Abstract
The most commonly prescribed opioids in the United States are formulations containing hydrocodone and acetaminophen. Opioids, such as hydrocodone, oxycodone, and codeine, are combined with nonopioid analgesics including aspirin, ibuprofen, or acetaminophen. These commonly prescribed combination formulations create a potential problem by mixing an opioid that has no dose ceiling effect with acetaminophen or nonsteroidal antiinflammatory drugs (NSAIDs), which may cause toxicity beyond a certain dose.
The risk for acetaminophen and NSAID toxicity increases when over-the-counter acetaminophen or NSAIDs, such as ibuprofen, are taken with combination products containing an opioid and nonopioid analgesic. In 2009, the Food and Drug Administration (FDA) advisory committee recognized the public health burden associated with acetaminophen and voted in favor of eliminating prescription acetaminophen/opioid combination products. The FDA did not follow this recommendation but did require manufacturers to limit acetaminophen to 325 mg per dosage by January 2014.
Pharmacogenetic differences between patients can lead to significant variability in response to codeine, tramadol, oxycodone, and hydrocodone. Codeine and tramadol should not routinely be used to treat mild to moderate pain because a significant number of patients are poor CYP2D6 metabolizers and cannot metabolize the parent drug into the active metabolites required for analgesic effect. Patients who are poor CYP2D6 metabolizers and who are taking oxycodone or hydrocodone are at higher risk for significant drug interactions with medications that are CYP3A4 inhibitors. CYP3A4 inhibition in these patients can result in accumulation of oxycodone or hydrocodone leading to sedation and/or respiratory depression.
Keywords
codeine, CYP2D6 genotype, hydrocodone, oxycodone, tapentadol, tramadol
With 97 million prescriptions written in 2015 in the United States, the most commonly prescribed opioids are formulations combining the opioid (hydrocodone) with a nonopioid (acetaminophen). When opioids are administered with aspirin, acetaminophen, or ibuprofen, these medications are referred to as “weak opioids.” This is a misnomer referring to the limit to which they can be prescribed due to the restrictive dosing of the nonopioid component. For example, when a patient takes 12 hydrocodone/acetaminophen 10/325-mg tablets per day, they are receiving an impressive amount of opioid equivalent to approximately 180 mg oral morphine per day. These products may not provide the optimum opioid sparing effects that are desired by patients when compared to patients utilizing these medications in separate formulations. These commonly prescribed combination formulations create a potential problem by mixing an opioid that has no dose ceiling effect with acetaminophen or a nonsteroidal antiinflammatory drug (NSAID), which may cause toxicity beyond a certain dose. Patients are often unaware of the potential renal or hepatic toxicity from the nonopioid component and may take over-the-counter (OTC) acetaminophen along with their prescribed combination formulation containing an opioid with acetaminophen.
Acetaminophen-related adverse events are a significant public health burden with an average of 112,000 poison center calls, 59,000 emergency department visits, and 38,000 hospitalizations annually in the United States. Approximately half of all acetaminophen-related hepatotoxicity is caused by unintentional overdose, and 63% of these cases involve opioid combination products. The National Poison Data System annual report from 2012 listed acetaminophen combination products as the sixth highest cause of fatalities related to substance poisoning.
In 2009, a Food and Drug Administration (FDA) advisory committee voted in favor of eliminating prescription acetaminophen/opioid combination products, but the FDA has not followed this recommendation. In 2011, the FDA announced that manufacturers of prescription acetaminophen-combination products would be required to limit the amount of acetaminophen in products to 325 mg per tablet, capsule, or other dosage with a January 2014 deadline for implementation. By January 2014, over half of the pharmaceutical manufacturers had complied with this recommendation. The FDA said that it would begin proceedings to withdraw approval of prescription combination drug products that contain more than 325 mg acetaminophen per dosage unit that remained on the market; it completed those proceedings in March 2014.
There are few studies investigating the usual period of time that patients require opioid analgesics after surgery. As a result, clinicians are often unsure about the best quantity of opioids to prescribe for postoperative pain. A retrospective review of hydrocodone 5 mg and acetaminophen 500 mg (10 tablets 1 refill) prescriptions after orthopedic surgery (arthroscopies, anterior cruciate ligament, etc.) found 61% of patients did not refill their prescriptions and 89% required less than or equal to 20 tablets. In another study, 250 patients given 30 tablets of oxycodone, hydrocodone, or propoxyphene were interviewed about medication usage after outpatient upper extremity surgery. Overall, each patient reported about 19 unused tablets, leaving approximately 4700 unused tablets for the entire study population. Other investigators have shown that many patients use only 50% to 60% of their prescribed opioids after cesarean section, thoracic surgery, and urologic procedures. Further research is needed to determine the optimal number of opioid tablets to prescribe to patients with different sources of pain because unused tablets are often ingested by people other than the patient, thereby contributing to the current opioid overdose epidemic in the United States.
