Mko (Midazolam-Ketamine-Ondan)

Drug overview for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl):

Generic name: midazolam/ketamine HCl/ondansetron HCl
Drug class: Benzodiazepines
Therapeutic class: Anesthetics

Ketamine hydrochloride, an N-methyl-d-aspartate (NMDA) receptor antagonist, Midazolam is a benzodiazepine. The drug has anticonvulsant, anxiolytic, Ondansetron hydrochloride, a selective, first-generation inhibitor of type 3 serotonin (5-HT3) receptors, is an antiemetic. is a nonbarbiturate general anesthetic that also has analgesic and sedative/hypnotic, and amnestic properties. antidepressant properties.

Ketamine hydrochloride was initially developed as an anesthetic agent; however, the drug can also produce profound analgesia and other pharmacologic effects, and is therefore used for a variety of other indications such as procedural sedation, pain management+, sedation and analgesia in the intensive care setting+, and some psychiatric indications, including treatment-resistant depression and suicidality+.

DRUG IMAGES

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The following indications for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl) have been approved by the FDA:

Indications:
None.

Professional Synonyms:
None.

The following dosing information is available for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl):

Dosing
Administration
Dosing Information
Generic

Dosage of ondansetron, which is available for oral or IV use as the hydrochloride dihydrate and also for oral use as ondansetron base (orally disintegrating tablets), is expressed in terms of ondansetron.

For the prevention of nausea and vomiting associated with moderately emetogenic cancer chemotherapy in adults and children 12 years of age and older, an initial ondansetron dose of 8 mg is given 30 minutes before administration of an emetogenic drug and the dose is repeated 8 hours after the initial dose. An 8-mg dose should be administered at 12-hour intervals for 1-2 days following completion of the emetogenic chemotherapy.

For children 4-11 years of age, an initial ondansetron dose of 4 mg is given 30 minutes before administration of a moderately emetogenic cancer chemotherapy drug, with subsequent doses 4 and 8 hours after the initial dose. A 4-mg dose should then be administered at 8-hour intervals for 1-2 days following completion of emetogenic cancer chemotherapy. Little information currently is available regarding dosages for children younger than 4 years of age.

For the prevention of nausea and vomiting associated with highly emetogenic cancer chemotherapy in adults, a single oral 24-mg dose of ondansetron is given 30 minutes before administration of single-day chemotherapy. The manufacturer states that multiple-day, single-daily-dose oral administration of ondansetron 24 mg has not been studied to date. In addition, safety and efficacy of single-daily-dose oral administration of the 24-mg dose have not been established in pediatric patients.

The manufacturer states that dosage modification is not necessary in geriatric patients.

For the prevention of cancer chemotherapy-induced nausea and vomiting in adults and pediatric patients 6 months of age and older, an initial IV ondansetron dose of 0.15 mg/kg (up to a maximum of 16 mg per dose) is given as a 15-minute infusion beginning 30 minutes before administration of an emetogenic drug and is repeated twice at 4-hour intervals following the initial dose. Because of the risk of QT interval prolongation (see Cautions: Cardiovascular Effects), an antiemetic regimen consisting of a single IV ondansetron dose of 32 mg no longer is recommended for prevention of cancer chemotherapy-induced nausea and vomiting.

Efficacy and safety of alternative single-dose IV ondansetron regimens for prevention of cancer chemotherapy-induced nausea and vomiting have not been established.

The manufacturer states that dosage modification is not necessary in geriatric patients. Little information currently is available regarding dosages for pediatric patients younger than 6 months of age.

The manufacturer states that patients with renal impairment do not require ondansetron dosage adjustment, but there is no experience with continuing ondansetron beyond the first day of therapy in such patients. Although only about 5% of the drug is eliminated by the kidneys and renal impairment was not expected to substantially alter elimination of ondansetron, mean plasma clearance has been decreased by about 41-50% in patients with severe renal impairment (creatinine clearances less than 30 mL/minute). However, the decrease in clearance was variable and not consistent with an increase in plasma half-life of the drug.

In patients with severe hepatic impairment (Child-Pugh score of 10 or greater) clearance is decreased and apparent volume of distribution of ondansetron is increased with a resultant increase in plasma half-life; therefore, the manufacturer recommends that the total daily dose not exceed 8 mg in such patients.

Dosage of ketamine hydrochloride is expressed in terms of ketamine. Midazolam is commercially available as midazolam or the hydrochloride salt;

dosage is expressed in terms of midazolam. Midazolam is a potent sedative that requires individualized dosing.

When midazolam is used for sedation or anesthesia, dosage must be carefully adjusted according to individual requirements and response, age, body weight, physical and clinical status, underlying pathologic condition(s), type and amount of premedication or concomitant medication, and the nature and duration of the surgical or other procedure; however, individual response to the drug also may vary independent of these factors. Titration should be more gradual in patients 60 years of age and older for procedural sedation, in those 55 years of age and older for induction of anesthesia, and in patients with chronic debilitating diseases. Excessive doses or rapid or single large IV injections may result in respiratory depression and/or arrest, particularly in geriatric or debilitated patients and in patients receiving other cardiorespiratory depressants concomitantly.

The smallest effective dose should be used, especially in geriatric and/or debilitated patients.

It should be recognized that the depth of sedation/anxiolysis needed for pediatric patients depends on the type of procedure performed. For example, simple light sedation in the preoperative period is different from the deeper sedation required for a therapeutic or diagnostic procedure (e.g., endoscopy); therefore, there is a broad dosage range. For all pediatric patients, regardless of the indications for sedation/anxiolysis, it is vital to titrate the midazolam dose and the dose of other concomitant drugs slowly for the desired clinical effect.

Unlike adults, pediatric patients generally receive increments of midazolam on a mg/kg basis; drug dose in obese pediatric patients should be calculated on the basis of ideal body weight. Pediatric patients generally require higher dosages of midazolam on a mg/kg basis than adults, and pediatric patients younger than 6 years of age generally require higher dosages on a mg/kg basis than older pediatric patients and may require closer monitoring.

When midazolam is used for sedation in geriatric patients, the initial dose should be reduced, since some degree of organ impairment frequently is present. Dosage requirements in this age group generally appear to decrease with increasing age, and the possibility of profound and/or prolonged effects should be considered in older and/or debilitated patients. Low doses of midazolam usually are required in high-risk surgical patients, debilitated patients, and geriatric patients when the drug is administered with or without premedication.

Dosage of ketamine depends on the intended use and desired pharmacologic effect. At low doses, ketamine produces analgesia and sedation, and at higher doses, the drug produces a state of dissociative anesthesia. Ketamine has a dosing threshold at which dissociation occurs; doses at or above the threshold are referred to as ''dissociative'' or ''anesthetic,'' and doses below this threshold are referred to as ''subdissociative'' or ''subanesthetic.''

Although specific dosing ranges have not been established, dissociation generally appears at an IV dose of approximately 1-1.5 mg/kg or an IM dose of approximately 3-5 mg/kg. Once the dissociative threshold has been reached, additional administration of ketamine will not enhance or deepen sedation.

For induction of anesthesia in adults, the manufacturer recommends an initial IV ketamine dose of 1-4.5 mg/kg or an initial IM dose of 6.5-13 mg/kg.

Administer IV ketamine doses by slow IV injection over 60 seconds or as an IV infusion at a rate of 0.5 mg/kg per minute. On average, an IV dose of 2 mg/kg will produce surgical anesthesia for 5-10 minutes within 30 seconds of administration, and an IM dose of 9-13 mg/kg will produce surgical anesthesia for 12-25 minutes within 3-4 minutes following administration.

For maintenance of anesthesia in adults, additional IV doses of 0.5-4.5 mg/kg or IM doses of 3.25-13

mg/kg may be administered as needed. The manufacturer additionally states that a slow microdrip IV infusion, using a dosage of 0.1-0.5

mg/minute will maintain general anesthesia after induction with ketamine. A continuous IV infusion of 1-6 mg/kg per hour also has been recommended for maintenance of anesthesia. The maintenance dosage should be adjusted based on the patient's anesthetic requirements and concomitant use of other anesthetic agents.

The manufacturer states that the incidence of psychologic manifestations during emergence, particularly dream-like observations and emergence delirium, may be reduced by using lower recommended dosages of ketamine in conjunction with an IV benzodiazepine during induction and maintenance of anesthesia.

In general, pediatric patients require higher doses of ketamine compared with adults, although there is considerable interpatient variability in dosing requirements.

Some experts recommend an initial IV ketamine dose of 1-3 mg/kg for induction of anesthesia in pediatric patients+; supplemental IV doses of 0.5-1 mg/kg may be given if clinically indicated. The recommended IM dose of ketamine for induction of anesthesia in pediatric patients is 5-10 mg/kg.

Because of possible airway complications, some experts state that ketamine is contraindicated in infants younger than 3 months of age.

For dissociative sedation in adults undergoing short painful or emotionally disturbing procedures in the emergency department, the usual IV dose of ketamine is 1 mg/kg administered by IV injection over 30-60 seconds. Dissociative sedation is usually achieved with a single IV loading dose; however, if sedation is inadequate or a prolonged period of sedation is needed for longer procedures, additional IV doses of 0.5-1 mg/kg may be administered every 5-15 minutes as needed.

Lower IV doses of ketamine (e.g., 0.2-0.75 mg/kg) also have been used to produce analgesia, particularly if a dissociative effect is not required for the procedure.

Although the IM route is not preferred in adults, some experts state that an IM dose of 4-5 mg/kg may be administered; additional doses of 2-5 mg/kg may be given after 5-10 minutes if initial sedation is inadequate or additional doses are needed for longer procedures. Lower IM doses of ketamine (e.g., 0.4-2 mg/kg) also have been used, particularly if a dissociative effect is not required for the procedure.

For dissociative sedation in pediatric patients+ 3 months of age or older undergoing short painful or emotionally disturbing procedures in the emergency department, some experts state that the usual IV dose of ketamine is 1.5-2 mg/kg administered by IV injection over 30-60 seconds. Dissociative sedation is usually achieved with a single IV loading dose; however, if initial sedation is inadequate or prolonged sedation is necessary for longer procedures, additional incremental IV doses of 0.5-1

mg/kg may be administered every 5-15 minutes as needed. These experts state that the minimum IV dose that will reliably elicit the dissociative state in children is 1.5 mg/kg; however, lower IV doses (e.g., 0.25-1 mg/kg) also have been used successfully to provide adequate procedural sedation in pediatric patients, particularly if a dissociative effect is not required for the procedure.

The recommended IM dose of ketamine for dissociative sedation in pediatric patients+ 3 months of age or older undergoing short painful or emotionally disturbing procedures in the emergency department is 4-5 mg/kg. Although dissociative sedation is usually achieved with a single IM dose, additional doses of 2-5 mg/kg may be administered after 5-10 minutes if initial sedation is inadequate or additional doses are needed for longer procedures. Although some experts state that the minimum IM dose that will reliably elicit the dissociative state in children is 4-5 mg/kg, lower IM doses (e.g., 1-2 mg/kg) also have been used successfully, particularly if a dissociative effect is not required for the procedure.

Changes in heart rate and blood pressure, respiratory depression, and apnea may occur with overdosage or by a rapid rate of administration of ketamine. Monitor patients for clinically relevant changes in heart rate and blood pressure. Assisted ventilation, including mechanical ventilation, may be required.

Several cases of accidental ketamine overdosage (with doses up to 10 or 100 times the intended dose in adults or children, respectively) resulted in prolonged sedation, but no other clinically important adverse effects or complications; ventilator support was required rarely. Death secondary to acute ketamine overdosage in the absence of multidrug intoxication is rare, although accidental deaths have been reported. A lethal dose of ketamine in humans has not been identified.

Midazolam hydrochloride is administered orally, by IM or slow IV injection, or by IV infusion. Midazolam also has been used in IV patient-controlled analgesia (PCA). Midazolam is administered intranasally.

Midazolam also has been orally administered as the maleate salt+; however, midazolam maleate currently is not commercially available in the US. Because serious and life-threatening adverse cardiorespiratory effects can occur during therapy with midazolam, provision should be made for monitoring, detecting, and correcting such effects in every patient in whom the drug is administered, regardless of age or health status. When IV or oral midazolam is used for sedation or anesthesia, the drug should be administered in a hospital or ambulatory care setting equipped to provide continuous monitoring of cardiorespiratory function.

Resuscitative equipment, drugs, and personnel for airway and ventilation management should be immediately available. For deeply sedated pediatric patients, a dedicated individual other than the clinician performing the procedure should monitor the patient throughout the procedure. When IM midazolam is used for status epilepticus, the drug should be administered in a monitored setting that allows for immediate access to resuscitative drugs, and the patient's cardiorespiratory function should be continuously monitored until stabilized.

When midazolam nasal spray is used, consideration should be given to administering the drug under the supervision of a healthcare professional. Ketamine hydrochloride usually is administered by slow (e.g., over 60 seconds) IV injection, IV infusion, or IM injection. Ketamine also has been used in IV patient-controlled analgesia (PCA), either as the sole analgesic or in combination with opioids to improve pain control and reduce opioid-related adverse effects.

Ketamine also has been administered by oral+, intranasal+, rectal+, subcutaneous+, and intraosseous (IO)+ routes. Because of extensive first-pass metabolism, the bioavailability of ketamine following oral or rectal administration is limited (approximately 20-30%). Although ketamine has been administered epidurally+ or intrathecally+, there have been concerns about potential neurotoxicity with these routes, and some experts state it may be prudent to avoid neuraxial administration of the drug.

Some experts state that IV administration of ketamine is preferred to IM administration when access can be obtained readily. IM administration is associated with a higher rate of vomiting and longer recovery times compared with IV administration. In addition, IV access can permit convenient administration of additional doses for longer procedures and allow for rapid treatment of adverse effects (e.g., IV benzodiazepines for emergence reactions).

In certain patients (e.g., severely agitated or uncooperative patients, young children), IM administration may be preferred. Store ketamine hydrochloride injection at controlled room temperature between 20-25degreesC (excursions permitted between 15-30degreesC) and protect from light. Ketamine has been reported to be compatible with several drugs when administered as additives, simultaneously in the same syringe, or when a Y-type administration set is used; specialized references should be consulted for more specific information.

No dosing information available.

No generic dosing information available.

The following drug interaction information is available for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl):

Contraindicated
Severe
Moderate

There are 2 contraindications. These drug combinations generally should not be dispensed or administered to the same patient. A manufacturer label warning that indicates the contraindication warrants inclusion of a drug combination in this category, regardless of clinical evidence or lack of clinical evidence to support the contraindication.

