients with a variety of respiratory conditions: only 4 had pneumonia on chest x-ray. The most reliable findings (dullness to percussion and wheezing) had only fair agreement among examiners (kappa approximately 0.5).
Nine symptoms (cough, dyspnea, sputum production, subjective fever, chills, night sweats, myalgias, sore throat, and rhinorrhea) and 3 items in the past medical history (asthma, immunosuppression, and dementia) were associated with pneumonia. For most elements of history, both the positive and negative likelihood ratios (LR+, LR−) were in the indeterminate range of 0.5 to 2.0. No single feature was sufficient to either rule in or rule out the diagnosis.1
Regarding the physical examination, tachypnea, tachycardia, and fever had LR+s between 1.5 and 2.4 in an ambulatory setting. In one study, the absence of any vital sign abnormalities reduced the likelihood of pneumonia substantially (LR− = 0.18), but did not rule out the diagnosis completely.1 Egophony had an LR+ of 5.3. Other physical findings (rhonchi, crackles, decreased breath sounds, dullness to percussion, and bronchial breath sounds) yielded LR+s from 1.5 to 3.5, respectively. Most individual findings were insufficient to diagnose pneumonia. For example, if the baseline prevalence of pneumonia was 5%, the presence of crackles raised the probability to 10% and their absence decreased the probability to 3%.
The sensitivity and specificity of clinical diagnosis varied with the prevalence of pneumonia. In a general practice setting, 20 of 402 patients with cough were diagnosed with pneumonia by chest x-ray.3 Physicians correctly diagnosed 7 patients clinically, and incorrectly diagnosed pneumonia in 22 additional patients.3 At a Veterans Administration hospital, a prospective cohort of 52 men with acute cough and change in sputum production underwent sequential blinded examination by 3 physicians. Rales and bronchial breath sounds were common, and chest x-ray confirmed pneumonia in 28 patients. Sensitivity of clinical diagnosis ranged from 47% to 69%, and specificity from 58% to 75%.4
Several researchers improved diagnostic accuracy by combining multiple elements from the history and physical examination. For example, according to Metlay and colleagues,1 Heckerling et al calculated the probability of pneumonia if up to 5 predictors were present. However, if the prevalence of pneumonia in a primary care population is 5%, the presence of all 5 predictors raises the probability of pneumonia only to 53%.1 The absence of 4 of the 5 findings (fever >37.8°C, heart rate >100 beats per minute, decreased breath sounds, crackles) reduces the risk of pneumonia to 1%, thus eliminating the need for radiography or antibiotics in most situations. If the patient also has asthma, the risk drops even further.
Recommendations from others
The Infectious Diseases Society of North America states that a chest x-ray is necessary for accurate diagnosis. In otherwise healthy adults with acute cough illness, antibiotic therapy is indicated only for pneumonia. A normal chest x-ray obviates the need for antibiotics.5,6
John W. Ely, MD, MSPH
University of Iowa Iowa City
john-ely@uiowa.ed.
The immediate question for clinicians is “Can you treat pneumonia based on clinical findings alone?” Apparently, the answer is “no” unless the radiograph would be unacceptably difficult to obtain (eg, certain nursing home or homebound patients). Can the patient have pneumonia even if the chest radiograph is negative? Subtle early pneumonias sometimes blossom on chest film after a day or two. The diagnosis of pneumonia can be just as much a subjective “call” for the radiologist as “a few crackles” can be for the clinician, so the bottom line is: If you suspect pneumonia, order a chest film.
No element or combination of elements from the clinical history and physical examination are sufficiently sensitive or specific to confirm or exclude acute community-acquired pneumonia (CAP). A chest x-ray is recommended to make the diagnosis (Grade of Recommendation: A, based on well-designed cohort studies). No studies specifically demonstrate improved patient outcomes through use of chest x-ray in adults; however, accurate diagnosis is expected to reduce the number of unnecessary antibiotic prescriptions (Grade of Recommendation: D, based on expert opinion).
Evidence summary
Metlay and colleagues1 found only 4 high-quality, prospective cohort trials evaluating the sensitivity and specificity of the clinical history and physical examination in pneumonia. In each of the 4 studies, the reference standard for the diagnosis of pneumonia was a new infiltrate on chest radiograph. Subjects were community-dwelling adults with acute cough who were seen in ambulatory settings, and who had an average pneumonia prevalence of 7% (range, 3%–38%).1 Although no study specifically addressed the interobserver reliability of the history and physical examination findings in pneumonia, other studies of chest findings typically found variable reproducibility. In a study by Spiteri and associates,2 24 physicians examined 24 patients with a variety of respiratory conditions: only 4 had pneumonia on chest x-ray. The most reliable findings (dullness to percussion and wheezing) had only fair agreement among examiners (kappa approximately 0.5).
