Leslie Mackler, MSLS

Evidence summary

The annual incidence of infectious mononucleosis is somewhere between 345 and 671 cases per 100,000 in the US; it is highest in the adolescent age group.¹ Splenic rupture is the leading cause of death in infectious mononucleosis, occurring in 0.1% to 0.2% of all cases.^{1- 4} Based on this figure, approximately 100 cases of rupture may occur yearly in the US, only a few of which are reported.

A retrospective analysis of 8116 patients with infectious mononucleosis at the Mayo Clinic estimated the risk of spontaneous splenic rupture to be 0.1% of cases, correlating with rates found in other studies. The study’s criteria for definite spontaneous rupture are: no recent trauma; recent symptoms; hematologic, serologic, and histologic (splenic) evidence of infectious mononucleosis. Five patients with rupture (average age, 22) were identified; 3 were male. Splenectomy was performed for all patients. Follow-up over 33-years found all patients healthy with minimal subsequent illness.³

A review of 55 cases found almost all splenic ruptures occurred between the fourth and twenty-first days of illness, and that all affected spleens were enlarged, although only half were palpable on exam. Ninety percent of the ruptures occurred in males, and more than half were nontraumatic. There was no correlation between severity of illness and susceptibility to splenic rupture. No specifics were given on duration of illness or how splenomegaly was diagnosed.⁴

The best technique for identifying splenic enlargement and determining risk of rupture is unclear. In a case-control study, 29 patients were admitted to an ear, nose, and throat department with infectious mononucleosis and were evaluated serially for splenic and hepatic enlargement by ultrasound. Diagnosis was based on clinical picture, a positive heterophile test, and other blood tests. Four patients were included despite negative serology due to compelling clinical presentations and symptoms. Serial ultrasound imaging showed that all had enlarged spleens (mean enlargement 50%–60%); 50% had hepatic enlargement (5%–20% enlargement). The patients were compared with a control group of 8 patients admitted with peritonsillar abscess, as verified by tonsillectomy. No controls had hepatic or splenic enlargement. Physical examinations detected splenomegaly in only 17% of the study patients. The exams were conducted by house staff without blinding, randomization, or tests of reproducibility. Ultrasound scanning was completed on days 1, 3, 5, 10, 20, 90, and 120. The spleen was significantly larger in the infectious mononucleosis group than in the control group for the first 30 days, and no difference in size was found over the subsequent 3 months. No correlation existed between laboratory values and enlargement of the spleen or liver.⁵

No quality studies evaluate the risks of physical activity in infectious mononucleosis. Case reports of rupture have found comparable rates between traumatic and nontraumatic causes. In addition, no clinical trials evaluate imaging in decisions regarding return to activity and its effect on splenic rupture. Ultrasound is often used in the athletic setting for these decisions but no evidence supports its use as routine practice. The routine use of ultrasound for this purpose would cost more than $1 million to prevent 1 traumatic rupture.⁶

Recommendations from others

Clinical Sports Medicine recommends athletes refrain from sporting activities until all acute symptoms resolve and contact sports avoided while the spleen is enlarged. No recommendation is given on determining spleen size.⁷

Team Physician Handbook recommends athletes do no cardiovascular work, lifting, strength training, or contact sports for 2 weeks because of the risk of splenic rupture. Activity is then gradually increased as the athlete improves. Athletes are to avoid contact or weight-lifting for 4 weeks unless they feel well and ultrasound reveals a normal-sized spleen.⁸

Sports Medicine Secrets advises ultrasound or CT of the spleen to be obtained if there is any suspicion of splenomegaly or if return to play before 4 weeks is contemplated. Light athletic activity may be resumed approximately 3 weeks after symptom onset if the spleen is not tender or enlarged on examination, the patient is afebrile, liver enzymes are normal, and all other complications are resolved. Contact sports may be resumed 4 weeks after symptom onset if there is no documentation of splenomegaly, the athlete feels ready, and all other complications have resolved.⁹

Evidence summary

The annual incidence of infectious mononucleosis is somewhere between 345 and 671 cases per 100,000 in the US; it is highest in the adolescent age group.¹ Splenic rupture is the leading cause of death in infectious mononucleosis, occurring in 0.1% to 0.2% of all cases.^{1- 4} Based on this figure, approximately 100 cases of rupture may occur yearly in the US, only a few of which are reported.

A retrospective analysis of 8116 patients with infectious mononucleosis at the Mayo Clinic estimated the risk of spontaneous splenic rupture to be 0.1% of cases, correlating with rates found in other studies. The study’s criteria for definite spontaneous rupture are: no recent trauma; recent symptoms; hematologic, serologic, and histologic (splenic) evidence of infectious mononucleosis. Five patients with rupture (average age, 22) were identified; 3 were male. Splenectomy was performed for all patients. Follow-up over 33-years found all patients healthy with minimal subsequent illness.³

A review of 55 cases found almost all splenic ruptures occurred between the fourth and twenty-first days of illness, and that all affected spleens were enlarged, although only half were palpable on exam. Ninety percent of the ruptures occurred in males, and more than half were nontraumatic. There was no correlation between severity of illness and susceptibility to splenic rupture. No specifics were given on duration of illness or how splenomegaly was diagnosed.⁴

The best technique for identifying splenic enlargement and determining risk of rupture is unclear. In a case-control study, 29 patients were admitted to an ear, nose, and throat department with infectious mononucleosis and were evaluated serially for splenic and hepatic enlargement by ultrasound. Diagnosis was based on clinical picture, a positive heterophile test, and other blood tests. Four patients were included despite negative serology due to compelling clinical presentations and symptoms. Serial ultrasound imaging showed that all had enlarged spleens (mean enlargement 50%–60%); 50% had hepatic enlargement (5%–20% enlargement). The patients were compared with a control group of 8 patients admitted with peritonsillar abscess, as verified by tonsillectomy. No controls had hepatic or splenic enlargement. Physical examinations detected splenomegaly in only 17% of the study patients. The exams were conducted by house staff without blinding, randomization, or tests of reproducibility. Ultrasound scanning was completed on days 1, 3, 5, 10, 20, 90, and 120. The spleen was significantly larger in the infectious mononucleosis group than in the control group for the first 30 days, and no difference in size was found over the subsequent 3 months. No correlation existed between laboratory values and enlargement of the spleen or liver.⁵

No quality studies evaluate the risks of physical activity in infectious mononucleosis. Case reports of rupture have found comparable rates between traumatic and nontraumatic causes. In addition, no clinical trials evaluate imaging in decisions regarding return to activity and its effect on splenic rupture. Ultrasound is often used in the athletic setting for these decisions but no evidence supports its use as routine practice. The routine use of ultrasound for this purpose would cost more than $1 million to prevent 1 traumatic rupture.⁶

Recommendations from others

Clinical Sports Medicine recommends athletes refrain from sporting activities until all acute symptoms resolve and contact sports avoided while the spleen is enlarged. No recommendation is given on determining spleen size.⁷

Team Physician Handbook recommends athletes do no cardiovascular work, lifting, strength training, or contact sports for 2 weeks because of the risk of splenic rupture. Activity is then gradually increased as the athlete improves. Athletes are to avoid contact or weight-lifting for 4 weeks unless they feel well and ultrasound reveals a normal-sized spleen.⁸

Sports Medicine Secrets advises ultrasound or CT of the spleen to be obtained if there is any suspicion of splenomegaly or if return to play before 4 weeks is contemplated. Light athletic activity may be resumed approximately 3 weeks after symptom onset if the spleen is not tender or enlarged on examination, the patient is afebrile, liver enzymes are normal, and all other complications are resolved. Contact sports may be resumed 4 weeks after symptom onset if there is no documentation of splenomegaly, the athlete feels ready, and all other complications have resolved.⁹

Evidence summary

The annual incidence of infectious mononucleosis is somewhere between 345 and 671 cases per 100,000 in the US; it is highest in the adolescent age group.¹ Splenic rupture is the leading cause of death in infectious mononucleosis, occurring in 0.1% to 0.2% of all cases.^{1- 4} Based on this figure, approximately 100 cases of rupture may occur yearly in the US, only a few of which are reported.