This chapter reviews the use of short-acting opioids, and provides the reader with a practical approach to using these medications in clinical practice. It also reviews significant pharmacokinetic and pharmacogenetic variables that can influence analgesic efficacy, toxicity, and clearance, as well as potential drug interactions.
Specific Short-Acting Opioids
Oxycodone
Oxycodone is found in the following branded combination products: Percocet, Roxicet Solution, Xartemis XR, Combunox, and Percodan. Oxycodone is a semisynthetic opioid processed from thebaine, an organic chemical found in opium. Oxycodone is available as an immediate-release tablet combined with acetaminophen, aspirin, or ibuprofen. It is also available as an immediate release (IR) solution and controlled-release tablet combined with acetaminophen. With so many formulations available, it is one of the most popular opioids in the United States. The popularity of oxycodone is, in some part, due to its suitability for oral administration due to high bioavailability (60%); oral oxycodone is 1.5 times more potent than oral morphine. Unfortunately, this property may also contribute to its abuse. Even though oxycodone in combination products has been placed in the more restricted Schedule II controlled substance category in the United States, its abuse has been a recurrent problem with law enforcement authorities. Clinicians also need to be aware that oxycodone is converted by P450 CYP2D6 hepatic enzymes to oxymorphone and P450 CYP3A4 to noroxycodone. Patients that are poor metabolizers at CYP2D6 are at risk for accumulation of oxycodone if they take a drug such as fluconazole, a moderate CYP3A4 inhibitor. Similarly, patients taking a strong CYP2D6 inhibitor (paroxetine) and strong CYP3A4 inhibitor (itraconazole) are at risk for the accumulation of oxycodone. It is less clear whether CYP2D6 phenotypes correlate with analgesia or risk of toxicity because physiologic effects correlate best with exposure to the parent compound, oxycodone.
Hydrocodone
Hydrocodone, an opium derivative, found in both combination products and single entity extended-release (ER) formulations was rescheduled from Schedule III to Schedule II on October 6, 2014 by the Drug Enforcement Administration. Hydrocodone is slightly less potent than oxycodone and is found in the following combination products: Norco, Hycet oral solution (hydrocodone and acetaminophen), and Vicoprofen (hydrocodone and ibuprofen). Clinicians need to be aware that hydrocodone is converted by P450 hepatic enzymes CYP2D6 to hydromorphone and CYP3A4 to norhydrocodone. Patients who are poor metabolizers at CYP2D6 are at risk for the accumulation of hydrocodone when given a potent CYP 3A4 inhibitor. A case report describing a fatal hydrocodone overdose provides evidence for the seriousness of drug interactions in patients that are poor metabolizers at CYP2D6. In this case, a young girl was given hydrocodone 3 times per day for cold symptoms, and clarithromycin for an ear infection. The patient used approximately 30 mg of hydrocodone over 24 hours along with clarithromycin, a potent CYP3A4 inhibitor. Postmortem hydrocodone blood concentration was 0.14 μg/mL, a concentration associated with fatality while the hydromorphone concentration was below the limit of detection 0.008 μg/mL (a finding expected in a poor metabolizer at CYP2D6). Postmortem analysis showed the patient had a CYP2D6 ∗ 2A/∗41 genotype, which is associated with poor metabolizer status. As pharmacogenetic testing becomes more widely available, pharmacists with access to this patient data will be able to anticipate significant pharmacogenetic–drug interactions and help clinicians manage them.
Codeine
Codeine has a very similar chemical structure to morphine, but has approximately 200 times less affinity for the mu-opioid receptor than morphine. Approximately 5% to 10% of codeine is metabolized via the hepatic microsomal enzyme cytochrome P450 2D6 to morphine. In patients with poor metabolizer phenotype at CYP 2D6 (∼5% to 10% of patients), there is greatly reduced morphine formation after codeine administration, leading to insufficient pain relief. In patients with ultrarapid metabolizer phenotype (∼1% to 2% of patients), there is greatly increased morphine formation after codeine administration, leading to a higher risk of toxicity. The FDA issued a Boxed Warning that codeine is contraindicated in children undergoing tonsillectomy and/or adenoidectomy because deaths have occurred postoperatively in children with obstructive sleep apnea who received codeine for pain relief following a tonsillectomy and/or adenoidectomy. These children had evidence of being ultrarapid metabolizers of codeine. When codeine (≤90 mg per dosage unit) is administered in combination with acetaminophen as an analgesic, it is placed in the Schedule III controlled substance category. This allows clinicians to prescribe codeine combination products with less regulatory restrictions than combination products containing oxycodone or hydrocodone. Many physicians view codeine as a safer analgesic than morphine as evidenced by the 13.2 million patients in the United States that received codeine-containing products in 2014. On December 10, 2015, an FDA advisory committee recommended codeine be contraindicated for pain and cough management in children and adolescents younger than 18 years of age due to concerns about respiratory depression and death.
