According to the United Nations Office on Drugs and Crime, the last decade saw an alarming rise in the use of recreational substances.¹ There was an escalation not only in the use of the more well-known street drugs (cannabis, stimulants, opiates, and hallucinogens), but also an exponential increase in the abuse of novel psychoactive substances. Although most health care providers (HCPs) are at least relatively familiar with some of these designer drugs—often synthesized analogues of common street drugs—region-specific herbal products with psychoactive properties are now entering the market worldwide. Certainly, the cause of this increased use is multifactorial: Ease of access to these drugs and ambiguous legality are believed to be among the largest contributors. Infrastructure established through globalization promotes easy drug transportation and distribution across borders, and widespread Internet use makes knowledge of and accessibility to such substances exceedingly simple.^2,3

In particular, widespread online access has permanently altered the acquisition of knowledge in all realms—including drug use. Although Erowid Center remains one of the oldest and best-known of the “dark Internet” websites and bills itself as providing “harm reduction,” others have cropped up online and disseminate information about many forms of potentially psychoactive substances. Despite these websites’ purported raison d’être, recent studies have demonstrated these sites’ efficacy in promoting drug use under the guise of safety, particularly among adolescents and young adults. Among these is a qualitative study by Boyer and colleagues of 12 drug users admitted to a pediatric psychiatry unit. Through extensive questioning about the patient’s digital habits, the researchers demonstrated that the majority of subjects used these websites and as a result either increased their drug use or learned about (and tried) new substances!⁴

One drug that has benefited from globalization and the Internet is kratom (Mitragyna speciosa korth). This formerly regionally confined herbal psychoactive substance is native to Southeast Asia, where it has been used (and abused) for centuries as a mild stimulant, to prevent opiate withdrawal, and for recreational purposes. In recent years, kratom has been marketed as a psychotropic drug and is increasingly popular in the U.S. and in the United Kingdom.^2,5,6 In the U.S., this poses a problem for HCPs who often are unaware of this plant’s existence, much less its abuse potential or health effects.² Also known as ketum, kakuam, thang, thom, or biak, kratom is marketed in stores and online as a cheap, safe alternative to opioids.

Although considered a “substance of concern” without any approved medical use by the U.S. Drug Enforcement Agency (DEA), kratom is not a regulated or controlled substance in the U.S.³ In the past few months, out of concern for public safety, the DEA placed a temporary ban on kratom. The agency’s move was followed by a substantial negative reaction from kratom supporters and was quickly rescinded. As of September 2016, the DEA does not have a timetable for banning or scheduling the drug.

To that end, users consider kratom a legal high, and it is easily purchased online. A 2010 study in the United Kingdom examined websites where kratom and many other quasilegal substances (including Salvia divinorum and legal precursors to LSD) could be purchased for an average of £10 (about U.S. $13).⁵ This study’s authors also noted a significant lack of product information on these marketplaces. As these products are not overseen by any regulatory body, the risk of overdose or adulteration is extremely high.^2,3,6-8 In fact, Krypton, a product sold online, was found to be adulterated with O-desmethyltramadol—the active metabolite of the synthetic opiate tramadol—and implicated in at least 9 deaths.⁷

This article presents a case of kratom abuse and will outline a brief history, the pharmacologic characteristics, clinical presentation of kratom abuse, and conclude with an overview of the treatment of kratom-related illness and evaluation of potential toxic sequelae. In light of the rapid proliferation of kratom in the U.S., a basic working knowledge of the drug is quickly becoming a must for federal HCPs.

Case Presentation

At his employer’s request, a 33-year-old married man presented to his family physician for a worsening of his uncontrolled back pain from a herniated lumbar disc resulting from a motor vehicle collision 3 months before. At his physician’s office he stated, “I don’t care if I live or die, I’m tired of the pain,” and “I’m going to go off on somebody if I can’t get this pain under control.” He also endorsed having auditory hallucinations for several years and a history of violence and homicide. The problem arose precipitously after he thought that he was abusing his opiate medication, and it was discontinued. The patient was transferred to the local hospital and admitted to the psychiatric service for his suicidal ideations and risk of harming self and others.

On admission to the psychiatric service, the patient complained of body aches, chills, rhinorrhea, and significantly worsened irritability from his baseline. Initial point-of-care admission drug testing had been negative as had expanded urine tests looking for synthetic opioids, cannabinoids, and cathinones. The patient reported no opioid use but was unable to explain his current symptom patterns, which were worsening his chronic pain and hampering any attempt to build rapport. On hospital day 3, the patient’s additional sequelae had passed, and psychiatric treatment was able to progress fully. On hospital day 4, the inpatient treatment team received a message from the patient’s primary care manager stating that a friend of the patient had found a bottle of herbal pills in the patient’s car. This was later revealed to be a kratom formulation that he had purchased online.

Background

Kratom is the colloquial name of a tree that is native to Thailand, Malaysia, and other countries in Southeast Asia. These trees, which can grow to 50 feet high and 15 feet wide, have long been the source of herbal remedies in Southeast Asia (eFigure).^2,3 The leaves contain psychoactive substances that have a variety of effects when consumed. At low doses, kratom causes a stimulant effect (akin to the leaves of the coca plant in South America); laborers and farmers often use it to help boost their energy. At higher doses, kratom causes an opioid-l

In the United Kingdom, kratom is currently the second most common drug that is considered a legal high, only behind salvia (Salvia divinorum), a hallucinogenic herb that is better known as a result of its use by young celebrities over the past decade.^5,8 Presently, kratom’s legal status in the U.S. continues to be nebulous: It has not been officially scheduled by the DEA, and it is easily obtained.

Kratom can be taken in a variety of ways: Crushed leaves often are placed in gel caps and swallowed; it can be drunk as a tea, juice, or boiled syrup; and it can be smoked or insufflated.^2,3,5,6

Pharmacology and Clinical Presentation

More than 20 psychoactive compounds have been isolated from kratom. Although a discussion of all these compounds is beyond the scope of this review, the 2 major compounds are mitragynine and 7-hydroxymitragynine.

Mitragynine

Mitragynine, the most abundant psychoactive compound found in kratom, is an indole alkaloid (Figure 1). Extraction and analysis of this compound has demonstrated numerous effects on multiple receptors, including μ, δ, and κ opioid receptors, leading to its opioid-like ef

7-Hydroxymitragynine

7-hydroxymitragynine, despite being far less concentrated in kratom preparations, is about 13 times more potent than morphine and 46 times more potent than mitragynine. It is thought that its hydroxyl side chain added to C7 (Figure 2) adds to its lipophilicity and ability to cross the blood-brain barrier at a far more rapid rate than that of mitragynine.²

Mitragynine and 7-hydroxymitragynine remain the best-studied psychoactive components of kratom at this time. Other compounds that have been isolated, such as speciociliatine, paynantheine, and speciogynine, may play a role in kratom’s analgesic and psychoactive effects. Animal studies have demonstrated antimuscarinic properties in these compounds, but the properties do not seem to have any demonstrable effect at the opioid receptors.²

Intoxication and Withdrawal

Due to its increasing worldwide popularity, it is now imperative for HCPs to be aware of the clinical presentation of kratom abuse as well as the management of withdrawal in light of its dependence potential. However, large-scale studies have not been performed, and much of the evidence comes not from the medical literature but from prodrug websites like Erowid or SageWisdom.^2,5-9 To that end, such information will be discussed along with the limited research and expert consensuses available in peer-reviewed medical literature.

Kratom seems to have dose-dependent effects. At low doses (1 g-5 g of raw crushed leaves), kratom abusers often report a mild energizing effect, thought to be secondary to the stimulant properties of kratom’s multiple alkaloids. Users have reported mild euphoria and highs similar to those of the abuse of methylphenidate or modafinil.^2,9,10 Also similar to abuse of those substances, users have reported anxiety, irritability, and aggressiveness as a result of the stimulant-like effects.

At moderate-to-high doses (5 g-15 g of raw crushed leaves), it is believed that the μ opiate receptor agonism overtakes the stimulant effects, leading to the euphoria, relaxation, and analgesia seen with conventional opioid use and abuse.^2,10 In light of the drug’s substantial binding and agonism of all opioid receptors, constipation and itching also are seen.² As such, if an individual is intoxicated, he or she should be managed symptomatically with judicious use of benzodiazepines and continuous monitoring of heart rate, blood pressure, respiratory rate, and oxygen saturation.^2,10 Kratom intoxication can precipitate psychotic episodes similar to those caused by opiate intoxication, so monitoring for agitation or psychotic behaviors is also indicated.^9,10

The medical management of an acute kratom overdose (typically requiring ingestion of > 15 g of crushed leaves) begins with addressing airway blockage, breathing, and circulation along with continuous vital sign monitoring and laboratory testing, including point-of-care glucose, complete blood count, electrolytes, lactate, venous blood gas, and measurable drug levels (ethanol, acetaminophen, tricyclic antidepressants, etc).¹¹ If it is determined that kratom was the intoxicant, the greatest concern of death is similar to that of opioid overdose: respiratory depression. Although there are no large-scale human studies demonstrating efficacy, multiple authors suggest the use of naloxone in kratom-related hypoventilation.^9,10

The development of dependence on kratom and its subsequent withdrawal phenomena are thought to be similar to that of opioids, in light of its strong μ agonism.^2,5,9,10 Indeed, kratom has a long history of being used by opioid-dependent patients as an attempt to quit drug abuse or stave off debilitating withdrawal symptoms when they are unable to acquire their substance of choice.^2,5-10 As such, withdrawal and the treatment thereof will also mimic that of opioid detoxification.

The kratom-dependent individual will often present with rhinorrhea, lacrimation, dry mouth, hostility, aggression, and emotional lability similar to the case study described earlier.^2,9,10 Kratom withdrawal, much like intoxication, also may precipitate or worsen psychotic symptoms, and monitoring is necessary throughout the detoxification process.^2,5,10 Withdrawal management should proceed along ambulatory clinic or hospital opioid withdrawal protocols that include step-down administration of opioids or with nonopioid medications for symptomatic relief, including muscle relaxants, α-2 agonists, and antidiarrheal agents.^5,9,10

Kratom Toxicity

A review of the available medical literature has demonstrated a number of toxic effects with kratom abuse, either as the sole agent or in concert with prescribed medications, recreational coingestants, or as a result of manufacturer’s adulteration with other chemicals or drugs. Of particular interest to HCPs are manic or psychotic episode precipitation, seizure, hypothyroidism, intrahepatic cholestatic injury, and even sudden cardiac death.^2,3,5-10 In addition to the basic history, physical, and laboratory examination, the workup of patients identified as kratom users should include the following:

• Fastidious medication reconciliation with drug-interaction check;
• Exhaustive substance abuse history;
• Identification of the brand name and source of kratom purchased, to determine whether there are advertised coingestants or reports of adulteration;
• Electrocardiogram;
• Thyroid function testing;
• Hepatic function testing; and
• Comprehensive neurologic and mental status exams.

In chronic users of kratom, a number of effects have been seen whose etiologies have not yet been determined. These effects include depression, anxiety, tremulousness, weight loss, and permanent psychosis.^3-7 Additionally, a 2008 study by Kittirattanapaiboon and colleagues correlated drug use by those with concurrent mental health disorders (in particular, kratom, which was used in 59% of the ≥ 14,000 individuals included in the study sample) with statistically significant higher suicide risk.¹²

Detection

Because kratom is a relatively new compound in the U.S., medical and forensic laboratories are only now implementing kratom detection protocols. Many laboratories now use high-performance liquid chromatography to analyze for mitragynine, 7-hydroxymitragynine, and 2 metabolites of mitragynine in urine.⁷ Le and colleagues were able to detect mitragynine in the urine in levels as low as 1 ng/mL, which is clinically useful as mitragynine has a half-life determined in animal studies to be 3.85 hours.¹³ Similar detection limits for mitragynine and 7-hydroxymitragynine are used only at Naval Medical Center Portsmouth in Virginia; however, kratom was not detected in the study patient’s urine because a urine test was not done until hospital day 5.

Conclusion

When gently confronted about the kratom found in his car, the case study patient admitted that he had purchased kratom online after he was “cut off” from prescription opioids for his pain. He admitted that although it was beneficial for his pain, he did notice worsening in his aggression toward his spouse and coworkers. This progressed to an exacerbation of his psychotic symptoms of hallucinations and persecutory delusions. These symptoms remained well hidden in this highly intelligent individual—but were present for years prior to his presentation at the hospital. The patient was discharged from the inpatient psychiatric unit on hospital day 16 with a diagnosis of schizoaffective disorder, depressive type in addition to opioid use disorder. The patient agreed to seek a pain management specialist and discontinue kratom use.

Kratom is an emerging drug of abuse in the Western World. Although significant research is being conducted on its possible medical uses, little is known about kratom beyond the “trip reports” of kratom users posted online. Because of its technically legal status in the U.S. and multiple other Western countries, kratom is easily accessible and is difficult to detect. Health care providers need to be aware of kratom, and during their evaluations, question patients about kratom and other legal highs.