Drug Interaction	Drug Names
Sodium Oxybate/Sedative Hypnotics; Alcohol SEVERITY LEVEL: 1-Contraindicated Drug Combination: This drug combination is contraindicated and generally should not be dispensed or administered to the same patient. MECHANISM OF ACTION: Oxybate may be associated with respiratory depression. As oxybate is taken at bedtime, concurrent use with alcohol or hypnotics may increase the risk for respiratory depression or loss of consciousness.(1-3) Primidone is metabolized to phenobarbital. CLINICAL EFFECTS: Concurrent use of sodium oxybate and sedative hypnotics or alcohol may further increase the risk for respiratory depression and profound sedation or coma.(1,2) Fatalities have been reported.(3) PREDISPOSING FACTORS: Based upon FDA evaluation of deaths in patients taking sodium oxybate, risk factors may include: use of multiple drugs which depress the CNS, more rapid than recommended oxybate dose titration, exceeding the maximum recommended oxybate dose, and prescribing for unapproved uses such as fibromyalgia, insomnia or migraine. Note that in oxybate clinical trials for narcolepsy 78% - 85% of patients were also receiving concomitant CNS stimulants.(1-3) PATIENT MANAGEMENT: The FDA states that sodium oxybate is contraindicated in patients also taking hypnotics or alcohol.(1,2) Significant quantities of alcohol may be present in medicinal products. Alcohol is is used to improve docetaxel and paclitaxel solubility. - The quantity of alcohol in paclitaxel injection formulations (0.385-0.396 grams/mL) is similar across manufacturers. A paclitaxel 200 mg dose contains approximately 13 grams of alcohol. - The quantity of alcohol in docetaxel formulations varies approximately 3-fold depending upon the manufacturer. FDA data on alcohol content (4): Product Manufacturer Alcohol/200 mg dose Docetaxel Inj. Pfizer 6.4 grams Docetaxel Inj. Sandoz 5.5 grams Docetaxel Inj. Accord 4.0 grams Taxotere-one vial Sanofi 4.0 grams formulation Docetaxel Inj. Hospira 3.7 grams Docefrez Sun Pharma 2.9 grams Taxotere-two vial Sanofi 2.0 grams formulation DISCUSSION: The FDA evaluated sodium oxybate postmarket fatal adverse event reports from the FDA Adverse Event Reporting System(AERS)and from the manufacturer. Although report documentation was not always optimal or complete, useful information was obtained. Factors which may have contributed to fatal outcome: concomitant use of one or more drugs which depress the CNS, more rapid than recommended upward dose titration, exceeding the maximum recommended oxybate dose, and prescribing for unapproved uses such as fibromyalgia, insomnia or migraine. Many deaths occurred in patients with serious psychiatric disorders such as depression and substance abuse. Other concomitant diseases may have also contributed to respiratory and CNS depressant effects of oxybate.(3)	LUMRYZ, LUMRYZ STARTER PACK, SODIUM OXYBATE, XYREM, XYWAV
Midazolam/Lonafarnib SEVERITY LEVEL: 1-Contraindicated Drug Combination: This drug combination is contraindicated and generally should not be dispensed or administered to the same patient. MECHANISM OF ACTION: The metabolism of midazolam by CYP3A4 may be inhibited by lonafarnib.(1) CLINICAL EFFECTS: The concurrent administration of lonafarnib may result in elevated levels of midazolam, which may result in increased adverse effects including profound sedation, respiratory depression, coma, and/or death.(1) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The US manufacturers of lonafarnib states that concurrent use of midazolam is contraindicated. Temporarily discontinue lonafarnib 10-14 days before and 2 days after administration of midazolam.(1) If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a study in healthy subjects, concomitant administration of midazolam (3 mg single dose) with lonafarnib (100 mg twice daily for 5 days) increased the concentration maximum (Cmax) and area-under-curve (AUC) of midazolam by 180% and 639%, respectively.(1)	ZOKINVY

Drug Interaction

Drug Names

Sodium Oxybate/Sedative Hypnotics; Alcohol

SEVERITY LEVEL: 1-Contraindicated Drug Combination: This drug combination is contraindicated and generally should not be dispensed or administered to the same patient.

MECHANISM OF ACTION: Oxybate may be associated with respiratory depression. As oxybate is taken at bedtime, concurrent use with alcohol or hypnotics may increase the risk for respiratory depression or loss of consciousness.(1-3) Primidone is metabolized to phenobarbital.

CLINICAL EFFECTS: Concurrent use of sodium oxybate and sedative hypnotics or alcohol may further increase the risk for respiratory depression and profound sedation or coma.(1,2) Fatalities have been reported.(3)

PREDISPOSING FACTORS: Based upon FDA evaluation of deaths in patients taking sodium oxybate, risk factors may include: use of multiple drugs which depress the CNS, more rapid than recommended oxybate dose titration, exceeding the maximum recommended oxybate dose, and prescribing for unapproved uses such as fibromyalgia, insomnia or migraine. Note that in oxybate clinical trials for narcolepsy 78% - 85% of patients were also receiving concomitant CNS stimulants.(1-3)

PATIENT MANAGEMENT: The FDA states that sodium oxybate is contraindicated in patients also taking hypnotics or alcohol.(1,2) Significant quantities of alcohol may be present in medicinal products. Alcohol is is used to improve docetaxel and paclitaxel solubility.

- The quantity of alcohol in paclitaxel injection formulations (0.385-0.396 grams/mL) is similar across manufacturers. A paclitaxel 200 mg dose contains approximately 13 grams of alcohol. - The quantity of alcohol in docetaxel formulations varies approximately 3-fold depending upon the manufacturer.

FDA data on alcohol content (4): Product Manufacturer Alcohol/200 mg dose Docetaxel Inj. Pfizer 6.4 grams Docetaxel Inj.

Sandoz 5.5 grams Docetaxel Inj. Accord 4.0

grams Taxotere-one vial Sanofi 4.0 grams formulation Docetaxel Inj. Hospira 3.7

grams Docefrez Sun Pharma 2.9 grams Taxotere-two vial Sanofi 2.0 grams formulation

DISCUSSION: The FDA evaluated sodium oxybate postmarket fatal adverse event reports from the FDA Adverse Event Reporting System(AERS)and from the manufacturer. Although report documentation was not always optimal or complete, useful information was obtained. Factors which may have contributed to fatal outcome: concomitant use of one or more drugs which depress the CNS, more rapid than recommended upward dose titration, exceeding the maximum recommended oxybate dose, and prescribing for unapproved uses such as fibromyalgia, insomnia or migraine.

Many deaths occurred in patients with serious psychiatric disorders such as depression and substance abuse. Other concomitant diseases may have also contributed to respiratory and CNS depressant effects of oxybate.(3)

LUMRYZ, LUMRYZ STARTER PACK, SODIUM OXYBATE, XYREM, XYWAV

Midazolam/Lonafarnib

SEVERITY LEVEL: 1-Contraindicated Drug Combination: This drug combination is contraindicated and generally should not be dispensed or administered to the same patient.

MECHANISM OF ACTION: The metabolism of midazolam by CYP3A4 may be inhibited by lonafarnib.(1)

CLINICAL EFFECTS: The concurrent administration of lonafarnib may result in elevated levels of midazolam, which may result in increased adverse effects including profound sedation, respiratory depression, coma, and/or death.(1)

PREDISPOSING FACTORS: None determined.

PATIENT MANAGEMENT: The US manufacturers of lonafarnib states that concurrent use of midazolam is contraindicated. Temporarily discontinue lonafarnib 10-14 days before and 2 days after administration of midazolam.(1) If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.

DISCUSSION: In a study in healthy subjects, concomitant administration of midazolam (3 mg single dose) with lonafarnib (100 mg twice daily for 5 days) increased the concentration maximum (Cmax) and area-under-curve (AUC) of midazolam by 180% and 639%, respectively.(1)

ZOKINVY

There are 14 severe interactions. These drug interactions can produce serious consequences in most patients. Actions required for severe interactions include, but are not limited to, discontinuing one or both agents, adjusting dosage, altering administration scheduling, and providing additional patient monitoring. Review the full interaction monograph for more information.