A retrospective analysis of 8116 patients with infectious mononucleosis at the Mayo Clinic estimated the risk of spontaneous splenic rupture to be 0.1% of cases, correlating with rates found in other studies. The study’s criteria for definite spontaneous rupture are: no recent trauma; recent symptoms; hematologic, serologic, and histologic (splenic) evidence of infectious mononucleosis. Five patients with rupture (average age, 22) were identified; 3 were male. Splenectomy was performed for all patients. Follow-up over 33-years found all patients healthy with minimal subsequent illness.³

A review of 55 cases found almost all splenic ruptures occurred between the fourth and twenty-first days of illness, and that all affected spleens were enlarged, although only half were palpable on exam. Ninety percent of the ruptures occurred in males, and more than half were nontraumatic. There was no correlation between severity of illness and susceptibility to splenic rupture. No specifics were given on duration of illness or how splenomegaly was diagnosed.⁴

The best technique for identifying splenic enlargement and determining risk of rupture is unclear. In a case-control study, 29 patients were admitted to an ear, nose, and throat department with infectious mononucleosis and were evaluated serially for splenic and hepatic enlargement by ultrasound. Diagnosis was based on clinical picture, a positive heterophile test, and other blood tests. Four patients were included despite negative serology due to compelling clinical presentations and symptoms. Serial ultrasound imaging showed that all had enlarged spleens (mean enlargement 50%–60%); 50% had hepatic enlargement (5%–20% enlargement). The patients were compared with a control group of 8 patients admitted with peritonsillar abscess, as verified by tonsillectomy. No controls had hepatic or splenic enlargement. Physical examinations detected splenomegaly in only 17% of the study patients. The exams were conducted by house staff without blinding, randomization, or tests of reproducibility. Ultrasound scanning was completed on days 1, 3, 5, 10, 20, 90, and 120. The spleen was significantly larger in the infectious mononucleosis group than in the control group for the first 30 days, and no difference in size was found over the subsequent 3 months. No correlation existed between laboratory values and enlargement of the spleen or liver.⁵

No quality studies evaluate the risks of physical activity in infectious mononucleosis. Case reports of rupture have found comparable rates between traumatic and nontraumatic causes. In addition, no clinical trials evaluate imaging in decisions regarding return to activity and its effect on splenic rupture. Ultrasound is often used in the athletic setting for these decisions but no evidence supports its use as routine practice. The routine use of ultrasound for this purpose would cost more than $1 million to prevent 1 traumatic rupture.⁶

Recommendations from others

Clinical Sports Medicine recommends athletes refrain from sporting activities until all acute symptoms resolve and contact sports avoided while the spleen is enlarged. No recommendation is given on determining spleen size.⁷

Team Physician Handbook recommends athletes do no cardiovascular work, lifting, strength training, or contact sports for 2 weeks because of the risk of splenic rupture. Activity is then gradually increased as the athlete improves. Athletes are to avoid contact or weight-lifting for 4 weeks unless they feel well and ultrasound reveals a normal-sized spleen.⁸

Sports Medicine Secrets advises ultrasound or CT of the spleen to be obtained if there is any suspicion of splenomegaly or if return to play before 4 weeks is contemplated. Light athletic activity may be resumed approximately 3 weeks after symptom onset if the spleen is not tender or enlarged on examination, the patient is afebrile, liver enzymes are normal, and all other complications are resolved. Contact sports may be resumed 4 weeks after symptom onset if there is no documentation of splenomegaly, the athlete feels ready, and all other complications have resolved.⁹

Evidence summary

Leg cramps (heat cramps) in athletes are defined as painful involuntary muscle contractions, usually in the large muscle groups of the legs, which occur during or in the hours following exercise. Oral quinine is sometimes used to treat nocturnal leg cramps in the general adult and elderly populations. However, its use is controversial secondary to concerns regarding efficacy and safety.

Efficacy of quinine in young athletes has not been well studied. A case series reported on 2 athletes: 1 college basketball player and 1 professional football player.¹ The basketball player experienced heat cramps during games that were resistant to hydration and dietary treatment. A regimen of 60 mg oral quinine sulfate taken 1 hour before game time and again at halftime eliminated cramps during the first game and the subsequent 15 games. The football player’s heat cramps were only partially improved with oral electrolyte repletion and oral hydration. However, he suffered no further cramps after initiating a regimen of 120 mg oral quinine sulfate before games and 60 mg oral quinine during games for an undisclosed period of time. Both players had normal blood chemistries before starting quinine. No side effects were mentioned.

Several trials involving the general adult population exist. A meta-analysis of 4 published and 3 unpublished reports of randomized, double-blind controlled crossover trials (n=409) showed that adult patients had significantly fewer nocturnal cramps when taking quinine compared with placebo.² The absolute reduction in number of leg cramps was 3.6 (95% confidence interval [CI], 2.15–5.05) over a 4-week period, and the relative risk reduction was 0.21 (95% CI, 0.12–0.30).

Two randomized controlled trials were not included in the meta-analysis discussed above. One double-blind, randomized, controlled parallel group trial of 98 adult patients with a mean age of 50 years demonstrated that a regimen of daily quinine sulfate therapy of 200 mg with the evening meal and 200 mg at bedtime significantly reduced the number of nocturnal muscle cramps compared with placebo.³ Over a 2-week treatment period the quinine group experienced a median of 8 fewer cramps (95% CI, 7–10), while the placebo group experienced a median of 6 fewer cramps (95% CI, 3–7). However, patient evaluation of global efficacy of treatment was not statistically significant between the quinine and placebo groups.

A second double-blind, randomized, controlled parallel group trial of 102 adult patients, mean age approximately 50 years, showed that a 2-week treatment period of hydroquinine (not available in the US) also produced a significant reduction in day- and nighttime muscle cramps compared with placebo.⁴ This study used a regimen of two 100-mg hydroquinine or placebo tablets with the evening meal and one 100-mg tablet or placebo at bedtime. The median difference in the number of cramps between the treatment and control groups was 5 (95% CI, 2–8).

It should be noted that during the 2 weeks immediately following the treatment period, numbers of cramps were still low compared with the pretreatment period and no significant difference was seen in number of cramps between groups. This raises suspicion that the improvement in both groups was due to the self-limited nature of cramps and represented the regression-to-the-mean phenomenon rather than a true treatment effect of hydroquinine. In addition, extrapolating results from studies of nocturnal cramps to heat cramps is problematic, as it is unknown whether these differ in physiology or cause.

Use of quinine for common cramps in nonathletes has been controversial. In 1994 the Food and Drug Administration (FDA) issued a statement banning over-the-counter sale of quinine for nocturnal leg cramps, citing lack of adequate data to establish efficacy and concern for potential toxicity.⁵ Between 1969 and 1990 the FDA received 26 adverse reaction reports in which quinine was concluded to be the causative agent. The 3 studies discussed above consistently mention only tinnitus as likely related to quinine use. However, the descriptions and inference testing of side effects were inadequate in each study.

Of note, quinine is a category X drug and should not be used during pregnancy.⁶

Recommendations from others

No specific recommendations exist regarding the use of quinine in athletes. The American Medical Society of Sports Medicine recommends rest, stretching, and oral hydration for simple heat cramps, and intravenous fluids for very severe cases.⁷ Several texts also recommend rehydration with an oral electrolyte solution, as well as rest, stretching, and massage.^8-10

Evidence summary

Leg cramps (heat cramps) in athletes are defined as painful involuntary muscle contractions, usually in the large muscle groups of the legs, which occur during or in the hours following exercise. Oral quinine is sometimes used to treat nocturnal leg cramps in the general adult and elderly populations. However, its use is controversial secondary to concerns regarding efficacy and safety.

Efficacy of quinine in young athletes has not been well studied. A case series reported on 2 athletes: 1 college basketball player and 1 professional football player.¹ The basketball player experienced heat cramps during games that were resistant to hydration and dietary treatment. A regimen of 60 mg oral quinine sulfate taken 1 hour before game time and again at halftime eliminated cramps during the first game and the subsequent 15 games. The football player’s heat cramps were only partially improved with oral electrolyte repletion and oral hydration. However, he suffered no further cramps after initiating a regimen of 120 mg oral quinine sulfate before games and 60 mg oral quinine during games for an undisclosed period of time. Both players had normal blood chemistries before starting quinine. No side effects were mentioned.

Several trials involving the general adult population exist. A meta-analysis of 4 published and 3 unpublished reports of randomized, double-blind controlled crossover trials (n=409) showed that adult patients had significantly fewer nocturnal cramps when taking quinine compared with placebo.² The absolute reduction in number of leg cramps was 3.6 (95% confidence interval [CI], 2.15–5.05) over a 4-week period, and the relative risk reduction was 0.21 (95% CI, 0.12–0.30).