According to the United Nations Office on Drugs and Crime, the last decade saw an alarming rise in the use of recreational substances.¹ There was an escalation not only in the use of the more well-known street drugs (cannabis, stimulants, opiates, and hallucinogens), but also an exponential increase in the abuse of novel psychoactive substances. Although most health care providers (HCPs) are at least relatively familiar with some of these designer drugs—often synthesized analogues of common street drugs—region-specific herbal products with psychoactive properties are now entering the market worldwide. Certainly, the cause of this increased use is multifactorial: Ease of access to these drugs and ambiguous legality are believed to be among the largest contributors. Infrastructure established through globalization promotes easy drug transportation and distribution across borders, and widespread Internet use makes knowledge of and accessibility to such substances exceedingly simple.^2,3

In particular, widespread online access has permanently altered the acquisition of knowledge in all realms—including drug use. Although Erowid Center remains one of the oldest and best-known of the “dark Internet” websites and bills itself as providing “harm reduction,” others have cropped up online and disseminate information about many forms of potentially psychoactive substances. Despite these websites’ purported raison d’être, recent studies have demonstrated these sites’ efficacy in promoting drug use under the guise of safety, particularly among adolescents and young adults. Among these is a qualitative study by Boyer and colleagues of 12 drug users admitted to a pediatric psychiatry unit. Through extensive questioning about the patient’s digital habits, the researchers demonstrated that the majority of subjects used these websites and as a result either increased their drug use or learned about (and tried) new substances!⁴

One drug that has benefited from globalization and the Internet is kratom (Mitragyna speciosa korth). This formerly regionally confined herbal psychoactive substance is native to Southeast Asia, where it has been used (and abused) for centuries as a mild stimulant, to prevent opiate withdrawal, and for recreational purposes. In recent years, kratom has been marketed as a psychotropic drug and is increasingly popular in the U.S. and in the United Kingdom.^2,5,6 In the U.S., this poses a problem for HCPs who often are unaware of this plant’s existence, much less its abuse potential or health effects.² Also known as ketum, kakuam, thang, thom, or biak, kratom is marketed in stores and online as a cheap, safe alternative to opioids.

Although considered a “substance of concern” without any approved medical use by the U.S. Drug Enforcement Agency (DEA), kratom is not a regulated or controlled substance in the U.S.³ In the past few months, out of concern for public safety, the DEA placed a temporary ban on kratom. The agency’s move was followed by a substantial negative reaction from kratom supporters and was quickly rescinded. As of September 2016, the DEA does not have a timetable for banning or scheduling the drug.

To that end, users consider kratom a legal high, and it is easily purchased online. A 2010 study in the United Kingdom examined websites where kratom and many other quasilegal substances (including Salvia divinorum and legal precursors to LSD) could be purchased for an average of £10 (about U.S. $13).⁵ This study’s authors also noted a significant lack of product information on these marketplaces. As these products are not overseen by any regulatory body, the risk of overdose or adulteration is extremely high.^2,3,6-8 In fact, Krypton, a product sold online, was found to be adulterated with O-desmethyltramadol—the active metabolite of the synthetic opiate tramadol—and implicated in at least 9 deaths.⁷

This article presents a case of kratom abuse and will outline a brief history, the pharmacologic characteristics, clinical presentation of kratom abuse, and conclude with an overview of the treatment of kratom-related illness and evaluation of potential toxic sequelae. In light of the rapid proliferation of kratom in the U.S., a basic working knowledge of the drug is quickly becoming a must for federal HCPs.

Case Presentation

At his employer’s request, a 33-year-old married man presented to his family physician for a worsening of his uncontrolled back pain from a herniated lumbar disc resulting from a motor vehicle collision 3 months before. At his physician’s office he stated, “I don’t care if I live or die, I’m tired of the pain,” and “I’m going to go off on somebody if I can’t get this pain under control.” He also endorsed having auditory hallucinations for several years and a history of violence and homicide. The problem arose precipitously after he thought that he was abusing his opiate medication, and it was discontinued. The patient was transferred to the local hospital and admitted to the psychiatric service for his suicidal ideations and risk of harming self and others.

On admission to the psychiatric service, the patient complained of body aches, chills, rhinorrhea, and significantly worsened irritability from his baseline. Initial point-of-care admission drug testing had been negative as had expanded urine tests looking for synthetic opioids, cannabinoids, and cathinones. The patient reported no opioid use but was unable to explain his current symptom patterns, which were worsening his chronic pain and hampering any attempt to build rapport. On hospital day 3, the patient’s additional sequelae had passed, and psychiatric treatment was able to progress fully. On hospital day 4, the inpatient treatment team received a message from the patient’s primary care manager stating that a friend of the patient had found a bottle of herbal pills in the patient’s car. This was later revealed to be a kratom formulation that he had purchased online.

Background

Kratom is the colloquial name of a tree that is native to Thailand, Malaysia, and other countries in Southeast Asia. These trees, which can grow to 50 feet high and 15 feet wide, have long been the source of herbal remedies in Southeast Asia (eFigure).^2,3 The leaves contain psychoactive substances that have a variety of effects when consumed. At low doses, kratom causes a stimulant effect (akin to the leaves of the coca plant in South America); laborers and farmers often use it to help boost their energy. At higher doses, kratom causes an opioid-l

In the United Kingdom, kratom is currently the second most common drug that is considered a legal high, only behind salvia (Salvia divinorum), a hallucinogenic herb that is better known as a result of its use by young celebrities over the past decade.^5,8 Presently, kratom’s legal status in the U.S. continues to be nebulous: It has not been officially scheduled by the DEA, and it is easily obtained.

Kratom can be taken in a variety of ways: Crushed leaves often are placed in gel caps and swallowed; it can be drunk as a tea, juice, or boiled syrup; and it can be smoked or insufflated.^2,3,5,6

Pharmacology and Clinical Presentation

More than 20 psychoactive compounds have been isolated from kratom. Although a discussion of all these compounds is beyond the scope of this review, the 2 major compounds are mitragynine and 7-hydroxymitragynine.

Mitragynine

Mitragynine, the most abundant psychoactive compound found in kratom, is an indole alkaloid (Figure 1). Extraction and analysis of this compound has demonstrated numerous effects on multiple receptors, including μ, δ, and κ opioid receptors, leading to its opioid-like ef

7-Hydroxymitragynine

7-hydroxymitragynine, despite being far less concentrated in kratom preparations, is about 13 times more potent than morphine and 46 times more potent than mitragynine. It is thought that its hydroxyl side chain added to C7 (Figure 2) adds to its lipophilicity and ability to cross the blood-brain barrier at a far more rapid rate than that of mitragynine.²

Mitragynine and 7-hydroxymitragynine remain the best-studied psychoactive components of kratom at this time. Other compounds that have been isolated, such as speciociliatine, paynantheine, and speciogynine, may play a role in kratom’s analgesic and psychoactive effects. Animal studies have demonstrated antimuscarinic properties in these compounds, but the properties do not seem to have any demonstrable effect at the opioid receptors.²

Intoxication and Withdrawal

Due to its increasing worldwide popularity, it is now imperative for HCPs to be aware of the clinical presentation of kratom abuse as well as the management of withdrawal in light of its dependence potential. However, large-scale studies have not been performed, and much of the evidence comes not from the medical literature but from prodrug websites like Erowid or SageWisdom.^2,5-9 To that end, such information will be discussed along with the limited research and expert consensuses available in peer-reviewed medical literature.

Kratom seems to have dose-dependent effects. At low doses (1 g-5 g of raw crushed leaves), kratom abusers often report a mild energizing effect, thought to be secondary to the stimulant properties of kratom’s multiple alkaloids. Users have reported mild euphoria and highs similar to those of the abuse of methylphenidate or modafinil.^2,9,10 Also similar to abuse of those substances, users have reported anxiety, irritability, and aggressiveness as a result of the stimulant-like effects.

At moderate-to-high doses (5 g-15 g of raw crushed leaves), it is believed that the μ opiate receptor agonism overtakes the stimulant effects, leading to the euphoria, relaxation, and analgesia seen with conventional opioid use and abuse.^2,10 In light of the drug’s substantial binding and agonism of all opioid receptors, constipation and itching also are seen.² As such, if an individual is intoxicated, he or she should be managed symptomatically with judicious use of benzodiazepines and continuous monitoring of heart rate, blood pressure, respiratory rate, and oxygen saturation.^2,10 Kratom intoxication can precipitate psychotic episodes similar to those caused by opiate intoxication, so monitoring for agitation or psychotic behaviors is also indicated.^9,10

The medical management of an acute kratom overdose (typically requiring ingestion of > 15 g of crushed leaves) begins with addressing airway blockage, breathing, and circulation along with continuous vital sign monitoring and laboratory testing, including point-of-care glucose, complete blood count, electrolytes, lactate, venous blood gas, and measurable drug levels (ethanol, acetaminophen, tricyclic antidepressants, etc).¹¹ If it is determined that kratom was the intoxicant, the greatest concern of death is similar to that of opioid overdose: respiratory depression. Although there are no large-scale human studies demonstrating efficacy, multiple authors suggest the use of naloxone in kratom-related hypoventilation.^9,10

The development of dependence on kratom and its subsequent withdrawal phenomena are thought to be similar to that of opioids, in light of its strong μ agonism.^2,5,9,10 Indeed, kratom has a long history of being used by opioid-dependent patients as an attempt to quit drug abuse or stave off debilitating withdrawal symptoms when they are unable to acquire their substance of choice.^2,5-10 As such, withdrawal and the treatment thereof will also mimic that of opioid detoxification.

The kratom-dependent individual will often present with rhinorrhea, lacrimation, dry mouth, hostility, aggression, and emotional lability similar to the case study described earlier.^2,9,10 Kratom withdrawal, much like intoxication, also may precipitate or worsen psychotic symptoms, and monitoring is necessary throughout the detoxification process.^2,5,10 Withdrawal management should proceed along ambulatory clinic or hospital opioid withdrawal protocols that include step-down administration of opioids or with nonopioid medications for symptomatic relief, including muscle relaxants, α-2 agonists, and antidiarrheal agents.^5,9,10

Kratom Toxicity

A review of the available medical literature has demonstrated a number of toxic effects with kratom abuse, either as the sole agent or in concert with prescribed medications, recreational coingestants, or as a result of manufacturer’s adulteration with other chemicals or drugs. Of particular interest to HCPs are manic or psychotic episode precipitation, seizure, hypothyroidism, intrahepatic cholestatic injury, and even sudden cardiac death.^2,3,5-10 In addition to the basic history, physical, and laboratory examination, the workup of patients identified as kratom users should include the following:

• Fastidious medication reconciliation with drug-interaction check;
• Exhaustive substance abuse history;
• Identification of the brand name and source of kratom purchased, to determine whether there are advertised coingestants or reports of adulteration;
• Electrocardiogram;
• Thyroid function testing;
• Hepatic function testing; and
• Comprehensive neurologic and mental status exams.

In chronic users of kratom, a number of effects have been seen whose etiologies have not yet been determined. These effects include depression, anxiety, tremulousness, weight loss, and permanent psychosis.^3-7 Additionally, a 2008 study by Kittirattanapaiboon and colleagues correlated drug use by those with concurrent mental health disorders (in particular, kratom, which was used in 59% of the ≥ 14,000 individuals included in the study sample) with statistically significant higher suicide risk.¹²

Detection

Because kratom is a relatively new compound in the U.S., medical and forensic laboratories are only now implementing kratom detection protocols. Many laboratories now use high-performance liquid chromatography to analyze for mitragynine, 7-hydroxymitragynine, and 2 metabolites of mitragynine in urine.⁷ Le and colleagues were able to detect mitragynine in the urine in levels as low as 1 ng/mL, which is clinically useful as mitragynine has a half-life determined in animal studies to be 3.85 hours.¹³ Similar detection limits for mitragynine and 7-hydroxymitragynine are used only at Naval Medical Center Portsmouth in Virginia; however, kratom was not detected in the study patient’s urine because a urine test was not done until hospital day 5.

Conclusion

When gently confronted about the kratom found in his car, the case study patient admitted that he had purchased kratom online after he was “cut off” from prescription opioids for his pain. He admitted that although it was beneficial for his pain, he did notice worsening in his aggression toward his spouse and coworkers. This progressed to an exacerbation of his psychotic symptoms of hallucinations and persecutory delusions. These symptoms remained well hidden in this highly intelligent individual—but were present for years prior to his presentation at the hospital. The patient was discharged from the inpatient psychiatric unit on hospital day 16 with a diagnosis of schizoaffective disorder, depressive type in addition to opioid use disorder. The patient agreed to seek a pain management specialist and discontinue kratom use.

Kratom is an emerging drug of abuse in the Western World. Although significant research is being conducted on its possible medical uses, little is known about kratom beyond the “trip reports” of kratom users posted online. Because of its technically legal status in the U.S. and multiple other Western countries, kratom is easily accessible and is difficult to detect. Health care providers need to be aware of kratom, and during their evaluations, question patients about kratom and other legal highs.