Drug Interaction	Drug Names
Memantine/N-Methyl-D-Aspartate (NMDA) Antagonists SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: N-methyl-D-aspartate (NMDA) antagonists act at the same receptor system as does memantine.(1,2) CLINICAL EFFECTS: Concurrent use may result in more frequent and more pronounced side effects, especially CNS-related effects.(1) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The UK manufacturer of memantine states that the concurrent use of memantine with N-methyl-D-aspartate (NMDA) antagonists such as amantadine or ketamine should be avoided.(1) The US manufacturer of memantine states that concurrent use should be approached with caution.(2) DISCUSSION: Because N-methyl-D-aspartate (NMDA) antagonists act at the same receptor system as does memantine, concurrent use may result in more frequent and more pronounced side effects, especially CNS-related effects. Therefore, the UK manufacturer of memantine states that the concurrent use of memantine with NMDA antagonists such as amantadine or ketamine should be avoided.(1) The US manufacturer of memantine states that concurrent use should be approached with caution.(2) In a study in 52 healthy subjects, concurrent memantine (20 mg daily) and dextromethorphan/quinidine (30/30 mg daily) resulted in no changes in dextromethorphan or memantine levels. There was a slight increase in dizziness as measured by the dizziness visual analog scale (VAS) when compared to memantine alone but not the combination of dextromethorphan/quinidine alone. For other pharmacodynamic assessments, there was either no effect or improvement on some subscales.(3)	MEMANTINE HCL, MEMANTINE HCL ER, MEMANTINE HCL-DONEPEZIL HCL ER, NAMENDA, NAMENDA XR, NAMZARIC
Clozapine/Benzodiazepines SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: The exact mechanism is unknown. Some benzodiazepines may increase clozapine levels.(1) CLINICAL EFFECTS: Concurrent administration of clozapine with a benzodiazepine may result in orthostatic hypotension, delirium, collapse, profound sedation, respiratory arrest, and/or cardiac arrest.(2-3) PREDISPOSING FACTORS: Patients with preexisting cardiovascular, liver, organic brain disease(1) or sleep apnea may be predisposed to the interaction. The interaction may be more likely when initiating clozapine therapy, when restarting clozapine after a brief clozapine-free interval, or when adding clozapine to benzodiazepine therapy.(1,2) PATIENT MANAGEMENT: The concurrent use of clozapine with benzodiazepines should be approached with caution, especially in patients who have recently started or restarted clozapine therapy. Monitor patients for excessive sedation, decreased respiratory rate, and ataxia.(3) DISCUSSION: Collapse has been reported in a patients in whom clozapine and clonazepam were initiated simultaneously.(4) Somnolence, confusion, ataxia, and disorientation were reported in a patient following the addition of clozapine to clonazepam therapy.(5) Collapse has been reported in three patients maintained on diazepam in whom clozapine was initiated.(6,7) Cardiac arrest and death during sleep were reported in a patient in whom clozapine and oxazepam were initiated simultaneously.(4) Delirium has been reported in four clozapine-treated patients in whom lorazepam was initiated.(5,8) Respiratory arrest and death were reported in one patient in whom clozapine was initiated who had been maintained on oral lorazepam. The patient received three supplemental doses of intravenous lorazepam for increased psychosis and was found dead 12 hours later.(9)	CLOZAPINE, CLOZAPINE ODT, CLOZARIL, VERSACLOZ
Ethyl Alcohol/Benzodiazepines SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Concurrent use may result in additive central nervous system depressant effects. Concurrent use may also result in altered absorption, altered distribution, or decreased elimination leading to higher concentrations of the benzodiazepine in the brain.(1-4) CLINICAL EFFECTS: Concurrent use of benzodiazepines and alcohol-containing products may result in enhanced disruption of psychomotor performance and increased central nervous system depression. Increased CNS depression may result in profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Patients should be informed that alcohol consumption may result in significant decreased psychomotor performance and its associated risks. Use of a short acting benzodiazepine may minimize the potential for extreme effects. If suicide or drug abuse is a concern, benzodiazepine use may be ill advised, since alcohol tends to greatly increase benzodiazepine-induced CNS depression in acute overdosage. Patients should be informed about unsuspected sources of alcohol such as medications. Alcohol is used to improve docetaxel and paclitaxel solubility. - The quantity of alcohol in paclitaxel injection formulations (0.385-0.396 grams/mL) is similar across manufacturers. A paclitaxel 200 mg dose contains approximately 13 grams of alcohol. - The quantity of alcohol in docetaxel formulations varies approximately 3-fold depending upon the manufacturer. FDA data on alcohol content (18): Product Manufacturer Alcohol/200 mg dose Docetaxel Inj. Pfizer 6.4 grams Docetaxel Inj. Sandoz 5.5 grams Docetaxel Inj. Accord 4.0 grams Taxotere-one vial Sanofi 4.0 grams formulation Docetaxel Inj. Hospira 3.7 grams Docefrez Sun Pharma 2.9 grams Taxotere-two vial Sanofi 2.0 grams formulation DISCUSSION: Several articles have detailed enhanced disruption of psychomotor performance and increased CNS depression with concurrent use of diazepam and alcohol.(1-6) Evidence shows that temazepam and the other short-acting or intermediate-acting benzodiazepines (e.g., alprazolam, halazepam, triazolam) tend to result in less profound alcohol interactions.(7) Although one study showed no effect on triazolam pharmacokinetics, a clinically significant pharmacodynamic interaction cannot be ruled out.(8) Other reports have shown clinically significant effects from concurrent triazolam and alcohol use.(9,10) In 8 healthy subjects, concurrent midazolam and alcohol resulted in impairment of immediate recall.(11) In a similar study, the hypnotic effect of midazolam was augmented by alcohol.(12) In a study involving 9 subjects, measurements of total reaction time were longer after concurrent alcohol and lorazepam as compared to the use of either agent alone.(13) Reports have been conflicting regarding the actions of chlordiazepoxide when combined with alcohol. Differences in time of exposure, dosage, and response parameters have been used to explain the inconsistent findings with chlordiazepoxide.(14)	ALCOHOL,DEHYDRATED
Midazolam/Conivaptan SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Conivaptan may inhibit the metabolism of midazolam via CYP3A4.(1) CLINICAL EFFECTS: Concurrent use of midazolam and conivaptan may result in increased levels of midazolam, which may lead to increased clinical effects and toxicity, including respiratory depression.(1) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The US manufacturer of conivaptan states the concurrent use of agents primarily metabolized by CYP3A4, such as midazolam, should be avoided. Treatment with midazolam may be initiated no sooner than 1 week after the infusion of conivaptan is completed.(1) DISCUSSION: Conivaptan is a potent inhibitor of CYP3A4. In an evaluation of the combination of intravenous conivaptan (40 mg) with either an intravenous dose of midazolam (1 mg) or an oral dose of midazolam (2 mg), mean area under the curve (AUC) values of midazolam were increased 2- and 3-fold, respectively.(1)	CONIVAPTAN-D5W, VAPRISOL-5% DEXTROSE
Midazolam; Triazolam/Diltiazem; Verapamil SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Diltiazem and verapamil may inhibit the metabolism of midazolam and triazolam by CYP3A4.(1-7) CLINICAL EFFECTS: Concurrent use of diltiazem or verapamil may result in elevated levels of and clinical effects, including profound sedation, respiratory depression, coma, and/or death, from midazolam and triazolam.(1-4) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Consider the use of alternative agents to midazolam and triazolam in patients maintained on diltiazem or verapamil. The concurrent use of midazolam or triazolam with diltiazem or verapamil should be approached with caution. The dose of midazolam or triazolam should be reduced and patients should be observed for increased benzodiazepine effects such as prolonged sedation.(1-4) If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a double-blind, randomized, cross-over study in 9 healthy subjects, pretreatment with diltiazem (60 mg 3 times daily for 2 days) increased the area-under-curve (AUC) of a single oral dose of midazolam (15 mg) by 2.75-fold. Midazolam maximum concentration (Cmax) doubled and half-life (T1/2) was prolonged. These changes were associated with profound and prolonged sedative effects.(1) In a double-blind, randomized, cross-over study in 9 healthy subjects, pretreatment with verapamil (80 mg 3 times daily for 2 days) increased the AUC of a single oral dose of midazolam (15 mg) by 1.9-fold. Midazolam Cmax doubled and T1/2 was prolonged. These changes were associated with profound and prolonged sedative effects.(1) In a randomized, cross-over study in 7 healthy males, pretreatment with diltiazem (180 mg daily for 3 days) increased the AUC, Cmax, and T1/s of a single oral dose of triazolam (0.25 mg) by 1.275-fold, 71%, and 85%, respectively. Pharmacodynamic effects of triazolam were significantly increased as measured by peak saccadic velocity of eye movements (PSV), electroencephalogram (EEG), and visual analogue scale (VAS).(2) In a randomized, double-blind, cross-over study in 10 healthy subjects, pretreatment with diltiazem (60 mg 3 times daily for 2 days) increased the AUC, Cmax, and T1/2 of a single oral dose of triazolam (0.25 mg) by 3-fold, 2-fold, and 2-fold, respectively. These changes were associated with increased and prolonged pharmacodynamic effects.(3) Studies have shown that diltiazem increases midazolam and triazolam AUC by 3-fold to 4-fold, Cmax by 2-fold, and T1/2 by 1.5-fold to 2.5-fold.(4)	CARDIZEM, CARDIZEM CD, CARDIZEM LA, CARTIA XT, DILT-XR, DILTIAZEM 12HR ER, DILTIAZEM 24HR ER, DILTIAZEM 24HR ER (CD), DILTIAZEM 24HR ER (LA), DILTIAZEM 24HR ER (XR), DILTIAZEM HCL, DILTIAZEM HCL-0.7% NACL, DILTIAZEM HCL-0.9% NACL, DILTIAZEM HCL-NACL, DILTIAZEM-D5W, MATZIM LA, TIADYLT ER, TIAZAC, TRANDOLAPRIL-VERAPAMIL ER, VERAPAMIL ER, VERAPAMIL ER PM, VERAPAMIL HCL, VERAPAMIL SR
Selected CYP3A4 Substrates/Ceritinib SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Ceritinib inhibits CYP3A4, and thus may inhibit the metabolism of agents processed by this isoenzyme.(1) CLINICAL EFFECTS: Concurrent use of ceritinib with drugs primarily metabolized by CYP3A4 may lead to elevated drug levels and increased side effects of these agents. Drugs with a narrow therapeutic window that are metabolized by this isoenzyme include: cyclosporine, felodipine, hydroquinidine, midazolam, nisoldipine, quinidine, and sirolimus.(1,2) PREDISPOSING FACTORS: Greater risk for adverse events would be expected for drugs with a narrow therapeutic window, or for drugs especially sensitive to CYP3A4 inhibition. With pimozide, the risk of anticholinergic toxicities including cognitive decline, delirium, falls and fractures is increased in geriatric patients using more than one medicine with anticholinergic properties.(4) PATIENT MANAGEMENT: Avoid coadministration of sensitive CYP3A4 substrates with a narrow therapeutic index. If concomitant use is unavoidable, dosage adjustment of the CYP3A4 substrate should be considered when initiating or discontinuing ceritinib.(1) Patients maintained on ceritinib may need lower initial doses of the CYP3A4 substrate. Monitor patients receiving concurrent therapy for adverse effects. DISCUSSION: In a study, ceritinib (750 mg daily for 3 weeks) increased the area-under-curve (AUC) and maximum concentration (Cmax) of midazolam (a CYP3A4 substrate) by 5.4-fold and 1.8-fold, respectively, compared to midazolam alone.(1) Thus, ceritinib is expected to increase levels of cyclosporine, felodipine, hydroquinidine, midazolam, nisoldipine, quinidine, and sirolimus.	ZYKADIA
Alprazolam; Estazolam; Midazolam; Triazolam/Nefazodone SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Nefazodone is a strong inhibitor of CYP3A4 and may decrease metabolism of benzodiazepines cleared by this pathway. CLINICAL EFFECTS: Concurrent administration of nefazodone and benzodiazepines metabolized by CYP3A4 may result in increased clinical effects of benzodiazepines, including toxic effects profound sedation, respiratory depression, coma, and/or death. CYP3A4 is the major or only hepatic metabolism pathway for the phase I elimination of alprazolam, estazolam, midazolam, and triazolam. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Benzodiazepines that do not undergo extensive CYP hepatic metabolism (e.g. lorazepam, oxazepam) may be an alternative in nefazodone patients. If nefazodone is administered in combination with triazolam, the manufacturer of nefazodone recommends that the initial dose triazolam be reduced by 75%. In interaction studies nefazodone 200 mg twice daily increased triazolam exposure (area-under-curve, AUC) 4-fold. However, because not all commercially available triazolam dosage forms permit a sufficient dosage adjustment, the manufacturer of nefazodone recommends that the combination of nefazodone and triazolam be avoided in most patients, especially the elderly. When nefazodone is coadministered with alprazolam, AUC and half-life increased approximately 2-fold. The US manufacturers of nefazodone recommend a 50% reduction in the initial dose of alprazolam. The US manufacturer of estazolam recommends caution and consideration of an appropriate dose reduction when concomitant therapy is considered. Two other strong CYP3A4 inhibitors, itraconazole and oral ketoconazole, are contraindicated with estazolam use. It would be prudent to avoid the combination of nefazodone and estazolam. If nefazodone is started in a patient already receiving a benzodiazepine primarily metabolized by CYP3A4, then monitor closely and anticipate the need to reduce the benzodiazepine dose. Counsel patient to report excess drowsiness, confusion, memory problems including sleep-driving behaviors, loss of coordination, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In an interaction study, nefazodone 200 mg twice daily increased triazolam exposure (area-under-curve, AUC) 4-fold. When nefazodone is coadministered with alprazolam, AUC and half-life increased approximately 2-fold.	NEFAZODONE HCL
Opioids (Cough and Cold)/Benzodiazepines SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Concurrent use of opioids and benzodiazepines may result in additive CNS depression.(1) CLINICAL EFFECTS: Concurrent use of opioids and other CNS depressants, such as benzodiazepines, may result in profound sedation, respiratory depression, coma, and/or death.(1) PREDISPOSING FACTORS: Concurrent use of alcohol or other CNS depressants may increase the risk of adverse effects. PATIENT MANAGEMENT: Avoid prescribing opioid-including cough medications for patients taking CNS depressants such as benzodiazepines.(1) Respiratory depression can occur at any time during opioid therapy, especially during therapy initiation and following dosage increases. Consider this risk when using concurrently with other agents that may cause CNS depression.(2) If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.(1) Discuss naloxone with all patients when prescribing or renewing an opioid analgesic or medicine to treat opioid use disorder (OUD). Consider prescribing naloxone to patients prescribed medicines to treat OUD or opioid analgesics (such as those taking CNS depressants) who are at increased risk of opioid overdose and when a patient has household members/close contacts at risk for accidental overdose.(3) DISCUSSION: Between 2002 and 2014, the number of patients receiving an opioid analgesic increased 8%, from 75 million to 81 million patients, and the number of patients receiving a benzodiazepine increased 31%, from 23 million to 30 million patients. During this time, the proportion of patients receiving concurrent therapy increased 31%, from 23 million to 30 million patients.(4) From 2004 to 2011, the rate of nonmedical use-related emergency room visits involving both opioids and benzodiazepines increased from 11 to 34.2 per 100,000 and drug overdose deaths involving both opioids and benzodiazepines increased from 0.6 to 1.7 per 100,000. The proportion of prescription opioid analgesic deaths which also involved benzodiazepines increased from 18% to 31% during this time.(5) A prospective observational cohort study in North Carolina found that the rates of overdose death among patients co-dispensed opioid analgesics and benzodiazepines were 10 times higher than patients receiving opioid analgesics alone.(6) A case-cohort study of VA data from 2004-2009 found that the risk of death from overdose increased with concomitant opioid analgesics and benzodiazepines. Compared to patients with no history of benzodiazepines, patients with a history of benzodiazepine use (hazard ratio [HR] = 2.33) and patients with a current benzodiazepine prescription (HR=3.86) had an increased risk of fatal overdose.(7) A study found that opioid analgesics contributed to 77% of deaths in which benzodiazepines were determined to be a cause of death and that benzodiazepines contributed to 30% of deaths in which opioid analgesics were determined to be a cause of death. This study also found that other CNS depressants (including barbiturates, antipsychotic and neuroleptic drugs, antiepileptic and antiparkinsonian drugs, anesthetics, autonomic nervous system drugs, and muscle relaxants) were contributory to death in many cases where opioid analgesics were also implicated.(8) A study found that alcohol was involved in 18.5% of opioid analgesic abuse-related ED visits and 22.1 percent of opioid analgesic-related deaths.(9) A study of 315,428 privately insured patients who filled at least one prescription for an opioid from 2001 to 2013 were enrolled in a retrospective study. Concurrent use of a benzodiazepine was recorded as having at least one day of overlap in a given calendar year. Baseline characteristics among opioid users with concurrent use of a benzodiazepine were older (44.5 v. 42.4, p<0.001), less likely to be men (35% v. 43%, p<0.001), and had a higher prevalence rate of every comorbidity examined (p<0.001). The proportion of opioid users with concurrent benzodiazepine use nearly doubled from 9% in 2001 to 17% in 2013. The primary outcome was an emergency room visit or inpatient admission for opioid overdose within a calendar year. Among all opioid users, the annual adjusted incidence for the primary outcome was 1.16% without concurrent benzodiazepine use compared to 2.42% with concurrent benzodiazepine use (OR 2.14; 95% CI 2.05-2.24; p<0.001). Intermittent opioid users (1.45% v. 1.02%; OR 1.42; 95% CI 1.33-1.51; p<0.001) and chronic opioid users (5.36% v. 3.13%; OR 1.81; 95% CI 1.67-1.96; p<0.001) also experienced a higher adjusted incidence of the primary outcome with concurrent benzodiazepine use compared to without concurrent benzodiazepine use, respectively.(10) In a nested case-control study of adults with a new opioid dispensing between 2010-2018, patients with concurrent use of an opioid with a benzodiazepine were significantly more likely to have opioid-related overdose compared to patients receiving opioids, benzodiazepines, or neither (OR 9.28; 95% CI 7.87, 10.93). Longer concurrent use of 1-7, 8-30, and 31-90 days was associated with 4.6, 12.1, and 26.7-fold higher likelihood of opioid-related overdose (p<0.01). Patients with overlapping prescriptions during previous 0-30, 31-60, and 61-90 days were 13.2, 6.0, and 3.2-times more likely to experience an overdose (p<0.01).(11)	HYCODAN, HYDROCODONE-CHLORPHENIRAMNE ER, HYDROCODONE-HOMATROPINE MBR, HYDROMET, PROMETHAZINE-CODEINE, TUXARIN ER
Midazolam/Ribociclib SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Ribociclib is a strong inhibitor of CYP3A4 and may decrease metabolism of midazolam. CLINICAL EFFECTS: Concurrent administration of ribociclib and midazolam, metabolized by CYP3A4, may result in increased clinical effects (e.g. profound sedation, respiratory depression, coma, and/or death) of midazolam. CYP3A4 is the major or only hepatic metabolism pathway for the phase I elimination of midazolam. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Benzodiazepines that do not undergo extensive CYP hepatic metabolism (e.g. lorazepam, oxazepam) may be an alternative in ribociclib patients. If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a study in healthy subjects, concomitant administration of ribociclib (400 mg once daily for 8 days) with midazolam increased the midazolam maximum concentration (Cmax) and area under the curve (AUC) by 2.1-fold and 3.8-fold, respectively. Administration of ribociclib 600 mg once daily is predicted to increase the midazolam Cmax and AUC by 2.4-fold and 5.2-fold, respectively.	KISQALI
Selected Sensitive CYP3A4 Substrates/Oral Lefamulin SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Lefamulin is considered a moderate inhibitor of CYP3A4. FDA defines a moderate inhibitor as a drug which increases the area-under-curve (AUC) of a sensitive substrate by 2- to 5-fold.(1,4) CLINICAL EFFECTS: Concurrent use of oral lefamulin may lead to increased serum levels and adverse effects of drugs sensitive to inhibition of the CYP3A4 pathway.(1) PREDISPOSING FACTORS: With darifenacin, the risk of anticholinergic toxicities including cognitive decline, delirium, falls and fractures is increased in geriatric patients using more than one medicine with anticholinergic properties.(5) PATIENT MANAGEMENT: If oral lefamulin must be coadministered with a sensitive CYP3A4 substrate, it is recommended to closely monitor for adverse effects of the CYP3A4 substrate.(1) Drug-specific recommendations: The manufacturer of abemaciclib recommends monitoring for adverse reactions and considering a dose reduction of abemaciclib in 50 mg decrements as detailed in prescribing information (based on starting dose, previous dose reductions, and combination or monotherapy use) with concurrent use of moderate CYP3A4 inhibitors.(2) The US manufacturer of sirolimus protein-bound injection (Fyarro) states a dose reduction to 56 mg/m2 is recommended when used concurrently with moderate or weak CYP3A4 inhibitors. Concurrent use with strong CYP3A4 inhibitors should be avoided.(3) DISCUSSION: In a study, oral lefamulin tablets administered concomitantly with and at 2 or 4 hours before oral midazolam (a CYP3A4 substrate) increased the area-under-curve (AUC) and maximum concentration (Cmax) of midazolam by 200% and 100%, respectively. No clinically significant effect on midazolam pharmacokinetics was observed when co-administered with lefamulin injection.(1) Sensitive CYP3A4 substrates linked to this monograph include: abemaciclib, acalabrutinib, alfentanil, alprazolam, atorvastatin, brotizolam, budesonide, buspirone, cobimetinib, darifenacin, ebastine, eletriptan, elvitegravir, everolimus, lovastatin, lurasidone, maraviroc, midazolam, nisoldipine, paritaprevir, sildenafil, simvastatin, sirolimus, ticagrelor, triazolam, and ulipristal.(1,4,6)	XENLETA
Selected CYP3A4 Substrates/Crizotinib SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Crizotinib inhibits CYP3A4, and thus may inhibit the metabolism of agents processed by this isoenzyme.(1) CLINICAL EFFECTS: Concurrent use of crizotinib with drugs primarily metabolized by CYP3A4 may lead to elevated drug levels and increased side effects of these agents.(1) Drugs with a narrow therapeutic window that are metabolized by this isoenzyme include: abemaciclib, cisapride, cyclosporine, felodipine, hydroquinidine, lovastatin, midazolam, nisoldipine, quinidine, simvastatin, and sirolimus.(1-2) PREDISPOSING FACTORS: Greater risk for adverse events would be expected for drugs with a narrow therapeutic window, or for drugs especially sensitive to CYP3A4 inhibition. PATIENT MANAGEMENT: Avoid coadministration of sensitive CYP3A4 substrates with a narrow therapeutic index. If concomitant use is unavoidable, dosage adjustment of the CYP3A4 substrate should be considered when initiating or discontinuing crizotinib.(1) Patients maintained on crizotinib may need lower initial doses of the CYP3A4 substrate. Monitor patients receiving concurrent therapy for adverse effects. Drug-specific recommendations: The manufacturer of abemaciclib recommends monitoring for adverse reactions and considering a dose reduction of abemaciclib in 50 mg decrements as detailed in prescribing information (based on starting dose, previous dose reductions, and combination or monotherapy use) with concurrent use of moderate CYP3A4 inhibitors.(3) The US manufacturer of sirolimus protein-bound injection (Fyarro) states a dose reduction to 56 mg/m2 is recommended when used concurrently with moderate or weak CYP3A4 inhibitors. Concurrent use with strong CYP3A4 inhibitors should be avoided.(4) DISCUSSION: Crizotinib (250 mg twice daily for 28 days) increased the area-under-curve (AUC) of oral midazolam by 3.7-fold.(1) Thus, crizotinib is expected to increase levels of abemaciclib, cisapride, cyclosporine, felodipine, hydroquinidine, lovastatin, midazolam, nisoldipine, quinidine, simvastatin, and sirolimus.	XALKORI
Selected Sensitive CYP3A4 Substrates/Tucatinib SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Tucatinib is a strong inhibitor of CYP3A4 and may decrease the metabolism of drugs metabolized by the CYP3A4 enzyme. Tucatinib is also an inhibitor of P-glycoprotein (P-gp) and may increase the absorption of sirolimus. CLINICAL EFFECTS: Concurrent use of tucatinib may lead to increased serum levels and adverse effects of drugs sensitive to inhibition of the CYP3A4 pathway or P-gp.(1) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The manufacturer of tucatinib states that coadministration of CYP3A4 substrates should be avoided. If concomitant use is unavoidable, consider dose reduction of the CYP3A4 substrate.(1) The manufacturer of tucatinib states that the dose of P-gp substrates may need to be reduced with coadministration with tucatinib.(1) DISCUSSION: In a study, tucatinib increased the area-under-the-curve (AUC) and maximum concentration (Cmax) of a single dose of midazolam (2 mg) by 5.7-fold and 3-fold, respectively.(1) In a study, tucatinib increased the AUC and Cmax of digoxin (0.5 mg single dose) by 1.5-fold and 2.4-fold, respectively.(1) CYP3A4 substrates with a narrow therapeutic index linked to this monograph include: cyclosporine, midazolam, nisoldipine, and sirolimus.(1-3)	TUKYSA
Selected CYP3A4 Substrates/Pexidartinib SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Pexidartinib is a moderate inducer of CYP3A4 and may increase the metabolism of drugs metabolized by the CYP3A4 enzyme. CLINICAL EFFECTS: Concurrent use of pexidartinib may lead to decreased serum levels and effectiveness of drugs metabolized by the CYP3A4 pathway.(1) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The manufacturer of pexidartinib states that co-administration of CYP3A4 substrates for which minimal concentration decreases may lead to serious therapeutic failure should be avoided. If concomitant use is unavoidable, increase the dose of the CYP3A4 substrate in accordance with approved product labeling.(1) DISCUSSION: Coadministration of pexidartinib 400 mg twice daily with oral midazolam, a sensitive CYP3A4 substrate, in patients decreased midazolam area-under-curve (AUC) by 59% and maximum concentration (Cmax) by 28%.(1) CYP3A4 substrates with a narrow therapeutic index linked to this monograph include: alfentanil, everolimus, felodipine, fentanyl, hydroquinidine, midazolam, nisoldipine, quinidine, sirolimus, tacrolimus, ticagrelor, and triazolam.(1-3)	TURALIO
Selected CYP3A4 Substrates/Sotorasib SEVERITY LEVEL: 2-Severe Interaction: Action is required to reduce the risk of severe adverse interaction. MECHANISM OF ACTION: Sotorasib is a moderate inducer of CYP3A4 and may increase the metabolism of drugs metabolized by the CYP3A4 enzyme. CLINICAL EFFECTS: Concurrent use of sotorasib may lead to decreased serum levels and effectiveness of drugs metabolized by the CYP3A4 pathway.(1) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The manufacturer of sotorasib states that co-administration of CYP3A4 substrates for which minimal concentration decreases may lead to serious therapeutic failure should be avoided. If concomitant use is unavoidable, increase the dose of the CYP3A4 substrate in accordance with approved product labeling.(1) DISCUSSION: Coadministration of sotorasib with midazolam, a sensitive CYP3A4 substrate, decreased midazolam area-under-curve (AUC) by 53% and maximum concentration (Cmax) by 48%.(1) CYP3A4 substrates with a narrow therapeutic index linked to this monograph include: alfentanil, felodipine, fentanyl, hydroquinidine, parenteral lefamulin, midazolam, nisoldipine, quinidine, tacrolimus, ticagrelor, and triazolam.(2,3)	LUMAKRAS

