Joan Nashelsky, MLS

Evidence summary

A Cochrane review found only a small number of poor-quality trials, providing insufficient support to recommend cranberry juice to prevent UTI.¹ However, 2 recent randomized studies, not included in the Cochrane review, found that women taking cranberry juice have fewer symptomatic UTIs.

In women with prior Escherichia coli UTI, 50 mL of cranberry-lingonberry juice concentrate daily for 6 months reduced the recurrence of symptomatic UTI from 36% in the control group to 16% in the treated group (NNT=5).²

In a placebo-controlled randomized trial, women with prior UTI who took 1 tablet of concentrated cranberry juice (at least 1:30 parts concentrated juice) twice daily (n=50) or drank 250 mL of pure unsweetened cranberry juice 3 times a day for 12 months (n=50) reduced their incidence of symptomatic UTI.3 Women who drank the juice had an ARR of 12% (32% symptomatic UTI on placebo group, 20% in cranberry juice group, NNT=8.3) over 1 year. Use of cranberry juice tablets produced an ARR of 14% (32% symptomatic UTI in placebo group; 18% in cranberry tablet group, NNT=7.1). Self-reported compliance was 75% to 90% in the juice group and 90% in the tablet group.

No dose-response studies have been done to determine the optimal volume of juice or number of tablets needed to prevent infection. Studies have used between 200 mL once a day to 250 mL 3 times a day of the juice or 1 cranberry tablet taken twice daily. The subject dropout rate was as high as 34% in one study using juice,⁴ implying that cranberry juice—which is acidic and astringent at full strength—may not be acceptable to many patients as a prophylactic therapy over a long period. The 1-month compliance rate of patients taking cranberry tablets was between 88% and 100%, suggesting that this form of cranberry may improve compliance.

The cost of cranberry juice and cranberry tablets was estimated at $1400 and $624 per year, respectively.³ This must be balanced against the cost of treating symptomatic UTIs. No randomized trials have tested the more readily available and palatable cranberry juice cocktail—which is mixed with water, a sweetener, and vitamin C—to prevent recurrent UTI.

Cranberry juice does not inhibit bacterial growth and will not sterilize the urinary tract. Also, cranberry juice does not prevent or treat UTI by changing the pH of the urine. Rather, the suspected mechanism of action is that proanthocyanidins contained in cranberry juice prevent bacterial adherence to uroepithelial cells, thus reducing the development of UTI.⁵ Cranberry juice has been shown to reduce uroepithelial cell adherence by bacteria resistant to trimethoprim-sulfamethoxazole.⁶

Recommendations from others

No national practice guidelines have recommended cranberry juice as a preventive strategy for recurrent UTI but, anecdotally, patients are often advised to try cranberry juice to prevent UTI.

Evidence summary

A Cochrane review found only a small number of poor-quality trials, providing insufficient support to recommend cranberry juice to prevent UTI.¹ However, 2 recent randomized studies, not included in the Cochrane review, found that women taking cranberry juice have fewer symptomatic UTIs.

In women with prior Escherichia coli UTI, 50 mL of cranberry-lingonberry juice concentrate daily for 6 months reduced the recurrence of symptomatic UTI from 36% in the control group to 16% in the treated group (NNT=5).²

In a placebo-controlled randomized trial, women with prior UTI who took 1 tablet of concentrated cranberry juice (at least 1:30 parts concentrated juice) twice daily (n=50) or drank 250 mL of pure unsweetened cranberry juice 3 times a day for 12 months (n=50) reduced their incidence of symptomatic UTI.3 Women who drank the juice had an ARR of 12% (32% symptomatic UTI on placebo group, 20% in cranberry juice group, NNT=8.3) over 1 year. Use of cranberry juice tablets produced an ARR of 14% (32% symptomatic UTI in placebo group; 18% in cranberry tablet group, NNT=7.1). Self-reported compliance was 75% to 90% in the juice group and 90% in the tablet group.