According to the United Nations Office on Drugs and Crime, the last decade saw an alarming rise in the use of recreational substances.¹ There was an escalation not only in the use of the more well-known street drugs (cannabis, stimulants, opiates, and hallucinogens), but also an exponential increase in the abuse of novel psychoactive substances. Although most health care providers (HCPs) are at least relatively familiar with some of these designer drugs—often synthesized analogues of common street drugs—region-specific herbal products with psychoactive properties are now entering the market worldwide. Certainly, the cause of this increased use is multifactorial: Ease of access to these drugs and ambiguous legality are believed to be among the largest contributors. Infrastructure established through globalization promotes easy drug transportation and distribution across borders, and widespread Internet use makes knowledge of and accessibility to such substances exceedingly simple.^2,3

In particular, widespread online access has permanently altered the acquisition of knowledge in all realms—including drug use. Although Erowid Center remains one of the oldest and best-known of the “dark Internet” websites and bills itself as providing “harm reduction,” others have cropped up online and disseminate information about many forms of potentially psychoactive substances. Despite these websites’ purported raison d’être, recent studies have demonstrated these sites’ efficacy in promoting drug use under the guise of safety, particularly among adolescents and young adults. Among these is a qualitative study by Boyer and colleagues of 12 drug users admitted to a pediatric psychiatry unit. Through extensive questioning about the patient’s digital habits, the researchers demonstrated that the majority of subjects used these websites and as a result either increased their drug use or learned about (and tried) new substances!⁴

One drug that has benefited from globalization and the Internet is kratom (Mitragyna speciosa korth). This formerly regionally confined herbal psychoactive substance is native to Southeast Asia, where it has been used (and abused) for centuries as a mild stimulant, to prevent opiate withdrawal, and for recreational purposes. In recent years, kratom has been marketed as a psychotropic drug and is increasingly popular in the U.S. and in the United Kingdom.^2,5,6 In the U.S., this poses a problem for HCPs who often are unaware of this plant’s existence, much less its abuse potential or health effects.² Also known as ketum, kakuam, thang, thom, or biak, kratom is marketed in stores and online as a cheap, safe alternative to opioids.

Although considered a “substance of concern” without any approved medical use by the U.S. Drug Enforcement Agency (DEA), kratom is not a regulated or controlled substance in the U.S.³ In the past few months, out of concern for public safety, the DEA placed a temporary ban on kratom. The agency’s move was followed by a substantial negative reaction from kratom supporters and was quickly rescinded. As of September 2016, the DEA does not have a timetable for banning or scheduling the drug.

To that end, users consider kratom a legal high, and it is easily purchased online. A 2010 study in the United Kingdom examined websites where kratom and many other quasilegal substances (including Salvia divinorum and legal precursors to LSD) could be purchased for an average of £10 (about U.S. $13).⁵ This study’s authors also noted a significant lack of product information on these marketplaces. As these products are not overseen by any regulatory body, the risk of overdose or adulteration is extremely high.^2,3,6-8 In fact, Krypton, a product sold online, was found to be adulterated with O-desmethyltramadol—the active metabolite of the synthetic opiate tramadol—and implicated in at least 9 deaths.⁷

This article presents a case of kratom abuse and will outline a brief history, the pharmacologic characteristics, clinical presentation of kratom abuse, and conclude with an overview of the treatment of kratom-related illness and evaluation of potential toxic sequelae. In light of the rapid proliferation of kratom in the U.S., a basic working knowledge of the drug is quickly becoming a must for federal HCPs.

Case Presentation

At his employer’s request, a 33-year-old married man presented to his family physician for a worsening of his uncontrolled back pain from a herniated lumbar disc resulting from a motor vehicle collision 3 months before. At his physician’s office he stated, “I don’t care if I live or die, I’m tired of the pain,” and “I’m going to go off on somebody if I can’t get this pain under control.” He also endorsed having auditory hallucinations for several years and a history of violence and homicide. The problem arose precipitously after he thought that he was abusing his opiate medication, and it was discontinued. The patient was transferred to the local hospital and admitted to the psychiatric service for his suicidal ideations and risk of harming self and others.

On admission to the psychiatric service, the patient complained of body aches, chills, rhinorrhea, and significantly worsened irritability from his baseline. Initial point-of-care admission drug testing had been negative as had expanded urine tests looking for synthetic opioids, cannabinoids, and cathinones. The patient reported no opioid use but was unable to explain his current symptom patterns, which were worsening his chronic pain and hampering any attempt to build rapport. On hospital day 3, the patient’s additional sequelae had passed, and psychiatric treatment was able to progress fully. On hospital day 4, the inpatient treatment team received a message from the patient’s primary care manager stating that a friend of the patient had found a bottle of herbal pills in the patient’s car. This was later revealed to be a kratom formulation that he had purchased online.

Background

Kratom is the colloquial name of a tree that is native to Thailand, Malaysia, and other countries in Southeast Asia. These trees, which can grow to 50 feet high and 15 feet wide, have long been the source of herbal remedies in Southeast Asia (eFigure).^2,3 The leaves contain psychoactive substances that have a variety of effects when consumed. At low doses, kratom causes a stimulant effect (akin to the leaves of the coca plant in South America); laborers and farmers often use it to help boost their energy. At higher doses, kratom causes an opioid-l

In the United Kingdom, kratom is currently the second most common drug that is considered a legal high, only behind salvia (Salvia divinorum), a hallucinogenic herb that is better known as a result of its use by young celebrities over the past decade.^5,8 Presently, kratom’s legal status in the U.S. continues to be nebulous: It has not been officially scheduled by the DEA, and it is easily obtained.

Kratom can be taken in a variety of ways: Crushed leaves often are placed in gel caps and swallowed; it can be drunk as a tea, juice, or boiled syrup; and it can be smoked or insufflated.^2,3,5,6

Pharmacology and Clinical Presentation

More than 20 psychoactive compounds have been isolated from kratom. Although a discussion of all these compounds is beyond the scope of this review, the 2 major compounds are mitragynine and 7-hydroxymitragynine.

Mitragynine

Mitragynine, the most abundant psychoactive compound found in kratom, is an indole alkaloid (Figure 1). Extraction and analysis of this compound has demonstrated numerous effects on multiple receptors, including μ, δ, and κ opioid receptors, leading to its opioid-like ef

7-Hydroxymitragynine

7-hydroxymitragynine, despite being far less concentrated in kratom preparations, is about 13 times more potent than morphine and 46 times more potent than mitragynine. It is thought that its hydroxyl side chain added to C7 (Figure 2) adds to its lipophilicity and ability to cross the blood-brain barrier at a far more rapid rate than that of mitragynine.²

Mitragynine and 7-hydroxymitragynine remain the best-studied psychoactive components of kratom at this time. Other compounds that have been isolated, such as speciociliatine, paynantheine, and speciogynine, may play a role in kratom’s analgesic and psychoactive effects. Animal studies have demonstrated antimuscarinic properties in these compounds, but the properties do not seem to have any demonstrable effect at the opioid receptors.²

Intoxication and Withdrawal

Due to its increasing worldwide popularity, it is now imperative for HCPs to be aware of the clinical presentation of kratom abuse as well as the management of withdrawal in light of its dependence potential. However, large-scale studies have not been performed, and much of the evidence comes not from the medical literature but from prodrug websites like Erowid or SageWisdom.^2,5-9 To that end, such information will be discussed along with the limited research and expert consensuses available in peer-reviewed medical literature.

Kratom seems to have dose-dependent effects. At low doses (1 g-5 g of raw crushed leaves), kratom abusers often report a mild energizing effect, thought to be secondary to the stimulant properties of kratom’s multiple alkaloids. Users have reported mild euphoria and highs similar to those of the abuse of methylphenidate or modafinil.^2,9,10 Also similar to abuse of those substances, users have reported anxiety, irritability, and aggressiveness as a result of the stimulant-like effects.

At moderate-to-high doses (5 g-15 g of raw crushed leaves), it is believed that the μ opiate receptor agonism overtakes the stimulant effects, leading to the euphoria, relaxation, and analgesia seen with conventional opioid use and abuse.^2,10 In light of the drug’s substantial binding and agonism of all opioid receptors, constipation and itching also are seen.² As such, if an individual is intoxicated, he or she should be managed symptomatically with judicious use of benzodiazepines and continuous monitoring of heart rate, blood pressure, respiratory rate, and oxygen saturation.^2,10 Kratom intoxication can precipitate psychotic episodes similar to those caused by opiate intoxication, so monitoring for agitation or psychotic behaviors is also indicated.^9,10

The medical management of an acute kratom overdose (typically requiring ingestion of > 15 g of crushed leaves) begins with addressing airway blockage, breathing, and circulation along with continuous vital sign monitoring and laboratory testing, including point-of-care glucose, complete blood count, electrolytes, lactate, venous blood gas, and measurable drug levels (ethanol, acetaminophen, tricyclic antidepressants, etc).¹¹ If it is determined that kratom was the intoxicant, the greatest concern of death is similar to that of opioid overdose: respiratory depression. Although there are no large-scale human studies demonstrating efficacy, multiple authors suggest the use of naloxone in kratom-related hypoventilation.^9,10

The development of dependence on kratom and its subsequent withdrawal phenomena are thought to be similar to that of opioids, in light of its strong μ agonism.^2,5,9,10 Indeed, kratom has a long history of being used by opioid-dependent patients as an attempt to quit drug abuse or stave off debilitating withdrawal symptoms when they are unable to acquire their substance of choice.^2,5-10 As such, withdrawal and the treatment thereof will also mimic that of opioid detoxification.

The kratom-dependent individual will often present with rhinorrhea, lacrimation, dry mouth, hostility, aggression, and emotional lability similar to the case study described earlier.^2,9,10 Kratom withdrawal, much like intoxication, also may precipitate or worsen psychotic symptoms, and monitoring is necessary throughout the detoxification process.^2,5,10 Withdrawal management should proceed along ambulatory clinic or hospital opioid withdrawal protocols that include step-down administration of opioids or with nonopioid medications for symptomatic relief, including muscle relaxants, α-2 agonists, and antidiarrheal agents.^5,9,10

Kratom Toxicity

A review of the available medical literature has demonstrated a number of toxic effects with kratom abuse, either as the sole agent or in concert with prescribed medications, recreational coingestants, or as a result of manufacturer’s adulteration with other chemicals or drugs. Of particular interest to HCPs are manic or psychotic episode precipitation, seizure, hypothyroidism, intrahepatic cholestatic injury, and even sudden cardiac death.^2,3,5-10 In addition to the basic history, physical, and laboratory examination, the workup of patients identified as kratom users should include the following:

• Fastidious medication reconciliation with drug-interaction check;
• Exhaustive substance abuse history;
• Identification of the brand name and source of kratom purchased, to determine whether there are advertised coingestants or reports of adulteration;
• Electrocardiogram;
• Thyroid function testing;
• Hepatic function testing; and
• Comprehensive neurologic and mental status exams.

In chronic users of kratom, a number of effects have been seen whose etiologies have not yet been determined. These effects include depression, anxiety, tremulousness, weight loss, and permanent psychosis.^3-7 Additionally, a 2008 study by Kittirattanapaiboon and colleagues correlated drug use by those with concurrent mental health disorders (in particular, kratom, which was used in 59% of the ≥ 14,000 individuals included in the study sample) with statistically significant higher suicide risk.¹²

Detection

Because kratom is a relatively new compound in the U.S., medical and forensic laboratories are only now implementing kratom detection protocols. Many laboratories now use high-performance liquid chromatography to analyze for mitragynine, 7-hydroxymitragynine, and 2 metabolites of mitragynine in urine.⁷ Le and colleagues were able to detect mitragynine in the urine in levels as low as 1 ng/mL, which is clinically useful as mitragynine has a half-life determined in animal studies to be 3.85 hours.¹³ Similar detection limits for mitragynine and 7-hydroxymitragynine are used only at Naval Medical Center Portsmouth in Virginia; however, kratom was not detected in the study patient’s urine because a urine test was not done until hospital day 5.

Conclusion

When gently confronted about the kratom found in his car, the case study patient admitted that he had purchased kratom online after he was “cut off” from prescription opioids for his pain. He admitted that although it was beneficial for his pain, he did notice worsening in his aggression toward his spouse and coworkers. This progressed to an exacerbation of his psychotic symptoms of hallucinations and persecutory delusions. These symptoms remained well hidden in this highly intelligent individual—but were present for years prior to his presentation at the hospital. The patient was discharged from the inpatient psychiatric unit on hospital day 16 with a diagnosis of schizoaffective disorder, depressive type in addition to opioid use disorder. The patient agreed to seek a pain management specialist and discontinue kratom use.

Kratom is an emerging drug of abuse in the Western World. Although significant research is being conducted on its possible medical uses, little is known about kratom beyond the “trip reports” of kratom users posted online. Because of its technically legal status in the U.S. and multiple other Western countries, kratom is easily accessible and is difficult to detect. Health care providers need to be aware of kratom, and during their evaluations, question patients about kratom and other legal highs.

Editor’s note: “Everything We Say and Do” is an informational series developed by SHM’s Patient Experience Committee to provide readers with thoughtful and actionable communication tactics that have great potential to positively impact patients’ experience of care. Each article will focus on how the contributor applies one or more of the “key communication” tactics in practice to maintain provider accountability for “everything we say and do that affects our patients’ thoughts, feelings, and well-being.”

View a chart outlining key communication tactics

What I Say and Do

At every opportunity, I position and endorse my colleagues who are or will be participating in my patient’s care by describing their roles and expressing my confidence in their abilities.

Why I Do It

It is vital that our patients feel assured they are being cared for by a high-functioning team of experts. During any given hospital stay, our patients will meet consulting physicians, nurses, therapists, case managers … The list goes on and on. Each person plays a vital part in patients’ care. But it can be difficult for patients to understand every person’s role and to feel assured that each person is highly skilled and aligned with the care plan.

As hospitalists, we are in a unique position to provide a foundation of assuredness and confidence that is a cornerstone of patient experience before our teammates meet patients. When we miss this opportunity, our patients perceive us as a sea of white coats passing in and out of their rooms rather than a cohesive team with their best interests at heart.

