naloxone and Syncope

The haemodynamic response to progressive hypovolaemia, whether simulated by lower body negative pressure (LBNP) or head-up tilt, or induced by haemorrhage or haemodialysis, has a typical biphasic pattern: a first, sympathoexcitatory, phase of vasoconstriction, tachycardia, and stable blood pressure, and a second, sympathoinhibitory, phase of vasodilatation, bradycardia, and hypotension. The opioid system is involved in this response, since animal studies showed that opioid antagonism by naloxone can attenuate hypovolaemic hypotension. In humans, this finding could not be confirmed. We hypothesized that this could result from inadequate dosing.. Six healthy subjects underwent LBNP at -45 mmHg until presyncope before and after administration of naloxone 2 mg/kg. During the study, blood pressure, heart rate, vascular resistance, cardiac output, and plasma beta-endorphin were measured.. LBNP caused an immediate increase in vasoconstriction and heart rate, resulting in stable blood pressure. After 12 +/- 3.5 min, vasodilatory hypotension followed, accompanied by a modest increase in plasma beta-endorphin. Naloxone did not alter the first or the second phase of the circulatory response, and tolerance to LBNP even tended to decrease (hypotension after 7.5 +/- 2.0 min, NS). Pre-LBNP plasma beta-endorphin as well as hypotensive levels were increased after naloxone.. Our results suggest that naloxone, in a sufficient dose to interfere with the opioid system, does not influence the circulatory response to simulated hypovolaemia in humans is not influenced by naloxone. Given the mechanistic resemblance of LBNP hypotension to dialysis-induced hypotension, we propose that high-dose naloxone is not useful to treat the latter form of hypotension.

Topics: Adult; Blood Volume; Dose-Response Relationship, Drug; Female; Humans; Lower Body Negative Pressure; Male; Naloxone; Narcotic Antagonists; Neural Inhibition; Sympathetic Nervous System; Syncope

The mechanism of vasovagal syncope during orthostasis in humans is unknown. Opioid receptors have been implicated in the vasovagal-like responses to hemorrhagic hypotension in conscious animals. We sought to determine if opioid receptor blockade with naloxone (mu receptor antagonist) would prevent or delay the onset of vasovagal syncope in humans. Three protocols were performed in which heart rate, arterial pressure, sympathetic nerve activity, thoracic impedance and forearm vascular resistance were measured during stepwise steady-state increments of lower body negative pressure (LBNP) in nine healthy volunteers. In protocol 1, duplicate trials of LBNP to syncope or -60 mmHg were performed with a 30-45 minute rest period separating the trials. No significant differences in any physiologic responses or cumulative stress tolerance were found. In protocol 2, graded LBNP was repeated after administration of saline or naloxone (0.1 mg/kg) in six subjects in which vasovagal syncope occurred prior to -60 mmHg LBNP. The peak increase of sympathetic nerve activity during LBNP was augmented after naloxone (P = 0.02), but the occurrence of vasovagal syncope was not prevented nor was the cumulative stress tolerated affected (P = 0.42). The heart rate and arterial pressure responses to LBNP were not affected by naloxone. Similarly, in protocol 3, naloxone given just prior to the onset of pre-syncopal symptoms did not alter the physiologic response or the occurrence of vasovagal syncope. These data show that naloxone does not prevent or delay the onset of vasovagal syncope in humans which suggests that mu opioid receptors do not mediate the vasovagal response.

Topics: Adult; Blood Pressure; Electrocardiography; Female; Heart Rate; Humans; Hypotension, Orthostatic; Injections, Intravenous; Lower Body Negative Pressure; Male; Naloxone; Regional Blood Flow; Sympathetic Nervous System; Syncope; Vagus Nerve; Vascular Resistance