No dose-response studies have been done to determine the optimal volume of juice or number of tablets needed to prevent infection. Studies have used between 200 mL once a day to 250 mL 3 times a day of the juice or 1 cranberry tablet taken twice daily. The subject dropout rate was as high as 34% in one study using juice,⁴ implying that cranberry juice—which is acidic and astringent at full strength—may not be acceptable to many patients as a prophylactic therapy over a long period. The 1-month compliance rate of patients taking cranberry tablets was between 88% and 100%, suggesting that this form of cranberry may improve compliance.

The cost of cranberry juice and cranberry tablets was estimated at $1400 and $624 per year, respectively.³ This must be balanced against the cost of treating symptomatic UTIs. No randomized trials have tested the more readily available and palatable cranberry juice cocktail—which is mixed with water, a sweetener, and vitamin C—to prevent recurrent UTI.

Cranberry juice does not inhibit bacterial growth and will not sterilize the urinary tract. Also, cranberry juice does not prevent or treat UTI by changing the pH of the urine. Rather, the suspected mechanism of action is that proanthocyanidins contained in cranberry juice prevent bacterial adherence to uroepithelial cells, thus reducing the development of UTI.⁵ Cranberry juice has been shown to reduce uroepithelial cell adherence by bacteria resistant to trimethoprim-sulfamethoxazole.⁶

Recommendations from others

No national practice guidelines have recommended cranberry juice as a preventive strategy for recurrent UTI but, anecdotally, patients are often advised to try cranberry juice to prevent UTI.

Evidence summary

A Cochrane review found only a small number of poor-quality trials, providing insufficient support to recommend cranberry juice to prevent UTI.¹ However, 2 recent randomized studies, not included in the Cochrane review, found that women taking cranberry juice have fewer symptomatic UTIs.

In women with prior Escherichia coli UTI, 50 mL of cranberry-lingonberry juice concentrate daily for 6 months reduced the recurrence of symptomatic UTI from 36% in the control group to 16% in the treated group (NNT=5).²

In a placebo-controlled randomized trial, women with prior UTI who took 1 tablet of concentrated cranberry juice (at least 1:30 parts concentrated juice) twice daily (n=50) or drank 250 mL of pure unsweetened cranberry juice 3 times a day for 12 months (n=50) reduced their incidence of symptomatic UTI.3 Women who drank the juice had an ARR of 12% (32% symptomatic UTI on placebo group, 20% in cranberry juice group, NNT=8.3) over 1 year. Use of cranberry juice tablets produced an ARR of 14% (32% symptomatic UTI in placebo group; 18% in cranberry tablet group, NNT=7.1). Self-reported compliance was 75% to 90% in the juice group and 90% in the tablet group.

No dose-response studies have been done to determine the optimal volume of juice or number of tablets needed to prevent infection. Studies have used between 200 mL once a day to 250 mL 3 times a day of the juice or 1 cranberry tablet taken twice daily. The subject dropout rate was as high as 34% in one study using juice,⁴ implying that cranberry juice—which is acidic and astringent at full strength—may not be acceptable to many patients as a prophylactic therapy over a long period. The 1-month compliance rate of patients taking cranberry tablets was between 88% and 100%, suggesting that this form of cranberry may improve compliance.

The cost of cranberry juice and cranberry tablets was estimated at $1400 and $624 per year, respectively.³ This must be balanced against the cost of treating symptomatic UTIs. No randomized trials have tested the more readily available and palatable cranberry juice cocktail—which is mixed with water, a sweetener, and vitamin C—to prevent recurrent UTI.

Cranberry juice does not inhibit bacterial growth and will not sterilize the urinary tract. Also, cranberry juice does not prevent or treat UTI by changing the pH of the urine. Rather, the suspected mechanism of action is that proanthocyanidins contained in cranberry juice prevent bacterial adherence to uroepithelial cells, thus reducing the development of UTI.⁵ Cranberry juice has been shown to reduce uroepithelial cell adherence by bacteria resistant to trimethoprim-sulfamethoxazole.⁶

Recommendations from others

No national practice guidelines have recommended cranberry juice as a preventive strategy for recurrent UTI but, anecdotally, patients are often advised to try cranberry juice to prevent UTI.

