Indian Society for Study of Pain, Cancer Pain Special Interest Group Guidelines on Pharmacological Management of Cancer Pain (Part I)

Nonopioid analgesics – Step 1 of three-step World Health Organization analgesic ladder

Paracetamol and NSAIDs are the analgesics used for the management of cancer pain through any stage of the three-step WHO analgesic ladder. They are used alone, as a combination with adjuvants or in combination with opioids. Both medications have a “ceiling effect” or maximum therapeutic dose beyond which, the risk of toxicity increases with no additional analgesic benefits.

Paracetamol

A Cochrane review in 2017, found no evidence of using paracetamol alone. In regard to the opioid-sparing effect of paracetamol, it stated that although reduction in drug burden from large dosages of opioids was possible, there is no evidence to support the same. There is no high-quality evidence to support or refute the use of paracetamol alone or in combination with opioids for the first two steps of the three-step WHO cancer pain ladder. The authors did find randomized controlled trials (RCTs), but the GRADE assessment of evidence quality was very low for all outcomes, because studies were at high risk of bias from several sources.[13]

Nonsteroidal anti-inflammatory drugs

The anti-inflammatory and analgesic effects of NSAIDs are based on the suppression of the COX-1 and COX-2 enzymes. By blocking the COX enzymes and prostaglandins, vasodilation is reduced, and inflammation is relieved causing reduction of pain. Nonselective NSAIDs such as ibuprofen, diclofenac, indomethacin, naproxen, and piroxicam block COX-1 and COX-2 enzymes to various degrees. Selective COX-2 inhibiting NSAIDs such as celecoxib and etoricoxib selectively inhibit the COX-2 enzyme. COX-1 enzyme is responsible for gastric mucosal protection, and hence blockade of this leads to the gastrointestinal side effects of NSAIDs. The others include antiplatelet, cardiovascular, renal, and hepatotoxic side effects.[1415]

A Cochrane review held in 2017 identified 11 studies that looked into the effects of NSAIDs on their own, comparative studies of various NSAIDs and NSAIDs with opioids. Moderate or severe cancer pain was reduced to no worse than mild pain in 26%–51% of patients using any NSAIDs, after 1 or 2 weeks in 4 of the 11 studies. Thus, based on this review, we have no high-quality evidence to support or refute the use of NSAIDs alone or in combination with opioids for the three steps of the three-step WHO cancer pain ladder.[16]

Depending on the cause of pain, topical NSAID gel or patches can be tried for analgesia.

Weak opioid analgesics – Step 2 of three-step World Health Organization analgesic ladder

The Step 2 in WHO Ladder is used to manage moderate cancer pain.

Tramadol, codeine, and tapentadol are the drugs in Step 2.

Tramadol

Tramadol acts as a μ-opioid agonist, and a serotonin and noradrenaline reuptake inhibitor. Its effect on serotonin reuptake can potentially lead to serotonergic syndrome, especially in the elderly and with polypharmacy (e.g. metoclopramide, ondansetron, antidepressants). One RCT provided direct comparative data for the step 2 opioids, and it showed no difference in efficacy between tramadol, codeine plus paracetamol, and hydrocodone plus paracetamol, although tramadol was associated with more side effects.[17]

Codeine

Codeine exerts its analgesic effect when metabolized to morphine mainly via the CYP2D6 enzyme. There are four phenotypic categories of CYP2D6 polymorphisms-ultra rapid metabolizers, extensive metabolizers, intermediate metabolizers, and poor metabolizers. No significant difference was found between the effectiveness of nonopioid analgesics and nonopioids in combination with weak opioids in a meta-analysis.[1819] The available evidence suggests that codeine is more effective against cancer pain in adults than placebo, but with increased risk of nausea, vomiting, and constipation.[20]

Step 2 weak opioids have a therapeutic ceiling effect and increased incidence of side effects. There is no evidence that in moderate pain initiation of step 2 drugs alone improve pain. European Association for Palliative Care recommends the use of low-dose step 3 opioids such as morphine, oxycodone, and hydromorphone in management of moderate cancer pain in opioid-naiïve patients.[21] Oxycodone and hydromorphone are not available in India. In a Cochrane review in 2017 on tramadol, the authors have suggested that there is limited, very-low-quality evidence from RCTs that tramadol produced pain relief in some adults with pain due to cancer.[22] The quality of evidence is very low to say that tramadol is not as effective as morphine.

Tapentadol

Tapentadol is a novel, centrally-acting analgesic agent with two mechanisms of action: μ opioid receptor agonism and norepinephrine reuptake inhibition. Tapentadol has been developed for the management of moderate-to-severe chronic pain. The moderate affinity at the μ receptor and the opioid-sparing effect of inhibition of norepinephrine reuptake suggest that tapentadol should produce fewer opioid-related adverse effects than typical μ agonists.[23] Tapentadol, when used at doses equivalent to the step 3 of the analgesic ladder (≥60 mg of oral morphine equivalents) in opioid-tolerant patients with cancer pain, or after titration starting with step 2 doses (<200 mg/day), was well tolerated and effective and could be used for the management of moderate-to-severe cancer pain.[24] In a Cochrane review, the authors concluded that information from RCTs on the effectiveness and tolerability of tapentadol was limited, pain relief, and adverse events were comparable between the tapentadol and morphine and oxycodone groups.[25]

Step 3 of the World Health Organization three-step analgesic ladder

Strong opioids are the mainstay of management of moderate-to-severe cancer-related pain. Morphine continues to be the most widely available and prescribed opioid although other opioids do exist.