Two randomized controlled trials were not included in the meta-analysis discussed above. One double-blind, randomized, controlled parallel group trial of 98 adult patients with a mean age of 50 years demonstrated that a regimen of daily quinine sulfate therapy of 200 mg with the evening meal and 200 mg at bedtime significantly reduced the number of nocturnal muscle cramps compared with placebo.³ Over a 2-week treatment period the quinine group experienced a median of 8 fewer cramps (95% CI, 7–10), while the placebo group experienced a median of 6 fewer cramps (95% CI, 3–7). However, patient evaluation of global efficacy of treatment was not statistically significant between the quinine and placebo groups.

A second double-blind, randomized, controlled parallel group trial of 102 adult patients, mean age approximately 50 years, showed that a 2-week treatment period of hydroquinine (not available in the US) also produced a significant reduction in day- and nighttime muscle cramps compared with placebo.⁴ This study used a regimen of two 100-mg hydroquinine or placebo tablets with the evening meal and one 100-mg tablet or placebo at bedtime. The median difference in the number of cramps between the treatment and control groups was 5 (95% CI, 2–8).

It should be noted that during the 2 weeks immediately following the treatment period, numbers of cramps were still low compared with the pretreatment period and no significant difference was seen in number of cramps between groups. This raises suspicion that the improvement in both groups was due to the self-limited nature of cramps and represented the regression-to-the-mean phenomenon rather than a true treatment effect of hydroquinine. In addition, extrapolating results from studies of nocturnal cramps to heat cramps is problematic, as it is unknown whether these differ in physiology or cause.

Use of quinine for common cramps in nonathletes has been controversial. In 1994 the Food and Drug Administration (FDA) issued a statement banning over-the-counter sale of quinine for nocturnal leg cramps, citing lack of adequate data to establish efficacy and concern for potential toxicity.⁵ Between 1969 and 1990 the FDA received 26 adverse reaction reports in which quinine was concluded to be the causative agent. The 3 studies discussed above consistently mention only tinnitus as likely related to quinine use. However, the descriptions and inference testing of side effects were inadequate in each study.

Of note, quinine is a category X drug and should not be used during pregnancy.⁶

Recommendations from others

No specific recommendations exist regarding the use of quinine in athletes. The American Medical Society of Sports Medicine recommends rest, stretching, and oral hydration for simple heat cramps, and intravenous fluids for very severe cases.⁷ Several texts also recommend rehydration with an oral electrolyte solution, as well as rest, stretching, and massage.^8-10

Evidence summary

Leg cramps (heat cramps) in athletes are defined as painful involuntary muscle contractions, usually in the large muscle groups of the legs, which occur during or in the hours following exercise. Oral quinine is sometimes used to treat nocturnal leg cramps in the general adult and elderly populations. However, its use is controversial secondary to concerns regarding efficacy and safety.

Efficacy of quinine in young athletes has not been well studied. A case series reported on 2 athletes: 1 college basketball player and 1 professional football player.¹ The basketball player experienced heat cramps during games that were resistant to hydration and dietary treatment. A regimen of 60 mg oral quinine sulfate taken 1 hour before game time and again at halftime eliminated cramps during the first game and the subsequent 15 games. The football player’s heat cramps were only partially improved with oral electrolyte repletion and oral hydration. However, he suffered no further cramps after initiating a regimen of 120 mg oral quinine sulfate before games and 60 mg oral quinine during games for an undisclosed period of time. Both players had normal blood chemistries before starting quinine. No side effects were mentioned.

Several trials involving the general adult population exist. A meta-analysis of 4 published and 3 unpublished reports of randomized, double-blind controlled crossover trials (n=409) showed that adult patients had significantly fewer nocturnal cramps when taking quinine compared with placebo.² The absolute reduction in number of leg cramps was 3.6 (95% confidence interval [CI], 2.15–5.05) over a 4-week period, and the relative risk reduction was 0.21 (95% CI, 0.12–0.30).

Two randomized controlled trials were not included in the meta-analysis discussed above. One double-blind, randomized, controlled parallel group trial of 98 adult patients with a mean age of 50 years demonstrated that a regimen of daily quinine sulfate therapy of 200 mg with the evening meal and 200 mg at bedtime significantly reduced the number of nocturnal muscle cramps compared with placebo.³ Over a 2-week treatment period the quinine group experienced a median of 8 fewer cramps (95% CI, 7–10), while the placebo group experienced a median of 6 fewer cramps (95% CI, 3–7). However, patient evaluation of global efficacy of treatment was not statistically significant between the quinine and placebo groups.

A second double-blind, randomized, controlled parallel group trial of 102 adult patients, mean age approximately 50 years, showed that a 2-week treatment period of hydroquinine (not available in the US) also produced a significant reduction in day- and nighttime muscle cramps compared with placebo.⁴ This study used a regimen of two 100-mg hydroquinine or placebo tablets with the evening meal and one 100-mg tablet or placebo at bedtime. The median difference in the number of cramps between the treatment and control groups was 5 (95% CI, 2–8).

It should be noted that during the 2 weeks immediately following the treatment period, numbers of cramps were still low compared with the pretreatment period and no significant difference was seen in number of cramps between groups. This raises suspicion that the improvement in both groups was due to the self-limited nature of cramps and represented the regression-to-the-mean phenomenon rather than a true treatment effect of hydroquinine. In addition, extrapolating results from studies of nocturnal cramps to heat cramps is problematic, as it is unknown whether these differ in physiology or cause.

Use of quinine for common cramps in nonathletes has been controversial. In 1994 the Food and Drug Administration (FDA) issued a statement banning over-the-counter sale of quinine for nocturnal leg cramps, citing lack of adequate data to establish efficacy and concern for potential toxicity.⁵ Between 1969 and 1990 the FDA received 26 adverse reaction reports in which quinine was concluded to be the causative agent. The 3 studies discussed above consistently mention only tinnitus as likely related to quinine use. However, the descriptions and inference testing of side effects were inadequate in each study.

Of note, quinine is a category X drug and should not be used during pregnancy.⁶

Recommendations from others

No specific recommendations exist regarding the use of quinine in athletes. The American Medical Society of Sports Medicine recommends rest, stretching, and oral hydration for simple heat cramps, and intravenous fluids for very severe cases.⁷ Several texts also recommend rehydration with an oral electrolyte solution, as well as rest, stretching, and massage.^8-10

Evidence summary

Tramadol is a novel, central-acting synthetic opioid with weak mu-opioid activity, and is approved for treatment of moderate to moderately severe pain in adults. Anecdotally, some clinicians have assumed this popular analgesic’s nonscheduled status under the Controlled Substance Act (CSA) means tramadol has no substance abuse potential. (The term “abuse” herein denotes substance abuse or dependence.)

Evidence of tramadol abuse in the US comes primarily from federally operated programs collecting adverse drug event (ADE) data. The MedWatch program of the Food and Drug Administration (FDA) provides a central depository for receiving and compiling postmarketing voluntary case reports. While passive reporting systems can significantly underestimate serious ADE numbers, these reports are often the first evidence of an ADE after a new drug’s release into the market.¹ MedWatch has received 766 case reports of abuse associated with tramadol, as well as 482 cases of withdrawal associated with tramadol from the drug’s initial US marketing in 1995 through September 2004.^2,3

The Drug Abuse Warning Network (DAWN) is a federally operated, national surveillance system that monitors trends in drug-related emergency department visits. Over the period from 1995 to 2002, DAWN reported drug-related emergency department visits mentioning tramadol in more than 12,000 cases. Tramadol case numbers significantly increased 165% during this time. For perspective, during the same period, DAWN found nalbuphine (Nubain, also not CSA scheduled) in 118 cases, propoxyphene drug combinations (CSA Class IV) in more than 45,000 cases, codeine drug combinations (CSA Classes III & V) in about 50,000 cases, and hydrocodone drug combinations (CSA Class III) in around 128,000 cases.⁴

Using data from observational postmarketing studies, investigators have extrapolated a tramadol abuse rate for the general tramadolexposed population.^5,6 Ortho-McNeil, Ultram’s manufacturer, funded a surveillance program that compiled tramadol abuse and withdrawal case reports from 2 sources: (1) periodic surveys for tramadol abuse case reports from a group of 255 substance abuse experts studying and caring for addiction communities, and (2) voluntary ADE case reports from health care professionals and consumers received by Ortho-McNeil. Over 3 years of surveillance, the program received 454 case reports classified as tramadol abuse. Over 5 years of surveillance, 422 cases of substance withdrawal, with primarily opioid withdrawal symptoms, were reported. There are significant threats to the validity and generalizability of the investigators’ estimated abuse rate of 1 to 3 cases per 100,000 tramadol-exposed patients. The abuse cases were collected in nonrepresentative samples of the tramadol-exposed population. Tramadol exposure is likely suppressed in addiction communities with access to preferred, more potent or euphoriant opioids than tramadol. Voluntary case reports of tramadol abuse significantly underestimate the actual number of abuse cases in the tramadol-exposed population. In addition, the low survey return rate (49%) further decreases the accuracy of any estimation of tramadol abuse rates.