Evidence summary

The only studies of hand paresthesias that we found pertained to of CTS. A consensus statement on CTS listed intermittent numbness, tingling, and pain along the sensory distribution of the median nerve as diagnostic criteria for CTS.¹ Patients often report that these symptoms awaken them at night. Shaking the hand may relieve the discomfort. Commonly, the pain is burning in nature and worsens with use during the day. Repetitive trauma or mechanical stress related to workplace tasks is associated with CTS.

A meta-analysis of studies reviewing the precision and accuracy of the history and physical examination in the diagnosis of CTS in adults found that hypoalgesia (LR+, 3.1), classic or probable hand diagram results (LR+ 2.4, LR- 0.2), and weak thumb abduction strength (weakness of resisted movement of the thumb at right angles to the palm; LR+ 1.8, LR- 0.5) best distinguish those with and those without CTS.² A hand diagram is a graphical depiction of the distribution of tingling created by the patient; a classical distribution is in that of the median nerve, while a probable distribution involves the entire palmar surface. The reference standard for these studies was a nerve conduction study. Nocturnal paresthesias, Phalen and Tinel signs, and thenar atrophy had little or no diagnostic utility.

Recommendations from others

Collins³ recommends the following approach to paresthesias of the upper extremity. If the paresthesias are symmetric, consider peripheral neuropathy, Raynaud’s, or multiple sclerosis. If asymmetric, evaluate for radiculopathy with a neurological examination. If pain is radicular, and neurologic findings are consistent, consider spinal cord or nerve root compression. If the examination is normal, consider a plexopathy or herpes zoster. If there is no radiculopathy, the following maneuvers may suggest a cause. A positive Adson’s maneuver is consistent with thoracic outlet syndrome, a Tinel’s or Phalen’s sign at the wrist suggests carpal tunnel syndrome, or Tinel’s sign at the elbow suggests ulnar neuropathy. Note that the latter signs are not well validated by good quality diagnostic test studies.

Clinical Commentary by Peter Danis, MD, at http://www.fpin.org.

Evidence summary

The only studies of hand paresthesias that we found pertained to of CTS. A consensus statement on CTS listed intermittent numbness, tingling, and pain along the sensory distribution of the median nerve as diagnostic criteria for CTS.¹ Patients often report that these symptoms awaken them at night. Shaking the hand may relieve the discomfort. Commonly, the pain is burning in nature and worsens with use during the day. Repetitive trauma or mechanical stress related to workplace tasks is associated with CTS.

A meta-analysis of studies reviewing the precision and accuracy of the history and physical examination in the diagnosis of CTS in adults found that hypoalgesia (LR+, 3.1), classic or probable hand diagram results (LR+ 2.4, LR- 0.2), and weak thumb abduction strength (weakness of resisted movement of the thumb at right angles to the palm; LR+ 1.8, LR- 0.5) best distinguish those with and those without CTS.² A hand diagram is a graphical depiction of the distribution of tingling created by the patient; a classical distribution is in that of the median nerve, while a probable distribution involves the entire palmar surface. The reference standard for these studies was a nerve conduction study. Nocturnal paresthesias, Phalen and Tinel signs, and thenar atrophy had little or no diagnostic utility.

Recommendations from others

Collins³ recommends the following approach to paresthesias of the upper extremity. If the paresthesias are symmetric, consider peripheral neuropathy, Raynaud’s, or multiple sclerosis. If asymmetric, evaluate for radiculopathy with a neurological examination. If pain is radicular, and neurologic findings are consistent, consider spinal cord or nerve root compression. If the examination is normal, consider a plexopathy or herpes zoster. If there is no radiculopathy, the following maneuvers may suggest a cause. A positive Adson’s maneuver is consistent with thoracic outlet syndrome, a Tinel’s or Phalen’s sign at the wrist suggests carpal tunnel syndrome, or Tinel’s sign at the elbow suggests ulnar neuropathy. Note that the latter signs are not well validated by good quality diagnostic test studies.

Clinical Commentary by Peter Danis, MD, at http://www.fpin.org.