How I Do It

Let’s take the example of an elderly patient admitted for a hip fracture after a fall. Alongside the hospitalist will be the orthopedic surgeon, nurse, physical therapist, and case manager, all working toward an optimal outcome. In each case, the hospitalist can choose to provide no information about these team members or to position them for a positive first impression.

Here are the steps to take when positioning colleagues with patients:

1. Identify team members and explain their roles.
2. Endorse colleagues by expressing honest confidence in their expertise and ability.
3. Describe how communication between you and your team members will work.
4. Assure the patient that during handoff, your colleagues will be up-to-date and aligned with the plan.
5. Tell your patients they are part of a team dedicated to a safe and effective hospitalization.

Mark Shapiro, MD, is medical director for hospital medicine at St. Joseph Health Medical Group in Santa Rosa, Calif., and producer and host of Explore the Space podcast (explorethespaceshow.com).

Editor’s note: “Everything We Say and Do” is an informational series developed by SHM’s Patient Experience Committee to provide readers with thoughtful and actionable communication tactics that have great potential to positively impact patients’ experience of care. Each article will focus on how the contributor applies one or more of the “key communication” tactics in practice to maintain provider accountability for “everything we say and do that affects our patients’ thoughts, feelings, and well-being.”

View a chart outlining key communication tactics

What I Say and Do

At every opportunity, I position and endorse my colleagues who are or will be participating in my patient’s care by describing their roles and expressing my confidence in their abilities.

Why I Do It

It is vital that our patients feel assured they are being cared for by a high-functioning team of experts. During any given hospital stay, our patients will meet consulting physicians, nurses, therapists, case managers … The list goes on and on. Each person plays a vital part in patients’ care. But it can be difficult for patients to understand every person’s role and to feel assured that each person is highly skilled and aligned with the care plan.

As hospitalists, we are in a unique position to provide a foundation of assuredness and confidence that is a cornerstone of patient experience before our teammates meet patients. When we miss this opportunity, our patients perceive us as a sea of white coats passing in and out of their rooms rather than a cohesive team with their best interests at heart.

How I Do It

Let’s take the example of an elderly patient admitted for a hip fracture after a fall. Alongside the hospitalist will be the orthopedic surgeon, nurse, physical therapist, and case manager, all working toward an optimal outcome. In each case, the hospitalist can choose to provide no information about these team members or to position them for a positive first impression.

Here are the steps to take when positioning colleagues with patients:

1. Identify team members and explain their roles.
2. Endorse colleagues by expressing honest confidence in their expertise and ability.
3. Describe how communication between you and your team members will work.
4. Assure the patient that during handoff, your colleagues will be up-to-date and aligned with the plan.
5. Tell your patients they are part of a team dedicated to a safe and effective hospitalization.

Mark Shapiro, MD, is medical director for hospital medicine at St. Joseph Health Medical Group in Santa Rosa, Calif., and producer and host of Explore the Space podcast (explorethespaceshow.com).

Editor’s note: “Everything We Say and Do” is an informational series developed by SHM’s Patient Experience Committee to provide readers with thoughtful and actionable communication tactics that have great potential to positively impact patients’ experience of care. Each article will focus on how the contributor applies one or more of the “key communication” tactics in practice to maintain provider accountability for “everything we say and do that affects our patients’ thoughts, feelings, and well-being.”

View a chart outlining key communication tactics

What I Say and Do

At every opportunity, I position and endorse my colleagues who are or will be participating in my patient’s care by describing their roles and expressing my confidence in their abilities.

Why I Do It

It is vital that our patients feel assured they are being cared for by a high-functioning team of experts. During any given hospital stay, our patients will meet consulting physicians, nurses, therapists, case managers … The list goes on and on. Each person plays a vital part in patients’ care. But it can be difficult for patients to understand every person’s role and to feel assured that each person is highly skilled and aligned with the care plan.

As hospitalists, we are in a unique position to provide a foundation of assuredness and confidence that is a cornerstone of patient experience before our teammates meet patients. When we miss this opportunity, our patients perceive us as a sea of white coats passing in and out of their rooms rather than a cohesive team with their best interests at heart.

How I Do It

Let’s take the example of an elderly patient admitted for a hip fracture after a fall. Alongside the hospitalist will be the orthopedic surgeon, nurse, physical therapist, and case manager, all working toward an optimal outcome. In each case, the hospitalist can choose to provide no information about these team members or to position them for a positive first impression.

Here are the steps to take when positioning colleagues with patients:

1. Identify team members and explain their roles.
2. Endorse colleagues by expressing honest confidence in their expertise and ability.
3. Describe how communication between you and your team members will work.
4. Assure the patient that during handoff, your colleagues will be up-to-date and aligned with the plan.
5. Tell your patients they are part of a team dedicated to a safe and effective hospitalization.

Mark Shapiro, MD, is medical director for hospital medicine at St. Joseph Health Medical Group in Santa Rosa, Calif., and producer and host of Explore the Space podcast (explorethespaceshow.com).

The 5-year relative survival rate for non-Hodgkin lymphoma (NHL) climbed to 72.7% and is as high as 82.6% for localized NHL, according to the most recent SEER data. The number of new cases remains high at 19.1 per 100,000 people (all races) per year; however the number of deaths is relatively low at 5.7 deaths per 100,000 people (all races) per year. Death rates have been falling on average 2.4% each year from 2004 to 2013.

While the new cases represent 4.3% of all new cancer diagnoses, NHL deaths represent 3.4% of all cancer deaths. Based on 2011-2013 SEER data, about 2.1% of men and women will receive a NHL diagnosis at some point during their lifetime.

Patient diagnoses by stage:

• 28% are diagnosed at the local stage
• 15% are diagnosed with spread to regional lymph nodes
• 50% are diagnosed after distant cancer has metastasized
• 8% unknown/unstaged

As of 2013, there were an estimated 569,536 people living with NHL in the U.S.

Using statistical models for analysis, rates for new non-Hodgkin lymphoma cases have not changed significantly over the past 10 years.

The 5-year relative survival rate for non-Hodgkin lymphoma (NHL) climbed to 72.7% and is as high as 82.6% for localized NHL, according to the most recent SEER data. The number of new cases remains high at 19.1 per 100,000 people (all races) per year; however the number of deaths is relatively low at 5.7 deaths per 100,000 people (all races) per year. Death rates have been falling on average 2.4% each year from 2004 to 2013.

While the new cases represent 4.3% of all new cancer diagnoses, NHL deaths represent 3.4% of all cancer deaths. Based on 2011-2013 SEER data, about 2.1% of men and women will receive a NHL diagnosis at some point during their lifetime.

Patient diagnoses by stage:

• 28% are diagnosed at the local stage
• 15% are diagnosed with spread to regional lymph nodes
• 50% are diagnosed after distant cancer has metastasized
• 8% unknown/unstaged

As of 2013, there were an estimated 569,536 people living with NHL in the U.S.

Using statistical models for analysis, rates for new non-Hodgkin lymphoma cases have not changed significantly over the past 10 years.

The 5-year relative survival rate for non-Hodgkin lymphoma (NHL) climbed to 72.7% and is as high as 82.6% for localized NHL, according to the most recent SEER data. The number of new cases remains high at 19.1 per 100,000 people (all races) per year; however the number of deaths is relatively low at 5.7 deaths per 100,000 people (all races) per year. Death rates have been falling on average 2.4% each year from 2004 to 2013.

While the new cases represent 4.3% of all new cancer diagnoses, NHL deaths represent 3.4% of all cancer deaths. Based on 2011-2013 SEER data, about 2.1% of men and women will receive a NHL diagnosis at some point during their lifetime.

Patient diagnoses by stage:

• 28% are diagnosed at the local stage
• 15% are diagnosed with spread to regional lymph nodes
• 50% are diagnosed after distant cancer has metastasized
• 8% unknown/unstaged

As of 2013, there were an estimated 569,536 people living with NHL in the U.S.

Using statistical models for analysis, rates for new non-Hodgkin lymphoma cases have not changed significantly over the past 10 years.

Micrograph showing MM

The European Commission (EC) has granted conditional marketing authorization for ixazomib (Ninlaro^TM) to be used in combination with lenalidomide and dexamethasone to treat adults with multiple myeloma (MM) who have received at least 1 prior therapy.

This decision makes ixazomib the first oral proteasome inhibitor approved to treat MM in the European Economic Area.

“With the approval of Ninlaro by the European Commission, physicians across the region will have the option to prescribe an all-oral triplet regimen to treat patients with multiple myeloma who have received at least 1 prior therapy,” said Philippe Moreau, MD, of the University Hospital of Nantes in France.

Conditional marketing authorization represents an expedited path for approval. The EC grants this type of authorization before pivotal registration studies are completed.

Conditional marketing authorization is granted to products whose benefits are thought to outweigh their risks, products that address unmet needs, and products that are expected to provide a significant public health benefit.

The conditional authorization for ixazomib means the company developing the drug, Takeda Pharmaceutical Company Limited, is required to provide post-approval updates on safety and efficacy analyses from ongoing studies to demonstrate the long-term effects of ixazomib.

Phase 3 trial

The EC’s decision to grant ixazomib conditional marketing authorization is based on results from the phase 3 TOURMALINE-MM1 trial, which were presented at the 2015 ASH Annual Meeting.

The trial included 722 patients with relapsed or refractory MM. The patients were randomized to receive ixazomib, lenalidomide, and dexamethasone (IRd, n=360) or placebo, lenalidomide, and dexamethasone (Rd, n=362).

Baseline patient characteristics were similar between the treatment arms. Fifty-nine percent of patients in both arms had received 1 prior line of therapy, and 41% in both arms had 2 or 3 prior lines of therapy.

Seventy-eight percent of patients responded to IRd, and 72% responded to Rd (P=0.035). The rates of complete response were 12% and 7%, respectively (P=0.019).

At a median follow-up of about 15 months, the median progression-free survival was 20.6 months in the IRd arm and 14.7 months in the Rd arm. The hazard ratio was 0.742 (P=0.012).

At a median follow-up of about 23 months, the median overall survival had not been reached in either treatment arm. Follow-up analyses for overall survival are planned for 2017.

The incidence of adverse events (AEs) was 98% in the IRd arm and 99% in the Rd arm. The incidence of grade 3 or higher AEs was 74% and 69%, respectively. The incidence of serious AEs was 47% and 49%, respectively.

Common AEs in the IRd and Rd arms, respectively, were diarrhea (45% vs 39%), constipation (35% vs 26%), nausea (29% vs 22%), vomiting (23% vs 12%), rash (36% vs 23%), back pain (24% vs 17%), upper respiratory tract infection (23% vs 19%), thrombocytopenia (31% vs 16%), peripheral neuropathy (27% vs 22%), peripheral edema (28% vs 20%), thromboembolism (8% vs 11%), and neutropenia (33% vs 31%).

Micrograph showing MM

The European Commission (EC) has granted conditional marketing authorization for ixazomib (Ninlaro^TM) to be used in combination with lenalidomide and dexamethasone to treat adults with multiple myeloma (MM) who have received at least 1 prior therapy.

This decision makes ixazomib the first oral proteasome inhibitor approved to treat MM in the European Economic Area.

“With the approval of Ninlaro by the European Commission, physicians across the region will have the option to prescribe an all-oral triplet regimen to treat patients with multiple myeloma who have received at least 1 prior therapy,” said Philippe Moreau, MD, of the University Hospital of Nantes in France.

Conditional marketing authorization represents an expedited path for approval. The EC grants this type of authorization before pivotal registration studies are completed.

Conditional marketing authorization is granted to products whose benefits are thought to outweigh their risks, products that address unmet needs, and products that are expected to provide a significant public health benefit.

The conditional authorization for ixazomib means the company developing the drug, Takeda Pharmaceutical Company Limited, is required to provide post-approval updates on safety and efficacy analyses from ongoing studies to demonstrate the long-term effects of ixazomib.

Phase 3 trial

The EC’s decision to grant ixazomib conditional marketing authorization is based on results from the phase 3 TOURMALINE-MM1 trial, which were presented at the 2015 ASH Annual Meeting.

The trial included 722 patients with relapsed or refractory MM. The patients were randomized to receive ixazomib, lenalidomide, and dexamethasone (IRd, n=360) or placebo, lenalidomide, and dexamethasone (Rd, n=362).

Baseline patient characteristics were similar between the treatment arms. Fifty-nine percent of patients in both arms had received 1 prior line of therapy, and 41% in both arms had 2 or 3 prior lines of therapy.

Seventy-eight percent of patients responded to IRd, and 72% responded to Rd (P=0.035). The rates of complete response were 12% and 7%, respectively (P=0.019).

At a median follow-up of about 15 months, the median progression-free survival was 20.6 months in the IRd arm and 14.7 months in the Rd arm. The hazard ratio was 0.742 (P=0.012).

At a median follow-up of about 23 months, the median overall survival had not been reached in either treatment arm. Follow-up analyses for overall survival are planned for 2017.

The incidence of adverse events (AEs) was 98% in the IRd arm and 99% in the Rd arm. The incidence of grade 3 or higher AEs was 74% and 69%, respectively. The incidence of serious AEs was 47% and 49%, respectively.

Common AEs in the IRd and Rd arms, respectively, were diarrhea (45% vs 39%), constipation (35% vs 26%), nausea (29% vs 22%), vomiting (23% vs 12%), rash (36% vs 23%), back pain (24% vs 17%), upper respiratory tract infection (23% vs 19%), thrombocytopenia (31% vs 16%), peripheral neuropathy (27% vs 22%), peripheral edema (28% vs 20%), thromboembolism (8% vs 11%), and neutropenia (33% vs 31%).