Prospective studies among patients with known abuse, or at high risk of abuse, reported a tramadol abuse rate, as well as subjective experiences of tramadol withdrawal. A 3-year post-marketing cohort study measured tramadol’s nonmedical misuse rates using urine drug testing for tramadol among 1601 participants in 4 US state monitoring programs for impaired healthcare professionals.⁷ Tramadol exposure occurred in 140 (8.7%) participants. Thirty-nine (28%) were classified as extensive experimentation or abuse of tramadol. Overall, the rate of extensive experimentation or abuse was 18 cases per thousand personyears. The Hawthorne effect, where awareness of being monitored alters a subject’s behavior, may threaten these measured frequency rates’ generalizability. Another prospective study assessed the subjective tramadol withdrawal experience in 219 patients with a diagnosis of “Tramadol misuse” who were attending 6 drug detoxification centers in China.⁸ Validated drug dependence symptom scales found that while the degree of physical dependence reported was uniformly mild, the majority of patients reported the psychic dependence symptom of tramadol craving.

The FDA’s Drug Abuse Advisory Committee performed a formal review of the tramadol abuse evidence in 1998, including the data from OrthoMcNeil’s surveillance studies and federal case reporting/surveillance programs. The FDA did not recommend changing tramadol’s unscheduled status.⁹ The FDA’s considered decision to not schedule tramadol as a controlled substance implies its abuse risk to the general population is low. in comparison to its novel analgesic benefit.

Recommendations from others

Ortho-McNeil’s revised 2001 product package insert for Ultram states, “Tramadol may induce psychic and physical dependence of the morphine type (mu-opioid). Dependence and abuse, including drug-seeking behavior and taking illicit actions to obtain the drug are not limited to those patients with prior history of opioid dependence.” (italics in original, emphasizing 2001 addition). The risk for patients with a history of substance abuse has been observed to be higher.¹⁰

Evidence summary

Tramadol is a novel, central-acting synthetic opioid with weak mu-opioid activity, and is approved for treatment of moderate to moderately severe pain in adults. Anecdotally, some clinicians have assumed this popular analgesic’s nonscheduled status under the Controlled Substance Act (CSA) means tramadol has no substance abuse potential. (The term “abuse” herein denotes substance abuse or dependence.)

Evidence of tramadol abuse in the US comes primarily from federally operated programs collecting adverse drug event (ADE) data. The MedWatch program of the Food and Drug Administration (FDA) provides a central depository for receiving and compiling postmarketing voluntary case reports. While passive reporting systems can significantly underestimate serious ADE numbers, these reports are often the first evidence of an ADE after a new drug’s release into the market.¹ MedWatch has received 766 case reports of abuse associated with tramadol, as well as 482 cases of withdrawal associated with tramadol from the drug’s initial US marketing in 1995 through September 2004.^2,3

The Drug Abuse Warning Network (DAWN) is a federally operated, national surveillance system that monitors trends in drug-related emergency department visits. Over the period from 1995 to 2002, DAWN reported drug-related emergency department visits mentioning tramadol in more than 12,000 cases. Tramadol case numbers significantly increased 165% during this time. For perspective, during the same period, DAWN found nalbuphine (Nubain, also not CSA scheduled) in 118 cases, propoxyphene drug combinations (CSA Class IV) in more than 45,000 cases, codeine drug combinations (CSA Classes III & V) in about 50,000 cases, and hydrocodone drug combinations (CSA Class III) in around 128,000 cases.⁴

Using data from observational postmarketing studies, investigators have extrapolated a tramadol abuse rate for the general tramadolexposed population.^5,6 Ortho-McNeil, Ultram’s manufacturer, funded a surveillance program that compiled tramadol abuse and withdrawal case reports from 2 sources: (1) periodic surveys for tramadol abuse case reports from a group of 255 substance abuse experts studying and caring for addiction communities, and (2) voluntary ADE case reports from health care professionals and consumers received by Ortho-McNeil. Over 3 years of surveillance, the program received 454 case reports classified as tramadol abuse. Over 5 years of surveillance, 422 cases of substance withdrawal, with primarily opioid withdrawal symptoms, were reported. There are significant threats to the validity and generalizability of the investigators’ estimated abuse rate of 1 to 3 cases per 100,000 tramadol-exposed patients. The abuse cases were collected in nonrepresentative samples of the tramadol-exposed population. Tramadol exposure is likely suppressed in addiction communities with access to preferred, more potent or euphoriant opioids than tramadol. Voluntary case reports of tramadol abuse significantly underestimate the actual number of abuse cases in the tramadol-exposed population. In addition, the low survey return rate (49%) further decreases the accuracy of any estimation of tramadol abuse rates.

Prospective studies among patients with known abuse, or at high risk of abuse, reported a tramadol abuse rate, as well as subjective experiences of tramadol withdrawal. A 3-year post-marketing cohort study measured tramadol’s nonmedical misuse rates using urine drug testing for tramadol among 1601 participants in 4 US state monitoring programs for impaired healthcare professionals.⁷ Tramadol exposure occurred in 140 (8.7%) participants. Thirty-nine (28%) were classified as extensive experimentation or abuse of tramadol. Overall, the rate of extensive experimentation or abuse was 18 cases per thousand personyears. The Hawthorne effect, where awareness of being monitored alters a subject’s behavior, may threaten these measured frequency rates’ generalizability. Another prospective study assessed the subjective tramadol withdrawal experience in 219 patients with a diagnosis of “Tramadol misuse” who were attending 6 drug detoxification centers in China.⁸ Validated drug dependence symptom scales found that while the degree of physical dependence reported was uniformly mild, the majority of patients reported the psychic dependence symptom of tramadol craving.

The FDA’s Drug Abuse Advisory Committee performed a formal review of the tramadol abuse evidence in 1998, including the data from OrthoMcNeil’s surveillance studies and federal case reporting/surveillance programs. The FDA did not recommend changing tramadol’s unscheduled status.⁹ The FDA’s considered decision to not schedule tramadol as a controlled substance implies its abuse risk to the general population is low. in comparison to its novel analgesic benefit.

Recommendations from others

Ortho-McNeil’s revised 2001 product package insert for Ultram states, “Tramadol may induce psychic and physical dependence of the morphine type (mu-opioid). Dependence and abuse, including drug-seeking behavior and taking illicit actions to obtain the drug are not limited to those patients with prior history of opioid dependence.” (italics in original, emphasizing 2001 addition). The risk for patients with a history of substance abuse has been observed to be higher.¹⁰

Evidence summary

Tramadol is a novel, central-acting synthetic opioid with weak mu-opioid activity, and is approved for treatment of moderate to moderately severe pain in adults. Anecdotally, some clinicians have assumed this popular analgesic’s nonscheduled status under the Controlled Substance Act (CSA) means tramadol has no substance abuse potential. (The term “abuse” herein denotes substance abuse or dependence.)