Evidence summary

The only studies of hand paresthesias that we found pertained to of CTS. A consensus statement on CTS listed intermittent numbness, tingling, and pain along the sensory distribution of the median nerve as diagnostic criteria for CTS.¹ Patients often report that these symptoms awaken them at night. Shaking the hand may relieve the discomfort. Commonly, the pain is burning in nature and worsens with use during the day. Repetitive trauma or mechanical stress related to workplace tasks is associated with CTS.

A meta-analysis of studies reviewing the precision and accuracy of the history and physical examination in the diagnosis of CTS in adults found that hypoalgesia (LR+, 3.1), classic or probable hand diagram results (LR+ 2.4, LR- 0.2), and weak thumb abduction strength (weakness of resisted movement of the thumb at right angles to the palm; LR+ 1.8, LR- 0.5) best distinguish those with and those without CTS.² A hand diagram is a graphical depiction of the distribution of tingling created by the patient; a classical distribution is in that of the median nerve, while a probable distribution involves the entire palmar surface. The reference standard for these studies was a nerve conduction study. Nocturnal paresthesias, Phalen and Tinel signs, and thenar atrophy had little or no diagnostic utility.

Recommendations from others

Collins³ recommends the following approach to paresthesias of the upper extremity. If the paresthesias are symmetric, consider peripheral neuropathy, Raynaud’s, or multiple sclerosis. If asymmetric, evaluate for radiculopathy with a neurological examination. If pain is radicular, and neurologic findings are consistent, consider spinal cord or nerve root compression. If the examination is normal, consider a plexopathy or herpes zoster. If there is no radiculopathy, the following maneuvers may suggest a cause. A positive Adson’s maneuver is consistent with thoracic outlet syndrome, a Tinel’s or Phalen’s sign at the wrist suggests carpal tunnel syndrome, or Tinel’s sign at the elbow suggests ulnar neuropathy. Note that the latter signs are not well validated by good quality diagnostic test studies.

Clinical Commentary by Peter Danis, MD, at http://www.fpin.org.

Evidence summary

It has been widely stated that 80% to 90% of attacks of acute low back pain resolve within approximately 6 weeks,¹ though there is little evidence to support this claim. Although there are many studies and guidelines regarding treatment methods for low back pain, few studies evaluate the natural history of low back pain. One prospective series in a primary care setting found that 90% of patients were without pain 2 weeks after initial evaluation by their physician.² This study had a 3-month follow-up period for 103 patients presenting with pain of less than 72 hours’ duration.

Another prospective study found that 94% of patients evaluated for a new episode of low back pain were no longer visiting their physician for treatment after 3 months. However, this was not an adequate measure of resolution of pain. Only 21% (39/188) were pain free at 3 months and only 25% (42/170) were pain free at 12 months.³ A larger study involved 1555 patients during a 6-month follow up after an episode of acute low back pain. The article reports a mean of 16 days to functional recovery, although only 69% of the patients considered themselves “completely recovered” at 6 months.⁴

Recurrences of low back pain are common. In one prospective cohort study of 443 patients with low back pain, 75% had a recurrence with a mean of 2 relapses in 1 year of follow-up, but only 228 patients completed the study.⁵ Another prospective study of 208 patients found that 35% to 44% of patients had recurrence of pain within 6 months of their first episode, and 50% to 59% had a recurrence in 22 months of follow-up.⁶ No studies identified findings or risk factors associated with higher recurrence rates.

Recommendations from others

The Agency for Healthcare Research and Quality (www.ahcpr.gov) section on health outcomes (see http://www.ahcpr.gov/research/jan99/ra6.htm) states, “recent studies suggest that once experienced, low back pain becomes a part of life for almost half of those affected, and for many, it is intermittently disabling. Repeated visits and procedures do not appear to improve patients’ long-term well-being, but they clearly account for substantial health care costs. Finally, back pain prognosis does not differ based on the type of provider initially seen or the level of practitioner confidence.” This site offers several nice summaries of studies on low back pain.

Read the clinical commentary by Anne Fitzsimmons, MD, at www.fpin.org.

