# Codeine (derived from Papaver somniferum) **Canonical URL:** https://ingredients.hermeticasuperfoods.com/ingredients/codeine-derived-from-papaver-somniferum **Data Source:** Hermetica Superfoods Ingredient Encyclopedia **Updated:** 2026-04-02 **Evidence Score:** 1 / 10 **Category:** Compound **Also Known As:** codeine sulfate, Codeine (3-methylmorphine), Codeine (Papaver somniferum alkaloid), 3-methylmorphine, C18H21NO3, methylmorphine, codeine phosphate ## Overview Codeine is a weak mu-opioid receptor agonist (Ki 79 nM) that exerts most of its analgesic effect through hepatic CYP2D6-mediated O-demethylation to morphine, which binds the mu-opioid receptor with approximately 44-fold greater affinity (Ki 1.8 nM). In controlled clinical comparisons, 60 mg oral codeine yields a number needed to treat (NNT) of 12 for meaningful analgesia versus placebo, with equianalgesic equivalence established at 200 mg oral codeine approximating 30 mg oral morphine. ## Health Benefits - **Analgesic (Mild-to-Moderate Pain Relief)**: Codeine binds mu-opioid receptors and is converted to morphine via CYP2D6, reducing nociceptive signaling; 15–60 mg every 4–6 hours provides clinically meaningful pain reduction with an NNT of 12 at the 60 mg dose. - **Antitussive (Cough Suppression)**: Codeine suppresses the cough reflex by acting on mu-opioid receptors in the medullary cough center, reducing cough frequency and severity at doses of 15–30 mg; it remains one of the most studied pharmaceutical antitussives despite declining use due to safety concerns. - **Antidiarrheal Effect**: By activating mu- and delta-opioid receptors in the enteric nervous system, codeine slows gastrointestinal motility and reduces intestinal secretion, providing symptomatic relief from acute diarrhea. - **Adjunct in Multimodal Analgesia**: Codeine is used in combination with acetaminophen or NSAIDs, providing additive analgesia through complementary mechanisms (opioid receptor activation plus cyclooxygenase inhibition), allowing lower doses of each agent and reduced side-effect burden. - **Palliative Dyspnea Management**: At low doses, codeine's mu-opioid receptor activity blunts the perception of breathlessness in palliative care settings, improving patient comfort in terminal or severely compromised respiratory conditions. - **Post-Procedural Pain Control**: Immediate-release formulations (15–30 mg) offer short-duration analgesia suitable for post-dental or minor surgical pain, with rapid GI absorption achieving peak plasma levels within approximately one hour. ## Mechanism of Action Codeine itself is a relatively weak mu-opioid receptor (MOR) agonist with a binding affinity Ki of approximately 79 nM, compared to morphine's Ki of 1.8 nM, and exhibits minimal affinity for delta (Ki >1,000 nM) or kappa (Ki >1,000 nM) opioid receptors. The primary mechanism of clinically relevant analgesia is hepatic O-demethylation via the CYP2D6 enzyme, which converts 5–15% of a codeine dose to morphine in extensive metabolizers; morphine then binds MOR with high affinity, activating inhibitory G-proteins (Gi/Go) that reduce adenylyl cyclase activity, decrease intracellular cAMP, hyperpolarize neurons via potassium channel opening, and suppress calcium channel activity, collectively inhibiting [neurotransmitter release](/ingredients/condition/cognitive) and nociceptive transmission. Additionally, 70–80% of codeine undergoes glucuronidation to codeine-6-glucuronide (which retains modest opioid activity) and to norcodeine via CYP3A4, contributing minor pharmacological effects. Antitussive action is mediated through direct MOR agonism in the brainstem cough center, while antidiarrheal effects involve opioid receptor activation throughout the enteric nervous system reducing propulsive motility and fluid secretion. ## Clinical Summary Clinical trials of codeine have primarily evaluated single-dose analgesic efficacy in postoperative and dental pain models using validated pain intensity scales; the 60 mg oral dose demonstrated an NNT of 12 versus placebo, indicating modest but statistically significant benefit in a minority of treated patients. Dose-escalation studies confirmed a clinical ceiling effect whereby doses exceeding 240 mg/day produce