Evidence of tramadol abuse in the US comes primarily from federally operated programs collecting adverse drug event (ADE) data. The MedWatch program of the Food and Drug Administration (FDA) provides a central depository for receiving and compiling postmarketing voluntary case reports. While passive reporting systems can significantly underestimate serious ADE numbers, these reports are often the first evidence of an ADE after a new drug’s release into the market.¹ MedWatch has received 766 case reports of abuse associated with tramadol, as well as 482 cases of withdrawal associated with tramadol from the drug’s initial US marketing in 1995 through September 2004.^2,3

The Drug Abuse Warning Network (DAWN) is a federally operated, national surveillance system that monitors trends in drug-related emergency department visits. Over the period from 1995 to 2002, DAWN reported drug-related emergency department visits mentioning tramadol in more than 12,000 cases. Tramadol case numbers significantly increased 165% during this time. For perspective, during the same period, DAWN found nalbuphine (Nubain, also not CSA scheduled) in 118 cases, propoxyphene drug combinations (CSA Class IV) in more than 45,000 cases, codeine drug combinations (CSA Classes III & V) in about 50,000 cases, and hydrocodone drug combinations (CSA Class III) in around 128,000 cases.⁴

Using data from observational postmarketing studies, investigators have extrapolated a tramadol abuse rate for the general tramadolexposed population.^5,6 Ortho-McNeil, Ultram’s manufacturer, funded a surveillance program that compiled tramadol abuse and withdrawal case reports from 2 sources: (1) periodic surveys for tramadol abuse case reports from a group of 255 substance abuse experts studying and caring for addiction communities, and (2) voluntary ADE case reports from health care professionals and consumers received by Ortho-McNeil. Over 3 years of surveillance, the program received 454 case reports classified as tramadol abuse. Over 5 years of surveillance, 422 cases of substance withdrawal, with primarily opioid withdrawal symptoms, were reported. There are significant threats to the validity and generalizability of the investigators’ estimated abuse rate of 1 to 3 cases per 100,000 tramadol-exposed patients. The abuse cases were collected in nonrepresentative samples of the tramadol-exposed population. Tramadol exposure is likely suppressed in addiction communities with access to preferred, more potent or euphoriant opioids than tramadol. Voluntary case reports of tramadol abuse significantly underestimate the actual number of abuse cases in the tramadol-exposed population. In addition, the low survey return rate (49%) further decreases the accuracy of any estimation of tramadol abuse rates.

Prospective studies among patients with known abuse, or at high risk of abuse, reported a tramadol abuse rate, as well as subjective experiences of tramadol withdrawal. A 3-year post-marketing cohort study measured tramadol’s nonmedical misuse rates using urine drug testing for tramadol among 1601 participants in 4 US state monitoring programs for impaired healthcare professionals.⁷ Tramadol exposure occurred in 140 (8.7%) participants. Thirty-nine (28%) were classified as extensive experimentation or abuse of tramadol. Overall, the rate of extensive experimentation or abuse was 18 cases per thousand personyears. The Hawthorne effect, where awareness of being monitored alters a subject’s behavior, may threaten these measured frequency rates’ generalizability. Another prospective study assessed the subjective tramadol withdrawal experience in 219 patients with a diagnosis of “Tramadol misuse” who were attending 6 drug detoxification centers in China.⁸ Validated drug dependence symptom scales found that while the degree of physical dependence reported was uniformly mild, the majority of patients reported the psychic dependence symptom of tramadol craving.

The FDA’s Drug Abuse Advisory Committee performed a formal review of the tramadol abuse evidence in 1998, including the data from OrthoMcNeil’s surveillance studies and federal case reporting/surveillance programs. The FDA did not recommend changing tramadol’s unscheduled status.⁹ The FDA’s considered decision to not schedule tramadol as a controlled substance implies its abuse risk to the general population is low. in comparison to its novel analgesic benefit.

Recommendations from others

Ortho-McNeil’s revised 2001 product package insert for Ultram states, “Tramadol may induce psychic and physical dependence of the morphine type (mu-opioid). Dependence and abuse, including drug-seeking behavior and taking illicit actions to obtain the drug are not limited to those patients with prior history of opioid dependence.” (italics in original, emphasizing 2001 addition). The risk for patients with a history of substance abuse has been observed to be higher.¹⁰

Evidence summary

Testing the effectiveness of therapy for osteoporosis by measuring changes in bone mineral density (BMD) is difficult because changes are often small and occur slowly, and a decrease in BMD does not necessarily mean treatment failure. Testing patients after starting bisphosphonate therapy has been part of many drug trials to assess the effectiveness of therapy. Follow-up testing in clinical practice has not been the focus of a prospective trial and therefore remains controversial.¹

DEXA is considered the gold standard because it is the most extensively validated test for predicting fracture outcomes.² Understanding the rate of bone density response to therapy, and the precision error of DEXA, helps to determine monitoring intervals. The larger the responses in BMD to therapy and the more precise the DEXA scan result, the shorter the period between testing in which clinically relevant differences can be found. Precision error rates are estimated at <1% for the anterior-posterior spine and 1% to 2% for the hip.³ The BMD change after the initiation of treatment must escape the precision error of the testing device or exceed the least significant change (LSC) value.⁴ The LSC—roughly analogous to a 95% confidence interval—is 2.8 times the precision error of the test on a specific machine and site of measurement. If the precision error for DEXA of the femoral neck BMD is 2%, then the LSC is 5.6%.⁵ Changes in BMD of <2%–4% in the vertebrae and 3% to 6% at the hip could be due to inherent measurement error.⁶

A clinician must also understand the anticipated response to the prescribed therapy. It is not clinically useful to retest BMD before a therapy would have time to affect bone turnover. Alendronate and risedronate increase lumbar spine BMD by 5% to 7% and hip BMD by 3% to 6% when used for approximately 3 years.^7,8 These increases in BMD are associated with 30% to 50% reductions in vertebral and hip fractures.⁶ Alendronate continues to increase BMD: following 10 years of treatment, it increased BMD by 13.7% in the lumbar spine, 6.7% in the total hip, and 5.4 % in the femoral neck.⁹

Frequent testing, as seen in bisphosphonate clinical trials, demonstrates the phenomenon of regression to the mean. One analysis of the FIT trial, which compared alendronate with placebo in postmenopausal women with low BMD and at least 1 vertebral fracture, focused on the early evaluation of BMD. The study found a high degree of variability in BMD when tested after 1 year of treatment. This wide variety of response in the first year normalized in the second year.¹⁰ A second analysis showed that when women were divided into 8 groups, the group with the greatest increase in BMD in the first year (10.4%) also had the greatest decrease (1.0%) in year 2. In addition, the group with the greatest decrease in year 1 (6.6%) had the greatest increase in year 2 (4.8%). The variability in response among the 8 groups was approximately 17% (+10.4% and –6.6%) in year 1 and narrowed to a 6% difference in year 2 This regression to the mean leads to a normalization of bone density results.^11,12 This patient variability in BMD response to the prescribed therapy should be considered when deciding to retest.

In summary, limitations in DEXA precision mean any changes in BMD of less than 5.6% at the femoral neck may be due to measurement error, and BMD response to bisphosphonates vacillates in the first few years of use but can be expected to increase femoral neck BMD 3% to 6% over 3 years. Therefore, if serial DEXA scanning is preformed on patients prescribed bisphosphonate therapy, it should be considered no earlier than 2 to 3 years after therapy begins. When monitoring osteoporosis therapy, a BMD change within the LSC should be interpreted as “no change” and should not lead to changes in patient management. If the BMD has decreased beyond the LSC there is cause for concern and reevaluation of diagnosis and treatment are warranted.⁴

Recommendations from others

Guidelines on monitoring the clinical response to osteoporosis therapy with DEXA are available from numerous groups ( TABLE ). In clinical practice, it is common for a BMD difference of 3% to 5% at the spine or 4% to 6 % at the hip to be considered clinically significant.¹³

TABLE
Recommendations on monitoring the clinical response to DEXA in osteoporosis therapy

Evidence summary

Testing the effectiveness of therapy for osteoporosis by measuring changes in bone mineral density (BMD) is difficult because changes are often small and occur slowly, and a decrease in BMD does not necessarily mean treatment failure. Testing patients after starting bisphosphonate therapy has been part of many drug trials to assess the effectiveness of therapy. Follow-up testing in clinical practice has not been the focus of a prospective trial and therefore remains controversial.¹

DEXA is considered the gold standard because it is the most extensively validated test for predicting fracture outcomes.² Understanding the rate of bone density response to therapy, and the precision error of DEXA, helps to determine monitoring intervals. The larger the responses in BMD to therapy and the more precise the DEXA scan result, the shorter the period between testing in which clinically relevant differences can be found. Precision error rates are estimated at <1% for the anterior-posterior spine and 1% to 2% for the hip.³ The BMD change after the initiation of treatment must escape the precision error of the testing device or exceed the least significant change (LSC) value.⁴ The LSC—roughly analogous to a 95% confidence interval—is 2.8 times the precision error of the test on a specific machine and site of measurement. If the precision error for DEXA of the femoral neck BMD is 2%, then the LSC is 5.6%.⁵ Changes in BMD of <2%–4% in the vertebrae and 3% to 6% at the hip could be due to inherent measurement error.⁶