Evidence summary

It has been widely stated that 80% to 90% of attacks of acute low back pain resolve within approximately 6 weeks,¹ though there is little evidence to support this claim. Although there are many studies and guidelines regarding treatment methods for low back pain, few studies evaluate the natural history of low back pain. One prospective series in a primary care setting found that 90% of patients were without pain 2 weeks after initial evaluation by their physician.² This study had a 3-month follow-up period for 103 patients presenting with pain of less than 72 hours’ duration.

Another prospective study found that 94% of patients evaluated for a new episode of low back pain were no longer visiting their physician for treatment after 3 months. However, this was not an adequate measure of resolution of pain. Only 21% (39/188) were pain free at 3 months and only 25% (42/170) were pain free at 12 months.³ A larger study involved 1555 patients during a 6-month follow up after an episode of acute low back pain. The article reports a mean of 16 days to functional recovery, although only 69% of the patients considered themselves “completely recovered” at 6 months.⁴

Recurrences of low back pain are common. In one prospective cohort study of 443 patients with low back pain, 75% had a recurrence with a mean of 2 relapses in 1 year of follow-up, but only 228 patients completed the study.⁵ Another prospective study of 208 patients found that 35% to 44% of patients had recurrence of pain within 6 months of their first episode, and 50% to 59% had a recurrence in 22 months of follow-up.⁶ No studies identified findings or risk factors associated with higher recurrence rates.

Recommendations from others

The Agency for Healthcare Research and Quality (www.ahcpr.gov) section on health outcomes (see http://www.ahcpr.gov/research/jan99/ra6.htm) states, “recent studies suggest that once experienced, low back pain becomes a part of life for almost half of those affected, and for many, it is intermittently disabling. Repeated visits and procedures do not appear to improve patients’ long-term well-being, but they clearly account for substantial health care costs. Finally, back pain prognosis does not differ based on the type of provider initially seen or the level of practitioner confidence.” This site offers several nice summaries of studies on low back pain.

Read the clinical commentary by Anne Fitzsimmons, MD, at www.fpin.org.

Evidence summary

It has been widely stated that 80% to 90% of attacks of acute low back pain resolve within approximately 6 weeks,¹ though there is little evidence to support this claim. Although there are many studies and guidelines regarding treatment methods for low back pain, few studies evaluate the natural history of low back pain. One prospective series in a primary care setting found that 90% of patients were without pain 2 weeks after initial evaluation by their physician.² This study had a 3-month follow-up period for 103 patients presenting with pain of less than 72 hours’ duration.

Another prospective study found that 94% of patients evaluated for a new episode of low back pain were no longer visiting their physician for treatment after 3 months. However, this was not an adequate measure of resolution of pain. Only 21% (39/188) were pain free at 3 months and only 25% (42/170) were pain free at 12 months.³ A larger study involved 1555 patients during a 6-month follow up after an episode of acute low back pain. The article reports a mean of 16 days to functional recovery, although only 69% of the patients considered themselves “completely recovered” at 6 months.⁴

Recurrences of low back pain are common. In one prospective cohort study of 443 patients with low back pain, 75% had a recurrence with a mean of 2 relapses in 1 year of follow-up, but only 228 patients completed the study.⁵ Another prospective study of 208 patients found that 35% to 44% of patients had recurrence of pain within 6 months of their first episode, and 50% to 59% had a recurrence in 22 months of follow-up.⁶ No studies identified findings or risk factors associated with higher recurrence rates.

Recommendations from others

The Agency for Healthcare Research and Quality (www.ahcpr.gov) section on health outcomes (see http://www.ahcpr.gov/research/jan99/ra6.htm) states, “recent studies suggest that once experienced, low back pain becomes a part of life for almost half of those affected, and for many, it is intermittently disabling. Repeated visits and procedures do not appear to improve patients’ long-term well-being, but they clearly account for substantial health care costs. Finally, back pain prognosis does not differ based on the type of provider initially seen or the level of practitioner confidence.” This site offers several nice summaries of studies on low back pain.

Read the clinical commentary by Anne Fitzsimmons, MD, at www.fpin.org.