There are 17 moderate interactions. The clinician should assess the patient’s characteristics and take action as needed. Actions required for moderate interactions include, but are not limited to, discontinuing one or both agents, adjusting dosage, altering administration.

Drug Interaction	Drug Names
Cimetidine/Benzodiazepines SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Cimetidine may decrease the metabolism of Phase I hepatically metabolized benzodiazepines. At doses of 800-2400 mg daily, cimetidine is a weak inhibitor of CYP1A2, CYP2C19, CYP2C9, CYP2D6, and CYP3A4. CLINICAL EFFECTS: Concurrent use may result in increased pharmacologic or toxic effects of certain benzodiazepines. Toxic effects include profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Benzodiazepines that do not undergo extensive Phase I metabolism (lorazepam, oxazepam) may be an alternative to interacting benzodiazepines in patients receiving cimetidine or by administering another H-2 antagonist (e.g., ranitidine, famotidine, nizatidine). Cimetidine use at higher doses of 200-400 mg four times daily would have an increased risk of inhibiting the metabolism of benzodiazepines. Lower doses and over-the-counter doses of cimetidine would be expected to have a diminished effect. Consider using alternative H2 antagonists when long-term concurrent therapy with benzodiazepines is indicated. If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: Cimetidine increases the half-life and serum concentration and decreases the clearance of benzodiazepines that undergo oxidative metabolism (e.g., alprazolam, bromazepam, diazepam, flurazepam, midazolam, triazolam). In a clinical study, cimetidine 1,200 mg daily decreased the clearance of bromazepam by 50% and increased its half-life from 23 hours to 29 hours.(22) The sedative effects of benzodiazepines have been reported to be increased during concurrent administration of cimetidine. This interaction does not appear to occur with benzodiazepines that undergo glucuronide conjugation.	CIMETIDINE
Midazolam/Macrolide Antibiotics SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Macrolides may inhibit the metabolism of midazolam through inhibition of CYP3A4. CLINICAL EFFECTS: Serum concentrations of midazolam may be increased, enhancing its pharmacological effects. Toxic effects of increased midazolam levels include profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Patients should be cautioned about possible increased sedation and observed for this side effect. Decreasing the dose of midazolam may be necessary. If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a study of 12 healthy volunteers, clarithromycin (250 mg twice daily for 5 days) increased the area-under-curve (AUC) of oral midazolam (15 mg) by 3.57-fold.(1) Sixteen elderly volunteers who received clarithromycin pre-treatment (500 mg twice daily for 7 days) had increases in the AUC of oral midazolam of 8-fold and of IV midazolam of 3.2-fold.(2) In a study involving 12 healthy volunteers, oral erythromycin (500 mg three times daily for 7 days) was followed by a single oral 15 mg midazolam dose. Concomitant administration of erythromycin and oral midazolam produced a decrease in midazolam clearance and an increase in the half-life and serum concentration of midazolam, with an AUC increase of 4.4-fold. Sedation produced by midazolam was pronounced and long-lasting. When midazolam was given IV, first-pass metabolism was avoided and the effects of the interaction were less profound. A single IV dose of 0.15 mg/kg midazolam given after 1 week of erythromycin 500 mg three times daily resulted in a 54% decrease in midazolam clearance.(3) Oral use of midazolam and IV erythromycin has been associated with unconsciousness in an 8-year-old boy.(4,5) In a study of 10 healthy volunteers, roxithromycin (300 mg daily for 6 days) increased the AUC of oral midazolam (15 mg) by 1.5-fold.(6) Concurrent administration of telithromycin increased the AUC of IV and oral midazolam by 2-fold and 6-fold, respectively.(7)	CLARITHROMYCIN, CLARITHROMYCIN ER, E.E.S. 200, E.E.S. 400, ERY-TAB, ERYPED 200, ERYPED 400, ERYTHROCIN LACTOBIONATE, ERYTHROCIN STEARATE, ERYTHROMYCIN, ERYTHROMYCIN ESTOLATE, ERYTHROMYCIN ETHYLSUCCINATE, ERYTHROMYCIN LACTOBIONATE, LANSOPRAZOL-AMOXICIL-CLARITHRO, OMECLAMOX-PAK, VOQUEZNA TRIPLE PAK
Selected Benzodiazepines/Posaconazole SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Posaconazole may inhibit the metabolism of benzodiazepines by CYP3A4.(1,2) CLINICAL EFFECTS: The concurrent administration of posaconazole with benzodiazepines metabolized by CYP3A4 may result in elevated levels of and increased clinical effects from the benzodiazepines.(1,2) Toxic effects of increased levels of benzodiazepines include profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Patients receiving concurrent therapy with posaconazole should be monitored for increased benzodiazepine effects. The dosage of the benzodiazepine may need to be decreased or the benzodiazepine may need to be discontinued. If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: Posaconazole (200 mg daily for 10 days) increased the AUC of a single dose of intravenous midazolam (30 minute infusion of 0.05 mg/kg) by 83%.(1) Posaconazole (200 mg twice daily for 7 days) increased the Cmax and AUC of a single dose of intravenous midazolam (0.4 mg) by 30% and 362%, respectively. Posaconazole (200 mg twice daily for 7 days) increased the Cmax and AUC of a single dose of oral midazolam (2 mg) by 169% and 470%, respectively. Posaconazole (400 mg twice daily for 7 days) increased the Cmax and AUC of a single dose of intravenous midazolam (0.4 mg) by 62% and 524%, respectively. Posaconazole (400 mg twice daily for 7 days) increased the Cmax and AUC of a single dose of oral midazolam (2 mg) by 138% and 397%, respectively.(2) In a study of 12 healthy volunteers (11 male and 1 female), posaconazole (200mg twice daily for 7 days and 400mg twice daily for 7 days) increased midazolam Cmax up to 1.3 and 2.4 fold, respectively, and midazolam AUC 4.6 and 6.2 fold, respectively. Midazolam half-life was also increased.(3)	NOXAFIL, POSACONAZOLE
Tramadol/5-HT3 Antagonists SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: The interaction may involve a reduction in the binding involving 5-HT3 receptors.(1) CLINICAL EFFECTS: Concurrent use of 5-HT3 antagonists may decrease the effectiveness of tramadol, resulting in increased use of tramadol.(1-3) 5-HT3 antagonists may not be effective in reducing tramadol-induced nausea.(4) PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Consider the use of alternative anti-emetics in patients receiving tramadol, or the use of other opioids in patients receiving 5-HT3 antagonists. DISCUSSION: In a randomized study in 59 post-surgical patients in recovery, compared to tramadol alone, patients receiving concurrent ondansetron required significantly larger doses of tramadol at four hours (223 mg versus 71 mg), at 8 hours (285 mg versus 128 mg), and at 12 hours (406 mg versus 190 mg). Vomiting rates at 4 hours and 8 hours were significantly higher with tramadol and concurrent ondansetron compared to tramadol alone.(1) In a randomized, double-blind study in 40 surgical patients undergoing lumbar laminectomy, compared to tramadol alone, cumulative tramadol consumption with concurrent ondansetron during the first 24 hours was significantly increased (between 26% and 35%) as well as thereafter (22% to 25%).(2) In another randomized study in 120 post-surgical patients, it was discovered that tramadol consumption was increased in those patients receiving concurrent ondansetron compared to tramadol alone.(3) In a prospective, randomized, double-blinded study in dental patients, patients received one of four treatments: fentanyl and metoclopramide, tramadol and metoclopramide, fentanyl and ondansetron, or tramadol and ondansetron. The patients who received tramadol and ondansetron had the highest nausea scores among the treatment groups. There were no significant differences in the incidences of pain or nausea in the 24 hours following the procedure.(4) In a randomized, controlled trial in 40 surgical patients undergoing hernioplasty or thyroidectomy, compared to tramadol alone, cumulative tramadol consumption was higher at the 2-hour time point with concurrent ondansetron (0.24 +/- 0.1 vs. 0.17 +/- 0.16; p = 0.01).(5) A systematic review and meta-analysis of randomized controlled trials in the postoperative setting comparing tramadol alone and in combination with ondansetron were included. At 4-hours, 8-hours, 12-hours, and 24-hours post-procedure, patients had increased tramadol requirements when administered with concurrent ondansetron compared to tramadol alone.(6) 5-HT3 antagonists linked to this monograph include: alosetron, azasetron, dolasetron, granisetron, ondansetron, palonosetron, ramosetron, and tropisetron.	CONZIP, QDOLO, TRAMADOL HCL, TRAMADOL HCL ER, TRAMADOL HCL-ACETAMINOPHEN
Selected Benzodiazepines/Selected CYP3A4 Inducers SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: CYP3A4 inducers may induce the metabolism of some benzodiazepines. CLINICAL EFFECTS: Concurrent or recent use of CYP3A4 inducers may result in decreased levels and loss of effectiveness of some benzodiazepines. PREDISPOSING FACTORS: Induction effects may be more likely with regular use of the inducer for longer than 1-2 weeks. PATIENT MANAGEMENT: Monitor patients receiving CYP3A4 inducers or who have received these agents in the previous 2 weeks for decreased benzodiazepine effectiveness. The dose of the benzodiazepine may need to be adjusted or an alternative agent used. If the CYP3A4 inducer is discontinued, benzodiazepine levels will gradually rise as induction effects diminish. Monitor for increased benzodiazepine effects and adjust the dose accordingly. DISCUSSION: In a study in 95 healthy subjects, rifampin (450 mg daily for 5 days) decreased the plasma concentrations of a single oral dose of alprazolam (1 mg) by 79%.(1) In another study in 4 healthy subjects, rifampin (given for 4 days) decreased the area-under-curve (AUC) of a single oral dose of alprazolam (1 mg) by 88%.(2) In a double-blind, randomized, cross-over trial in 13 healthy subjects, rifampin (450 mg daily for 7 days) decreased the maximum concentration (Cmax), AUC, and half-life of a single oral dose of brotizolam (0.5 mg) by 69%, 90%, and 69%, respectively. Concurrent rifampin increased scores on the Digit Symbol Substitution Test (DSST) and decreased scores on the Stanford Sleepiness Scale.(3) In a study in 21 healthy subjects, rifampin (600 mg or 1200 mg daily for 7 days) increased total body clearance of diazepam by 300%.(4) An in vitro study in human hepatocytes found that rifampin increased the biotransformation of diazepam and midazolam by 1.9-fold.(5) In a study in 24 healthy subjects, rifampin (600 mg daily for 10 days) increased the clearance of a single intravenous dose of lorazepam by 140%.(6) In an open-label cross-over study in 19 healthy subjects, rifampin (600 mg daily for 9 days) increased the clearance of a single oral dose of midazolam (0.075 mg/kg) by 7-fold.(7) In a study in 57 healthy subjects, rifampin increased the systemic and oral clearance of midazolam by 2-fold and 16-fold, respectively.(8) In a study in 8 healthy subjects, rifampin (given for 6 days) significantly increased the clearance of midazolam.(9) In a study in 9 healthy subjects, received a single oral dose of midazolam (15 mg) before, one day after the administration of rifampin (600 mg daily for 5 days), and 4 days after the last dose of rifampin. One day after rifampin, the AUC of midazolam was decreased by 97.7% when compared to the administration of midazolam prior to rifampin. Four days after the completion of rifampin, the AUC of midazolam was decreased by 87% when compared to the administration of midazolam prior to rifampin.(10) In a double-blind, randomized, cross-over study in 10 healthy subjects, rifampin (600 mg daily for 5 days) decreased the Cmax, AUC, and half-life of a single oral dose of midazolam (15 mg) by 94%, 96%, and 58%, respectively. The pharmacodynamic effects of midazolam were also significantly decreased during rifampin therapy.(11) In a study in 16 healthy subjects, rifampin (600 mg daily for 7 days) increased the clearance of nitrazepam by 83%. There were no significant effects on the pharmacokinetics of temazepam.(12) In a randomized, double-blind, cross-over study in 10 healthy subjects, rifampin (600 mg daily for 5 days) decreased the Cmax, AUC, and half-life of a single dose of triazolam (0.5 mg) by 87.6%, 94.9%, and 54%, respectively. The pharmacodynamic effects of triazolam were also significantly decreased during rifampin therapy.(13) In an open-label, randomized, cross-over study in 27 healthy subjects, rifaximin (200 mg three times daily for 7 days) had no effect on the pharmacokinetics of single doses of oral or intravenous midazolam.(14) In a study in 98 patients with schizophrenia or bipolar disorder, the expression of CYP3A4 was found to be the major determinant of clonazepam plasma concentrations normalized by the dose and bodyweight (1263 +/- 482.9 and 558.5 +/- 202.4 ng/mL per mg/kg bodyweight in low and normal expressers, respectively, p<0.0001).(18) Selected CYP3A4 inducers linked to this monograph include: apalutamide, carbamazepine, encorafenib, enzalutamide, fosphenytoin, ivosidenib, lumacaftor, mitotane, phenytoin, rifabutin, rifampin, rifapentine, and St. John's wort.	BRAFTOVI, CARBAMAZEPINE, CARBAMAZEPINE ER, CARBATROL, CEREBYX, DILANTIN, DILANTIN-125, EPITOL, EQUETRO, ERLEADA, FOSPHENYTOIN SODIUM, LYSODREN, MITOTANE, ORKAMBI, PHENYTEK, PHENYTOIN, PHENYTOIN SODIUM, PHENYTOIN SODIUM EXTENDED, PRIFTIN, RIFABUTIN, RIFADIN, RIFAMPIN, TALICIA, TEGRETOL, TEGRETOL XR, TIBSOVO, XTANDI