A clinician must also understand the anticipated response to the prescribed therapy. It is not clinically useful to retest BMD before a therapy would have time to affect bone turnover. Alendronate and risedronate increase lumbar spine BMD by 5% to 7% and hip BMD by 3% to 6% when used for approximately 3 years.^7,8 These increases in BMD are associated with 30% to 50% reductions in vertebral and hip fractures.⁶ Alendronate continues to increase BMD: following 10 years of treatment, it increased BMD by 13.7% in the lumbar spine, 6.7% in the total hip, and 5.4 % in the femoral neck.⁹

Frequent testing, as seen in bisphosphonate clinical trials, demonstrates the phenomenon of regression to the mean. One analysis of the FIT trial, which compared alendronate with placebo in postmenopausal women with low BMD and at least 1 vertebral fracture, focused on the early evaluation of BMD. The study found a high degree of variability in BMD when tested after 1 year of treatment. This wide variety of response in the first year normalized in the second year.¹⁰ A second analysis showed that when women were divided into 8 groups, the group with the greatest increase in BMD in the first year (10.4%) also had the greatest decrease (1.0%) in year 2. In addition, the group with the greatest decrease in year 1 (6.6%) had the greatest increase in year 2 (4.8%). The variability in response among the 8 groups was approximately 17% (+10.4% and –6.6%) in year 1 and narrowed to a 6% difference in year 2 This regression to the mean leads to a normalization of bone density results.^11,12 This patient variability in BMD response to the prescribed therapy should be considered when deciding to retest.

In summary, limitations in DEXA precision mean any changes in BMD of less than 5.6% at the femoral neck may be due to measurement error, and BMD response to bisphosphonates vacillates in the first few years of use but can be expected to increase femoral neck BMD 3% to 6% over 3 years. Therefore, if serial DEXA scanning is preformed on patients prescribed bisphosphonate therapy, it should be considered no earlier than 2 to 3 years after therapy begins. When monitoring osteoporosis therapy, a BMD change within the LSC should be interpreted as “no change” and should not lead to changes in patient management. If the BMD has decreased beyond the LSC there is cause for concern and reevaluation of diagnosis and treatment are warranted.⁴

Recommendations from others

Guidelines on monitoring the clinical response to osteoporosis therapy with DEXA are available from numerous groups ( TABLE ). In clinical practice, it is common for a BMD difference of 3% to 5% at the spine or 4% to 6 % at the hip to be considered clinically significant.¹³

TABLE
Recommendations on monitoring the clinical response to DEXA in osteoporosis therapy

Evidence summary

Testing the effectiveness of therapy for osteoporosis by measuring changes in bone mineral density (BMD) is difficult because changes are often small and occur slowly, and a decrease in BMD does not necessarily mean treatment failure. Testing patients after starting bisphosphonate therapy has been part of many drug trials to assess the effectiveness of therapy. Follow-up testing in clinical practice has not been the focus of a prospective trial and therefore remains controversial.¹

DEXA is considered the gold standard because it is the most extensively validated test for predicting fracture outcomes.² Understanding the rate of bone density response to therapy, and the precision error of DEXA, helps to determine monitoring intervals. The larger the responses in BMD to therapy and the more precise the DEXA scan result, the shorter the period between testing in which clinically relevant differences can be found. Precision error rates are estimated at <1% for the anterior-posterior spine and 1% to 2% for the hip.³ The BMD change after the initiation of treatment must escape the precision error of the testing device or exceed the least significant change (LSC) value.⁴ The LSC—roughly analogous to a 95% confidence interval—is 2.8 times the precision error of the test on a specific machine and site of measurement. If the precision error for DEXA of the femoral neck BMD is 2%, then the LSC is 5.6%.⁵ Changes in BMD of <2%–4% in the vertebrae and 3% to 6% at the hip could be due to inherent measurement error.⁶

A clinician must also understand the anticipated response to the prescribed therapy. It is not clinically useful to retest BMD before a therapy would have time to affect bone turnover. Alendronate and risedronate increase lumbar spine BMD by 5% to 7% and hip BMD by 3% to 6% when used for approximately 3 years.^7,8 These increases in BMD are associated with 30% to 50% reductions in vertebral and hip fractures.⁶ Alendronate continues to increase BMD: following 10 years of treatment, it increased BMD by 13.7% in the lumbar spine, 6.7% in the total hip, and 5.4 % in the femoral neck.⁹

Frequent testing, as seen in bisphosphonate clinical trials, demonstrates the phenomenon of regression to the mean. One analysis of the FIT trial, which compared alendronate with placebo in postmenopausal women with low BMD and at least 1 vertebral fracture, focused on the early evaluation of BMD. The study found a high degree of variability in BMD when tested after 1 year of treatment. This wide variety of response in the first year normalized in the second year.¹⁰ A second analysis showed that when women were divided into 8 groups, the group with the greatest increase in BMD in the first year (10.4%) also had the greatest decrease (1.0%) in year 2. In addition, the group with the greatest decrease in year 1 (6.6%) had the greatest increase in year 2 (4.8%). The variability in response among the 8 groups was approximately 17% (+10.4% and –6.6%) in year 1 and narrowed to a 6% difference in year 2 This regression to the mean leads to a normalization of bone density results.^11,12 This patient variability in BMD response to the prescribed therapy should be considered when deciding to retest.

In summary, limitations in DEXA precision mean any changes in BMD of less than 5.6% at the femoral neck may be due to measurement error, and BMD response to bisphosphonates vacillates in the first few years of use but can be expected to increase femoral neck BMD 3% to 6% over 3 years. Therefore, if serial DEXA scanning is preformed on patients prescribed bisphosphonate therapy, it should be considered no earlier than 2 to 3 years after therapy begins. When monitoring osteoporosis therapy, a BMD change within the LSC should be interpreted as “no change” and should not lead to changes in patient management. If the BMD has decreased beyond the LSC there is cause for concern and reevaluation of diagnosis and treatment are warranted.⁴

Recommendations from others

Guidelines on monitoring the clinical response to osteoporosis therapy with DEXA are available from numerous groups ( TABLE ). In clinical practice, it is common for a BMD difference of 3% to 5% at the spine or 4% to 6 % at the hip to be considered clinically significant.¹³

TABLE
Recommendations on monitoring the clinical response to DEXA in osteoporosis therapy

Evidence summary

No prospective, interventional studies evaluate the treatment of Osgood-Schlatter disease. One case series followed the natural course of the disease in 261 patients (365 symptomatic knees) for 12 to 24 months; 237 (90.8%) patients responded well to restriction of sports activity and nonsteroidal anti-inflammatory agents. The 24 patients who did not improve with conservative measures underwent surgical excision of ossicles, and all returned to normal activities (mean time, 4.5 weeks).¹

In another case series of 118 patients (151 knees), 88% responded to intermittent limitation of activity (weeks to months) or cylinder casting if limiting activity was ineffective. The remaining 14 patients showed no improvement from these measures; all had surgical excision of an ossicle, sometimes combined with a tubercle-thinning procedure. Only 1 of these patients (7%) did not have complete relief and return to full activities at 6 weeks.²

Retrospective analyses also support a conservative approach. One retrospective survey of 68 young athletes with Osgood-Schlatter found they required an average of 3.2 months off all training and 7.3 months of some activity restrictions.³ In another survey, 20 of 22 (91%) adolescent athletes with Osgood-Schlatter were able to manage their symptoms with ice, aspirin, and mild activity modification. Only 2 needed to stop playing all sports for any period of time, and none required surgery.⁴

Another retrospective review analyzed 50 patients with Osgood-Schlatter (69 knees) for an average of 9 years. No treatments or activity restrictions were recommended. At time of follow-up, 36 (76%) had no limitations, but kneeling continued to be uncomfortable in 60%.⁵

No interventional studies have explicitly evaluated commonly recommended conservative treatments such as ice, analgesics, activity restriction, stretching, strengthening, or anti-inflammatory medication. Corticosteroid injections are generally not recommended, due to case reports of complications, primarily related to subcutaneous atrophy.⁶ One small case series demonstrated improvement in Osgood-Schlatter disease pain in 19 of 24 (79%) knees after using an infrapatellar strap for 6 to 8 weeks.⁷

Refractory cases have been treated with a variety of surgical interventions. In 1 case series, 67 patients (70 knees) (mean age 19.6, 77% male) with at least 18 months of symptoms despite conservative treatment underwent resection of an ossicle (62 cases) or excision of prominent tibial tubercle (8 cases). These patients were followed for 2.2 years, with 56 (90%) patients with ossicle-resection able to return to maximal sports activity without pain, tenderness, loss of motion, or atrophy.⁸

