a) CODEINE/ACETAMINOPHEN: Three patients developed severe-to-profound hearing loss after taking increasing doses of acetaminophen with codeine over many months. At the time of presentation, they were taking sublethal amounts (up to 200 tablets/day; 300 to 500 mg of acetaminophen per tablet; 8 to 60 mg of codeine per tablet) of this combination. Tympanograms and magnetic resonance imaging for all 3 patients were normal. Despite treatment with prednisone 60 mg/day, no improvement were noted. All 3 patients underwent successful cochlear implantation (Blakley & Schilling, 2008).

a) Hypotension and shock may occur, especially in the presence of prolonged and severe hypoxia (Whipple et al, 1994; Miller, 1980).

a) Respiratory depression and apnea are characteristic effects of codeine overdose and when severe may result in severe hypoxia, leading to hypotension and shock, acute lung injury and respiratory arrest (Prod Info codeine sulfate oral tablets, 2007; Wilkes et al, 1981) .
b) INFANT: A 3-month-old preterm infant received codeine 6.6 mg/kg within 24 hours, well above the recommended dose of 1 to 2 mg/kg. The infant developed apnea and presented at the hospital with pinpoint pupils and was semicomatose. Effects were reversed with IV naloxone (Wilkes et al, 1981).

a) CASE REPORT: A 5-week-old infant presented with moderate respiratory distress, stridor and CNS depression, which got progressively worse in the ED. The toxicology screen was positive for opiates and the patient was given naloxone 0.4 mg resulting in the resolution of his stridor and CNS depression. Upon further questioning, his mother admitted to administering one crushed tablet of her prescription analgesics which contained 500 mg acetaminophen/5 mg oxycodone. Morphine and codeine, but not oxycodone, were detected in the child's urine, suggesting that codeine was actually the drug administered (Perez et al, 2004).

a) Dizziness, lightheadedness, and sedation commonly occur with codeine therapy, and may be more pronounced in ambulatory patients and in those patients who are not in severe pain (Prod Info codeine sulfate oral tablets, 2007).

a) Decreased mental status is one of the most prominent symptoms in a narcotic overdose, which may progress to coma (Whipple et al, 1994).

a) Nausea and vomiting commonly occur with codeine therapy, and may be more pronounced in ambulatory patients and in those patients who are not in severe pain (Prod Info codeine sulfate oral tablets, 2007).

a) CASE REPORT: An adult male who was taking a codeine-containing cough syrup experienced several attacks of urticaria. On patch-testing, he reacted to codeine and its derivatives (De Groot & Conemans, 1986).

a) Sweating commonly occurs with codeine therapy, and may be more pronounced in ambulatory patients and in those patients who are not in severe pain (Prod Info codeine sulfate oral tablets, 2007).

a) CASE REPORT: Fatal morphine poisoning due to polymorphism of CYP2D6 occurred in a breastfed neonate of a mother who was prescribed codeine. Following delivery of a full-term healthy male infant, the mother was prescribed an oral combination product of codeine 30 mg and paracetamol 500 mg for episiotomy pain. Initially, the dose was 2 tablets every 12 hours; however, this was reduced to 1 tablet every 12 hours due to somnolence and constipation. On day 7, the infant displayed intermittent periods of difficulty in breastfeeding and lethargy. Although the infant had regained his birthweight on day 11, he had grey skin and decreased milk intake on day 12, and expired the following day. An autopsy revealed a morphine (active metabolite of codeine) blood concentration of 70 ng/mL (normal 0 to 2.2 ng/mL in nursing women receiving codeine). A sample of breast milk that was stored on day 10 showed a morphine concentration of 87 ng/mL (normal 1.9 to 20.5 ng/mL at repeated codeine doses of 60 mg every 6 hours). Subsequent genotype analysis of the mother revealed that she was heterozygous for the CYP2D6*2A allele with CYP2D6*2x2 gene duplication, classifying her as an ultra-rapid metabolizer (Koren et al, 2006).

