naloxone and Hyperkalemia

Myotonic dystrophy (MyD) is a common genetic neuromuscular disorder in which chromosome 19 gives rise to an abnormal expansion of CTG-trinucleotide repeats. MyD is a highly variable multisystem disorder with muscular and nonmuscular abnormalities. Increasingly, endocrine abnormalities, such as gonadal, pancreatic, and adrenal dysfunction are being uncovered. Herein we present three unrelated cases with MyD with abnormally elevated serum potassium; 2 of the 3 cases presented clinically with cardiac dysrhythmias. Hyperkalaemic conditions such as renal failure, cortisol deficiency, pseudohyperkalaemia, and hyperkalaemic periodic paralysis were excluded. Further endocrine evaluation revealed baseline hypoaldosteronism associated with elevated renin activity. Perturbation of the renin-angiotensin-aldosterone system resulted in appropriately enhanced renin activity but with a subnormal aldosterone response, which appeared to be due to adrenal hyporesponsiveness. The treatment of all cases with fludrocortisone was without effect. Whether the apparent mineralocorticoid abnormality in MyD is due to associated hormonal perturbations (i.e. excessive ACTH responsiveness. elevated cytokines, elevated atrial natriuretic hormone, etc.), adrenal atrophy, and/or a manifestation of the underlying kinase dysfunction is uncertain, but merits further evaluation in view of the clinical consequence of hyperkalaemia.

Topics: Adrenal Cortex; Adrenocorticotropic Hormone; Adult; Diuretics; Female; Fludrocortisone; Furosemide; Humans; Hydrocortisone; Hyperkalemia; Hypoaldosteronism; Male; Mineralocorticoids; Myotonic Dystrophy; Naloxone; Renin; Stimulation, Chemical; Treatment Failure; Trinucleotide Repeat Expansion

The aim was to investigate the cardiac electrophysiological effects of the opioid receptor antagonist naloxone and examine whether hyperkalaemia and ischaemia influence these effects.. The cardiac electrophysiological effects of racemic naloxone, nalmafene, and morphine were examined in superfused rabbit papillary muscles under normal conditions and in the case of naloxone under conditions of hyperkalaemia. The electrophysiological effects of racemic naloxone and d-naloxone were examined in arterially perfused rabbit interventricular septa before and during 30 min global zero flow ischaemia; the rate of rise of extracellular K+ concentration was also measured.. Naloxone, nalmafene and morphine all prolonged action potential duration and effective refractory period in superfused papillary muscles (class III effects), suggesting that these effects are not receptor mediated. During hyperkalaemia, naloxone increased the depressant effect on the maximum upstroke velocity of the action potential and enhanced post-repolarisation refractoriness, further suggesting a class I effect. Both racemic naloxone (active at opioid receptors) and d-naloxone (inactive) prolonged action potential duration and effective refractory period in septa, again suggesting non-receptor-mediated effects. During myocardial ischaemia the class III effects of both compounds were gradually lost in such a way that post-repolarisation refractoriness developed. Both compounds reduced the rate of rise of extracellular K+ concentration and preserved resting membrane potential, but the fall in maximum upstroke velocity was enhanced, again suggesting that naloxone has an additional class I effect in partially depolarised ventricular myocardium.. The antiarrhythmic activity of naloxone in models of myocardial ischaemia/reperfusion can be explained by non-opioid receptor mediated effects on the duration and maximum upstroke velocity of the action potential and on extracellular potassium accumulation during ischaemia.

Topics: Action Potentials; Animals; Culture Techniques; Dose-Response Relationship, Drug; Electrophysiology; Heart Conduction System; Hyperkalemia; Morphine; Myocardial Ischemia; Naloxone; Naltrexone; Narcotic Antagonists; Rabbits; Refractory Period, Electrophysiological