Buprenorphine/Benzodiazepines SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Buprenorphine is a partial agonist at mu-opioid receptors leading to ceiling effects which limit agonist activity, including respiratory depression, at high doses. However, concomitant benzodiazepine use (e.g. taken shortly after buprenorphine dose) or high doses of benzodiazepines may lead to potentiation of respiratory depression, counteracting the ceiling effect.(1,2) Concurrent use of buprenorphine and benzodiazepines may result in additive CNS depression.(3) CLINICAL EFFECTS: Concurrent use may result in profound sedation, respiratory depression, coma, and/or death. Fatal respiratory depression has occurred with the combination of buprenorphine and a benzodiazepine.(1-2,4-7) High benzodiazepine levels have been identified in 80% or more of buprenorphine fatalities.(6) PREDISPOSING FACTORS: Patients with a history of alcohol or benzodiazepine abuse may be at risk for relapse and overuse or abuse of prescribed benzodiazepines.(1,2,4,6) Individuals with significant obstructive pulmonary disease (COPD), sleep apnea, the elderly, and debilitated patients are at greater risk for respiratory depression from either agent.(1,2,8) PATIENT MANAGEMENT: Limit prescribing opioid analgesics with CNS depressants such as benzodiazepines to patients for whom alternatives are inadequate.(3) For buprenorphine patients newly starting a benzodiazepine, consider beginning the benzodiazepine at a lower than usual dose, especially if predisposing factors (e.g. COPD, sleep apnea, debilitation, elderly) are present. High doses of benzodiazepines are associated with a greater risk for respiratory depression. Use the lowest effective dose and monitor for excessive sedation or respiratory depression, particularly in patients with predisposing risk factors for respiratory compromise.(1,2) Buprenorphine-naloxone combination products are used for maintenance treatment of opioid dependence. Patients with comorbid benzodiazepine dependence, on high doses of benzodiazepines, or a history of benzodiazepine abuse may require benzodiazepine detoxification prior to initiation of office-based buprenorphine treatment.(3) For patients receiving opioid maintenance treatment, it would be prudent to assure all controlled substance prescriptions are approved or written by the buprenorphine-naloxone provider.(5) Respiratory depression can occur at any time during opioid therapy, especially during therapy initiation and following dosage increases. Consider this risk when using concurrently with other agents that may cause CNS depression.(9) Monitor patients receiving concurrent therapy for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.(3) Discuss naloxone with all patients when prescribing or renewing an opioid analgesic or medicine to treat opioid use disorder (OUD). Consider prescribing naloxone to patients prescribed medicines to treat OUD or opioid analgesics (such as those taking CNS depressants) who are at increased risk of opioid overdose and when a patient has household members/close contacts at risk for accidental overdose.(10) DISCUSSION: Buprenorphine is a partial agonist at mu-opioid receptors leading to ceiling effects which limits agonist activity, including respiratory depression, at high doses. However, concomitant benzodiazepine use (e.g. taking shortly after buprenorphine dose) or high doses of benzodiazepines may counteract the ceiling effect leading to potentiation of respiratory depression or sedative effects. High benzodiazepine levels have identified in 80% or more of buprenorphine fatalities.(6) Between 2002 and 2014, the number of patients receiving an opioid analgesic increased 8%, from 75 million to 81 million patients, and the number of patients receiving a benzodiazepine increased 31%, from 23 million to 30 million patients. During this time, the proportion of patients receiving concurrent therapy increased 31%, from 23 million to 30 million patients.(11) From 2004 to 2011, the rate of nonmedical use-related emergency room visits involving both opioids and benzodiazepines increased from 11 to 34.2 per 100,000 and drug overdose deaths involving both opioids and benzodiazepines increased from 0.6 to 1.7 per 100,000. The proportion of prescription opioid analgesic deaths which also involved benzodiazepines increased from 18% to 31% during this time.(12) A prospective observational cohort study in North Carolina found that the rates of overdose death among patients co-dispensed opioid analgesics and benzodiazepines were 10 times higher than patients receiving opioid analgesics alone.(13) A case-cohort study of VA data from 2004-2009 found that the risk of death from overdose increased with concomitant opioid analgesics and benzodiazepines. Compared to patients with no history of benzodiazepines, patients with a history of benzodiazepine use (hazard ratio [HR] = 2.33) and patients with a current benzodiazepine prescription (HR=3.86) had an increased risk of fatal overdose.(14) A study found that opioid analgesics contributed to 77% of deaths in which benzodiazepines were determined to be a cause of death and that benzodiazepines contributed to 30% of deaths in which opioid analgesics were determined to be a cause of death. This study also found that other CNS depressants (including barbiturates, antipsychotic and neuroleptic drugs, antiepileptic and antiparkinsonian drugs, anesthetics, autonomic nervous system drugs, and muscle relaxants) were contributory to death in many cases where opioid analgesics were also implicated.(15) A study found that alcohol was involved in 18.5% of opioid analgesic abuse-related ED visits and 22.1 percent of opioid analgesic-related deaths.(16) A study of 315,428 privately insured patients who filled at least one prescription for an opioid from 2001 to 2013 were enrolled in a retrospective study. Concurrent use of a benzodiazepine was recorded as having at least one day of overlap in a given calendar year. Baseline characteristics among opioid users with concurrent use of a benzodiazepine were older (44.5 v. 42.4, p<0.001), less likely to be men (35% v. 43%, p<0.001), and had a higher prevalence rate of every comorbidity examined (p<0.001). The proportion of opioid users with concurrent benzodiazepine use nearly doubled from 9% in 2001 to 17% in 2013. The primary outcome was an emergency room visit or inpatient admission for opioid overdose within a calendar year. Among all opioid users, the annual adjusted incidence for the primary outcome was 1.16% without concurrent benzodiazepine use compared to 2.42% with concurrent benzodiazepine use (OR 2.14; 95% CI 2.05-2.24; p<0.001). Intermittent opioid users (1.45% v. 1.02%; OR 1.42; 95% CI 1.33-1.51; p<0.001) and chronic opioid users (5.36% v. 3.13%; OR 1.81; 95% CI 1.67-1.96; p<0.001) also experienced a higher adjusted incidence of the primary outcome with concurrent benzodiazepine use compared to without concurrent benzodiazepine use, respectively.(17)	BELBUCA, BRIXADI, BUPRENORPHINE, BUPRENORPHINE HCL, BUPRENORPHINE-NALOXONE, BUTRANS, SUBLOCADE, SUBOXONE, ZUBSOLV
Opioids (Extended Release)/Benzodiazepines SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Concurrent use of opioids and benzodiazepines may result in additive CNS depression.(1) CLINICAL EFFECTS: Concurrent use of opioids and other CNS depressants, such as benzodiazepines, may result in profound sedation, respiratory depression, coma, and/or death.(1) PREDISPOSING FACTORS: Concurrent use of alcohol or other CNS depressants may increase the risk of adverse effects. PATIENT MANAGEMENT: Limit prescribing opioid analgesics with CNS depressants such as benzodiazepines to patients for whom alternatives are inadequate.(1) If concurrent use is necessary, limit the dosages and duration of each drug to the minimum possible while achieving the desired clinical effect. If starting a CNS depressant (for an indication other than epilepsy) with an opioid analgesic, prescribe a lower initial dose of the CNS depressant than indicated in the absence of an opioid and titrate based upon clinical response. If an opioid analgesic is indicated in a patient already taking a CNS depressant, prescribe a lower dose of the opioid and titrate based upon clinical response.(1) Respiratory depression can occur at any time during opioid therapy, especially during therapy initiation and following dosage increases. Consider this risk when using concurrently with other agents that may cause CNS depression.(2) Monitor patients receiving concurrent therapy for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.(1) Discuss naloxone with all patients when prescribing or renewing an opioid analgesic or medicine to treat opioid use disorder (OUD). Consider prescribing naloxone to patients prescribed medicines to treat OUD or opioid analgesics (such as those taking CNS depressants) who are at increased risk of opioid overdose and when a patient has household members/close contacts at risk for accidental overdose.(3) DISCUSSION: Between 2002 and 2014, the number of patients receiving an opioid analgesic increased 8%, from 75 million to 81 million patients, and the number of patients receiving a benzodiazepine increased 31%, from 23 million to 30 million patients. During this time, the proportion of patients receiving concurrent therapy increased 31%, from 23 million to 30 million patients.(4) From 2004 to 2011, the rate of nonmedical use-related emergency room visits involving both opioids and benzodiazepines increased from 11 to 34.2 per 100,000 and drug overdose deaths involving both opioids and benzodiazepines increased from 0.6 to 1.7 per 100,000. The proportion of prescription opioid analgesic deaths which also involved benzodiazepines increased from 18% to 31% during this time.(5) A prospective observational cohort study in North Carolina found that the rates of overdose death among patients co-dispensed opioid analgesics and benzodiazepines were 10 times higher than patients receiving opioid analgesics alone.(6) A case-cohort study of VA data from 2004-2009 found that the risk of death from overdose increased with concomitant opioid analgesics and benzodiazepines. Compared to patients with no history of benzodiazepines, patients with a history of benzodiazepine use (hazard ratio [HR] = 2.33) and patients with a current benzodiazepine prescription (HR=3.86) had an increased risk of fatal overdose.(7) A study found that opioid analgesics contributed to 77% of deaths in which benzodiazepines were determined to be a cause of death and that benzodiazepines contributed to 30% of deaths in which opioid analgesics were determined to be a cause of death. This study also found that other CNS depressants (including barbiturates, antipsychotic and neuroleptic drugs, antiepileptic and antiparkinsonian drugs, anesthetics, autonomic nervous system drugs, and muscle relaxants) were contributory to death in many cases where opioid analgesics were also implicated.(8) A study found that alcohol was involved in 18.5% of opioid analgesic abuse-related ED visits and 22.1 percent of opioid analgesic-related deaths.(9) A study of 315,428 privately insured patients who filled at least one prescription for an opioid from 2001 to 2013 were enrolled in a retrospective study. Concurrent use of a benzodiazepine was recorded as having at least one day of overlap in a given calendar year. Baseline characteristics among opioid users with concurrent use of a benzodiazepine were older (44.5 v. 42.4, p<0.001), less likely to be men (35% v. 43%, p<0.001), and had a higher prevalence rate of every comorbidity examined (p<0.001). The proportion of opioid users with concurrent benzodiazepine use nearly doubled from 9% in 2001 to 17% in 2013. The primary outcome was an emergency room visit or inpatient admission for opioid overdose within a calendar year. Among all opioid users, the annual adjusted incidence for the primary outcome was 1.16% without concurrent benzodiazepine use compared to 2.42% with concurrent benzodiazepine use (OR 2.14; 95% CI 2.05-2.24; p<0.001). Intermittent opioid users (1.45% v. 1.02%; OR 1.42; 95% CI 1.33-1.51; p<0.001) and chronic opioid users (5.36% v. 3.13%; OR 1.81; 95% CI 1.67-1.96; p<0.001) also experienced a higher adjusted incidence of the primary outcome with concurrent benzodiazepine use compared to without concurrent benzodiazepine use, respectively.(10) In a nested case-control study of adults with a new opioid dispensing between 2010-2018, patients with concurrent use of an opioid with a benzodiazepine were significantly more likely to have opioid-related overdose compared to patients receiving opioids, benzodiazepines, or neither (OR 9.28; 95% CI 7.87, 10.93). Longer concurrent use of 1-7, 8-30, and 31-90 days was associated with 4.6, 12.1, and 26.7-fold higher likelihood of opioid-related overdose (p<0.01). Patients with overlapping prescriptions during previous 0-30, 31-60, and 61-90 days were 13.2, 6.0, and 3.2-times more likely to experience an overdose (p<0.01).(11)	CONZIP, FENTANYL, HYDROCODONE BITARTRATE ER, HYDROMORPHONE ER, HYSINGLA ER, MORPHINE SULFATE ER, MS CONTIN, NUCYNTA ER, OXYCODONE HCL ER, OXYCONTIN, OXYMORPHONE HCL ER, TRAMADOL HCL ER, XTAMPZA ER
Opioids (Immediate Release)/Benzodiazepines SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Concurrent use of opioids and benzodiazepines may result in additive CNS depression.(1) CLINICAL EFFECTS: Concurrent use of opioids and other CNS depressants, such as benzodiazepines, may result in profound sedation, respiratory depression, coma, and/or death.(1) PREDISPOSING FACTORS: Concurrent use of alcohol or other CNS depressants may increase the risk of adverse effects. PATIENT MANAGEMENT: Limit prescribing opioid analgesics with CNS depressants such as benzodiazepines to patients for whom alternatives are inadequate.(1) If concurrent use is necessary, limit the dosages and duration of each drug to the minimum possible while achieving the desired clinical effect. If starting a CNS depressant (for an indication other than epilepsy) with an opioid analgesic, prescribe a lower initial dose of the CNS depressant than indicated in the absence of an opioid and titrate based upon clinical response. If an opioid analgesic is indicated in a patient already taking a CNS depressant, prescribe a lower dose of the opioid and titrate based upon clinical response.(1) Respiratory depression can occur at any time during opioid therapy, especially during therapy initiation and following dosage increases. Consider this risk when using concurrently with other agents that may cause CNS depression.(2) Monitor patients receiving concurrent therapy for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.(1) Discuss naloxone with all patients when prescribing or renewing an opioid analgesic or medicine to treat opioid use disorder (OUD). Consider prescribing naloxone to patients prescribed medicines to treat OUD or opioid analgesics (such as those taking CNS depressants) who are at increased risk of opioid overdose and when a patient has household members/close contacts at risk for accidental overdose.(3) DISCUSSION: Between 2002 and 2014, the number of patients receiving an opioid analgesic increased 8%, from 75 million to 81 million patients, and the number of patients receiving a benzodiazepine increased 31%, from 23 million to 30 million patients. During this time, the proportion of patients receiving concurrent therapy increased 31%, from 23 million to 30 million patients.(4) From 2004 to 2011, the rate of nonmedical use-related emergency room visits involving both opioids and benzodiazepines increased from 11 to 34.2 per 100,000 and drug overdose deaths involving both opioids and benzodiazepines increased from 0.6 to 1.7 per 100,000. The proportion of prescription opioid analgesic deaths which also involved benzodiazepines increased from 18% to 31% during this time.(5) A prospective observational cohort study in North Carolina found that the rates of overdose death among patients co-dispensed opioid analgesics and benzodiazepines were 10 times higher than patients receiving opioid analgesics alone.(6) A case-cohort study of VA data from 2004-2009 found that the risk of death from overdose increased with concomitant opioid analgesics and benzodiazepines. Compared to patients with no history of benzodiazepines, patients with a history of benzodiazepine use (hazard ratio [HR] = 2.33) and patients with a current benzodiazepine prescription (HR=3.86) had an increased risk of fatal overdose.