a) After ingestion of poppy seeds, opioids show up in the urine within 5 hours (Beck et al, 1990).
b) Soaking the seeds in water removed 45.6% of free morphine and 48.4% of free codeine (Lo & Chua, 1992). Soaked seeds have less potential for producing elevated urine levels.

a) A urinary codeine concentration (following multiple doses of an anti-cough syrup) larger than 300 ng/mL and a ratio of morphine to codeine of less than 3 has been proposed as criteria for a positive codeine intake (as opposed to morphine) (Hsu et al, 2000).

a) Past opiate usage can be detected by means of hair analysis as well as the diagnosis of poisoning associated with opiate addiction. Hair analysis may be accomplished by means of RIA, HPLC, or GC/MS. Hair analysis may provide both hair drug content and hair profile. A single opiate ingestion may not be detectable through hair analysis, which may be a drawback of this method (Staub, 1993).

a) On site saliva drug testing (Cozart RapiScan), which detects the parent drug for opiates, is based on the principle of competitive lateral flow immunoassay using digital photography to provide a semiquantitative end point. Sensitivity and specificity were both 100% for codeine for 9 hours after ingestion. Tests are positive as long as codeine saliva concentrations are above 5 ng/mL by GC/MS (Jehanli et al, 2001).

a) This dose can also be given intramuscularly or subcutaneously in the absence of intravenous access (Howland & Nelson, 2011; Prod Info naloxone HCl IV, IM, subcutaneous injection solution, 2008; Maio et al, 1987; Wanger et al, 1998).

a) Single doses of up to 24 milligrams have been given without adverse effect (Evans et al, 1973).

a) OPIOID DEPENDENT PATIENTS: The goal of naloxone therapy is to reverse respiratory depression without precipitating significant withdrawal. Starting doses of naloxone 0.04 mg IV, or 0.001 mg/kg, have been suggested as appropriate for opioid-dependent patients without severe respiratory depression (Howland & Nelson, 2011). If necessary the dose may be repeated or increased gradually until the desired response is achieved (adequate respirations, ability to protect airway, responds to stimulation but no evidence of withdrawal) (Howland & Nelson, 2011). In the presence of opioid dependence, withdrawal symptoms typically appear within minutes of naloxone administration and subside in about 2 hours. The severity and duration of the withdrawal syndrome are dependant upon the naloxone dose and the degree and type of dependence.(Prod Info naloxone HCl IV, IM, subcutaneous injection solution, 2008)
b) PRECAUTION should be taken in the presence of a mixed overdose of a sympathomimetic with an opioid. Administration of naloxone may provoke serious sympathomimetic toxicity by removing the protective opioid-mediated CNS depressant effects. Arrhythmogenic effects of naloxone may also be potentiated in the presence of severe hyperkalemia (McCann et al, 2002).

a) LESS THAN 5 YEARS OF AGE OR LESS THAN 20 KG: 0.1 mg/kg IV/intraosseous/IM/subcutaneously maximum dose 2 mg; may repeat dose every 2 to 5 minutes until symptoms improve (Kleinman et al, 2010; Hegenbarth & American Academy of Pediatrics Committee on Drugs, 2008)
b) 5 YEARS OF AGE OR OLDER OR GREATER THAN 20 KG: 2 mg IV/intraosseous/IM/subcutaneouslymay repeat dose every 2 to 5 minutes until symptoms improve (Kleinman et al, 2010; Hegenbarth & American Academy of Pediatrics Committee on Drugs, 2008; Krauss & Green, 2006). Although naloxone may be given via the endotracheal tube for pediatric resuscitation, optimal doses are unknown. Some experts have recommended using 2 to 3 times the IV dose (Kleinman et al, 2010)
c) AVOIDANCE OF OPIOID WITHDRAWAL: In cases of known or suspected chronic opioid therapy, a lower dose of 0.01 mg/kg may be considered and titrated to effect to avoid withdrawal: INITIAL DOSE: 0.01 mg/kg body weight given IV. If this does not result in clinical improvement, an additional dose of 0.1 mg/kg body weight may be given. It may be given by the IM or subQ route if the IV route is not available (Prod Info naloxone HCl IV, IM, subcutaneous injection solution, 2008)