Micrograph showing MM

The European Commission (EC) has granted conditional marketing authorization for ixazomib (Ninlaro^TM) to be used in combination with lenalidomide and dexamethasone to treat adults with multiple myeloma (MM) who have received at least 1 prior therapy.

This decision makes ixazomib the first oral proteasome inhibitor approved to treat MM in the European Economic Area.

“With the approval of Ninlaro by the European Commission, physicians across the region will have the option to prescribe an all-oral triplet regimen to treat patients with multiple myeloma who have received at least 1 prior therapy,” said Philippe Moreau, MD, of the University Hospital of Nantes in France.

Conditional marketing authorization represents an expedited path for approval. The EC grants this type of authorization before pivotal registration studies are completed.

Conditional marketing authorization is granted to products whose benefits are thought to outweigh their risks, products that address unmet needs, and products that are expected to provide a significant public health benefit.

The conditional authorization for ixazomib means the company developing the drug, Takeda Pharmaceutical Company Limited, is required to provide post-approval updates on safety and efficacy analyses from ongoing studies to demonstrate the long-term effects of ixazomib.

Phase 3 trial

The EC’s decision to grant ixazomib conditional marketing authorization is based on results from the phase 3 TOURMALINE-MM1 trial, which were presented at the 2015 ASH Annual Meeting.

The trial included 722 patients with relapsed or refractory MM. The patients were randomized to receive ixazomib, lenalidomide, and dexamethasone (IRd, n=360) or placebo, lenalidomide, and dexamethasone (Rd, n=362).

Baseline patient characteristics were similar between the treatment arms. Fifty-nine percent of patients in both arms had received 1 prior line of therapy, and 41% in both arms had 2 or 3 prior lines of therapy.

Seventy-eight percent of patients responded to IRd, and 72% responded to Rd (P=0.035). The rates of complete response were 12% and 7%, respectively (P=0.019).

At a median follow-up of about 15 months, the median progression-free survival was 20.6 months in the IRd arm and 14.7 months in the Rd arm. The hazard ratio was 0.742 (P=0.012).

At a median follow-up of about 23 months, the median overall survival had not been reached in either treatment arm. Follow-up analyses for overall survival are planned for 2017.

The incidence of adverse events (AEs) was 98% in the IRd arm and 99% in the Rd arm. The incidence of grade 3 or higher AEs was 74% and 69%, respectively. The incidence of serious AEs was 47% and 49%, respectively.

Common AEs in the IRd and Rd arms, respectively, were diarrhea (45% vs 39%), constipation (35% vs 26%), nausea (29% vs 22%), vomiting (23% vs 12%), rash (36% vs 23%), back pain (24% vs 17%), upper respiratory tract infection (23% vs 19%), thrombocytopenia (31% vs 16%), peripheral neuropathy (27% vs 22%), peripheral edema (28% vs 20%), thromboembolism (8% vs 11%), and neutropenia (33% vs 31%).

Cancer patient

receiving chemotherapy

Photo by Rhoda Baer

Patients with TP53-mutated myelodysplastic syndromes (MDS) or acute myeloid leukemia (AML) may benefit from treatment with decitabine, according to a study published in NEJM.

All patients in this study who had TP53 mutations responded to decitabine.

Although these responses were not durable, the patients’ median overall survival was similar to that of patients with lower-risk disease who received decitabine.

“The findings need to be validated in a larger trial, but they do suggest that TP53 mutations can reliably predict responses to decitabine, potentially prolonging survival in this ultra-high-risk group of patients and providing a bridge to transplantation in some patients who might not otherwise be candidates,” said study author Timothy J. Ley, MD, of Washington University School of Medicine in St. Louis, Missouri.

For this study, Dr Ley and his colleagues analyzed 116 patients—54 with AML, 36 with relapsed AML, and 26 with MDS.

Eighty-four of the patients were enrolled in a prospective trial and received decitabine at a dose of 20 mg/m²/day for 10 consecutive days in monthly cycles. Thirty-two additional patients received decitabine on different protocols.

To determine whether genetic mutations could be used to predict responses to decitabine, the researchers performed enhanced exome or gene-panel sequencing in 67 of the patients. The team also performed sequencing at multiple time points to evaluate patterns of mutation clearance in 54 patients.

Response

Thirteen percent of patients (n=15) achieved a complete response (CR), 21% (n=24) had a CR with incomplete count recovery, 5% (n=6) had a morphologic CR with hematologic improvement, and 7% (n=8) had a morphologic CR without hematologic improvement.

Eight percent of patients (n=9) had a partial response, 20% (n=23) had stable disease, and 16% (n=19) had progressive disease.

There were 21 patients with TP53 mutations, and all of them achieved bone marrow blast clearance with less than 5% blasts.

Nineteen percent (n=4) had a CR, 43% (n=9) had a CR with incomplete count recovery, 24% (n=5) had morphologic CR with hematologic improvement, and 14% (n=3) had morphologic CR without hematologic improvement.

“What’s really unique here is that all the patients in the study with TP53 mutations had a response to decitabine and achieved an initial remission,” Dr Ley said.

“With standard aggressive chemotherapy, we only see about 20% to 30% of these patients achieving remission, which is the critical first step to have a chance to cure patients with additional therapies.”

Dr Ley and his colleagues also found that patients in this study were likely to respond to decitabine if they were considered “unfavorable risk” based on extensive chromosomal rearrangements. (Many of these patients also had TP53 mutations.)

Indeed, 67% (29/43) of patients with an unfavorable risk had less than 5% blasts after treatment with decitabine, compared with 34% (24/71) of patients with intermediate or favorable risk.

“The challenge with using decitabine has been knowing which patients are most likely to respond,” said study author Amanda Cashen, MD, of Washington University School of Medicine.

“The value of this study is the comprehensive mutational analysis that helps us figure out which patients are likely to benefit. This information opens the door to using decitabine in a more targeted fashion to treat not just older patients, but also younger patients who carry TP53 mutations.”

Survival and next steps

The researchers found that responses to decitabine were usually short-lived. The drug did not provide complete mutation clearance, which led to relapse.

“Remissions with decitabine typically don’t last long, and no one was cured with this drug,” Dr Ley noted. “But patients who responded to decitabine live longer than what you would expect with aggressive chemotherapy, and that can mean something. Some people live a year or 2 and with a good quality of life because the chemotherapy is not too toxic.”

The median overall survival was 11.6 months among patients with unfavorable risk and 10 months among patients with favorable or intermediate risk (P=0.29).

The median overall survival was 12.7 months among patients with TP53 mutations and 15.4 months among patients with wild-type TP53 (P=0.79).

“It’s important to note that patients with an extremely poor prognosis in this relatively small study had the same survival outcomes as patients facing a better prognosis, which is encouraging,” said study author John Welch, MD, PhD, of Washington University School of Medicine.

“We don’t yet understand why patients with TP53 mutations consistently respond to decitabine, and more work is needed to understand that phenomenon. We’re now planning a larger trial to evaluate decitabine in AML patients of all ages who carry TP53 mutations. It’s exciting to think we may have a therapy that has the potential to improve response rates in this group of high-risk patients.”

Cancer patient

receiving chemotherapy

Photo by Rhoda Baer

Patients with TP53-mutated myelodysplastic syndromes (MDS) or acute myeloid leukemia (AML) may benefit from treatment with decitabine, according to a study published in NEJM.

All patients in this study who had TP53 mutations responded to decitabine.

Although these responses were not durable, the patients’ median overall survival was similar to that of patients with lower-risk disease who received decitabine.

“The findings need to be validated in a larger trial, but they do suggest that TP53 mutations can reliably predict responses to decitabine, potentially prolonging survival in this ultra-high-risk group of patients and providing a bridge to transplantation in some patients who might not otherwise be candidates,” said study author Timothy J. Ley, MD, of Washington University School of Medicine in St. Louis, Missouri.

For this study, Dr Ley and his colleagues analyzed 116 patients—54 with AML, 36 with relapsed AML, and 26 with MDS.

Eighty-four of the patients were enrolled in a prospective trial and received decitabine at a dose of 20 mg/m²/day for 10 consecutive days in monthly cycles. Thirty-two additional patients received decitabine on different protocols.

To determine whether genetic mutations could be used to predict responses to decitabine, the researchers performed enhanced exome or gene-panel sequencing in 67 of the patients. The team also performed sequencing at multiple time points to evaluate patterns of mutation clearance in 54 patients.

Response

Thirteen percent of patients (n=15) achieved a complete response (CR), 21% (n=24) had a CR with incomplete count recovery, 5% (n=6) had a morphologic CR with hematologic improvement, and 7% (n=8) had a morphologic CR without hematologic improvement.

Eight percent of patients (n=9) had a partial response, 20% (n=23) had stable disease, and 16% (n=19) had progressive disease.

There were 21 patients with TP53 mutations, and all of them achieved bone marrow blast clearance with less than 5% blasts.

Nineteen percent (n=4) had a CR, 43% (n=9) had a CR with incomplete count recovery, 24% (n=5) had morphologic CR with hematologic improvement, and 14% (n=3) had morphologic CR without hematologic improvement.

“What’s really unique here is that all the patients in the study with TP53 mutations had a response to decitabine and achieved an initial remission,” Dr Ley said.

“With standard aggressive chemotherapy, we only see about 20% to 30% of these patients achieving remission, which is the critical first step to have a chance to cure patients with additional therapies.”

Dr Ley and his colleagues also found that patients in this study were likely to respond to decitabine if they were considered “unfavorable risk” based on extensive chromosomal rearrangements. (Many of these patients also had TP53 mutations.)

Indeed, 67% (29/43) of patients with an unfavorable risk had less than 5% blasts after treatment with decitabine, compared with 34% (24/71) of patients with intermediate or favorable risk.

“The challenge with using decitabine has been knowing which patients are most likely to respond,” said study author Amanda Cashen, MD, of Washington University School of Medicine.

“The value of this study is the comprehensive mutational analysis that helps us figure out which patients are likely to benefit. This information opens the door to using decitabine in a more targeted fashion to treat not just older patients, but also younger patients who carry TP53 mutations.”

Survival and next steps

The researchers found that responses to decitabine were usually short-lived. The drug did not provide complete mutation clearance, which led to relapse.

“Remissions with decitabine typically don’t last long, and no one was cured with this drug,” Dr Ley noted. “But patients who responded to decitabine live longer than what you would expect with aggressive chemotherapy, and that can mean something. Some people live a year or 2 and with a good quality of life because the chemotherapy is not too toxic.”

The median overall survival was 11.6 months among patients with unfavorable risk and 10 months among patients with favorable or intermediate risk (P=0.29).

The median overall survival was 12.7 months among patients with TP53 mutations and 15.4 months among patients with wild-type TP53 (P=0.79).

“It’s important to note that patients with an extremely poor prognosis in this relatively small study had the same survival outcomes as patients facing a better prognosis, which is encouraging,” said study author John Welch, MD, PhD, of Washington University School of Medicine.

“We don’t yet understand why patients with TP53 mutations consistently respond to decitabine, and more work is needed to understand that phenomenon. We’re now planning a larger trial to evaluate decitabine in AML patients of all ages who carry TP53 mutations. It’s exciting to think we may have a therapy that has the potential to improve response rates in this group of high-risk patients.”

Cancer patient

receiving chemotherapy

Photo by Rhoda Baer

Patients with TP53-mutated myelodysplastic syndromes (MDS) or acute myeloid leukemia (AML) may benefit from treatment with decitabine, according to a study published in NEJM.

All patients in this study who had TP53 mutations responded to decitabine.

Although these responses were not durable, the patients’ median overall survival was similar to that of patients with lower-risk disease who received decitabine.

“The findings need to be validated in a larger trial, but they do suggest that TP53 mutations can reliably predict responses to decitabine, potentially prolonging survival in this ultra-high-risk group of patients and providing a bridge to transplantation in some patients who might not otherwise be candidates,” said study author Timothy J. Ley, MD, of Washington University School of Medicine in St. Louis, Missouri.

For this study, Dr Ley and his colleagues analyzed 116 patients—54 with AML, 36 with relapsed AML, and 26 with MDS.

Eighty-four of the patients were enrolled in a prospective trial and received decitabine at a dose of 20 mg/m²/day for 10 consecutive days in monthly cycles. Thirty-two additional patients received decitabine on different protocols.

To determine whether genetic mutations could be used to predict responses to decitabine, the researchers performed enhanced exome or gene-panel sequencing in 67 of the patients. The team also performed sequencing at multiple time points to evaluate patterns of mutation clearance in 54 patients.

Response

Thirteen percent of patients (n=15) achieved a complete response (CR), 21% (n=24) had a CR with incomplete count recovery, 5% (n=6) had a morphologic CR with hematologic improvement, and 7% (n=8) had a morphologic CR without hematologic improvement.

Eight percent of patients (n=9) had a partial response, 20% (n=23) had stable disease, and 16% (n=19) had progressive disease.

There were 21 patients with TP53 mutations, and all of them achieved bone marrow blast clearance with less than 5% blasts.

Nineteen percent (n=4) had a CR, 43% (n=9) had a CR with incomplete count recovery, 24% (n=5) had morphologic CR with hematologic improvement, and 14% (n=3) had morphologic CR without hematologic improvement.