(7) A study found that opioid analgesics contributed to 77% of deaths in which benzodiazepines were determined to be a cause of death and that benzodiazepines contributed to 30% of deaths in which opioid analgesics were determined to be a cause of death. This study also found that other CNS depressants (including barbiturates, antipsychotic and neuroleptic drugs, antiepileptic and antiparkinsonian drugs, anesthetics, autonomic nervous system drugs, and muscle relaxants) were contributory to death in many cases where opioid analgesics were also implicated.(8) A study found that alcohol was involved in 18.5% of opioid analgesic abuse-related ED visits and 22.1 percent of opioid analgesic-related deaths.(9) A study of 315,428 privately insured patients who filled at least one prescription for an opioid from 2001 to 2013 were enrolled in a retrospective study. Concurrent use of a benzodiazepine was recorded as having at least one day of overlap in a given calendar year. Baseline characteristics among opioid users with concurrent use of a benzodiazepine were older (44.5 v. 42.4, p<0.001), less likely to be men (35% v. 43%, p<0.001), and had a higher prevalence rate of every comorbidity examined (p<0.001). The proportion of opioid users with concurrent benzodiazepine use nearly doubled from 9% in 2001 to 17% in 2013. The primary outcome was an emergency room visit or inpatient admission for opioid overdose within a calendar year. Among all opioid users, the annual adjusted incidence for the primary outcome was 1.16% without concurrent benzodiazepine use compared to 2.42% with concurrent benzodiazepine use (OR 2.14; 95% CI 2.05-2.24; p<0.001). Intermittent opioid users (1.45% v. 1.02%; OR 1.42; 95% CI 1.33-1.51; p<0.001) and chronic opioid users (5.36% v. 3.13%; OR 1.81; 95% CI 1.67-1.96; p<0.001) also experienced a higher adjusted incidence of the primary outcome with concurrent benzodiazepine use compared to without concurrent benzodiazepine use, respectively.(10) In a nested case-control study of adults with a new opioid dispensing between 2010-2018, patients with concurrent use of an opioid with a benzodiazepine were significantly more likely to have opioid-related overdose compared to patients receiving opioids, benzodiazepines, or neither (OR 9.28; 95% CI 7.87, 10.93). Longer concurrent use of 1-7, 8-30, and 31-90 days was associated with 4.6, 12.1, and 26.7-fold higher likelihood of opioid-related overdose (p<0.01). Patients with overlapping prescriptions during previous 0-30, 31-60, and 61-90 days were 13.2, 6.0, and 3.2-times more likely to experience an overdose (p<0.01).(11)	ACETAMIN-CAFF-DIHYDROCODEINE, ACETAMINOPHEN-CODEINE, APADAZ, ASA-BUTALB-CAFFEINE-CODEINE, ASCOMP WITH CODEINE, BELLADONNA-OPIUM, BENZHYDROCODONE-ACETAMINOPHEN, BUTALB-ACETAMINOPH-CAFF-CODEIN, BUTORPHANOL TARTRATE, CARISOPRODOL-ASPIRIN-CODEINE, CODEINE PHOSPHATE, CODEINE SULFATE, DEMEROL, DIHYDROCODEINE BITARTRATE, DILAUDID, DSUVIA, DURAMORPH, ENDOCET, FENTANYL CITRATE, FENTANYL CITRATE-0.9% NACL, FENTANYL CITRATE-D5W, FENTANYL CITRATE-STERILE WATER, FENTANYL CITRATE-WATER, FENTANYL-BUPIVACAINE-0.9% NACL, FENTANYL-BUPIVACAINE-NACL, FENTANYL-ROPIVACAINE-0.9% NACL, FENTANYL-ROPIVACAINE-NACL, FIORICET WITH CODEINE, HYDROCODONE BITARTRATE, HYDROCODONE-ACETAMINOPHEN, HYDROCODONE-IBUPROFEN, HYDROMORPHONE HCL, HYDROMORPHONE HCL-0.9% NACL, HYDROMORPHONE HCL-D5W, HYDROMORPHONE HCL-NACL, HYDROMORPHONE HCL-WATER, INFUMORPH, LEVORPHANOL TARTRATE, MEPERIDINE HCL, MEPERIDINE HCL-0.9% NACL, METHADONE HCL, METHADONE HCL-0.9% NACL, METHADONE HCL-NACL, MITIGO, MORPHINE SULFATE, MORPHINE SULFATE-0.9% NACL, MORPHINE SULFATE-NACL, NALBUPHINE HCL, NALOCET, NUCYNTA, OLINVYK, OPIUM TINCTURE, OXYCODONE HCL, OXYCODONE HYDROCHLORIDE, OXYCODONE-ACETAMINOPHEN, OXYMORPHONE HCL, PENTAZOCINE-NALOXONE HCL, PERCOCET, PRIMLEV, PROLATE, QDOLO, REMIFENTANIL HCL, ROXICODONE, ROXYBOND, SUFENTANIL CITRATE, TRAMADOL HCL, TRAMADOL HCL-ACETAMINOPHEN, TREZIX, ULTIVA
Selected Benzodiazepines/Barbiturates SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Barbiturates and phenobarbital, CYP3A4 inducers, may induce the metabolism of some benzodiazepines. In addition, barbiturates, phenobarbital and benzodiazepines are CNS depressants. Primidone is metabolized to phenobarbital. CLINICAL EFFECTS: Concurrent or recent use of barbiturates or phenobarbital may result in decreased levels and loss of effectiveness of some benzodiazepines. Concurrent use of barbiturates and benzodiazepines may result in additive CNS depression (e.g. respiratory depression, increased somnolence). PREDISPOSING FACTORS: Induction effects may be more likely with regular use of the inducer for longer than 1-2 weeks. PATIENT MANAGEMENT: Monitor patients receiving phenobarbital or who have received doses in the previous 2 weeks for decreased benzodiazepine effectiveness. The dose of the benzodiazepine may need to be adjusted or an alternative agent used. Patients on chronic benzodiazepine therapy who are started on phenobarbital should be initially monitored for additive CNS sedation or respiratory depression, particularly when predisposing factors (e.g. COPD, sleep apnea, debilitation, elderly) are present. Continued use of phenobarbital leads to induction of benzodiazepine metabolism. The onset is gradual and may not peak for several weeks. If phenobarbital is discontinued, benzodiazepine levels will gradually rise as induction effects diminish. Monitor for increased benzodiazepine effects and adjust the dose accordingly. DISCUSSION: In a study in 95 healthy subjects, rifampin, a CYP3A4 inducer (450 mg daily for 5 days), decreased the plasma concentrations of a single oral dose of alprazolam (1 mg) by 79%.(1) In another study in 4 healthy subjects, rifampin (given for 4 days) decreased the area-under-curve (AUC) of a single oral dose of alprazolam (1 mg) by 88%.(2) In a double-blind, randomized, cross-over trial in 13 healthy subjects, rifampin (450 mg daily for 7 days) decreased the maximum concentration (Cmax), area-under-curve (AUC), and half-life of a single oral dose of brotizolam (0.5 mg) by 69%, 90%, and 69%, respectively. Concurrent rifampin increased scores on the Digit Symbol Substitution Test (DSST) and decreased scores on the Stanford Sleepiness Scale.(3) In a study in 21 healthy subjects, rifampin (600 mg or 1200 mg daily for 7 days) increased total body clearance of diazepam by 300%.(4) An in vitro study in human hepatocytes found that rifampin increased the biotransformation of diazepam and midazolam by 1.9-fold.(5) In a study in 24 healthy subjects, rifampin (600 mg daily for 10 days) increased the clearance of a single intravenous dose of lorazepam by 140%.(6) In an open-label cross-over study in 19 healthy subjects, rifampin (600 mg daily for 9 days) increased the clearance of a single oral dose of midazolam (0.075 mg/kg) by 7-fold.(7) In a study in 57 healthy subjects, rifampin increased the systemic and oral clearance of midazolam by 2-fold and 16-fold, respectively.(8) In a study in 8 healthy subjects, rifampin (given for 6 days) significantly increased the clearance of midazolam.(9) In a study in 9 healthy subjects, received a single oral dose of midazolam (15 mg) before, one day after the administration of rifampin (600 mg daily for 5 days), and 4 days after the last dose of rifampin. One day after rifampin, the AUC of midazolam was decreased by 97.7% when compared to the administration of midazolam prior to rifampin. Four days after the completion of rifampin, the AUC of midazolam was decreased by 87% when compared to the administration of midazolam prior to rifampin.(10) In a double-blind, randomized, cross-over study in 10 healthy subjects, rifampin (600 mg daily for 5 days) decreased the Cmax, AUC, and half-life of a single oral dose of midazolam (15 mg) by 94%, 96%, and 58%, respectively. The pharmacodynamic effects of midazolam were also significantly decreased during rifampin therapy.(11) In a study in 16 healthy subjects, rifampin (600 mg daily for 7 days) increased the clearance of nitrazepam by 83%. There were no significant effects on the pharmacokinetics of temazepam.(12) In a randomized, double-blind, cross-over study in 10 healthy subjects, rifampin (600 mg daily for 5 days) decreased the Cmax, AUC, and half-life of a single dose of triazolam (0.5 mg) by 87.6%, 94.9%, and 54%, respectively. The pharmacodynamic effects of triazolam were also significantly decreased during rifampin therapy.(13) In an open-label, randomized, cross-over study in 27 healthy subjects, rifaximin (200 mg three times daily for 7 days) had no effect on the pharmacokinetics of single doses of oral or intravenous midazolam.(14) In a study in 98 patients with schizophrenia or bipolar disorder, the expression of CYP3A4 was found to be the major determinant of clonazepam plasma concentrations normalized by the dose and bodyweight (1263 +/- 482.9 and 558.5 +/- 202.4 ng/mL per mg/kg bodyweight in low and normal expressers, respectively, p<0.0001).(18)	ASA-BUTALB-CAFFEINE-CODEINE, ASCOMP WITH CODEINE, BUTALB-ACETAMINOPH-CAFF-CODEIN, BUTALBITAL, BUTALBITAL-ACETAMINOPHEN, BUTALBITAL-ACETAMINOPHEN-CAFFE, BUTALBITAL-ASPIRIN-CAFFEINE, DONNATAL, FIORICET, FIORICET WITH CODEINE, MYSOLINE, PENTOBARBITAL SODIUM, PHENOBARBITAL, PHENOBARBITAL SODIUM, PHENOBARBITAL-BELLADONNA, PHENOBARBITAL-HYOSC-ATROP-SCOP, PHENOHYTRO, PRIMIDONE, SEZABY, TENCON
Midazolam/Letermovir SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Letermovir is a moderate inhibitor of CYP3A4 and may decrease metabolism of midazolam.(1) CLINICAL EFFECTS: Concurrent administration of letermovir and midazolam, metabolized by CYP3A4, may result in increased clinical effects (e.g. profound sedation, respiratory depression, coma, and/or death) of midazolam. CYP3A4 is the major or only hepatic metabolism pathway for the phase I elimination of midazolam. PREDISPOSING FACTORS: Concurrent use with cyclosporine. PATIENT MANAGEMENT: Caution is advised when midazolam is administered with drugs known to inhibit CYP3A4, such as letermovir.(1) Benzodiazepines that do not undergo extensive CYP hepatic metabolism (e.g. lorazepam, oxazepam) may be an alternative in letermovir patients. When letermovir is coadministered with cyclosporine, the combined effect on midazolam may be similar to a strong CYP3A4 inhibitor. Monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a study, concomitant administration of letermovir (480 mg once daily) with midazolam (1 mg single dose intravenous) increased the midazolam area under the curve (AUC) and C24hr by 1.47-fold and 2.74-fold, respectively. Concomitant administration of letermovir (480 mg once daily) with midazolam (2 mg single dose oral) increased the midazolam AUC and maximum concentration (Cmax) by 2.25-fold and 1.72-fold.(1)	PREVYMIS
Selected Opioids for MAT/Benzodiazepines SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Concurrent use of diacetylmorphine or methadone and benzodiazepines may result in additive CNS depression.(1,2) Levomethadone is an enantiomer of methadone.(3) CLINICAL EFFECTS: Concurrent use of diacetylmorphine or methadone and other CNS depressants, such as benzodiazepines, may result in profound sedation, respiratory depression, coma, and/or death.(1,2) PREDISPOSING FACTORS: Concurrent use of alcohol or other CNS depressants may increase the risk of adverse effects. PATIENT MANAGEMENT: Medication assisted treatment (MAT) with diacetylmorphine or methadone is not contraindicated in patients taking benzodiazepines or other CNS depressants; however, discontinuation of benzodiazepines and other CNS depressants is preferred in most cases. In some cases, monitoring at a higher level of care for tapering may be appropriate. In others, gradual tapering or decreasing to the lowest effective dose of the benzodiazapine or CNS depressant is appropriate. Consider other medications and nonpharmacologic treatments to address anxiety or insomnia. Ensure that other health care providers prescribing benzodiazepines or other CNS depressants are aware of the patient's methadone treatment.(4) Respiratory depression can occur at any time during opioid therapy, especially during therapy initiation and following dosage increases. Consider this risk when using concurrently with other agents that may cause CNS depression.(5) Monitor patients receiving concurrent therapy for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.(1) Educate patients about the risks of concurrent use and monitor for use of prescribed and illicit benzodiazepines or other CNS depressants.(4) Discuss naloxone with all patients when prescribing or renewing an opioid analgesic or medicine to treat opioid use disorder (OUD). Consider prescribing naloxone to patients prescribed medicines to treat OUD or opioid analgesics (such as those taking CNS depressants) who are at increased risk of opioid overdose and when a patient has household members/close contacts at risk for accidental overdose.(6) DISCUSSION: Between 2002 and 2014, the number of patients receiving an opioid analgesic increased 8%, from 75 million to 81 million patients, and the number of patients receiving a benzodiazepine increased 31%, from 23 million to 30 million patients. During this time, the proportion of patients receiving concurrent therapy increased 31%, from 23 million to 30 million patients.(7) From 2004 to 2011, the rate of nonmedical use-related emergency room visits involving both opioids and benzodiazepines increased from 11 to 34.2 per 100,000 and drug overdose deaths involving both opioids and benzodiazepines increased from 0.6 to 1.7 per 100,000. The proportion of prescription opioid analgesic deaths which also involved benzodiazepines increased from 18% to 31% during this time.(8) A prospective observational cohort study in North Carolina found that the rates of overdose death among patients co-dispensed opioid analgesics and benzodiazepines were 10 times higher than patients receiving opioid analgesics alone.(9) A case-cohort study of VA data from 2004-2009 found that the risk of death from overdose increased with concomitant opioid analgesics and benzodiazepines. Compared to patients with no history of benzodiazepines, patients with a history of benzodiazepine use (hazard ratio [HR] = 2.33) and patients with a current benzodiazepine prescription (HR=3.86) had an increased risk of fatal overdose.(10) A study found that opioid analgesics contributed to 77% of deaths in which benzodiazepines were determined to be a cause of death and that benzodiazepines contributed to 30% of deaths in which opioid analgesics were determined to be a cause of death. This study also found that other CNS depressants (including barbiturates, antipsychotic and neuroleptic drugs, antiepileptic and antiparkinsonian drugs, anesthetics, autonomic nervous system drugs, and muscle relaxants) were contributory to death in many cases where opioid analgesics were also implicated.(11) A study found that alcohol was involved in 18.5% of opioid analgesic abuse-related ED visits and 22.1 percent of opioid analgesic-related deaths.(12) A study of 315,428 privately insured patients who filled at least one prescription for an opioid from 2001 to 2013 were enrolled in a retrospective study. Concurrent use of a benzodiazepine was recorded as having at least one day of overlap in a given calendar year. Baseline characteristics among opioid users with concurrent use of a benzodiazepine were older (44.5 v. 42.4, p<0.001), less likely to be men (35% v. 43%, p<0.001), and had a higher prevalence rate of every comorbidity examined (p<0.001). The proportion of opioid users with concurrent benzodiazepine use nearly doubled from 9% in 2001 to 17% in 2013. The primary outcome was an emergency room visit or inpatient admission for opioid overdose within a calendar year. Among all opioid users, the annual adjusted incidence for the primary outcome was 1.16% without concurrent benzodiazepine use compared to 2.42% with concurrent benzodiazepine use (OR 2.14; 95% CI 2.05-2.24; p<0.001). Intermittent opioid users (1.45% v. 1.02%; OR 1.42; 95% CI 1.33-1.51; p<0.001) and chronic opioid users (5.36% v. 3.13%; OR 1.81; 95% CI 1.67-1.96; p<0.001) also experienced a higher adjusted incidence of the primary outcome with concurrent benzodiazepine use compared to without concurrent benzodiazepine use, respectively.(13) In a nested case-control study of adults with a new opioid dispensing between 2010-2018, patients with concurrent use of an opioid with a benzodiazepine were significantly more likely to have opioid-related overdose compared to patients receiving opioids, benzodiazepines, or neither (OR 9.28; 95% CI 7.87, 10.93). Longer concurrent use of 1-7, 8-30, and 31-90 days was associated with 4.6, 12.1, and 26.7-fold higher likelihood of opioid-related overdose (p<0.01). Patients with overlapping prescriptions during previous 0-30, 31-60, and 61-90 days were 13.2, 6.0, and 3.2-times more likely to experience an overdose (p<0.01).(14) While concomitant use of MAT with CNS depressants increases the risk of adverse reactions, barriers to MAT can pose a greater risk of morbidity and mortality due to opioid use disorder.(4)	DISKETS, METHADONE HCL, METHADONE INTENSOL, METHADOSE