a) The American Academy of Pediatrics recommends a neonatal dose of 0.1 mg/kg IV or intratracheally from birth until age 5 years or 20 kilograms of body weight (AAP, 1989; Kleinman et al, 2010).
b) Smaller doses (10 to 30 mcg/kg IV) have been successful in the setting of exposure via maternal administration of narcotics or administration to neonates in therapeutic doses for anesthesia (Wiener et al, 1977; Welles et al, 1984; Fischer & Cook, 1974; Brice et al, 1979).
c) POTENTIAL OF WITHDRAWAL: The risk of precipitating withdrawal in an addicted neonate should be considered. Withdrawal seizures have been provoked in infants from opioid-abusing mothers when the infants were given naloxone at birth to stimulate breathing (Gibbs et al, 1989).
d) In cases of inadvertent administration of an opioid overdose to a neonate, larger doses may be required. In one case of oral morphine intoxication, 0.16 milligram/kilogram/hour was required for 5 days (Tenenbein, 1984).

a) If intravenous access cannot be rapidly established, naloxone can be administered via subcutaneous or intramuscular injection, intranasally, or via inhaled nebulization in patients with spontaneous respirations.
b) INTRAMUSCULAR/SUBCUTANEOUS ROUTES: If an intravenous line cannot be secured due to hypoperfusion or lack of adequate veins then naloxone can be administered by other routes.
c) The intramuscular or subcutaneous routes are effective if hypoperfusion is not present (Prod Info naloxone HCl IV, IM, subcutaneous injection solution, 2008). The delay required to establish an IV, offsets the slower rate of subcutaneous absorption (Wanger et al, 1998).
d) Naloxone Evzio(TM) is a hand-held autoinjector intended for the emergency treatment of known or suspected opioid overdose. The autoinjector is equipped with an electronic voice instruction system to assist caregivers with administration. It is available as 0.4 mg/0.4 mL solution for injection in a pre-filled auto-injector (Prod Info EVZIO(TM) injection solution, 2014).
e) INTRANASAL ROUTE: Intranasal naloxone has been shown to be effective in opioid overdose; bioavailability appears similar to the intravenous route (Kelly & Koutsogiannis, 2002). Based on several case series of patients with suspected opiate overdose, the average response time of 3.4 minutes was observed using a formulation of 1 mg/mL/nostril by a mucosal atomization device (Kerr et al, 2009; Kelly & Koutsogiannis, 2002). However, a young adult who intentionally masticated two 25 mcg fentanyl patches and developed agonal respirations (6 breaths per minute), decreased mental status and mitotic pupils did not respond to intranasal naloxone (1 mg in each nostril) administered by paramedics. After 11 minutes, paramedics placed an IV and administered 1 mg of IV naloxone; respirations normalized and mental status improved. Upon admission, 2 additional doses of naloxone 0.4 mg IV were needed. The patient was monitored overnight and discharged the following day without sequelae. Its suggested that intranasal administration can lead to unpredictable absorption (Zuckerman et al, 2014).
f) NEBULIZED ROUTE: DOSE: A suggested dose is 2 mg naloxone with 3 mL of normal saline for suspected opioid overdose in patients with some spontaneous respirations (Weber et al, 2012).
g) ENDOTRACHEAL ROUTE: Endotracheal administration of naloxone can be effective(Tandberg & Abercrombie, 1982), optimum dose unknown but 2 to 3 times the intravenous dose had been recommended by some (Kleinman et al, 2010).