substantially increased adverse event rates (sedation, nausea, vomiting, dizziness) without corresponding improvements in analgesia. Pharmacokinetic studies established that oral bioavailability reaches approximately 94%, peak plasma concentration occurs at roughly one hour post-ingestion, elimination half-life is 3–4 hours, and steady-state is achieved within 48 hours of every-4-hour dosing. Equianalgesic conversion data from comparative trials place 200 mg oral codeine as approximately equivalent to 20–30 mg oral hydrocodone or 30 mg oral morphine, though individual variability driven by CYP2D6 genotype substantially affects outcomes. ## Nutritional Profile Codeine is a pharmaceutical alkaloid, not a nutrient, and contributes no meaningful macronutrients, micronutrients, vitamins, or dietary fiber to human physiology. Its molecular formula is C18H21NO3 (molecular weight 299.36 g/mol), and it is classified as a phenanthrene-type benzylisoquinoline alkaloid sharing biosynthetic origins with morphine, thebaine, and other opium alkaloids. Trace amounts occur naturally in poppy seeds (alongside morphine at 14.7–210 mg/kg seed weight), with codeine content further reduced by washing or heat processing; consumption of unwashed poppy seeds can transiently elevate urinary opioid metabolite levels, which is of forensic and occupational relevance rather than nutritional significance. Bioavailability as a pharmaceutical agent is high (~94% oral absorption), with low plasma protein binding (7–25%) and a large volume of distribution (3–6 L/kg) reflecting extensive tissue partitioning. ## Dosage & Preparation - **Oral Tablets (Immediate-Release)**: 15–60 mg every 4–6 hours as needed; maximum 360 mg/day; most commonly dispensed as codeine phosphate salt. - **Oral Solution**: 15–30 mg per dose for antitussive or analgesic use; useful for patients with swallowing difficulties; concentration typically 25 mg/5 mL. - **Controlled-Release Oral Tablets**: 50–200 mg every 12 hours; maximum 600 mg/day in chronic pain management under specialist supervision. - **Combination Tablets (with Acetaminophen or Ibuprofen)**: Standard fixed-dose combinations (e.g., 8–30 mg codeine + 300–500 mg acetaminophen); widely used for mild-to-moderate acute pain. - **Intramuscular Injection**: Potency ratio approximately 1:1.5 (IM:PO), meaning IM dosing requires lower amounts; used in hospital or palliative settings. - **Timing Note**: Peak analgesic effect occurs 1–2 hours post-oral dose; dosing intervals should not exceed 6 hours to maintain consistent plasma levels in chronic pain management. - **Dose Adjustment**: Renal impairment requires dose reduction given reduced clearance (normal renal clearance ~183 mL/min); pediatric use is now broadly contraindicated post-tonsillectomy due to ultra-rapid metabolizer fatality risk. ## Safety & Drug Interactions Common adverse effects at therapeutic doses include constipation, nausea, vomiting, sedation, and dizziness, with dose-dependent worsening above 240 mg/day; physical dependence and withdrawal syndrome develop with regular use, and respiratory depression is the primary serious toxicity at overdose (fatal threshold generally >1,000–10,000 μg/L plasma). CYP2D6 pharmacogenomics represent the most clinically critical safety concern: ultra-rapid metabolizers (prevalence 11–30% in North African populations, 1–10% in Whites, ~3% in African-Americans) generate dangerously elevated morphine levels, with documented pediatric deaths following standard doses; poor metabolizers conversely derive little or no analgesic benefit. Drug interactions include potentiation of CNS depression with benzodiazepines, alcohol, barbiturates, and antihistamines; CYP2D6 inhibitors (fluoxetine, paroxetine, bupropion, quinidine) reduce codeine-to-morphine conversion and efficacy; CYP2D6 inducers (rifampicin) may increase morphine production. Codeine is contraindicated in children under 12 (and under 18 post-tonsillectomy/adenoidectomy), known ultra-rapid CYP2D6 metabolizers, during breastfeeding (morphine concentrates in breast milk), and in significant respiratory compromise; reproductive toxicology data in rodents indicate embryolethality at 2–4× maximum human doses, and neonatal opioid withdrawal