Another case series compared 22 patients who1 underwent drilling of the tibial tubercle (with or without the removal of the tibial tubercle) with 22 patients who had excision of loose ossicles or cartilage. Seventeen of the 22 (77%) patients with ossicle excision had complete resolution of symptoms compared with 8 of the 22 (36%) in the patients who underwent tibial tubercle drilling.⁹

One surgical series evaluated excision of tibial tuberosity in 35 patients (42 knees) who did not improve with conservative treatment for an average of 13.25 months. For 37 of 42 knees (88%), patients reported complete relief of pain, and all returned to activity without limitation. The average time to return to sports was 15.2 weeks.¹⁰

Recommendations from others

The American Academy of Orthopaedic Surgeons and the American Academy of Family Practice recommend activity limitation, ice, anti-inflammatories, protective padding, quadriceps/hamstring strengthening, and time in the management of Osgood-Schlatter disease.^11,12

Evidence summary

No prospective, interventional studies evaluate the treatment of Osgood-Schlatter disease. One case series followed the natural course of the disease in 261 patients (365 symptomatic knees) for 12 to 24 months; 237 (90.8%) patients responded well to restriction of sports activity and nonsteroidal anti-inflammatory agents. The 24 patients who did not improve with conservative measures underwent surgical excision of ossicles, and all returned to normal activities (mean time, 4.5 weeks).¹

In another case series of 118 patients (151 knees), 88% responded to intermittent limitation of activity (weeks to months) or cylinder casting if limiting activity was ineffective. The remaining 14 patients showed no improvement from these measures; all had surgical excision of an ossicle, sometimes combined with a tubercle-thinning procedure. Only 1 of these patients (7%) did not have complete relief and return to full activities at 6 weeks.²

Retrospective analyses also support a conservative approach. One retrospective survey of 68 young athletes with Osgood-Schlatter found they required an average of 3.2 months off all training and 7.3 months of some activity restrictions.³ In another survey, 20 of 22 (91%) adolescent athletes with Osgood-Schlatter were able to manage their symptoms with ice, aspirin, and mild activity modification. Only 2 needed to stop playing all sports for any period of time, and none required surgery.⁴

Another retrospective review analyzed 50 patients with Osgood-Schlatter (69 knees) for an average of 9 years. No treatments or activity restrictions were recommended. At time of follow-up, 36 (76%) had no limitations, but kneeling continued to be uncomfortable in 60%.⁵

No interventional studies have explicitly evaluated commonly recommended conservative treatments such as ice, analgesics, activity restriction, stretching, strengthening, or anti-inflammatory medication. Corticosteroid injections are generally not recommended, due to case reports of complications, primarily related to subcutaneous atrophy.⁶ One small case series demonstrated improvement in Osgood-Schlatter disease pain in 19 of 24 (79%) knees after using an infrapatellar strap for 6 to 8 weeks.⁷

Refractory cases have been treated with a variety of surgical interventions. In 1 case series, 67 patients (70 knees) (mean age 19.6, 77% male) with at least 18 months of symptoms despite conservative treatment underwent resection of an ossicle (62 cases) or excision of prominent tibial tubercle (8 cases). These patients were followed for 2.2 years, with 56 (90%) patients with ossicle-resection able to return to maximal sports activity without pain, tenderness, loss of motion, or atrophy.⁸

Another case series compared 22 patients who1 underwent drilling of the tibial tubercle (with or without the removal of the tibial tubercle) with 22 patients who had excision of loose ossicles or cartilage. Seventeen of the 22 (77%) patients with ossicle excision had complete resolution of symptoms compared with 8 of the 22 (36%) in the patients who underwent tibial tubercle drilling.⁹

One surgical series evaluated excision of tibial tuberosity in 35 patients (42 knees) who did not improve with conservative treatment for an average of 13.25 months. For 37 of 42 knees (88%), patients reported complete relief of pain, and all returned to activity without limitation. The average time to return to sports was 15.2 weeks.¹⁰

Recommendations from others

The American Academy of Orthopaedic Surgeons and the American Academy of Family Practice recommend activity limitation, ice, anti-inflammatories, protective padding, quadriceps/hamstring strengthening, and time in the management of Osgood-Schlatter disease.^11,12

Evidence summary

No prospective, interventional studies evaluate the treatment of Osgood-Schlatter disease. One case series followed the natural course of the disease in 261 patients (365 symptomatic knees) for 12 to 24 months; 237 (90.8%) patients responded well to restriction of sports activity and nonsteroidal anti-inflammatory agents. The 24 patients who did not improve with conservative measures underwent surgical excision of ossicles, and all returned to normal activities (mean time, 4.5 weeks).¹

In another case series of 118 patients (151 knees), 88% responded to intermittent limitation of activity (weeks to months) or cylinder casting if limiting activity was ineffective. The remaining 14 patients showed no improvement from these measures; all had surgical excision of an ossicle, sometimes combined with a tubercle-thinning procedure. Only 1 of these patients (7%) did not have complete relief and return to full activities at 6 weeks.²

Retrospective analyses also support a conservative approach. One retrospective survey of 68 young athletes with Osgood-Schlatter found they required an average of 3.2 months off all training and 7.3 months of some activity restrictions.³ In another survey, 20 of 22 (91%) adolescent athletes with Osgood-Schlatter were able to manage their symptoms with ice, aspirin, and mild activity modification. Only 2 needed to stop playing all sports for any period of time, and none required surgery.⁴

Another retrospective review analyzed 50 patients with Osgood-Schlatter (69 knees) for an average of 9 years. No treatments or activity restrictions were recommended. At time of follow-up, 36 (76%) had no limitations, but kneeling continued to be uncomfortable in 60%.⁵

No interventional studies have explicitly evaluated commonly recommended conservative treatments such as ice, analgesics, activity restriction, stretching, strengthening, or anti-inflammatory medication. Corticosteroid injections are generally not recommended, due to case reports of complications, primarily related to subcutaneous atrophy.⁶ One small case series demonstrated improvement in Osgood-Schlatter disease pain in 19 of 24 (79%) knees after using an infrapatellar strap for 6 to 8 weeks.⁷

Refractory cases have been treated with a variety of surgical interventions. In 1 case series, 67 patients (70 knees) (mean age 19.6, 77% male) with at least 18 months of symptoms despite conservative treatment underwent resection of an ossicle (62 cases) or excision of prominent tibial tubercle (8 cases). These patients were followed for 2.2 years, with 56 (90%) patients with ossicle-resection able to return to maximal sports activity without pain, tenderness, loss of motion, or atrophy.⁸

Another case series compared 22 patients who1 underwent drilling of the tibial tubercle (with or without the removal of the tibial tubercle) with 22 patients who had excision of loose ossicles or cartilage. Seventeen of the 22 (77%) patients with ossicle excision had complete resolution of symptoms compared with 8 of the 22 (36%) in the patients who underwent tibial tubercle drilling.⁹

One surgical series evaluated excision of tibial tuberosity in 35 patients (42 knees) who did not improve with conservative treatment for an average of 13.25 months. For 37 of 42 knees (88%), patients reported complete relief of pain, and all returned to activity without limitation. The average time to return to sports was 15.2 weeks.¹⁰

Recommendations from others

The American Academy of Orthopaedic Surgeons and the American Academy of Family Practice recommend activity limitation, ice, anti-inflammatories, protective padding, quadriceps/hamstring strengthening, and time in the management of Osgood-Schlatter disease.^11,12

Evidence summary

Hyperhomocysteinemia is defined as a fasting plasma homocysteine level 15 μmol/L, although levels >10 μmol/L appear to have detrimental effects on risk profiles for CAD and arteriosclerosis.¹ In 22 of 27 retrospective case-control studies, patients with CAD had significantly higher plasma homocysteine levels than control subjects (odds ratio [OR]=1.2–10.9, after adjustment for other CAD risk factors).^2,3 However, only 4 of 7 prospective nested case-control trials showed a correlation between elevated homocysteine and myocardial infarction (MI) and coronary death.²

A meta-analysis of 12 randomized controlled trials found that folate supplementation, with vitamin B₆ and B₁₂, reduces plasma homocysteine levels.⁴ However, the long-term clinical cons quences of these interventions are unknown. At doses of 1 gm/d folate has no known side-effects.⁵

Two randomized, placebo-controlled trials of folate reporting clinical endpoints have been completed. One study analyzed folate supplementation in a patient population with known, stable CAD and found no difference in clinical endpoints at 24 months.⁶ In this study, 593 patients were randomized to receive either 0.5 mg/d of folic acid or placebo. The primary study endpoint was a composite of events including: overall mortality, sudden death, MI, stroke, and major vascular surgery. The study was powered to detect a 50% reduction in clinical events based on existing observational data in populations with CAD. An event rate of 15% for the 2-year interval was assumed.⁶ All patients in this study were on statin therapy prior to initiation of folate supplementation.