a) A continuous infusion of naloxone may be employed in circumstances of opioid overdose with long acting opioids (Howland & Nelson, 2011; Redfern, 1983).
b) The patient is given an initial dose of IV naloxone to achieve reversal of opioid effects and is then started on a continuous infusion to maintain this state of antagonism.
c) DOSE: Utilize two-thirds of the initial naloxone bolus on an hourly basis (Howland & Nelson, 2011; Mofenson & Caraccio, 1987). For an adult, prepare the dose by multiplying the effective bolus dose by 6.6, and add that amount to 1000 mL and administer at an IV infusion rate of 100 mL/hour (Howland & Nelson, 2011).
d) Dose and duration of action of naloxone therapy varies based on several factors; continuous monitoring should be used to prevent withdrawal induction (Howland & Nelson, 2011).
e) Observe patients for evidence of CNS or respiratory depression for at least 2 hours after discontinuing the infusion (Howland & Nelson, 2011).

a) In general, the smallest dose of naloxone required to reverse life threatening opioid effects should be used in pregnant women. Naloxone detoxification of opioid addicts during pregnancy may result in fetal distress, meconium staining and fetal death (Zuspan et al, 1975). When naloxone is used during pregnancy, opioid abstinence may be provoked in utero (Umans & Szeto, 1985).

a) Consider prehospital administration of activated charcoal as an aqueous slurry in patients with a potentially toxic ingestion who are awake and able to protect their airway. Activated charcoal is most effective when administered within one hour of ingestion. Administration in the prehospital setting has the potential to significantly decrease the time from toxin ingestion to activated charcoal administration, although it has not been shown to affect outcome (Alaspaa et al, 2005; Thakore & Murphy, 2002; Spiller & Rogers, 2002).

a) Use a minimum of 240 milliliters of water per 30 grams charcoal (FDA, 1985). Optimum dose not established; usual dose is 25 to 100 grams in adults and adolescents; 25 to 50 grams in children aged 1 to 12 years (or 0.5 to 1 gram/kilogram body weight) ; and 0.5 to 1 gram/kilogram in infants up to 1 year old (Chyka et al, 2005).
b) ADVERSE EFFECTS/CONTRAINDICATIONS

a) Routine use of a cathartic with activated charcoal is NOT recommended as there is no evidence that cathartics reduce drug absorption and cathartics are known to cause adverse effects such as nausea, vomiting, abdominal cramps, electrolyte imbalances and occasionally hypotension (None Listed, 2004).

a) Complications: emesis, aspiration (Chyka et al, 2005). Aspiration may be complicated by acute respiratory failure, ARDS, bronchiolitis obliterans or chronic lung disease (Golej et al, 2001; Graff et al, 2002; Pollack et al, 1981; Harris & Filandrinos, 1993; Elliot et al, 1989; Rau et al, 1988; Golej et al, 2001; Graff et al, 2002). Refer to the ACTIVATED CHARCOAL/TREATMENT management for further information.
b) Contraindications: unprotected airway (increases risk/severity of aspiration) , nonfunctioning gastrointestinal tract, uncontrolled vomiting, and ingestion of most hydrocarbons (Chyka et al, 2005).

a) Naloxone, a pure opioid antagonist, reverses coma and respiratory depression from all opioids. It has no agonist effects and can safely be employed in a mixed or unknown overdose where it can be diagnostic and therapeutic without risk to the patient.
b) Indicated in patients with mental status and respiratory depression possibly related to opioid overdose (Hoffman et al, 1991).
c) DOSE: The initial dose of naloxone should be low (0.04 to 0.4 mg) with a repeat dosing as needed or dose escalation to 2 mg as indicated due to the risk of opioid withdrawal in an opioid-tolerant individual; if delay in obtaining venous access, may administer subcutaneously, intramuscularly, intranasally, via nebulizer (in a patient with spontaneous respirations) or via an endotracheal tube (Vanden Hoek,TL,et al).
d) Recurrence of opioid toxicity has been reported to occur in approximately 1 out of 3 adult ED opioid overdose cases after a response to naloxone. Recurrences are more likely with long-acting opioids (Watson et al, 1998)