Evidence summary

Nonsurgical treatments that are beneficial in eradicating genital warts are podofilox (Condylox) (8 randomized controlled trials [RCTs] with 1035 participants), imiquimod (Aldara) (2 RCTs with 968 participants), and intralesional interferon (8 RCTs). Cryotherapy is equivalent to trichloroacetic acid^1,2 and electrosurgery.³ Although surgical treatments have not been compared with placebo or no treatment, both electrosurgery and surgical excision are superior to podophyllin in clinical trials.^4,5 Laser surgery is as effective as surgical excision.⁶ Studies of topical interferon show conflicting results.⁷ Systemic interferon is not beneficial.⁷ Topical 5-FU has not been studied with RCTs. Wart clearance rates are summarized in the Table. Treatment duration for nonsurgical options is 4 to 8 weeks. Treatment of genital warts has not been shown to reduce transmission to sex partners.⁷

Two RCTs^4,5 showed more frequent recurrence with podophyllin (60% to 65%) than with surgical excision (19% to 20%). Another trial¹ showed recurrence in 22% of participants receiving electrosurgery, in 21% of those receiving cryotherapy, and in 44% of those receiving podophyllin treatment. Data are lacking on recurrence rates with imiquimod, podofilox, and intralesional interferon.

Pain occurs in less than 20% of people with imiquimod, cryotherapy, podophyllin, and electrosurgery; 39% with topical interferon; 44% with electrosurgery; 75% with podofilox; and 100% with surgical excision or laser surgery.⁷ However, pain has been measured using methods that are unlikely to be comparable across studies. Flulike symptoms, leukopenia, thrombocytopenia, and elevated aspartate transaminase levels are associated with intralesional interferon.⁷ Topical medications have not been studied in pregnant patients. Cryotherapy is safe in pregnancy based on case series, if only 3 or 4 treatments are given.⁷

Direct comparisons between home therapies (imiquimod, podofilox) and other treatments are needed. Products for home use are relatively expensive: a 1-month supply of imiquimod costs approximately $150; a 1-month supply of podofilox, $110 to $130. These are average wholesale prices, rounded to the nearest $10, as of Feb. 15, 2002.

TABLE
CLEARANCE RATES REPORTED IN CLINICAL TRIALS

Recommendations from others

The CDC endorses podophyllin, bi- and trichloroacetic acid, podofilox, imiquimod, cryotherapy, intralesional interferon, electrosurgery, laser surgery, and surgical excision.⁸ A United Kingdom guideline on anogenital warts recommends physical ablative methods such as cryotherapy and surgical options for keratinized lesions and topical medications for soft lesions. The guideline also recommends ablative therapy for persons with a small number of warts regardless of type. Interferon and 5-FU are not recommended.⁹

Clinical Commentary by David White, MD, at http://www.fpin.org.

Evidence summary

Nonsurgical treatments that are beneficial in eradicating genital warts are podofilox (Condylox) (8 randomized controlled trials [RCTs] with 1035 participants), imiquimod (Aldara) (2 RCTs with 968 participants), and intralesional interferon (8 RCTs). Cryotherapy is equivalent to trichloroacetic acid^1,2 and electrosurgery.³ Although surgical treatments have not been compared with placebo or no treatment, both electrosurgery and surgical excision are superior to podophyllin in clinical trials.^4,5 Laser surgery is as effective as surgical excision.⁶ Studies of topical interferon show conflicting results.⁷ Systemic interferon is not beneficial.⁷ Topical 5-FU has not been studied with RCTs. Wart clearance rates are summarized in the Table. Treatment duration for nonsurgical options is 4 to 8 weeks. Treatment of genital warts has not been shown to reduce transmission to sex partners.⁷

Two RCTs^4,5 showed more frequent recurrence with podophyllin (60% to 65%) than with surgical excision (19% to 20%). Another trial¹ showed recurrence in 22% of participants receiving electrosurgery, in 21% of those receiving cryotherapy, and in 44% of those receiving podophyllin treatment. Data are lacking on recurrence rates with imiquimod, podofilox, and intralesional interferon.