Selected Benzodiazepines/Idelalisib SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Idelalisib may inhibit the metabolism of benzodiazepines that are metabolized by CYP3A4.(1) CLINICAL EFFECTS: Inhibition of benzodiazepine CYP3A4 metabolism by idelalisib may produce increased levels of, as well as increased clinical effects, of benzodiazepines. Toxic effects of increased benzodiazepine levels include profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The manufacturer of idelalisib says to avoid coadministration with sensitive CYP3A substrates.(1) The manufacturers of some benzodiazepines (i.e., clonazepam, diazepam, estazolam, midazolam) advise caution when they are coadministered with inhibitors of CYP3A4 and to consider dose reduction of the benzodiazepine.(2-6) Monitor patients receiving concurrent therapy with idelalisib and benzodiazepines carefully for increased effects including unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a study of 12 healthy subjects, multiple doses of idelalisib (150 mg twice daily) increased the area-under-curve (AUC) and maximum concentration (Cmax) of midazolam 5 mg by 437 % and 138 %, respectively.(6) In a case report, a 71-year-old female on diazepam as needed was started on idelalisib 150 mg twice daily. She presented in the emergency room ten days later with altered mental status and respiratory failure, which resolved after discontinuation of idelalisib and diazepam. Other causes of her symptoms were ruled out and although the patient's other medications may have been contributory, idelalisib potentiation of diazepam's effects was thought to be the primary cause.(7) Benzodiazepines linked to this monograph include: brotizolam, chlordiazepoxide, clonazepam, clorazepic acid, diazepam, estazolam, etizolam, flunitrazepam, flurazepam, halazepam, midazolam, prazepam, and quazepam.	ZYDELIG
Benzodiazepines/Selected Stimulants SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Benzodiazepines and stimulants exhibit opposing effects on the CNS. CLINICAL EFFECTS: Concurrent use of benzodiazepine and stimulants may have unpredictable effects and may mask overdose symptoms of the benzodiazepine, such as drowsiness and inability to focus. PREDISPOSING FACTORS: Concurrent use of alcohol or other CNS depressants may increase the risk of adverse effects. PATIENT MANAGEMENT: Limit prescribing benzodiazepines with CNS stimulants such as amphetamines to patients for whom alternatives are inadequate. If concurrent use is necessary, limit the dosages and duration of each drug to the minimum possible while achieving the desired clinical effect. Monitor patients receiving concurrent therapy for signs of substance abuse. DISCUSSION: Analysis of the 2015 and 2016 National Survey on Drug Use and Health found that misuse of benzodiazepines was strongly associated with misuse of or dependences on stimulants.(1) Benzodiazepines are used to reduce the adverse effects of stimulant use, such as insomnia.(2) Patients abusing benzodiazepines in combination with other drugs tend to consume higher dosages of benzodiazepines than patients abusing only benzodiazepines.(3)	ADDERALL, ADDERALL XR, ADZENYS XR-ODT, AMPHETAMINE SULFATE, APTENSIO XR, AZSTARYS, CONCERTA, COTEMPLA XR-ODT, DAYTRANA, DESOXYN, DEXEDRINE, DEXMETHYLPHENIDATE HCL, DEXMETHYLPHENIDATE HCL ER, DEXTROAMPHETAMINE SULFATE, DEXTROAMPHETAMINE SULFATE ER, DEXTROAMPHETAMINE-AMPHET ER, DEXTROAMPHETAMINE-AMPHETAMINE, DYANAVEL XR, EVEKEO, FOCALIN, FOCALIN XR, JORNAY PM, LISDEXAMFETAMINE DIMESYLATE, METADATE CD, METADATE ER, METHAMPHETAMINE HCL, METHYLIN, METHYLPHENIDATE, METHYLPHENIDATE ER, METHYLPHENIDATE ER (LA), METHYLPHENIDATE HCL, METHYLPHENIDATE HCL CD, METHYLPHENIDATE HCL ER (CD), MYDAYIS, PROCENTRA, QUILLICHEW ER, QUILLIVANT XR, RELEXXII, RITALIN, RITALIN LA, VYVANSE, XELSTRYM, ZENZEDI
Gabapentinoids/Benzodiazepines SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Concurrent use may result in profound sedation, respiratory depression, coma, and/or death.(1-3) CLINICAL EFFECTS: Concurrent use of benzodiazepines may result in elevated levels of and toxicity from gabapentin and pregabalin, including profound sedation, respiratory depression, coma, and/or death.(1-3) PREDISPOSING FACTORS: Patients who are elderly, are taking other CNS depressants, have decreased renal function, and/or have conditions that reduce lung function (e.g. Chronic Obstructive Pulmonary Disease [COPD]) may be at a higher risk of this interaction. PATIENT MANAGEMENT: Limit prescribing benzodiazepines and gabapentinoids to patients for whom alternatives are inadequate.(1) If concurrent use is necessary, limit the dosages and duration of each drug to the minimum possible while achieving the desired clinical effect. If starting a gabapentinoid with an benzodiazepine, prescribe a lower initial dose of the gabapentinoid than indicated in the absence of an opioid and titrate based upon clinical response. If a benzodiazepine is indicated (other than an indication of epilepsy) in a patient already taking a gabapentinoid, prescribe a lower dose of the benzodiazepine and titrate based upon clinical response.(1) Monitor patients receiving concurrent therapy for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness.(1) DISCUSSION: Clinical trials have shown no pharmacokinetic interaction between pregabalin (300 mg BID) and lorazepam (1 mg single dose).(2) Among 49 case reports submitted to FDA over a 5 year period (2012-2017), 12 people died from respiratory depression with gabapentinoids. Two randomized, double-blind, placebo-controlled clinical trials in healthy people, three observational studies, and several studies in animals were reviewed. A trial showed that using pregabalin alone and using it with an opioid pain reliever can depress breathing function. Three observational studies showed a relationship between gabapentinoids given before surgery and respiratory depression occurring after surgery. Several animal studies also showed that pregabalin plus opioids can depress respiratory function. Benzodiazepines are expected to have a similar effect when used with gabapentinoids.(1)	GABAPENTIN, GABAPENTIN ER, GABARONE, GRALISE, HORIZANT, LYRICA, LYRICA CR, NEURONTIN, PREGABALIN, PREGABALIN ER
Selected Benzodiazepines/Protease Inhibitors SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Protease inhibitors may inhibit the metabolism of benzodiazepines that are metabolized by CYP3A4.(1) CLINICAL EFFECTS: Inhibition of benzodiazepine CYP3A4 metabolism by protease inhibitors may produce increased levels of, as well as increased clinical effects, of benzodiazepines. Toxic effects of increased benzodiazepine levels include profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The NIH Guidelines for Use of Antiretroviral Agents advise considering use of alternative benzodiazepines that do not undergo CYP metabolism, like lorazepam, oxazepam, and temazepam.(1) The manufacturers of the protease inhibitors recommend close clinical monitoring for respiratory depression and/or prolonged sedation and consideration of dosage adjustment of the benzodiazepine.(2-5) The manufacturers of some benzodiazepines (i.e., diazepam, estazolam, midazolam) advise caution when they are coadministered with inhibitors of CYP3A4 and to consider dose reduction of the benzodiazepine.(6-8) Monitor patients receiving concurrent therapy with protease inhibitors and benzodiazepines carefully for increased effects including unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: The interaction between most benzodiazepines and protease inhibitors has not been studied. Benzodiazepines are primarily metabolized by CYP3A4 and CYP2C19. Protease inhibitors are moderate to strong inhibitors of CYP3A4, and an elevation in benzodiazepine effects and concentrations with concomitant therapy can be expected. Benzodiazepines linked to this monograph include: brotizolam, chlordiazepoxide, clonazepam, clorazepic acid, diazepam, estazolam, etizolam, flunitrazepam, flurazepam, halazepam, non-oral midazolam, prazepam, and quazepam. Protease inhibitors linked to this monograph include: ritonavir-boosted lopinavir, nirmatrelvir, saquinavir, tipranavir; cobicistat- or ritonavir-boosted darunavir; cobicistat-boosted, ritonavir-boosted or unboosted atazanavir; ritonavir-boosted or unboosted amprenavir, fosamprenavir, indinavir; and nelfinavir.	APTIVUS, ATAZANAVIR SULFATE, DARUNAVIR, EVOTAZ, FOSAMPRENAVIR CALCIUM, KALETRA, LOPINAVIR-RITONAVIR, PAXLOVID, PREZCOBIX, PREZISTA, REYATAZ, SYMTUZA, VIRACEPT
Selected Benzodiazepines/Fluconazole; Voriconazole SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Fluconazole and voriconazole may inhibit the metabolism of benzodiazepines by CYP3A4. CLINICAL EFFECTS: The concurrent administration of fluconazole or voriconazole with benzodiazepines metabolized by CYP3A4 may result in elevated levels of and increased clinical effects from the benzodiazepines. Toxic effects of increased levels of benzodiazepines include profound sedation, respiratory depression, coma, and/or death. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: Patients receiving concurrent therapy with fluconazole or voriconazole should be monitored for increased benzodiazepine effects. The dosage of the benzodiazepine may need to be decreased or the benzodiazepine may need to be discontinued. If concurrent use is necessary, monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: In a study in 12 healthy subjects, pretreatment with fluconazole (400 mg twice daily Day 1, 200 mg twice daily Day 2) increased the area-under-curve (AUC) and half-life of a single dose of diazepam (5 mg) by 2.5-fold and 1.4-fold, respectively. Pharmacodynamic effects were increased slightly.(1) In a study in 12 healthy subjects, pretreatment with voriconazole (400 mg twice daily Day 1, 200 mg twice daily Day 2) increased the AUC and half-life of a single dose of diazepam (5 mg) by 2.2-fold and 100%, respectively. Pharmacodynamic effects were increased slightly.(1) A study in 10 patients showed that fluconazole (400 mg initially, then 200 mg intravenously) increased intravenous midazolam concentrations by 0-4-fold.(2) A study in nine subjects showed that fluconazole (400 mg) increased the midazolam AUC, maximum concentration (Cmax), and half-life by 2-3 fold, 2-2.5-fold, and 2.5-fold, respectively. The pharmacokinetic changes were larger when fluconazole was given orally when compared to intravenous fluconazole. Both oral and intravenous fluconazole increased the pharmacodynamic effects.(3) A study in 12 subjects showed that the AUC of oral midazolam increased 3.6-fold during fluconazole therapy.(4) One study found that a single, 150 mg dose of fluconazole did not significantly effect midazolam pharmacokinetics.(5) Fluconazole has also been shown to inhibit the metabolism of midazolam in vitro.(6) In a randomized, cross-over study in 10 healthy male volunteers, voriconazole (400 mg twice daily on the first day and 200 mg twice daily on the second day) reduced the clearance on intravenous midazolam (0.05 mg/kg) by 72% and increased its elimination half-life by 3-fold. Voriconazole increased the mean Cmax and the AUC of oral midazolam (7.5 mg) by 3.8 and 10.3-fold, respectively. Voriconazole also prolonged the half-life of oral midazolam by 3.5-fold, and increased the oral bioavailability of midazolam by 2.7-fold. Voriconazole profoundly increased the psychomotor effects of oral midazolam but only weakly increased the effects of intravenous midazolam.(7) In a study in 12 healthy subjects, fluconazole had no significant effects on the pharmacokinetics or pharmacodynamics of oral or rectal bromazepam.(8)	DIFLUCAN, FLUCONAZOLE, FLUCONAZOLE-NACL, VFEND, VFEND IV, VORICONAZOLE
Midazolam; Triazolam/Lenacapavir SEVERITY LEVEL: 3-Moderate Interaction: Assess the risk to the patient and take action as needed. MECHANISM OF ACTION: Lenacapavir is a moderate inhibitor of CYP3A4 and may decrease metabolism of midazolam and triazolam.(1-3) CLINICAL EFFECTS: Concurrent administration of lenacapavir and midazolam or triazolam may result in increased clinical effects (e.g. profound sedation, respiratory depression, coma, and/or death) of midazolam or triazolam.(1-3) CYP3A4 is the major or only hepatic metabolism pathway for the phase I elimination of midazolam. PREDISPOSING FACTORS: None determined. PATIENT MANAGEMENT: The manufacturer of lenacapavir states concurrent use with midazolam or triazolam should be approached with caution.(1-3) Monitor patients for unusual dizziness or lightheadedness, extreme sleepiness, slowed or difficult breathing, or unresponsiveness. DISCUSSION: Concurrent administration of lenacapavir 600 mg with a single 2.5 mg dose of midazolam increased midazolam maximum concentration (Cmax) and area-under-curve (AUC) by 1.94-fold and 3.59-fold, respectively.(1-3)	SUNLENCA