Nine symptoms (cough, dyspnea, sputum production, subjective fever, chills, night sweats, myalgias, sore throat, and rhinorrhea) and 3 items in the past medical history (asthma, immunosuppression, and dementia) were associated with pneumonia. For most elements of history, both the positive and negative likelihood ratios (LR+, LR−) were in the indeterminate range of 0.5 to 2.0. No single feature was sufficient to either rule in or rule out the diagnosis.1
Regarding the physical examination, tachypnea, tachycardia, and fever had LR+s between 1.5 and 2.4 in an ambulatory setting. In one study, the absence of any vital sign abnormalities reduced the likelihood of pneumonia substantially (LR− = 0.18), but did not rule out the diagnosis completely.1 Egophony had an LR+ of 5.3. Other physical findings (rhonchi, crackles, decreased breath sounds, dullness to percussion, and bronchial breath sounds) yielded LR+s from 1.5 to 3.5, respectively. Most individual findings were insufficient to diagnose pneumonia. For example, if the baseline prevalence of pneumonia was 5%, the presence of crackles raised the probability to 10% and their absence decreased the probability to 3%.
The sensitivity and specificity of clinical diagnosis varied with the prevalence of pneumonia. In a general practice setting, 20 of 402 patients with cough were diagnosed with pneumonia by chest x-ray.3 Physicians correctly diagnosed 7 patients clinically, and incorrectly diagnosed pneumonia in 22 additional patients.3 At a Veterans Administration hospital, a prospective cohort of 52 men with acute cough and change in sputum production underwent sequential blinded examination by 3 physicians. Rales and bronchial breath sounds were common, and chest x-ray confirmed pneumonia in 28 patients. Sensitivity of clinical diagnosis ranged from 47% to 69%, and specificity from 58% to 75%.4
Several researchers improved diagnostic accuracy by combining multiple elements from the history and physical examination. For example, according to Metlay and colleagues,1 Heckerling et al calculated the probability of pneumonia if up to 5 predictors were present. However, if the prevalence of pneumonia in a primary care population is 5%, the presence of all 5 predictors raises the probability of pneumonia only to 53%.1 The absence of 4 of the 5 findings (fever >37.8°C, heart rate >100 beats per minute, decreased breath sounds, crackles) reduces the risk of pneumonia to 1%, thus eliminating the need for radiography or antibiotics in most situations. If the patient also has asthma, the risk drops even further.
Recommendations from others
The Infectious Diseases Society of North America states that a chest x-ray is necessary for accurate diagnosis. In otherwise healthy adults with acute cough illness, antibiotic therapy is indicated only for pneumonia. A normal chest x-ray obviates the need for antibiotics.5,6
John W. Ely, MD, MSPH
University of Iowa Iowa City
john-ely@uiowa.ed.
The immediate question for clinicians is “Can you treat pneumonia based on clinical findings alone?” Apparently, the answer is “no” unless the radiograph would be unacceptably difficult to obtain (eg, certain nursing home or homebound patients). Can the patient have pneumonia even if the chest radiograph is negative? Subtle early pneumonias sometimes blossom on chest film after a day or two. The diagnosis of pneumonia can be just as much a subjective “call” for the radiologist as “a few crackles” can be for the clinician, so the bottom line is: If you suspect pneumonia, order a chest film.
1. Metlay JP, Kapoor WN, Fine MJ. Does this patient have community-acquired pneumonia? Diagnosing pneumonia by history and physical examination. JAMA 1997;278:1440-5.
2. Spiteri MA, Cook DG, Clarke SW. Reliability of eliciting physical signs in examination of the chest. Lancet 1988;1:873-5.
3. Melbye H, Straume B, Aasebo U, Dale K. Diagnosis of pneumonia in adults in general practice. Relative importance of typical symptoms and abnormal chest signs evaluated against a radiographic reference standard. Scand J Prim Health Care 1992;10:226-33.
4. Wipf JE, Lipsky BA, Hirschmann JV, et al. Diagnosing pneumonia by physical examination: relevant or relic? Arch Intern Med 1999;159:1082-7.
5. Gonzales R, Bartlett JG, Besser RE, et al. Principles of appropriate antibiotic use for treatment of uncomplicated acute bronchitis: background. Ann Intern Med 2001;134:521-9.
6. Bartlett JG, Dowell SF, Mandell LA, et al. Practice guidelines for the management of community-acquired pneumonia in adults.Infectious Diseases Society of America. Clin Infect Dis 2000;31:347-82.
1. Metlay JP, Kapoor WN, Fine MJ. Does this patient have community-acquired pneumonia? Diagnosing pneumonia by history and physical examination. JAMA 1997;278:1440-5.
2. Spiteri MA, Cook DG, Clarke SW. Reliability of eliciting physical signs in examination of the chest. Lancet 1988;1:873-5.
3. Melbye H, Straume B, Aasebo U, Dale K. Diagnosis of pneumonia in adults in general practice. Relative importance of typical symptoms and abnormal chest signs evaluated against a radiographic reference standard. Scand J Prim Health Care 1992;10:226-33.
4. Wipf JE, Lipsky BA, Hirschmann JV, et al. Diagnosing pneumonia by physical examination: relevant or relic? Arch Intern Med 1999;159:1082-7.
5. Gonzales R, Bartlett JG, Besser RE, et al. Principles of appropriate antibiotic use for treatment of uncomplicated acute bronchitis: background. Ann Intern Med 2001;134:521-9.
6. Bartlett JG, Dowell SF, Mandell LA, et al. Practice guidelines for the management of community-acquired pneumonia in adults.Infectious Diseases Society of America. Clin Infect Dis 2000;31:347-82.
Evidence-based answers from the Family Physicians Inquiries Network