Pain occurs in less than 20% of people with imiquimod, cryotherapy, podophyllin, and electrosurgery; 39% with topical interferon; 44% with electrosurgery; 75% with podofilox; and 100% with surgical excision or laser surgery.⁷ However, pain has been measured using methods that are unlikely to be comparable across studies. Flulike symptoms, leukopenia, thrombocytopenia, and elevated aspartate transaminase levels are associated with intralesional interferon.⁷ Topical medications have not been studied in pregnant patients. Cryotherapy is safe in pregnancy based on case series, if only 3 or 4 treatments are given.⁷

Direct comparisons between home therapies (imiquimod, podofilox) and other treatments are needed. Products for home use are relatively expensive: a 1-month supply of imiquimod costs approximately $150; a 1-month supply of podofilox, $110 to $130. These are average wholesale prices, rounded to the nearest $10, as of Feb. 15, 2002.

TABLE
CLEARANCE RATES REPORTED IN CLINICAL TRIALS

Recommendations from others

The CDC endorses podophyllin, bi- and trichloroacetic acid, podofilox, imiquimod, cryotherapy, intralesional interferon, electrosurgery, laser surgery, and surgical excision.⁸ A United Kingdom guideline on anogenital warts recommends physical ablative methods such as cryotherapy and surgical options for keratinized lesions and topical medications for soft lesions. The guideline also recommends ablative therapy for persons with a small number of warts regardless of type. Interferon and 5-FU are not recommended.⁹

Clinical Commentary by David White, MD, at http://www.fpin.org.

Evidence summary

Nonsurgical treatments that are beneficial in eradicating genital warts are podofilox (Condylox) (8 randomized controlled trials [RCTs] with 1035 participants), imiquimod (Aldara) (2 RCTs with 968 participants), and intralesional interferon (8 RCTs). Cryotherapy is equivalent to trichloroacetic acid^1,2 and electrosurgery.³ Although surgical treatments have not been compared with placebo or no treatment, both electrosurgery and surgical excision are superior to podophyllin in clinical trials.^4,5 Laser surgery is as effective as surgical excision.⁶ Studies of topical interferon show conflicting results.⁷ Systemic interferon is not beneficial.⁷ Topical 5-FU has not been studied with RCTs. Wart clearance rates are summarized in the Table. Treatment duration for nonsurgical options is 4 to 8 weeks. Treatment of genital warts has not been shown to reduce transmission to sex partners.⁷

Two RCTs^4,5 showed more frequent recurrence with podophyllin (60% to 65%) than with surgical excision (19% to 20%). Another trial¹ showed recurrence in 22% of participants receiving electrosurgery, in 21% of those receiving cryotherapy, and in 44% of those receiving podophyllin treatment. Data are lacking on recurrence rates with imiquimod, podofilox, and intralesional interferon.

Pain occurs in less than 20% of people with imiquimod, cryotherapy, podophyllin, and electrosurgery; 39% with topical interferon; 44% with electrosurgery; 75% with podofilox; and 100% with surgical excision or laser surgery.⁷ However, pain has been measured using methods that are unlikely to be comparable across studies. Flulike symptoms, leukopenia, thrombocytopenia, and elevated aspartate transaminase levels are associated with intralesional interferon.⁷ Topical medications have not been studied in pregnant patients. Cryotherapy is safe in pregnancy based on case series, if only 3 or 4 treatments are given.⁷

Direct comparisons between home therapies (imiquimod, podofilox) and other treatments are needed. Products for home use are relatively expensive: a 1-month supply of imiquimod costs approximately $150; a 1-month supply of podofilox, $110 to $130. These are average wholesale prices, rounded to the nearest $10, as of Feb. 15, 2002.

TABLE
CLEARANCE RATES REPORTED IN CLINICAL TRIALS

Recommendations from others

The CDC endorses podophyllin, bi- and trichloroacetic acid, podofilox, imiquimod, cryotherapy, intralesional interferon, electrosurgery, laser surgery, and surgical excision.⁸ A United Kingdom guideline on anogenital warts recommends physical ablative methods such as cryotherapy and surgical options for keratinized lesions and topical medications for soft lesions. The guideline also recommends ablative therapy for persons with a small number of warts regardless of type. Interferon and 5-FU are not recommended.⁹

Clinical Commentary by David White, MD, at http://www.fpin.org.