“What’s really unique here is that all the patients in the study with TP53 mutations had a response to decitabine and achieved an initial remission,” Dr Ley said.

“With standard aggressive chemotherapy, we only see about 20% to 30% of these patients achieving remission, which is the critical first step to have a chance to cure patients with additional therapies.”

Dr Ley and his colleagues also found that patients in this study were likely to respond to decitabine if they were considered “unfavorable risk” based on extensive chromosomal rearrangements. (Many of these patients also had TP53 mutations.)

Indeed, 67% (29/43) of patients with an unfavorable risk had less than 5% blasts after treatment with decitabine, compared with 34% (24/71) of patients with intermediate or favorable risk.

“The challenge with using decitabine has been knowing which patients are most likely to respond,” said study author Amanda Cashen, MD, of Washington University School of Medicine.

“The value of this study is the comprehensive mutational analysis that helps us figure out which patients are likely to benefit. This information opens the door to using decitabine in a more targeted fashion to treat not just older patients, but also younger patients who carry TP53 mutations.”

Survival and next steps

The researchers found that responses to decitabine were usually short-lived. The drug did not provide complete mutation clearance, which led to relapse.

“Remissions with decitabine typically don’t last long, and no one was cured with this drug,” Dr Ley noted. “But patients who responded to decitabine live longer than what you would expect with aggressive chemotherapy, and that can mean something. Some people live a year or 2 and with a good quality of life because the chemotherapy is not too toxic.”

The median overall survival was 11.6 months among patients with unfavorable risk and 10 months among patients with favorable or intermediate risk (P=0.29).

The median overall survival was 12.7 months among patients with TP53 mutations and 15.4 months among patients with wild-type TP53 (P=0.79).

“It’s important to note that patients with an extremely poor prognosis in this relatively small study had the same survival outcomes as patients facing a better prognosis, which is encouraging,” said study author John Welch, MD, PhD, of Washington University School of Medicine.

“We don’t yet understand why patients with TP53 mutations consistently respond to decitabine, and more work is needed to understand that phenomenon. We’re now planning a larger trial to evaluate decitabine in AML patients of all ages who carry TP53 mutations. It’s exciting to think we may have a therapy that has the potential to improve response rates in this group of high-risk patients.”

 

 

Micrograph showing DLBCL

 

The US Food and Drug Administration (FDA) has granted fast track designation for tazemetostat as a treatment for patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL) with EZH2 activating mutations.

Tazemetostat inhibits EZH2, a histone methyltransferase that appears to play a role in the growth and proliferation of a number of cancers, including DLBCL.

Tazemetostat is being developed by Epizyme, Inc.

The FDA’s fast track program is designed to facilitate the development and expedite the review of products intended to treat or prevent serious or life-threatening conditions and address unmet medical need.

Through the FDA’s fast track program, a product may be eligible for priority review. In addition, the company developing the product may be allowed to submit sections of the biologic license application or new drug application on a rolling basis as data become available.

Fast track designation also provides the company with opportunities for more frequent meetings and written communications with the FDA.

Tazemetostat trials

Tazemetostat is under investigation as monotherapy and in combination with other agents as a treatment for multiple cancers.

Results from a phase 1 study suggested tazemetostat monotherapy can produce durable responses in patients with advanced non-Hodgkin lymphomas, including DLBCL. The study was presented at the 2015 ASH Annual Meeting.

Now, Epizyme is conducting a phase 2 study of tazemetostat monotherapy in adults with relapsed or refractory DLBCL or follicular lymphoma.

Tazemetostat is also being evaluated in 2 combination studies in patients with DLBCL.

In a phase 1b/2 trial, researchers are investigating tazemetostat in combination with R-CHOP (rituximab, cyclophosphamide, doxorubicin, vincristine, and prednisone) as a front-line treatment for patients with DLBCL.

In a phase 1b study, researchers are evaluating tazemetostat in combination with atezolizumab, an anti-PD-L1 immunotherapy, in patients with relapsed and refractory DLBCL.

 

 

Micrograph showing DLBCL

 

The US Food and Drug Administration (FDA) has granted fast track designation for tazemetostat as a treatment for patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL) with EZH2 activating mutations.

Tazemetostat inhibits EZH2, a histone methyltransferase that appears to play a role in the growth and proliferation of a number of cancers, including DLBCL.

Tazemetostat is being developed by Epizyme, Inc.

The FDA’s fast track program is designed to facilitate the development and expedite the review of products intended to treat or prevent serious or life-threatening conditions and address unmet medical need.

Through the FDA’s fast track program, a product may be eligible for priority review. In addition, the company developing the product may be allowed to submit sections of the biologic license application or new drug application on a rolling basis as data become available.

Fast track designation also provides the company with opportunities for more frequent meetings and written communications with the FDA.

Tazemetostat trials

Tazemetostat is under investigation as monotherapy and in combination with other agents as a treatment for multiple cancers.

Results from a phase 1 study suggested tazemetostat monotherapy can produce durable responses in patients with advanced non-Hodgkin lymphomas, including DLBCL. The study was presented at the 2015 ASH Annual Meeting.

Now, Epizyme is conducting a phase 2 study of tazemetostat monotherapy in adults with relapsed or refractory DLBCL or follicular lymphoma.

Tazemetostat is also being evaluated in 2 combination studies in patients with DLBCL.

In a phase 1b/2 trial, researchers are investigating tazemetostat in combination with R-CHOP (rituximab, cyclophosphamide, doxorubicin, vincristine, and prednisone) as a front-line treatment for patients with DLBCL.

In a phase 1b study, researchers are evaluating tazemetostat in combination with atezolizumab, an anti-PD-L1 immunotherapy, in patients with relapsed and refractory DLBCL.

 

 

Micrograph showing DLBCL

 

The US Food and Drug Administration (FDA) has granted fast track designation for tazemetostat as a treatment for patients with relapsed or refractory diffuse large B-cell lymphoma (DLBCL) with EZH2 activating mutations.

Tazemetostat inhibits EZH2, a histone methyltransferase that appears to play a role in the growth and proliferation of a number of cancers, including DLBCL.

Tazemetostat is being developed by Epizyme, Inc.

The FDA’s fast track program is designed to facilitate the development and expedite the review of products intended to treat or prevent serious or life-threatening conditions and address unmet medical need.

Through the FDA’s fast track program, a product may be eligible for priority review. In addition, the company developing the product may be allowed to submit sections of the biologic license application or new drug application on a rolling basis as data become available.

Fast track designation also provides the company with opportunities for more frequent meetings and written communications with the FDA.

Tazemetostat trials

Tazemetostat is under investigation as monotherapy and in combination with other agents as a treatment for multiple cancers.

Results from a phase 1 study suggested tazemetostat monotherapy can produce durable responses in patients with advanced non-Hodgkin lymphomas, including DLBCL. The study was presented at the 2015 ASH Annual Meeting.

Now, Epizyme is conducting a phase 2 study of tazemetostat monotherapy in adults with relapsed or refractory DLBCL or follicular lymphoma.

Tazemetostat is also being evaluated in 2 combination studies in patients with DLBCL.

In a phase 1b/2 trial, researchers are investigating tazemetostat in combination with R-CHOP (rituximab, cyclophosphamide, doxorubicin, vincristine, and prednisone) as a front-line treatment for patients with DLBCL.

In a phase 1b study, researchers are evaluating tazemetostat in combination with atezolizumab, an anti-PD-L1 immunotherapy, in patients with relapsed and refractory DLBCL.

Patients with normal platelet counts who have a GI bleed while on antiplatelets were almost six times more likely to die in the hospital if they had a platelet transfusion in a retrospective cohort study from the Yale University in New Haven, Conn.

Ten of the 14 deaths in the 204 transfused patients – versus none of the 3 deaths in the 204 nontransfused patients - were due to bleeding, so it’s possible that the mortality difference was simply because patients with worse bleeding were more likely to get transfused. “On the other hand, the adjusted [odds ratios] for mortality (4.5-6.8 with different sensitivity analyses) [were] large, increasing the likelihood of a cause-and-effect relationship,” said investigators led by gastroenterologist Liam Zakko, MD, now at the Mayo Clinic in Rochester, Minn. (Clin Gastroenterol Hepatol. 2016 Jul 25. doi: 10.1016/j.cgh.2016.07.017).

Current guidelines suggest platelet transfusions are an option for antiplatelet patients with serious GI bleeds, but the Yale team found that they did not reduce rebleeding. “The observation of increased mortality without documentation of clinical benefit suggests a very cautious approach to the use of platelet transfusion. ... We do not support the use of platelet transfusions in patients with GI [bleeds] who are taking antiplatelet agents,” the investigators wrote.

Subjects in the two groups were matched for sex, age, and GI bleed location, and all had platelet counts above 100 × 10⁹/L. Almost everyone was on aspirin for cardiovascular protection, and 30% were on also on clopidogrel.

Just over half in both groups had upper GI bleeds, and about 40% in each group had colonic bleeds. Transfused patients had more-severe bleeding, with overall lower blood pressure and lower hemoglobin; a larger proportion was admitted to the ICU.

On univariate analyses, platelet patients had more cardiovascular events (23% vs. 13%) while in the hospital. They were also more likely to stay in the hospital for more than 4 days (47% vs. 33%) and more likely to die while there (7% vs. 1%). On multivariable analysis, only the greater risk for death during admission remained statistically significant (odds ratio, 5.57; 95% confidence interval, 1.52-27.1). The adjusted odds ratio for recurrent bleeding was not significant.

Four patients in the platelet group died from cardiovascular causes. One patient in the control group had a fatal cardiovascular event.

Although counterintuitive, the authors said that it’s possible that platelet transfusions might actually increase the risk of severe and fatal GI bleeding. “Mechanisms by which platelet transfusion would increase mortality or [GI bleeding]–related mortality are not clear,” but “platelet transfusions are reported to be proinflammatory and alter recipient immunity,” they said.

At least for now, “the most prudent way to manage patients on antiplatelet agents with [GI bleeding] is to follow current evidence-based recommendations,” including early endoscopy, endoscopic hemostatic therapy for high-risk lesions, and intensive proton pump inhibitor therapy in patients with ulcers and high-risk endoscopic features.

“Although not based on high-quality evidence, we believe that hemostatic techniques that do not cause significant tissue damage (e.g., clips rather than thermal devices or sclerosants) should be used in patients on antiplatelet agents, especially if patients are expected to remain on these agents in the future,” they said.

The mean age in the study was 74 years, and about two-thirds of the subjects were men.

The authors had no disclosures.

aotto@frontlinemedcom.com

Patients with normal platelet counts who have a GI bleed while on antiplatelets were almost six times more likely to die in the hospital if they had a platelet transfusion in a retrospective cohort study from the Yale University in New Haven, Conn.

Ten of the 14 deaths in the 204 transfused patients – versus none of the 3 deaths in the 204 nontransfused patients - were due to bleeding, so it’s possible that the mortality difference was simply because patients with worse bleeding were more likely to get transfused. “On the other hand, the adjusted [odds ratios] for mortality (4.5-6.8 with different sensitivity analyses) [were] large, increasing the likelihood of a cause-and-effect relationship,” said investigators led by gastroenterologist Liam Zakko, MD, now at the Mayo Clinic in Rochester, Minn. (Clin Gastroenterol Hepatol. 2016 Jul 25. doi: 10.1016/j.cgh.2016.07.017).

Current guidelines suggest platelet transfusions are an option for antiplatelet patients with serious GI bleeds, but the Yale team found that they did not reduce rebleeding. “The observation of increased mortality without documentation of clinical benefit suggests a very cautious approach to the use of platelet transfusion. ... We do not support the use of platelet transfusions in patients with GI [bleeds] who are taking antiplatelet agents,” the investigators wrote.

Subjects in the two groups were matched for sex, age, and GI bleed location, and all had platelet counts above 100 × 10⁹/L. Almost everyone was on aspirin for cardiovascular protection, and 30% were on also on clopidogrel.

Just over half in both groups had upper GI bleeds, and about 40% in each group had colonic bleeds. Transfused patients had more-severe bleeding, with overall lower blood pressure and lower hemoglobin; a larger proportion was admitted to the ICU.

On univariate analyses, platelet patients had more cardiovascular events (23% vs. 13%) while in the hospital. They were also more likely to stay in the hospital for more than 4 days (47% vs. 33%) and more likely to die while there (7% vs. 1%). On multivariable analysis, only the greater risk for death during admission remained statistically significant (odds ratio, 5.57; 95% confidence interval, 1.52-27.1). The adjusted odds ratio for recurrent bleeding was not significant.

Four patients in the platelet group died from cardiovascular causes. One patient in the control group had a fatal cardiovascular event.

Although counterintuitive, the authors said that it’s possible that platelet transfusions might actually increase the risk of severe and fatal GI bleeding. “Mechanisms by which platelet transfusion would increase mortality or [GI bleeding]–related mortality are not clear,” but “platelet transfusions are reported to be proinflammatory and alter recipient immunity,” they said.

At least for now, “the most prudent way to manage patients on antiplatelet agents with [GI bleeding] is to follow current evidence-based recommendations,” including early endoscopy, endoscopic hemostatic therapy for high-risk lesions, and intensive proton pump inhibitor therapy in patients with ulcers and high-risk endoscopic features.

“Although not based on high-quality evidence, we believe that hemostatic techniques that do not cause significant tissue damage (e.g., clips rather than thermal devices or sclerosants) should be used in patients on antiplatelet agents, especially if patients are expected to remain on these agents in the future,” they said.

