Article Notes
- pKa - 8.5 (9% nonionised @ 7.4)
- Octanol water coefficient - 39 (so 40x lipid solubility of morphine)
- phenylpiperidine opioid
- Dose - 25-100 mg (10% morphine potency). Limit 1000 mg 1st day, then 600 mg/day there after.
- Absorption - IV, IM, epidural, po (55% biov)
- Distribution - Vdss 4.5 L/kg. Crosses placenta - foetal 80% of maternal.
- Protein binding - 60%
- Onset 10 min ; Offset 2-3 h
- Metabolism - ß½ 3 h; N-demethylation to norpethidine and then hydrolysis to norpethidinic acid; also direct hydrolysis to pethidinic acid. Renal elimination.
- Norpethidine - ß½ 15 h; 50% analgesic properties, 2x convulsant effects.
- Clearance - 20 mL/kg/min (same as morph & fentanyl)
- Mech - mu and kappa agonist, causing potent spinal and supraspinal analgesia.
- CNS - more euphoria, less N/V than morphine. No miosis, but may cause mydriasis (pupil dilation -atropine-like kappa action). No EEG changes like morphine. ⇡ latency & amplitude of SSEPs.
- NB: has LA action, so can be used as sole agent for neuroaxial block.
- anti-shivering effect (kappa)
- CVS - ⇣ MAP (> than morphine) due to histamine release & alpha adrenergic blockade (vasodilation). Inc HR (atropine like effect). Large doses depress myocardial contractility. May cause hypertensive crisis in those on MAOIs.
- vasodilation
- tachycardia
- depress myocardial contractility
- Resp - potent resp depressant - greater effect on TV than RR. Histamine release. Chest wall rigidity.
- OWC 1800
- pKa 8.0
- Potency 5-10x fentanyl, 500x morphine.
- Vd 3 L/kg
- Protein binding 93%
- Clearance 12 mL/kg/min
- tß½ 3 hours
- CSHT(8h) 30 min (alfentanil ~60 m)
- mu agonist, also stimulates serotonin release and at high dose has local anaeshetic effect.
- Structurally different from fentanyl, with a methoxymethyl group on the piperidine ring (increases potency and reduces duration of action) and thiophene instead of phenyl ring.
- Natural phenathrene opioid - plant, animal and even human synthesis identified.
- Synthesized by mammalian cells from dopamine, although exact role unclear.
- pKa - 7.9 (20% nonionised @ 7.4)
- Octanol water coefficient - 1.4 (relatively low lipid solubility compared with other opioids)
- 3 rings attached to piperidine ring with a tertiary amine.
- Dose - 50 mcg/kg IV
- analgesia @ [plasma] 0.05 mcg/mL
- epidural: 10-20 mcg/mL
- PCA adult: 50 mg in 50 mL; 1 mL (1 mg) bolus 5 min lockout, commonly used.
- PCA paeds: 1 mg/kg in 50 mL; 1 mL (20 mcg/kg) bolus; background 0.5-1 mL/h (10-20 mcg/kg/h).
- Absorption - IV, IM, s/c, po (3x dose as HER 0.69)
- Distribution - Vdcc 0.3, Vdss 3.5 L/kg
- Protein binding - 30% (albumin)
- Onset: peak onset at 20 min when given parenteral, 60 min orally; Offset 4 h
- Metabolism - t½α 10-20 min, t½ß 2-4 h
- 75% metabolised by conjugation → 90% morphine-3-glucuronide (no activity)
- 10% morphine-6-gluc (13x potency of morphine). MAOIs inhibit glucuronidation.
- Clearance - 15 mL/kg/min
- Mech - mu, kappa, delta agonist. (GI linked). Effective against visceral, skeletal & joint pain.
- CNS - little CNS penetration (cf. heroin, which readily crosses BBB), although alkalisation (⇣pCO2) ⇡ non-ionised fraction, and ⇡pCO2 ⇡CBF. Both ⇡ cerebral morphine concentration.
- 'Ceiling effect' on EEG reaching high voltage, slow frequency (delta 2-4 Hz) waves.
- ⇣ CMRO2 & ⇣ ICP.
- ⇡ cortical stimulation of Edinger-Westphal nucleus → miosis.
- CVS - ⇣ SNS & ⇡ PNS tone. Bradycardia, venodilation, histamine release (causes ⇣ MAP). Orthostatic hypotension due to depression of SNS responses. Direct depressant effect on SA node, slowing conduction (⇡ VF risk).
- Administration with N2O results in CVS depression.
- Resp - Respiratory depression & response to CO2 & hypoxia (shift pCO2/VA curve to right).
- Bronchoconstriction due to histamine release (similar with pethidine). Depresses airway reflexes & ciliary reflexes.
- Renal - diuresis (kappa receptors → ADH release)
- GIT - Nausea & vomiting due to stimulation of CTZ (30-40% of subjets); ileus; constipation; sphincter of Oddi spasm.
- Pruritus
- Synthetic analgesic of 'amino-cyclo-hexanol' group.
- Unlike tramadol, prepared as only the (R,R) stereoisomer (weakest opioid activity).
- Oral: 50, 75 & 100 mg immediate release, and 50,100,150 & 200 mg extended release preparations.
- No parenteral preparation is approved for use.
- Dose: 50-200 mg bd/qid for immediate release preparations, 50-200mg bd for extended release.
- approximately double potency of tramadol, similar to oxycodone and between tramadol and morphine.
- Absorption - po (only 32% biov)
- increasing doses have a non-linear effect on increasing peak plasma concentration, thus higher doses result in disproportionately higher Cmax.