Tramadol
Tramadol (Ultram) is a Schedule IV controlled substance and has a dual mechanism of action. Tramadol is a weak mu agonist and inhibits norepinephrine and serotonin reuptake. Tramadol is metabolized via CYP2D6 to the active metabolite O -desmethyl tramadol (M1). The parent compound is primarily responsible for norepinephrine and serotonin reuptake inhibition, whereas M1 is primarily responsible for mu agonistic properties. Tramadol has approximately 6000 times less affinity for mu receptors than morphine. M1 has approximately 300 times greater affinity for mu receptors than the parent drug. In contrast to tramadol and M1, tapentandol, which is discussed below, is a relatively strong opioid agonist and norepinephrine reuptake inhibitor. Patients who are poor CYP2D6 metabolizers form less M1 after tramadol administration, leading to inadequate pain relief. Patients who are ultrarapid CYP2D6 metabolizers produce an increased amount of M1 after tramadol administration, leading to higher risk of toxicities, such as respiratory depression and over-sedation. On September 21, 2015, the FDA issued a safety alert stating that the use of tramadol is under investigation when used in children 17 years and younger, due to increased risk for respiratory depression. This alert was in response to the case report of a 5-year-old who experienced difficulty breathing after one dose of tramadol. It was later discovered the child was an ultrarapid metabolizer of CYP2D6 and had high levels of M1. This risk may be increased in children following a tonsillectomy and/or adenoidectomy, or potentially after any other use in children. The risk of inadequate pain relief and toxicities can be reduced with preemptive genetic testing. Tramadol is mostly renally excreted (30% as unchanged drug and 60% as metabolites). In normal renal function, the maximum total daily dose is 400 mg. In severe renal dysfunction (CrCl less than 30 mL/min), the IR formulation should not exceed 200 mg/day, and the dosing interval should be increased to 12 hours. The ER formulation of tramadol should be avoided in patients with severe renal dysfunction.
Tapentadol
Tapentadol (Nucynta), a Schedule II controlled substance, is an opioid agonist and a norepinephrine reuptake inhibitor that works at both the ascending (excitatory) and descending (inhibitory) pathways. Tapentadol appears to be 2 to 3 times less potent than morphine, even though its binding affinity for opioid receptors is 50 times lower. Data suggest that 3.3 mg of oral tapentandol is equivalent to 1 mg of oral morphine equivalence in both opioid naïve and tolerant patients.
Currently tapentadol is available in both IR (50, 75, and 100 mg) and ER (50, 100, 150, 200, and 250 mg) formulations. It is more expensive compared to other generically available opioids. Tapentadol has been shown equal to and noninferior to equianalgesic doses of oxycodone and morphine with a lower incidence of gastrointestinal side effects, including vomiting and constipation. Tapentadol is generally well tolerated, but it may cause nausea, vomiting, dizziness, and drowsiness. Although tapentadol does not directly increase serotonin levels, data suggest norepinephrine reuptake inhibition may indirectly elevate serotonin. This is demonstrated by case reports of serotonin syndrome, implying that additional serotonergic drugs should be avoided when prescribing tapentadol. The IR formulation of tapentadol is FDA approved for moderate to severe acute pain, and has further shown efficacy for acute lower back pain and associated radicular leg pain, osteoarthritis pain, and postoperative pain secondary to dental and orthopedic surgeries. The ER formulation is FDA approved for diabetic peripheral neuropathy severe enough to require daily, long-term, around-the-clock opioid use, and when alternative treatments are inadequate. The ER formulation has shown efficacy for chronic lower back pain, osteoarthritis knee pain, and moderate to severe chronic malignant tumor pain. For acute moderate to severe pain, the IR formulation dose is 50 mg to 100 mg by mouth every 4 to 6 hours as needed. On the first day of therapy, a second dose may be administered one or more hours after the initial dose (maximum total daily dose is equal to 700 mg). Subsequential maximum total daily doses are 600 mg daily.
Clinicians should be aware of how to transition a patient from a long-acting opioid to ER tapentadol. A general approach is to discontinue all other long-acting opioids, and then initiate ER tapentadol at 50% of the patient’s current 24-hour oral morphine equivalence. Titration should be limited to 50 mg twice daily every 3 days until the most effective dose is achieved. During the titration process, an IR opioid may be used for breakthrough pain.
Renal dose adjustments are not required for creatinine clearances greater than or equal to 30 mL/min; however, tapentadol should be avoided if creatinine clearance is less than 30 mL/min.
Tapentadol is mostly metabolized to tapentadol- O -glucuronide via glucuronidation and, to a lesser degree, through oxidation via CYP2C9, CYP2C19, and CYP2D6 pathways. All metabolites are inactive. Hepatic dose adjustments are not required for mild dysfunction (Child–Pugh score 5 to 6). For moderate dysfunction (Child-Pugh score 7 to 9), the initial IR tapentadol dose should not exceed 50 mg by mouth every 8 hours, and the initial ER tapentadol dose should be limited to 50 mg by mouth once daily with a maximum ER dose of 100 mg daily. Tapentadol is not recommended for severe hepatic dysfunction (Child–Pugh score 10 to 15).