The mean age in the study was 74 years, and about two-thirds of the subjects were men.

The authors had no disclosures.

aotto@frontlinemedcom.com

Patients with normal platelet counts who have a GI bleed while on antiplatelets were almost six times more likely to die in the hospital if they had a platelet transfusion in a retrospective cohort study from the Yale University in New Haven, Conn.

Ten of the 14 deaths in the 204 transfused patients – versus none of the 3 deaths in the 204 nontransfused patients - were due to bleeding, so it’s possible that the mortality difference was simply because patients with worse bleeding were more likely to get transfused. “On the other hand, the adjusted [odds ratios] for mortality (4.5-6.8 with different sensitivity analyses) [were] large, increasing the likelihood of a cause-and-effect relationship,” said investigators led by gastroenterologist Liam Zakko, MD, now at the Mayo Clinic in Rochester, Minn. (Clin Gastroenterol Hepatol. 2016 Jul 25. doi: 10.1016/j.cgh.2016.07.017).

Current guidelines suggest platelet transfusions are an option for antiplatelet patients with serious GI bleeds, but the Yale team found that they did not reduce rebleeding. “The observation of increased mortality without documentation of clinical benefit suggests a very cautious approach to the use of platelet transfusion. ... We do not support the use of platelet transfusions in patients with GI [bleeds] who are taking antiplatelet agents,” the investigators wrote.

Subjects in the two groups were matched for sex, age, and GI bleed location, and all had platelet counts above 100 × 10⁹/L. Almost everyone was on aspirin for cardiovascular protection, and 30% were on also on clopidogrel.

Just over half in both groups had upper GI bleeds, and about 40% in each group had colonic bleeds. Transfused patients had more-severe bleeding, with overall lower blood pressure and lower hemoglobin; a larger proportion was admitted to the ICU.

On univariate analyses, platelet patients had more cardiovascular events (23% vs. 13%) while in the hospital. They were also more likely to stay in the hospital for more than 4 days (47% vs. 33%) and more likely to die while there (7% vs. 1%). On multivariable analysis, only the greater risk for death during admission remained statistically significant (odds ratio, 5.57; 95% confidence interval, 1.52-27.1). The adjusted odds ratio for recurrent bleeding was not significant.

Four patients in the platelet group died from cardiovascular causes. One patient in the control group had a fatal cardiovascular event.

Although counterintuitive, the authors said that it’s possible that platelet transfusions might actually increase the risk of severe and fatal GI bleeding. “Mechanisms by which platelet transfusion would increase mortality or [GI bleeding]–related mortality are not clear,” but “platelet transfusions are reported to be proinflammatory and alter recipient immunity,” they said.

At least for now, “the most prudent way to manage patients on antiplatelet agents with [GI bleeding] is to follow current evidence-based recommendations,” including early endoscopy, endoscopic hemostatic therapy for high-risk lesions, and intensive proton pump inhibitor therapy in patients with ulcers and high-risk endoscopic features.

“Although not based on high-quality evidence, we believe that hemostatic techniques that do not cause significant tissue damage (e.g., clips rather than thermal devices or sclerosants) should be used in patients on antiplatelet agents, especially if patients are expected to remain on these agents in the future,” they said.

The mean age in the study was 74 years, and about two-thirds of the subjects were men.

The authors had no disclosures.

aotto@frontlinemedcom.com

BALTIMORE—Stimulation of the sphenopalatine ganglion (SPG) may be a safe and effective method of temporarily disrupting the blood–brain barrier to deliver therapeutics to the brain. In an animal model of stroke, SPG stimulation enhances the delivery of mesenchymal stem cells and improves functional outcomes, according to research presented at the 141st Annual Meeting of the American Neurological Association. The technique does not entail unwanted systemic effects and potentially could be applied in the treatment of other neurologic disorders.

Although it would be undesirable to deliver bone-marrow stem cells to the human brain, SPG stimulation could aid the delivery of neural stem cells, viral vectors, antibody infusions, and gene therapies, said Lorraine Iacovitti, PhD, Director of the Jefferson Stem Cell and Regenerative Neuroscience Center at Thomas Jefferson University in Philadelphia. She and her colleagues plan to investigate the mechanisms responsible for the response to SPG stimulation. In addition, they will examine various stimulation frequencies and determine the size of therapies that can be delivered to the brain.

Disruption of the Blood–Brain Barrier

Modifying the blood–brain barrier has been a longstanding goal of medicine. Achieving this goal would “improve treatments for many neurologic diseases and disorders, particularly if you could combine it with a focused endovascular delivery system so that these reagents get to the appropriate regions,” said Dr. Iacovitti. In 2004, Yarnitsky et al found that stimulating the SPG caused a transient, reversible increase in blood–brain barrier permeability in animals. The technique enabled Evans blue to penetrate nearly the entire side of the brain that received stimulation.

Michael Lang, MD, a fifth-year neurosurgical resident, led Dr. Iacovitti’s group in a study of SPG stimulation in rats with middle cerebral artery (MCA) occlusion. The researchers previously had found that injection of exogenous bone-marrow mesenchymal stem cells reduced infarct size, improved behavioral deficits, and decreased proinflammatory factors in this model of stroke. Although some stem cells reached the brain, most collected in the lungs, the kidneys, and the liver. Dr. Iacovitti’s group hypothesized that SPG stimulation would increase mesenchymal stem cell engraftment following intra-arterial delivery.

SPG Stimulation in a Stroke Model

The investigators studied three groups of rats. One group received MCA occlusion. The second group received MCA occlusion and an intra-arterial infusion of mesenchymal stem cells at one day post stroke. The third group underwent MCA occlusion, intra-arterial infusion of mesenchymal stem cells, and SPG stimulation at one day post stroke. The stimulation frequency was 10 Hz, and the potential was 5 V. Stimulation continuously alternated between 90-s on and 60-s off for a total of 20 minutes.

In the absence of SPG stimulation, few, if any, stem cells reached the parenchyma. The cells did reach the parenchyma, however, in rats that received SPG stimulation. In addition, SPG stimulation was associated with an improvement in functional outcome. At day 7 and at day 14, the researchers observed a difference in function between animals that received mesenchymal stem cells alone and those that received mesenchymal stem cells plus SPG stimulation. At day 14, the Modified Neurologic Severity score was approximately 50% lower in rats that received stem cells and SPG stimulation, compared with untreated rats.

Electron microscopy revealed that most tight junctions in the rats’ brains appeared normal after SPG stimulation, although tight junction discontinuity was common. The effect was similar to that of a mannitol infusion, said Dr. Iacovitti. “It is possible that stem cells are moving out of circulation into the brain in a fashion similar to what you would see after tumor-necrosis-factor-alpha-stimulated inflammation, where you would get immune cells to move out of the blood vessels and into the damaged brain area through a process of diapedesis.” Unlike mannitol administration, which causes dangerous systemic side effects, SPG stimulation has no observed adverse side effects.

“The combination of endovascular selectivity with SPG stimulation is potentially an extremely powerful tool to deliver [therapies] across the blood–brain barrier into the brain,” she continued. “We have just started to look at getting viruses across…. This work has really just begun.”

Dr. Iacovitti’s research was funded by grants awarded by the NIH, the Joseph and Marie Field Family Foundation, and the Mary E. Groff Charitable Trust.

—Erik Greb

BALTIMORE—Stimulation of the sphenopalatine ganglion (SPG) may be a safe and effective method of temporarily disrupting the blood–brain barrier to deliver therapeutics to the brain. In an animal model of stroke, SPG stimulation enhances the delivery of mesenchymal stem cells and improves functional outcomes, according to research presented at the 141st Annual Meeting of the American Neurological Association. The technique does not entail unwanted systemic effects and potentially could be applied in the treatment of other neurologic disorders.

Although it would be undesirable to deliver bone-marrow stem cells to the human brain, SPG stimulation could aid the delivery of neural stem cells, viral vectors, antibody infusions, and gene therapies, said Lorraine Iacovitti, PhD, Director of the Jefferson Stem Cell and Regenerative Neuroscience Center at Thomas Jefferson University in Philadelphia. She and her colleagues plan to investigate the mechanisms responsible for the response to SPG stimulation. In addition, they will examine various stimulation frequencies and determine the size of therapies that can be delivered to the brain.

Disruption of the Blood–Brain Barrier

Modifying the blood–brain barrier has been a longstanding goal of medicine. Achieving this goal would “improve treatments for many neurologic diseases and disorders, particularly if you could combine it with a focused endovascular delivery system so that these reagents get to the appropriate regions,” said Dr. Iacovitti. In 2004, Yarnitsky et al found that stimulating the SPG caused a transient, reversible increase in blood–brain barrier permeability in animals. The technique enabled Evans blue to penetrate nearly the entire side of the brain that received stimulation.

Michael Lang, MD, a fifth-year neurosurgical resident, led Dr. Iacovitti’s group in a study of SPG stimulation in rats with middle cerebral artery (MCA) occlusion. The researchers previously had found that injection of exogenous bone-marrow mesenchymal stem cells reduced infarct size, improved behavioral deficits, and decreased proinflammatory factors in this model of stroke. Although some stem cells reached the brain, most collected in the lungs, the kidneys, and the liver. Dr. Iacovitti’s group hypothesized that SPG stimulation would increase mesenchymal stem cell engraftment following intra-arterial delivery.

SPG Stimulation in a Stroke Model

The investigators studied three groups of rats. One group received MCA occlusion. The second group received MCA occlusion and an intra-arterial infusion of mesenchymal stem cells at one day post stroke. The third group underwent MCA occlusion, intra-arterial infusion of mesenchymal stem cells, and SPG stimulation at one day post stroke. The stimulation frequency was 10 Hz, and the potential was 5 V. Stimulation continuously alternated between 90-s on and 60-s off for a total of 20 minutes.

In the absence of SPG stimulation, few, if any, stem cells reached the parenchyma. The cells did reach the parenchyma, however, in rats that received SPG stimulation. In addition, SPG stimulation was associated with an improvement in functional outcome. At day 7 and at day 14, the researchers observed a difference in function between animals that received mesenchymal stem cells alone and those that received mesenchymal stem cells plus SPG stimulation. At day 14, the Modified Neurologic Severity score was approximately 50% lower in rats that received stem cells and SPG stimulation, compared with untreated rats.

Electron microscopy revealed that most tight junctions in the rats’ brains appeared normal after SPG stimulation, although tight junction discontinuity was common. The effect was similar to that of a mannitol infusion, said Dr. Iacovitti. “It is possible that stem cells are moving out of circulation into the brain in a fashion similar to what you would see after tumor-necrosis-factor-alpha-stimulated inflammation, where you would get immune cells to move out of the blood vessels and into the damaged brain area through a process of diapedesis.” Unlike mannitol administration, which causes dangerous systemic side effects, SPG stimulation has no observed adverse side effects.

“The combination of endovascular selectivity with SPG stimulation is potentially an extremely powerful tool to deliver [therapies] across the blood–brain barrier into the brain,” she continued. “We have just started to look at getting viruses across…. This work has really just begun.”

Dr. Iacovitti’s research was funded by grants awarded by the NIH, the Joseph and Marie Field Family Foundation, and the Mary E. Groff Charitable Trust.

—Erik Greb

BALTIMORE—Stimulation of the sphenopalatine ganglion (SPG) may be a safe and effective method of temporarily disrupting the blood–brain barrier to deliver therapeutics to the brain. In an animal model of stroke, SPG stimulation enhances the delivery of mesenchymal stem cells and improves functional outcomes, according to research presented at the 141st Annual Meeting of the American Neurological Association. The technique does not entail unwanted systemic effects and potentially could be applied in the treatment of other neurologic disorders.

Although it would be undesirable to deliver bone-marrow stem cells to the human brain, SPG stimulation could aid the delivery of neural stem cells, viral vectors, antibody infusions, and gene therapies, said Lorraine Iacovitti, PhD, Director of the Jefferson Stem Cell and Regenerative Neuroscience Center at Thomas Jefferson University in Philadelphia. She and her colleagues plan to investigate the mechanisms responsible for the response to SPG stimulation. In addition, they will examine various stimulation frequencies and determine the size of therapies that can be delivered to the brain.

Disruption of the Blood–Brain Barrier

Modifying the blood–brain barrier has been a longstanding goal of medicine. Achieving this goal would “improve treatments for many neurologic diseases and disorders, particularly if you could combine it with a focused endovascular delivery system so that these reagents get to the appropriate regions,” said Dr. Iacovitti. In 2004, Yarnitsky et al found that stimulating the SPG caused a transient, reversible increase in blood–brain barrier permeability in animals. The technique enabled Evans blue to penetrate nearly the entire side of the brain that received stimulation.

Michael Lang, MD, a fifth-year neurosurgical resident, led Dr. Iacovitti’s group in a study of SPG stimulation in rats with middle cerebral artery (MCA) occlusion. The researchers previously had found that injection of exogenous bone-marrow mesenchymal stem cells reduced infarct size, improved behavioral deficits, and decreased proinflammatory factors in this model of stroke. Although some stem cells reached the brain, most collected in the lungs, the kidneys, and the liver. Dr. Iacovitti’s group hypothesized that SPG stimulation would increase mesenchymal stem cell engraftment following intra-arterial delivery.