- Distribution - ~8 L/kg (higher than tramadol).
- Protein binding - 20% (low!)
- Onset 30 min; Offset 4-6 h
- Metabolism - t½ 4h
- hepatic conjugation with glucuronic acid → glucuronides is main pathway (tapentadol-O-glucuronide); p450 metabolism to N-desmethyl tapentadol and hydroxyl tapentadol.
- No known active metabolites
- 99% excreted in urine, 1% in faecies.
- Clearance - 22 mL/kg/min
- Mech - weak mu agonists (30% of action / 18x less affinity than morphine) ; inhibits NAd reuptake (through indirect activation of post-synaptic alpha-2 adrenoreceptors), activating descending NAd (70%) modulating pain pathways.
- CNS - analgesia, good for neuropathic pain, low(er) incidence of tolerance & dependence, lowers seizure threshold, dizziness, sweating, ⇡ ICP.
- CVS - few CVS effects. Some tachycardia and flushing.
- Resp - little respiratory depression.
- Renal - possible caution in renal failure, although no active metabolites even if 99% renal excreted.
- GIT - Nausea & vomiting (less than tramadol), minimal constipation, more biliary spasm than tramadol.
- SEs - interacts with MAOI (adrenergic storm), SSRIs (serotonin syndrome).
- Although thought to have less abuse potential than other common opioids, it is still classed as a Schedule 2 drug in the US, Schedule 1 in Canada, Class A controlled drug in the UK and S8 in Australia.
- Safety of tapentadol in pregnant, lactating women, and pediatric patients is not yet established.
- Synthetic analgesic of 'amino-cyclo-hexanol' group.
- Racemic mixture of two enantiomers + and -:
- (-) Inhibits NAd reuptake
- (+) Enhances 5HT release, inhibits 5HT reuptake, weak mu (& less kapaa/delta) agonist.
- Oral (50 mg capsules, 100 mg tablets) & parenteral (100 mg/2mL) preparations.
- pKa 9.4
- Dose - 5-10x less potent than morphine: 50-100 mg q6h, max 400-600 mg/day.
- 2-3 mg/kg loading, then 1-2 mg/kg q6h.
- PCA IV tramadol: 20 mg/mL then step down to oral (Prof Schug, Perth: 25-50 mg q1h PCA, using up to 1500 mg/24h).
- analgesic efficacy and potency comparable to pethidine
- Caudal: 2 mg/kg
- Absorption - IV, IM, po (80% biov)
- Distribution - 3 L/kg (80% crosses placenta).
- Protein binding - 20%
- Onset 30 min; Offset 6 h
- peak [plasma] after po: 2h
- Metabolism - t½ 6h (12h in renal impairment);
- 85% p450 (CYP-2D6 - also converts codeine → morphine & metabolises ondansetron!)
- Demethylation to 'O-demethyl-tramadol' (M1) t½ 9h - has some activity as it has 6x greater mu affinity than tramadol. Some consider tramadol a prodrug because of this.
- 90% excreted in urine, 10% in faecies.
- metabolism inhibited by quinidine
- Clearance - 9 mL/kg/min
- Mech - weak mu agonists (30% of action) (very weak kappa & delta); inhibits NAd reuptake (through indirect activation of post-synaptic alpha-2 adrenoreceptors) and stimulates 5HT release, so activates desc NAd and 5HT pathways (70%), modulating pain pathways.
- Naloxone antagonises only 30% tramadol analgesic effect. Ondansetron antagonises a further 30% of tramadol analgesic effect.
- CNS - analgesia, good for neuropathic pain, low(er) incidence of tolerance & dependence, lowers seizure threshold, dizziness, sweating.
- stops shivering?
- CVS - few CVS effects. Some tachycardia and flushing.
- Resp - little respiratory depression.
- Renal - caution in renal failure.
- GIT - Nausea & vomiting (30-40%, like morphine), minimal constipation, minimal biliary spasm.
- SEs - interacts with MAOI, SSRIs.
- Quinidine may decrease efficacy of tramadol by inhibiting CYP-2D6, thus decreasing production of M1. Codeine my compete for the same enzyme with a similar result.
- Carbamazepine induces CYP-2D6 decreasing effect by increasing metabolism.
Unfortunate wording in the conclusion here, implying causation where in fact there is no evidence of such. Delivery mode does not have a significant effect – it is rather significantly associated with PPD.
The mode of delivery has a significant effect on the occurrence of mild postpartum depression.
It's unfortunate that the authors and editors were not more careful with their wording in a very emotionally-charged and controversial area.
Although interesting and perhaps relevant to settings which require motor block resolution before discharge from PACU (or when there are bupivacaine shortages), the practical relevance of this study is questionable.
Notable in this French study is the extended duration of PACU stay after caesarean section: more than 2 hours in the prilocaine group, and 3 hours in the bupivcaine group! It is unclear whether this is routine post-CS care, or specific to the study design to allow for motor block assessment.
Also of note, the caesarean sections were "...performed using Misgav-Ladach technique with externalisation of the uterus" which may again make this study less relevant in settings where it is routinely accepted that avoiding uterine externalisation makes for better patient experience.
The most relevant takeaway from this meta-analysis is really just how poor a lot of the evidence around resuscitation and CPR is (not for lack of effort, but because of the obvious limitations of research around critical-event and end-of-life medicine). Not only was the analysed evidence of low certainty but notably all seven RCTs were manikin studies.
Manikins are designed for resuscitation education and training, not for physiological fidelity. Even if this study had shown an improvement in compression depth for different surfaces, it's relevance to CPR in flesh-and-blood humans would be no less questionable.
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