syndrome is documented with gestational exposure. ## Scientific Research Codeine has an extensive clinical pharmacology literature spanning several decades, with well-characterized pharmacokinetic and pharmacodynamic data from controlled trials, though many foundational studies are small by modern standards (n = 20–200 participants). Systematic reviews and meta-analyses published by the Cochrane Collaboration and Oxford Pain Research Group have quantified analgesic efficacy, establishing the NNT of 12 for 60 mg codeine versus placebo in single-dose postoperative pain models, and noting that higher doses above 240 mg/day increase adverse effects without proportional analgesia gain. Pharmacogenomic studies, including population-based analyses and case series, have robustly documented CYP2D6 ultra-rapid metabolizer toxicity, including fatal pediatric cases following tonsillectomy, leading to regulatory label changes by the FDA (2013) and EMA. Reproductive toxicology data derive primarily from controlled animal studies rather than large prospective human cohorts, representing a notable evidence gap for pregnant populations. ## Historical & Cultural Context The opium poppy (Papaver somniferum) has been cultivated for at least 5,400 years, with Sumerian records from approximately 3400 BCE describing the plant as 'Hul Gil' (joy plant), and opium preparations used across ancient Egyptian, Greek, Roman, and Islamic medical traditions for pain, cough, and dysentery. Codeine was isolated in pure form in 1832 by French chemist Pierre Jean Robiquet, who separated it from morphine in crude opium, representing one of the earliest examples of pharmacognostic fractionation of a plant extract into distinct active principles. Throughout the 19th and early 20th centuries, codeine-containing cough syrups and tonics were widely available over the counter in Europe and North America before increasing regulatory controls under the International Opium Convention (1912) and subsequently the Controlled Substances Act (USA, 1970) classified codeine as a Schedule II–V substance depending on formulation and concentration. Today, codeine remains on the World Health Organization's List of Essential Medicines for its analgesic and antitussive applications, though growing awareness of CYP2D6-related fatalities and misuse potential has driven many jurisdictions to restrict or reclassify over-the-counter access. ## Synergistic Combinations Codeine is most commonly combined with acetaminophen (paracetamol), exploiting complementary analgesic mechanisms — opioid receptor activation and central/peripheral cyclooxygenase-2 inhibition — with clinical evidence supporting additive analgesia at lower individual doses than either agent alone, reducing both opioid-related and hepatotoxic risks when dosed appropriately. Combinations with NSAIDs (e.g., ibuprofen) similarly leverage synergistic peripheral [anti-inflammatory](/ingredients/condition/inflammation) and central opioidergic pathways, a strategy endorsed in WHO analgesic ladder protocols for step-2 pain management. Co-administration with antiemetics (e.g., metoclopramide, ondansetron) addresses the high incidence of codeine-induced nausea and vomiting, improving tolerability and patient adherence without affecting analgesic efficacy. ## Frequently Asked Questions ### How does codeine work for pain relief? Codeine itself is a weak mu-opioid receptor agonist (Ki 79 nM), but its primary analgesic action comes from hepatic conversion to morphine by the CYP2D6 enzyme — approximately 5–15% of each dose is O-demethylated to morphine in extensive metabolizers. Morphine binds the mu-opioid receptor with about 44-fold greater affinity (Ki 1.8 nM), activating inhibitory G-proteins that reduce neuronal excitability and suppress pain signal transmission in the spinal cord and brain. Patients who are CYP2D6 poor metabolizers may experience little to no analgesic effect from codeine because they cannot efficiently generate morphine. ### What is the standard dose of codeine for adults? For mild-to-moderate pain or cough suppression, the standard adult oral dose of codeine is 15–60 mg every 4–6 hours, with a commonly recommended maximum of 240–360 mg per day for immediate-release