a) INITIAL BOLUS DOSE: Because naloxone can produce opioid withdrawal in an opioid-dependent individual leading to severe agitation and hypertension, the initial dose of naloxone should be low (0.04 to 0.4 mg) with a repeat dosing as needed or dose escalation to 2 mg as indicated (Vanden Hoek,TL,et al).
b) Larger doses may be needed to reverse opioid effects. Generally, if no response is observed after 8 to 10 milligrams has been administered, the diagnosis of opioid-induced respiratory depression should be questioned (Howland & Nelson, 2011; Prod Info naloxone HCl IV, IM, subcutaneous injection solution, 2008). Very large doses of naloxone (10 milligrams or more) may be required to reverse the effects of a buprenorphine overdose (Gal, 1989; Jasinski et al, 1978).
c) REPEAT DOSE: The effective naloxone dose may have to be repeated every 20 to 90 minutes due to the much longer duration of action of the opioid agonist used(Howland & Nelson, 2011).
d) NALOXONE DOSE/CHILDREN
e) NALOXONE DOSE/NEONATE
f) NALOXONE/ALTERNATE ROUTES
g) NALOXONE/CONTINUOUS INFUSION METHOD
h) NALOXONE/PREGNANCY

a) Infuse 10 to 20 milliliters/kilogram of isotonic fluid and keep the patient supine. If hypotension persists, administer dopamine or norepinephrine. Consider central venous pressure monitoring to guide further fluid therapy.

a) DOSE: Begin at 5 micrograms per kilogram per minute progressing in 5 micrograms per kilogram per minute increments as needed (Prod Info dopamine hcl, 5% dextrose IV injection, 2004). If hypotension persists, dopamine may need to be discontinued and a more potent vasoconstrictor (eg, norepinephrine) should be considered (Prod Info dopamine hcl, 5% dextrose IV injection, 2004).
b) CAUTION: If ventricular dysrhythmias occur, decrease rate of administration (Prod Info dopamine hcl, 5% dextrose IV injection, 2004). Extravasation may cause local tissue necrosis, administration through a central venous catheter is preferred (Prod Info dopamine hcl, 5% dextrose IV injection, 2004).

a) PREPARATION: 4 milligrams (1 amp) added to 1000 milliliters of diluent provides a concentration of 4 micrograms/milliliter of norepinephrine base. Norepinephrine bitartrate should be mixed in dextrose solutions (dextrose 5% in water, dextrose 5% in saline) since dextrose-containing solutions protect against excessive oxidation and subsequent potency loss. Administration in saline alone is not recommended (Prod Info norepinephrine bitartrate injection, 2005).
b) DOSE

a) ADULT DOSE: Initially 5 to 10 mg IV, OR 0.15 mg/kg IV up to 10 mg per dose up to a rate of 5 mg/minute; may be repeated every 5 to 20 minutes as needed (Brophy et al, 2012; Prod Info diazepam IM, IV injection, 2008; Manno, 2003).
b) PEDIATRIC DOSE: 0.1 to 0.5 mg/kg IV over 2 to 5 minutes; up to a maximum of 10 mg/dose. May repeat dose every 5 to 10 minutes as needed (Loddenkemper & Goodkin, 2011; Hegenbarth & American Academy of Pediatrics Committee on Drugs, 2008).
c) Monitor for hypotension, respiratory depression, and the need for endotracheal intubation. Consider a second agent if seizures persist or recur after repeated doses of diazepam .

