Hesham M. Amin

Efficacy of Methylnaltrexone Versus Naloxone for Reversal of Morphine-induced Depression of Hypoxic Ventilatory Response

Methylnaltrexone (MNTX) is a quaternary derivative of naltrexone. It does not cross the blood-brain barrier and, thus, it reverses peripherally mediated effects of morphine without blocking its centrally located analgesic effects. The effects of MNTX on morphine-induced depression of hypoxic ventilatory response are unknown. We evaluated the efficacy of MNTX, compared with naloxone, in reversing this effect. On three sessions separated by a week, 10 healthy male volunteers received morphine, 0.125 mg/kg, as a bolus at 20 min after completing a control hypoxic ventilatory challenge. At 60 min, naloxone, 5 μg/kg, MNTX, 0.3 mg/kg, or placebo was administered in a randomized double-blind order. Four isocapnic hypoxic ventilatory challenges were conducted: 0 min (control), 40 min (postmorphine), and 80 and 120 min (postreversal) and the hypoxic respiratory responses were recorded. Morphine administration was associated with a significant depression in hypoxic responses: The slope of the response (L/min/Spo2) and the predicted ventilation at 80% O2 saturation (VE80) (L/min) decreased significantly in the three sessions (P < 0.05). Naloxone injection reversed the respiratory depression at 80 min (85% of the control value of the slope and 89% of VE80), whereas MNTX and placebo did not. At 120 min, the slope (69%) and VE80 (80%) after naloxone administration were not significantly different from control. MNTX slope (69%) was not statistically different from the control, whereas VE80 (70%) was still depressed (P < 0.05). Placebo slope and VE80, at 120 min, remained lower than the control (P < 0.05). These data show that MNTX is not as effective as naloxone for reversal of morphine-mediated depression of respiration during acute hypoxia.

Site of action of endogenous nitric oxide on pulmonary vasculature in rats

The effect of endogenous nitric oxide (NO) on the pulmonary hypoxic vasoconstriction was studied in isolated and blood perfused rat lungs. By applying the occlusion technique we partitioned the total pulmonary vascular resistance (PVR) into four segments: (1) large arteries (Ra), (2) small arteries (Ra′), (3) small veins (Rv′), and (4) large veins (Rv). The resistances were evaluated under baseline (BL) conditions and during; hypoxic vasoconstriction and acetylcholine (Ach) which was injected during hypoxic vasoconstriction. After recovery from hypoxia and Ach, Nω-nitro-L-arginine (L-NA) was added to the reservoir and the responses to hypoxia and Ach were reevaluated. Before L-NA, hypoxia caused significant increase in the resistances of all segments (P < 0.05), with the largest being in Ra and Ra′. Ach-induced relaxation during hypoxia occurred in Ra, Ra′ and Rv′ (P < 0.05). L-NA did not change the basal tone of the pulmonary vasculature significantly. However, after L-NA, hypoxic vasoconstriction was markedly enhanced in Ra, Ra′, and Rv′ (P < 0.01) compared with the hypoxic response before L-NA. Ach-induced relaxation was abolished after L-NA. We conclude that, in rat lungs, inhibition of NO production during hypoxia enhances the response in the small arteries and veins as well as in the large arteries. The results suggest that hypoxic vasoconstriction in the large pulmonary arteries and small vessels is attenuated by NO release.

HEMATOLOGICAL ALTERATIONS AFTER ACUTE EXPOSURE TO HYPERBARIC OXYGEN IN RATS

1. Acute exposure to hyperbaric oxygen (HBO) is associated with a significant increase in haematocrit which returns to the control level after 24 h of recovery in room air. In this study we report changes in blood viscosity in Sprague‐Dawley rats after acute exposure to HBO.

Noninvasive monitoring of respiratory volume. Experimental evaluation of a breath monitoring device.

The authors studied the accuracy of the noninvasive breath monitor (Voltek Enterprise, Willowdale, Ontario, Canada) in predicting the tidal volumes in five healthy human volunteers. The signals of the breath monitor were compared with the volumes estimated by a calibrated pneumotachograph. The results show that the breath monitor is considerably accurate and can be accepted as a reliable device for clinical applications.