The following contraindication information is available for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl):

Overview
Contraindicated
Severe
Moderate

Drug contraindication overview.

*Patients in whom substantial blood pressure elevation would constitute a serious hazard. *Known hypersensitivity to ketamine or any ingredient in the formulation. *Some experts state that relative contraindications may include history of airway instability, tracheal surgery, or tracheal stenosis; active pulmonary infection or disease; known or suspected cardiovascular disease (e.g., angina, congestive heart failure (CHF), hypertension); CNS masses, abnormalities, or hydrocephalus; elevated intraocular pressure (IOP) (e.g., glaucoma, acute globe injury); and porphyria, hyperthyroidism, or concomitant thyroid replacement therapy.

There are 3 contraindications. Absolute contraindication.

Contraindication List
Acute decompensated heart failure
Angle-closure glaucoma
Severe uncontrolled hypertension

There are 10 severe contraindications. Adequate patient monitoring is recommended for safer drug use.

Severe List
Acute renal failure
Cardiac decompensation
Chronic obstructive pulmonary disease
Coma
Delirium
Drug abuse
Hemodynamic instability
Pregnancy
Respiratory depression
Shock

There are 8 moderate contraindications. Clinically significant contraindication, where the condition can be managed or treated before the drug may be given safely.

Moderate List
Acute cognitive impairment
Alcohol intoxication
Alcohol use disorder
Chronic heart failure
Hepatic cirrhosis
Increased cerebrospinal fluid pressure
Ocular hypertension
Peripheral vasoconstriction

The following adverse reaction information is available for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl):

Overview
Severe
Less Severe

Adverse reaction overview.

The most common adverse reactions with ketamine are emergence reactions and elevated blood pressure and pulse.

There are 58 severe adverse reactions.

More Frequent	Less Frequent
Hypertension Respiratory depression Tachycardia	Bradycardia Hypotension Hypoxia

Rare/Very Rare
Abnormal ECG Abnormal hepatic function tests Acquired dilation of bile duct Acute hepatic failure Acute kidney injury Allergic dermatitis Anaphylaxis Angioedema Apnea Atrial fibrillation Bradycardia Bronchospastic pulmonary disease Cardiac arrhythmia Cholestasis Cholestatic hepatitis Cystitis Delirium Drug-induced hepatitis Dyspnea Excitement Extrapyramidal disease Heart block Hematuria Hepatic fibrosis Hepatocellular damage Hydronephrosis Hypercapnia Hypotension Hypoventilation Hypoxia Increased cerebrospinal fluid pressure Irritability Laryngeal edema Laryngismus Myocardial ischemia Nervousness Oculogyric crisis Prolonged QT interval Pruritus of skin Respiratory depression Shock Stevens-johnson syndrome Supraventricular tachycardia Tachycardia Torsades de pointes Toxic epidermal necrolysis Transient blindness Tremor Urticaria Ventricular premature beats Viral infection Wheezing

Rare/Very Rare

Abnormal ECG
Abnormal hepatic function tests
Acquired dilation of bile duct
Acute hepatic failure
Acute kidney injury
Allergic dermatitis
Anaphylaxis
Angioedema
Apnea
Atrial fibrillation
Bradycardia
Bronchospastic pulmonary disease
Cardiac arrhythmia
Cholestasis
Cholestatic hepatitis
Cystitis
Delirium
Drug-induced hepatitis
Dyspnea
Excitement
Extrapyramidal disease
Heart block
Hematuria
Hepatic fibrosis
Hepatocellular damage
Hydronephrosis
Hypercapnia
Hypotension
Hypoventilation
Hypoxia
Increased cerebrospinal fluid pressure
Irritability
Laryngeal edema
Laryngismus
Myocardial ischemia
Nervousness
Oculogyric crisis
Prolonged QT interval
Pruritus of skin
Respiratory depression
Shock
Stevens-johnson syndrome
Supraventricular tachycardia
Tachycardia
Torsades de pointes
Toxic epidermal necrolysis
Transient blindness
Tremor
Urticaria
Ventricular premature beats
Viral infection
Wheezing

There are 68 less severe adverse reactions.

More Frequent	Less Frequent
Acute cognitive impairment Constipation Delirium Diarrhea Drowsy Fever Hallucinations Headache disorder Malaise Sedation Tremor	Agitation Behavioral disorders Diplopia Dizziness Dream disorder Drowsy Erythema Fatigue General weakness Hiccups Hypertonia Memory impairment Nausea Pruritus of skin Skin rash Symptoms of anxiety Tachypnea Urinary retention Vomiting

Rare/Very Rare
Accidental fall Aggressive behavior Agitation Angina Anorexia Anticholinergic toxicity Ataxia Blurred vision Cough Dizziness Drowsy Dysarthria Dysphoric mood Dysuria Hallucinations Headache disorder Hiccups Increased urinary frequency Injection site sequelae Mood changes Muscle spasm Nausea Nystagmus Ocular hypertension Palpitations Paresthesia Rhinorrhea Sialorrhea Skin rash Sneezing Stridor Syncope Urinary urge incontinence Urticaria Ventricular tachycardia Vertigo Visual changes Xerostomia

Rare/Very Rare

Accidental fall
Aggressive behavior
Agitation
Angina
Anorexia
Anticholinergic toxicity
Ataxia
Blurred vision
Cough
Dizziness
Drowsy
Dysarthria
Dysphoric mood
Dysuria
Hallucinations
Headache disorder
Hiccups
Increased urinary frequency
Injection site sequelae
Mood changes
Muscle spasm
Nausea
Nystagmus
Ocular hypertension
Palpitations
Paresthesia
Rhinorrhea
Sialorrhea
Skin rash
Sneezing
Stridor
Syncope
Urinary urge incontinence
Urticaria
Ventricular tachycardia
Vertigo
Visual changes
Xerostomia

The following precautions are available for MKO (MIDAZOLAM-KETAMINE-ONDAN) (midazolam/ketamine hcl/ondansetron hcl):

Pediatric
Pregnant
Lactation
Geriatric

Although the manufacturer states that safety and efficacy of ketamine have not been established in patients younger than 16 years of age, the drug has been used widely in pediatric patients+ in a variety of clinical settings for anesthesia, procedural sedation and analgesia, postoperative analgesia, and chronic pain management. Ketamine frequently is used in children to facilitate painful procedures in the emergency department and is considered a drug of choice for this use. Ketamine may be particularly useful in pediatric patients because the drug may be administered IM.

Repeated or prolonged use of general anesthetics and sedation drugs, including ketamine, in children <3 years of age or during the third trimester of pregnancy may adversely affect neurodevelopment. In animals, use of anesthetic and sedation drugs that block NMDA receptors and/or potentiate GABA activity leads to widespread neuronal apoptosis in the brain and long-term deficits in cognition and behavior when used for longer than 3 hours; however, the clinical relevance to humans is unknown. Ketamine may be preferred for induction of anesthesia in children with congenital heart disease with right-to-left shunt+ because of its sympathomimetic effects and hemodynamic stability.

Ketamine generally should not be used in infants younger than 3 months of age because of the potential increased risk of airway complications (e.g., airway obstruction, laryngospasm, apnea) thought to be due to age-specific differences in airway reactivity and anatomy.

Contraindicated

None

Severe Precaution

None

Management or Monitoring Precaution

None

Reproduction studies in rats and rabbits receiving oral ondansetron dosages up to 15 and 30 mg/kg daily, respectively, and IV ondansetron dosages up to 4 mg/kg daily (approximately 1.4 and 2.9 times, respectively, the recommended human IV dosage of 0.15 mg/kg given 3 times daily (calculated on the basis of body surface area)) have not revealed evidence of harm to the fetus. There are no adequate and controlled studies to date using ondansetron in pregnant women, and the drug should be used during pregnancy only when clearly needed. An increased risk of congenital malformations associated with the use of benzodiazepines (e.g., chlordiazepoxide, diazepam) during pregnancy has been suggested by several retrospective studies in humans.

Midazolam has been shown to cross the placenta in humans. Reproduction studies in rabbits and rats using IV midazolam in doses up to 1.85 times the human induction dose have not revealed evidence of fetal malformation.

If the drug is administered during pregnancy, the patient should be informed of the potential hazard to the fetus. Use of midazolam injection for obstetric procedures or during labor and delivery is not recommended, since such use has not been evaluated and use of other benzodiazepines during the last weeks of pregnancy has caused CNS depression in the neonate. Based on animal data, repeated or prolonged use of general anesthetics and sedation drugs, including midazolam, during the third trimester of pregnancy may result in adverse neurodevelopmental effects in the fetus.

The clinical relevance of these animal findings to humans is not known; the potential risk of adverse neurodevelopmental effects should be considered and discussed with pregnant women undergoing procedures requiring general anesthetics and sedation drugs. There are no adequate and well-controlled studies of ketamine in pregnant women. Although ketamine has been used for induction of anesthesia during vaginal delivery and caesarean sections, the manufacturer states that the drug is not recommended for use during pregnancy or delivery because safety has not been established.

Some neonates exposed to ketamine at maternal IV doses of 1.5 mg/kg or higher during delivery have experienced respiratory depression and low Apgar scores requiring resuscitation. Marked increases in maternal blood pressure and uterine tone have been observed following administration of IV ketamine doses greater than 2 mg/kg.

In animal reproduction studies using IM ketamine doses approximately 0.3-0.6 times the usual human IM dose of 10 mg/kg (based on body surface area), developmental delays, skeletal hypoplasia, and increased fetal resorptions were observed.

Based on animal data, repeated or prolonged use of general anesthetics and sedation drugs, including ketamine, during the third trimester of pregnancy may result in adverse neurodevelopmental effects in the fetus. The clinical relevance of these animal findings to humans is not known; the potential risk of adverse neurodevelopmental effects should be considered and discussed with pregnant women undergoing procedures requiring general anesthetics and sedation drugs.

It is not known whether ondansetron is distributed into human milk; however, the drug is distributed into the milk of lactating rats. Because many drugs are distributed in human milk, ondansetron should be used with caution in nursing women. Midazolam is distributed into milk in humans, and caution should be exercised when midazolam is administered to nursing women.

It is not known whether ketamine is distributed into milk. Because the drug should be undetectable in plasma approximately 11 hours after administration, nursing after this time period should not expose the infant to clinically relevant amounts of ketamine.

While reported clinical experience to date has not revealed age-related differences in response to ketamine when used as an anesthetic agent, clinical studies have not included sufficient numbers of patients >=65 years of age to determine whether geriatric patients respond differently than younger adults. When ketamine is used as an anesthetic agent in geriatric patients, the dosage should be selected carefully, usually starting at the low end of the dosing range, because of the greater frequency of age-related decreases in hepatic, renal, and/or cardiac function, and of concomitant disease or other drug therapy.