The second study analyzed folate supplementation in 553 post-PCI patients. Patients were treated with 1 mg of folate plus 10 mg of vitamin B₆ and 400 μg of vitamin B₁₂ for 6 months after the PCI. After a mean follow-up of 11 months, the rate of restenosis requiring revascularization was lower in the vitamin-treated study arm (9.9% vs 16% restenosis rate; relative risk [RR]=0.62; 95% confidence interval [CI], 0.40–0.97; number needed to treat=16).⁷ There was also a nonsignificant trend toward fewer deaths and MIs in the treated arm at both 6 and 12 months after intervention (death: 1.5% vs 2.8%; RR=0.54; 95% CI, 0.016–1.7; MI: 2.6% vs 4.3%; RR=0.60; 95% CI, 0.24–1.51). Statin use was similar in both control (71%) and treatment groups (69%).

Recommendations from others

The American Heart Association and American College of Cardiology do not recommend the routine use of high-dose folic acid or B-vitamin supplements for the primary or secondary prevention of cardiovascular events. The AHA recommendation is to meet recommended daily allowances of folate (400 μg), B₁₂ (2.4 μg), and B₆ (1.7 mg) primarily through a balanced diet, with use of supplements if diet alone does not meet the above requirements.⁸ Since 1998, wheat flour has been supplemented with folate, adding an estimated 100 μg/day to the average American diet.⁸

The Canadian Task Force on Preventive Health Care (CTFPHC) finds insufficient evidence to advocate screening for hyperhomocysteinemia and rely on expert opinion to advocate treatment in select, high-risk populations.² Currently, the CTFPHC advocates meeting the recommended daily allowance of folate, B₁₂, and B₆.²

Evidence summary

Hyperhomocysteinemia is defined as a fasting plasma homocysteine level 15 μmol/L, although levels >10 μmol/L appear to have detrimental effects on risk profiles for CAD and arteriosclerosis.¹ In 22 of 27 retrospective case-control studies, patients with CAD had significantly higher plasma homocysteine levels than control subjects (odds ratio [OR]=1.2–10.9, after adjustment for other CAD risk factors).^2,3 However, only 4 of 7 prospective nested case-control trials showed a correlation between elevated homocysteine and myocardial infarction (MI) and coronary death.²

A meta-analysis of 12 randomized controlled trials found that folate supplementation, with vitamin B₆ and B₁₂, reduces plasma homocysteine levels.⁴ However, the long-term clinical cons quences of these interventions are unknown. At doses of 1 gm/d folate has no known side-effects.⁵

Two randomized, placebo-controlled trials of folate reporting clinical endpoints have been completed. One study analyzed folate supplementation in a patient population with known, stable CAD and found no difference in clinical endpoints at 24 months.⁶ In this study, 593 patients were randomized to receive either 0.5 mg/d of folic acid or placebo. The primary study endpoint was a composite of events including: overall mortality, sudden death, MI, stroke, and major vascular surgery. The study was powered to detect a 50% reduction in clinical events based on existing observational data in populations with CAD. An event rate of 15% for the 2-year interval was assumed.⁶ All patients in this study were on statin therapy prior to initiation of folate supplementation.

The second study analyzed folate supplementation in 553 post-PCI patients. Patients were treated with 1 mg of folate plus 10 mg of vitamin B₆ and 400 μg of vitamin B₁₂ for 6 months after the PCI. After a mean follow-up of 11 months, the rate of restenosis requiring revascularization was lower in the vitamin-treated study arm (9.9% vs 16% restenosis rate; relative risk [RR]=0.62; 95% confidence interval [CI], 0.40–0.97; number needed to treat=16).⁷ There was also a nonsignificant trend toward fewer deaths and MIs in the treated arm at both 6 and 12 months after intervention (death: 1.5% vs 2.8%; RR=0.54; 95% CI, 0.016–1.7; MI: 2.6% vs 4.3%; RR=0.60; 95% CI, 0.24–1.51). Statin use was similar in both control (71%) and treatment groups (69%).

Recommendations from others

The American Heart Association and American College of Cardiology do not recommend the routine use of high-dose folic acid or B-vitamin supplements for the primary or secondary prevention of cardiovascular events. The AHA recommendation is to meet recommended daily allowances of folate (400 μg), B₁₂ (2.4 μg), and B₆ (1.7 mg) primarily through a balanced diet, with use of supplements if diet alone does not meet the above requirements.⁸ Since 1998, wheat flour has been supplemented with folate, adding an estimated 100 μg/day to the average American diet.⁸

The Canadian Task Force on Preventive Health Care (CTFPHC) finds insufficient evidence to advocate screening for hyperhomocysteinemia and rely on expert opinion to advocate treatment in select, high-risk populations.² Currently, the CTFPHC advocates meeting the recommended daily allowance of folate, B₁₂, and B₆.²

Evidence summary

Hyperhomocysteinemia is defined as a fasting plasma homocysteine level 15 μmol/L, although levels >10 μmol/L appear to have detrimental effects on risk profiles for CAD and arteriosclerosis.¹ In 22 of 27 retrospective case-control studies, patients with CAD had significantly higher plasma homocysteine levels than control subjects (odds ratio [OR]=1.2–10.9, after adjustment for other CAD risk factors).^2,3 However, only 4 of 7 prospective nested case-control trials showed a correlation between elevated homocysteine and myocardial infarction (MI) and coronary death.²

A meta-analysis of 12 randomized controlled trials found that folate supplementation, with vitamin B₆ and B₁₂, reduces plasma homocysteine levels.⁴ However, the long-term clinical cons quences of these interventions are unknown. At doses of 1 gm/d folate has no known side-effects.⁵

Two randomized, placebo-controlled trials of folate reporting clinical endpoints have been completed. One study analyzed folate supplementation in a patient population with known, stable CAD and found no difference in clinical endpoints at 24 months.⁶ In this study, 593 patients were randomized to receive either 0.5 mg/d of folic acid or placebo. The primary study endpoint was a composite of events including: overall mortality, sudden death, MI, stroke, and major vascular surgery. The study was powered to detect a 50% reduction in clinical events based on existing observational data in populations with CAD. An event rate of 15% for the 2-year interval was assumed.⁶ All patients in this study were on statin therapy prior to initiation of folate supplementation.

The second study analyzed folate supplementation in 553 post-PCI patients. Patients were treated with 1 mg of folate plus 10 mg of vitamin B₆ and 400 μg of vitamin B₁₂ for 6 months after the PCI. After a mean follow-up of 11 months, the rate of restenosis requiring revascularization was lower in the vitamin-treated study arm (9.9% vs 16% restenosis rate; relative risk [RR]=0.62; 95% confidence interval [CI], 0.40–0.97; number needed to treat=16).⁷ There was also a nonsignificant trend toward fewer deaths and MIs in the treated arm at both 6 and 12 months after intervention (death: 1.5% vs 2.8%; RR=0.54; 95% CI, 0.016–1.7; MI: 2.6% vs 4.3%; RR=0.60; 95% CI, 0.24–1.51). Statin use was similar in both control (71%) and treatment groups (69%).

Recommendations from others

The American Heart Association and American College of Cardiology do not recommend the routine use of high-dose folic acid or B-vitamin supplements for the primary or secondary prevention of cardiovascular events. The AHA recommendation is to meet recommended daily allowances of folate (400 μg), B₁₂ (2.4 μg), and B₆ (1.7 mg) primarily through a balanced diet, with use of supplements if diet alone does not meet the above requirements.⁸ Since 1998, wheat flour has been supplemented with folate, adding an estimated 100 μg/day to the average American diet.⁸

The Canadian Task Force on Preventive Health Care (CTFPHC) finds insufficient evidence to advocate screening for hyperhomocysteinemia and rely on expert opinion to advocate treatment in select, high-risk populations.² Currently, the CTFPHC advocates meeting the recommended daily allowance of folate, B₁₂, and B₆.²