a) DIAZEPAM may be given rectally or intramuscularly (Manno, 2003). RECTAL DOSE: CHILD: Greater than 12 years: 0.2 mg/kg; 6 to 11 years: 0.3 mg/kg; 2 to 5 years: 0.5 mg/kg (Brophy et al, 2012).
b) MIDAZOLAM has been used intramuscularly and intranasally, particularly in children when intravenous access has not been established. ADULT DOSE: 0.2 mg/kg IM, up to a maximum dose of 10 mg (Brophy et al, 2012). PEDIATRIC DOSE: INTRAMUSCULAR: 0.2 mg/kg IM, up to a maximum dose of 7 mg (Chamberlain et al, 1997) OR 10 mg IM (weight greater than 40 kg); 5 mg IM (weight 13 to 40 kg); INTRANASAL: 0.2 to 0.5 mg/kg up to a maximum of 10 mg/dose (Loddenkemper & Goodkin, 2011; Brophy et al, 2012). BUCCAL midazolam, 10 mg, has been used in adolescents and older children (5-years-old or more) to control seizures when intravenous access was not established (Scott et al, 1999).

a) MAXIMUM RATE: The rate of intravenous administration of lorazepam should not exceed 2 mg/min (Brophy et al, 2012; Prod Info lorazepam IM, IV injection, 2008).
b) ADULT DOSE: 2 to 4 mg IV initially; repeat every 5 to 10 minutes as needed, if seizures persist (Manno, 2003; Brophy et al, 2012).
c) PEDIATRIC DOSE: 0.05 to 0.1 mg/kg IV over 2 to 5 minutes, up to a maximum of 4 mg/dose; may repeat in 5 to 15 minutes as needed, if seizures continue (Brophy et al, 2012; Loddenkemper & Goodkin, 2011; Hegenbarth & American Academy of Pediatrics Committee on Drugs, 2008; Sreenath et al, 2009; Chin et al, 2008).

a) ADULT LOADING DOSE: 20 mg/kg IV at an infusion rate of 50 to 100 mg/minute IV. An additional 5 to 10 mg/kg dose may be given 10 minutes after loading infusion if seizures persist or recur (Brophy et al, 2012).
b) Patients receiving high doses will require endotracheal intubation and may require vasopressor support (Brophy et al, 2012).
c) PEDIATRIC LOADING DOSE: 20 mg/kg may be given as single or divided application (2 mg/kg/minute in children weighing less than 40 kg up to 100 mg/min in children weighing greater than 40 kg). A plasma concentration of about 20 mg/L will be achieved by this dose (Loddenkemper & Goodkin, 2011).
d) REPEAT PEDIATRIC DOSE: Repeat doses of 5 to 20 mg/kg may be given every 15 to 20 minutes if seizures persist, with cardiorespiratory monitoring (Loddenkemper & Goodkin, 2011).
e) MONITOR: For hypotension, respiratory depression, and the need for endotracheal intubation (Loddenkemper & Goodkin, 2011; Manno, 2003).
f) SERUM CONCENTRATION MONITORING: Monitor serum concentrations over the next 12 to 24 hours. Therapeutic serum concentrations of phenobarbital range from 10 to 40 mcg/mL, although the optimal plasma concentration for some individuals may vary outside this range (Hvidberg & Dam, 1976; Choonara & Rane, 1990; AMA Department of Drugs, 1992).

a) If seizures persist after phenobarbital, propofol or pentobarbital infusion, or neuromuscular paralysis with general anesthesia (isoflurane) and continuous EEG monitoring should be considered (Manno, 2003). Other anticonvulsants can be considered (eg, valproate sodium, levetiracetam, lacosamide, topiramate) if seizures persist or recur; however, there is very little data regarding their use in toxin induced seizures, controlled trials are not available to define the optimal dosage ranges for these agents in status epilepticus (Brophy et al, 2012):