SPG Stimulation in a Stroke Model

The investigators studied three groups of rats. One group received MCA occlusion. The second group received MCA occlusion and an intra-arterial infusion of mesenchymal stem cells at one day post stroke. The third group underwent MCA occlusion, intra-arterial infusion of mesenchymal stem cells, and SPG stimulation at one day post stroke. The stimulation frequency was 10 Hz, and the potential was 5 V. Stimulation continuously alternated between 90-s on and 60-s off for a total of 20 minutes.

In the absence of SPG stimulation, few, if any, stem cells reached the parenchyma. The cells did reach the parenchyma, however, in rats that received SPG stimulation. In addition, SPG stimulation was associated with an improvement in functional outcome. At day 7 and at day 14, the researchers observed a difference in function between animals that received mesenchymal stem cells alone and those that received mesenchymal stem cells plus SPG stimulation. At day 14, the Modified Neurologic Severity score was approximately 50% lower in rats that received stem cells and SPG stimulation, compared with untreated rats.

Electron microscopy revealed that most tight junctions in the rats’ brains appeared normal after SPG stimulation, although tight junction discontinuity was common. The effect was similar to that of a mannitol infusion, said Dr. Iacovitti. “It is possible that stem cells are moving out of circulation into the brain in a fashion similar to what you would see after tumor-necrosis-factor-alpha-stimulated inflammation, where you would get immune cells to move out of the blood vessels and into the damaged brain area through a process of diapedesis.” Unlike mannitol administration, which causes dangerous systemic side effects, SPG stimulation has no observed adverse side effects.

“The combination of endovascular selectivity with SPG stimulation is potentially an extremely powerful tool to deliver [therapies] across the blood–brain barrier into the brain,” she continued. “We have just started to look at getting viruses across…. This work has really just begun.”

Dr. Iacovitti’s research was funded by grants awarded by the NIH, the Joseph and Marie Field Family Foundation, and the Mary E. Groff Charitable Trust.

—Erik Greb

BOSTON – Metabolomics of liquid biopsies noninvasively identified nonalcoholic fatty liver disease (NAFLD) with and without steatosis, and assessed the severity of both steatosis and fibrosis, Puneet Puri, MD, reported at the annual meeting of the American Association for the Study of Liver Diseases.

“These data provide proof of concept that liquid biopsy metabolomics can be used to resolve diagnostic questions in NAFLD management,” said Dr. Puri of Virginia Commonwealth University Medical Center in Richmond.

Courtesy of Wikimedia / Nephron/ Creative Commons License

BOSTON – Metabolomics of liquid biopsies noninvasively identified nonalcoholic fatty liver disease (NAFLD) with and without steatosis, and assessed the severity of both steatosis and fibrosis, Puneet Puri, MD, reported at the annual meeting of the American Association for the Study of Liver Diseases.

“These data provide proof of concept that liquid biopsy metabolomics can be used to resolve diagnostic questions in NAFLD management,” said Dr. Puri of Virginia Commonwealth University Medical Center in Richmond.

Courtesy of Wikimedia / Nephron/ Creative Commons License

BOSTON – Metabolomics of liquid biopsies noninvasively identified nonalcoholic fatty liver disease (NAFLD) with and without steatosis, and assessed the severity of both steatosis and fibrosis, Puneet Puri, MD, reported at the annual meeting of the American Association for the Study of Liver Diseases.

“These data provide proof of concept that liquid biopsy metabolomics can be used to resolve diagnostic questions in NAFLD management,” said Dr. Puri of Virginia Commonwealth University Medical Center in Richmond.

Courtesy of Wikimedia / Nephron/ Creative Commons License

WASHINGTON – Denosumab built significantly more bone at the hip and lumbar spine than did risedronate when given for 1 year to patients with glucocorticoid-induced osteoporosis in an ongoing 2-year, head-to-head, randomized trial.

Denosumab (Prolia) is currently approved for the treatment of postmenopausal osteoporosis, and it performed so well in the trial that it could be put forward for the indication of glucocorticoid-induced osteoporosis as well, Kenneth Saag, MD, said at the annual meeting of the American College of Rheumatology.

“I would say there is definitely potential for this as a new therapeutic option for these patients,” he said in a video interview about the trial’s primary outcome of denosumab’s noninferiority to risedronate in percentage change in bone mineral density (BMD) at the lumbar spine after 1 year and secondary outcomes of the superiority of denosumab over risedronate in total hip and lumbar spine BMD at 1 year.

Denosumab is a particularly intriguing treatment option for patients with glucocorticoid-induced osteoporosis. They experience a double hit on bone health: increased RANKL, a protein that stimulates osteoclast development, and decreased osteoprotegerin, a protein that inhibits osteoclasts. Denosumab is a RANKL-inhibitor and, as such, tamps down on osteoclastic bone remodeling, said Dr. Saag, vice chair of the department of medicine and director of the Center for Education and Research on Therapeutics at the University of Alabama at Birmingham.

The phase III trial comprised 795 patients who were taking corticosteroids for a variety of rheumatic diseases, including rheumatoid arthritis, polymyalgia rheumatica, and systemic lupus erythematosus, and randomized them to denosumab or risedronate, which is already FDA approved for glucocorticoid-induced bone loss. Patients were randomized to 24 months of subcutaneous denosumab 60 mg given every 6 months or oral risedronate 5-mg daily. The study is still ongoing to test secondary outcomes at 24 months.

The patients were split into those who were continuing glucocorticoid therapy (505) and those who were just initiating it (290). Patients’ mean age ranged from 61 to 67 years, with the glucocorticoid-initiating group (GC-I) being somewhat older. The mean daily prednisone-equivalent dose was 16 mg in that group and 12 mg in the glucocorticoid-continuing group (GC-C). The mean BMD T-scores in the GC-C group were –1.96 at the lumbar spine and –1.56 at the total hip. In the GC-I group, BMD T-scores were –1.06 at the lumbar spine and –0.98 at the total hip.

In the GC-C group, denosumab increased BMD significantly more than risedronate at both spine and hip. At the lumbar spine, denosumab was associated with a mean increase of 4.4% over baseline, compared with a 2.3% increase with risedronate. Total hip BMD increased 2.1% with denosumab and 0.6% with risedronate.

The results were similar in the GC-I group. Denosumab increased lumbar spine BMD by 3.8% over baseline, compared with an increase of 0.8% with risedronate. Total hip BMD increased 1.7% with denosumab and 0.2% with risedronate.

Denosumab was also associated with significantly greater increases in femoral neck BMD in both groups, Dr. Saag noted. There were no significant differences in markers of bone turnover between the treatment groups. Adverse events, including pneumonia, diverticulitis, and bronchitis, were similar.

Amgen, manufacturer of denosumab, is sponsoring the 24-month study. Dr. Saag has been a consultant for Amgen. One coauthor is an employee of Amgen, and others disclosed financial relationships with Amgen and other pharmaceutical companies.

msullivan@frontlinemedcom.com

On Twitter @alz_gal

WASHINGTON – Denosumab built significantly more bone at the hip and lumbar spine than did risedronate when given for 1 year to patients with glucocorticoid-induced osteoporosis in an ongoing 2-year, head-to-head, randomized trial.

Denosumab (Prolia) is currently approved for the treatment of postmenopausal osteoporosis, and it performed so well in the trial that it could be put forward for the indication of glucocorticoid-induced osteoporosis as well, Kenneth Saag, MD, said at the annual meeting of the American College of Rheumatology.

“I would say there is definitely potential for this as a new therapeutic option for these patients,” he said in a video interview about the trial’s primary outcome of denosumab’s noninferiority to risedronate in percentage change in bone mineral density (BMD) at the lumbar spine after 1 year and secondary outcomes of the superiority of denosumab over risedronate in total hip and lumbar spine BMD at 1 year.

Denosumab is a particularly intriguing treatment option for patients with glucocorticoid-induced osteoporosis. They experience a double hit on bone health: increased RANKL, a protein that stimulates osteoclast development, and decreased osteoprotegerin, a protein that inhibits osteoclasts. Denosumab is a RANKL-inhibitor and, as such, tamps down on osteoclastic bone remodeling, said Dr. Saag, vice chair of the department of medicine and director of the Center for Education and Research on Therapeutics at the University of Alabama at Birmingham.

The phase III trial comprised 795 patients who were taking corticosteroids for a variety of rheumatic diseases, including rheumatoid arthritis, polymyalgia rheumatica, and systemic lupus erythematosus, and randomized them to denosumab or risedronate, which is already FDA approved for glucocorticoid-induced bone loss. Patients were randomized to 24 months of subcutaneous denosumab 60 mg given every 6 months or oral risedronate 5-mg daily. The study is still ongoing to test secondary outcomes at 24 months.

The patients were split into those who were continuing glucocorticoid therapy (505) and those who were just initiating it (290). Patients’ mean age ranged from 61 to 67 years, with the glucocorticoid-initiating group (GC-I) being somewhat older. The mean daily prednisone-equivalent dose was 16 mg in that group and 12 mg in the glucocorticoid-continuing group (GC-C). The mean BMD T-scores in the GC-C group were –1.96 at the lumbar spine and –1.56 at the total hip. In the GC-I group, BMD T-scores were –1.06 at the lumbar spine and –0.98 at the total hip.

In the GC-C group, denosumab increased BMD significantly more than risedronate at both spine and hip. At the lumbar spine, denosumab was associated with a mean increase of 4.4% over baseline, compared with a 2.3% increase with risedronate. Total hip BMD increased 2.1% with denosumab and 0.6% with risedronate.

The results were similar in the GC-I group. Denosumab increased lumbar spine BMD by 3.8% over baseline, compared with an increase of 0.8% with risedronate. Total hip BMD increased 1.7% with denosumab and 0.2% with risedronate.

Denosumab was also associated with significantly greater increases in femoral neck BMD in both groups, Dr. Saag noted. There were no significant differences in markers of bone turnover between the treatment groups. Adverse events, including pneumonia, diverticulitis, and bronchitis, were similar.

Amgen, manufacturer of denosumab, is sponsoring the 24-month study. Dr. Saag has been a consultant for Amgen. One coauthor is an employee of Amgen, and others disclosed financial relationships with Amgen and other pharmaceutical companies.

msullivan@frontlinemedcom.com

On Twitter @alz_gal

WASHINGTON – Denosumab built significantly more bone at the hip and lumbar spine than did risedronate when given for 1 year to patients with glucocorticoid-induced osteoporosis in an ongoing 2-year, head-to-head, randomized trial.

Denosumab (Prolia) is currently approved for the treatment of postmenopausal osteoporosis, and it performed so well in the trial that it could be put forward for the indication of glucocorticoid-induced osteoporosis as well, Kenneth Saag, MD, said at the annual meeting of the American College of Rheumatology.

“I would say there is definitely potential for this as a new therapeutic option for these patients,” he said in a video interview about the trial’s primary outcome of denosumab’s noninferiority to risedronate in percentage change in bone mineral density (BMD) at the lumbar spine after 1 year and secondary outcomes of the superiority of denosumab over risedronate in total hip and lumbar spine BMD at 1 year.

Denosumab is a particularly intriguing treatment option for patients with glucocorticoid-induced osteoporosis. They experience a double hit on bone health: increased RANKL, a protein that stimulates osteoclast development, and decreased osteoprotegerin, a protein that inhibits osteoclasts. Denosumab is a RANKL-inhibitor and, as such, tamps down on osteoclastic bone remodeling, said Dr. Saag, vice chair of the department of medicine and director of the Center for Education and Research on Therapeutics at the University of Alabama at Birmingham.

The phase III trial comprised 795 patients who were taking corticosteroids for a variety of rheumatic diseases, including rheumatoid arthritis, polymyalgia rheumatica, and systemic lupus erythematosus, and randomized them to denosumab or risedronate, which is already FDA approved for glucocorticoid-induced bone loss. Patients were randomized to 24 months of subcutaneous denosumab 60 mg given every 6 months or oral risedronate 5-mg daily. The study is still ongoing to test secondary outcomes at 24 months.

The patients were split into those who were continuing glucocorticoid therapy (505) and those who were just initiating it (290). Patients’ mean age ranged from 61 to 67 years, with the glucocorticoid-initiating group (GC-I) being somewhat older. The mean daily prednisone-equivalent dose was 16 mg in that group and 12 mg in the glucocorticoid-continuing group (GC-C). The mean BMD T-scores in the GC-C group were –1.96 at the lumbar spine and –1.56 at the total hip. In the GC-I group, BMD T-scores were –1.06 at the lumbar spine and –0.98 at the total hip.

In the GC-C group, denosumab increased BMD significantly more than risedronate at both spine and hip. At the lumbar spine, denosumab was associated with a mean increase of 4.4% over baseline, compared with a 2.3% increase with risedronate. Total hip BMD increased 2.1% with denosumab and 0.6% with risedronate.

The results were similar in the GC-I group. Denosumab increased lumbar spine BMD by 3.8% over baseline, compared with an increase of 0.8% with risedronate. Total hip BMD increased 1.7% with denosumab and 0.2% with risedronate.

Denosumab was also associated with significantly greater increases in femoral neck BMD in both groups, Dr. Saag noted. There were no significant differences in markers of bone turnover between the treatment groups. Adverse events, including pneumonia, diverticulitis, and bronchitis, were similar.

Amgen, manufacturer of denosumab, is sponsoring the 24-month study. Dr. Saag has been a consultant for Amgen. One coauthor is an employee of Amgen, and others disclosed financial relationships with Amgen and other pharmaceutical companies.

msullivan@frontlinemedcom.com

On Twitter @alz_gal