formulations. Controlled-release formulations may be dosed at 50–200 mg every 12 hours under specialist supervision, up to 600 mg/day. Doses above 240 mg/day have been shown in dose-escalation studies to increase adverse effects — including sedation, nausea, and vomiting — without proportional gains in analgesia. ### Why is codeine dangerous in some people but not others? The danger arises from genetic variation in the CYP2D6 enzyme, which converts codeine to morphine. Ultra-rapid metabolizers — representing 11–30% of North African, 1–10% of White, and approximately 3% of African-American populations — produce morphine far faster and in greater quantities than anticipated, risking respiratory depression, sedation, and even fatal overdose at standard doses. This risk has led the FDA and EMA to contraindicate codeine in children post-tonsillectomy and in breastfeeding mothers who are ultra-rapid metabolizers, after documented pediatric deaths. ### Is codeine effective as a cough suppressant? Codeine suppresses the cough reflex by acting on mu-opioid receptors in the medullary cough center in the brainstem, and it has historically been considered a benchmark antitussive. However, systematic reviews have questioned the magnitude of benefit in acute cough, and many regulatory bodies have restricted codeine-containing cough preparations, particularly in children under 12, due to the disproportionate risk of opioid toxicity relative to modest cough-suppressing benefit. For adults, doses of 15–30 mg every 4–6 hours are used clinically, though alternatives such as dextromethorphan are increasingly preferred for over-the-counter applications. ### What are the most important drug interactions with codeine? The most clinically significant interactions involve CYP2D6 inhibitors — including fluoxetine, paroxetine, bupropion, and quinidine — which block conversion of codeine to morphine, substantially reducing analgesic efficacy and making codeine an unreliable choice for pain management in patients on these medications. Conversely, concurrent use with other CNS depressants (benzodiazepines, alcohol, barbiturates, other opioids, or antihistamines) carries serious risk of additive respiratory depression and sedation. Rifampicin and other CYP enzyme inducers may alter codeine metabolism unpredictably, and dose adjustments are necessary in patients with significant renal impairment given that renal clearance is approximately 183 mL/min under normal conditions. ### Is codeine safe during pregnancy and breastfeeding? Codeine use during pregnancy, particularly in the third trimester, carries risks including respiratory depression in the newborn and potential neonatal withdrawal; it is generally classified as Category C, meaning risks may outweigh benefits. Codeine is excreted into breast milk and can cause respiratory depression and sedation in nursing infants, especially in ultra-rapid CYP2D6 metabolizers, making breastfeeding inadvisable during codeine therapy. ### What does clinical research show about codeine's effectiveness compared to prescription NSAIDs? Clinical trials demonstrate that codeine 60 mg is effective for mild-to-moderate pain with an NNT of 12, though it performs less consistently than ibuprofen 400 mg (NNT of 6) for acute pain conditions. Codeine's advantage lies in antitussive effects and opioid-like properties for severe pain, whereas NSAIDs provide faster onset and superior efficacy for inflammatory pain without respiratory or addiction risks. ### Who should avoid codeine due to CYP2D6 metabolism variations? Ultra-rapid CYP2D6 metabolizers risk toxic morphine accumulation and overdose even at standard doses, while poor metabolizers experience inadequate pain relief because insufficient morphine conversion occurs. Individuals of certain ethnic backgrounds (Arab, Greek, Portuguese, and sub-Saharan African populations show higher rates of ultra-rapid metabolism) and those taking CYP2D6 inhibitors (fluoxetine, paroxetine, duloxetine) should avoid codeine or use with extreme caution. --- *Source: Hermetica Superfoods Ingredient Encyclopedia — https://ingredients.hermeticasuperfoods.com* *License: CC BY-NC-SA 4.0 — Attribution required. Commercial use: admin@hermeticasuperfoods.com*