a) To minimize barotrauma and other complications, use the lowest amount of PEEP possible while maintaining adequate oxygenation. Use of smaller tidal volumes (6 mL/kg) and lower plateau pressures (30 cm water or less) has been associated with decreased mortality and more rapid weaning from mechanical ventilation in patients with ARDS (Brower et al, 2000). More treatment information may be obtained from ARDS Clinical Network website, NIH NHLBI ARDS Clinical Network Mechanical Ventilation Protocol Summary, http://www.ardsnet.org/node/77791 (NHLBI ARDS Network, 2008)

a) SUMMARY: The recommended dose of codeine in children is 0.5 mg/kg of body weight (15 mg/square meter of body surface area) orally, subcutaneously, or intramuscularly every 4 hours as needed (Prod Info acetaminophen and codeine phosphate oral tablets, 2009; Prod Info codeine phosphate injection, 2004).
b) 2 TO 3 YEARS: In combination with acetaminophen in the elixir formulation, the recommended dose is 3.75 to 5 mL (equivalent to 6 to 8 mg codeine phosphate) every 4 hours as needed, up to a maximum of 5 doses in a 24-hour period (Prod Info TYLENOL(R) oral caplets, tablets, oral solution, 2008).
c) 4 TO 5 YEARS: In combination with acetaminophen in the elixir formulation, the recommended dose is 5 to 6.25 mL (equivalent to 8 to 10 mg codeine phosphate) every 4 hours as needed, up to a maximum of 5 doses in a 24-hour period (Prod Info TYLENOL(R) oral caplets, tablets, oral solution, 2008).
d) 6 TO 8 YEARS: In combination with acetaminophen in the elixir formulation, the recommended dose is 6.25 to 8.75 mL (equivalent to 10 to 14 mg codeine phosphate) every 4 hours as needed, up to a maximum of 5 doses in a 24-hour period (Prod Info TYLENOL(R) oral caplets, tablets, oral solution, 2008).
e) 9 TO 10 YEARS: In combination with acetaminophen in the elixir formulation, the recommended dose is 8.75 to 10 mL (equivalent to 14 to 16 mg codeine phosphate) every 4 hours as needed, up to a maximum of 5 doses in a 24-hour period (Prod Info TYLENOL(R) oral caplets, tablets, oral solution, 2008).
f) 11 TO 12 YEARS: In combination with acetaminophen in the elixir formulation, the recommended dose is 10 to 12.5 mL (equivalent to 16 to 20 mg codeine phosphate) every 4 hours as needed, up to a maximum of 5 doses in a 24-hour period) (Prod Info TYLENOL(R) oral caplets, tablets, oral solution, 2008).
g) 12 TO 14 YEARS: In combination with acetaminophen and caffeine, the recommended dose is 1 caplet (equivalent to 8 mg codeine phosphate) three times daily, up to a maximum dose of 1 caplet 4 times daily (Prod Info TYLENOL(R) oral caplets, tablets, oral solution, 2008).

a) 6 TO 11 YEARS: In combination with promethazine, the recommended dose is 2.5 to 5 mL (equivalent to 5 to 10 mg codeine phosphate) every 4 to 6 hours, up to a maximum dose of 30 mL (equivalent to 60 mg codeine phosphate) in a 24-hour period (Prod Info promethazine HCl and codeine phosphate oral solution, 2008).
b) 12 YEARS AND OLDER: In combination with promethazine, the recommended dose is 5 mL (equivalent to 10 mg codeine phosphate) every 4 to 6 hours up to a maximum dose of 30 mL (equivalent to 60 mg codeine phosphate) in a 24-hour period (Prod Info promethazine HCl and codeine phosphate oral solution, 2008)

a) Surviving child: 174 ng/ml (codeine), 25.6 ng/mL (morphine)
b) Deceased child: 436.3 ng/mL (codeine), 138.7 ng/mL (morphine)
c) The authors speculated that the differences in codeine and morphine concentrations between the 2 children could be a result of variations in pharmacokinetic parameters of the deceased child, as well as postmortem release of the drug from its formulation vehicle within the gastrointestinal tract, with subsequent absorption and distribution during resuscitative efforts.