A Cochrane review of all step 3 opioids showed that the quality of evidence around the use of opioids for cancer pain is low. Ninety-five percentages of patients with moderate-to-severe pain, however, did report decrease in pain by 14 days. Adverse events were reported to be common, but withdrawals due to adverse events uncommon. Oral morphine is still considered as the gold standard for treating moderate-to-severe cancer pain.[26]

Morphine

Morphine acts on the μ receptors (subdivided into μ1, μ2, and μ3). Morphine is primarily metabolized in the liver by the cytochrome P450 CYP3A4 enzyme to M3G and M6G. In humans, approximately 60% of a morphine dose is converted to M3G and 10% to M6G. M6G contributes significantly to the analgesic potency of oral morphine, while M3G is neuroexcitatory and contributes to the adverse effects of morphine.[27]

In a Cochrane review, all formulations of morphine were compared with each other and other opioids. It was concluded that most patients will achieve a high level of pain relief within at least 2 weeks. A small proportion of participants did not achieve adequate analgesia with morphine and about 6% of participants discontinued treatment with morphine because of intolerable adverse events.[28]

Oral route is the preferred route of administration. Intravenous or subcutaneous route of administered is advised only when rapid control of pain is needed.

Methadone

Methadone a synthetic opioid is a potent agonist at the μ-opioid and delta-opioid receptors. Methadone has also been demonstrated in animal studies to have antagonist activity at the N-methyl-D-aspartate receptor, resulting in interest in management of neuropathic pain syndromes.[29]

A racemic mixture of two isomers-levorotatory (L) methadone and dextrorotatory (D) methadone, with L-methadone is 8–50 times being more potent than D-methadone and responsible for its analgesic properties. After oral administration, it reaches a measurable plasma level in 30 min.

The peak plasma levels are achieved in 4 h and begin to decline 24 h after dosing. Oral bioavailability is high, generally over 85%.

Particular concern is the potential for prolongation of the QT interval (a measure of cardiac function) resulting in the potentially fatal arrhythmia called torsade de pointes.[3031] The incidence is higher in doses higher than 100 mg a day.

Methadone's properties of high oral bioavailability, rapid onset of analgesic effect, long half-life (resulting in infrequent dosing schedules), lack of active metabolites, and low cost are positive factors for use in the management of pain in cancer patients.

Elimination of methadone is mediated by hepatic oxidative biotransformation, urinary, and fecal clearance. Renal impairment is not thought to impair clearance hence methadone is useful in the management of pain in patients with renal failure.[32] However, patients should be monitored closely for signs of drug toxicity.

In a Cochrane review, in 2017, based on low-quality evidence, methadone was found to have equianalgesic potency, when compared with morphine.[33]

A pain and palliative care specialist needs to be consulted if one is unfamiliar with methadone prescription and monitoring.

Fentanyl

Fentanyl is a strong opioid about 100 times more potent than morphine. It is lipophilic and exhibits strong protein-binding property. It has a large volume of distribution and its clearance relatively high. The inactive metabolites, and approximately 10% of the intact molecule, are mainly excreted by the kidneys.[34]

When administered intravenously, fentanyl is rapidly distributed from plasma into highly vascularized compartments. Following this, redistribution to muscle and fat tissue occurs. Elimination half time is highly variable due to the redistribution.[35]

Fentanyl is a synthetic opioid that acts at the mu opioid receptor. It takes 8–16 h before the full effect of transdermal fentanyl is observed, and steady state is not observed until after two to four applications of the “72-h” patches.[36] When used as a transdermal patch, fentanyl absorption occurs first into the cutaneous microcirculation, before entering the systemic circulation. Factors such as location of the patch applied, hypertrichosis, hyperhidrosis, and factors that could increase the body temperature to >40°C, can affect the absorption of fentanyl from the patch.[37]

The rapid-onset fentanyl products are absorbed by the highly vascularized oral mucosa and nasal membranes before entering the systemic circulation. In cancer patients, only a couple of studies have looked into whether mucositis or xerostomia affects the absorption. The studies have only included Grade 1-2 mucositis. This study of 13 patients did not find statistically significant differences in absorption.[38]

In cases of rhinitis/epistaxis and use of oxymetazoline nasal sprays, can cause a 50% decrease in absorption of fentanyl, postulated as due to vasoconstriction that occurs.[39]

In drug interactions, most strong CYP3A4 inhibitors significantly increased systemic fentanyl exposure and CYP3A4 inducers significantly decreased systemic fentanyl exposure, hence careful observation is required when using these drugs, while fentanyl infusion is ongoing.[35]

Pharmacogenetics also plays a vital role in the pharmacokinetics and pharmacodynamics of fentanyl metabolism.[35]

Buprenorphine

Buprenorphine is a semi-synthetic partial μ-opioid receptor agonist, with agonistic activity on κ-and δ-opioid receptors. It binds to receptors with high affinity and has slow dissociation, thus exhibiting a longer duration of analgesic action. Buprenorphine is available as parenteral, sublingual, and transdermal formulations. Buprenorphine patches are available as 7-day patches mainly, but 3–4 day patches are also available. Transdermal buprenorphine is recommended in patients with renal impairment as, due to its pharmacokinetic profile, buprenorphine does not accumulate in renal failure and is not removed by haemodialysis.[40] As per Cochrane review,[40] it might be considered as a fourth-line option compared to the standard therapies such as morphine, oxycodone, and fentanyl.