Effects of propofol on desipramine-sensitive [3H]-noradrenaline uptake kinetics in rat femoral artery

Novel Expression of GABAA Receptors on Resistance Arteries That Modulate Myogenic Tone

The clinical administration of GABAergic medications leads to hypotension which has classically been attributed to the modulation of neuronal activity in the central and peripheral nervous systems. However, certain types of peripheral smooth muscle cells have been shown to express GABAA receptors, which modulate smooth muscle tone, by the activation of these chloride channels on smooth muscle cell plasma membranes. Limited prior studies demonstrate that non-human large-caliber capacitance blood vessels mounted on a wire myograph are responsive to GABAA ligands. We questioned whether GABAA receptors are expressed in human resistance arteries and whether they modulate myogenic tone. We demonstrate the novel expression of GABAA subunits on vascular smooth muscle from small-caliber human omental and mouse tail resistance arteries. We show that GABAA receptors modulate both plasma membrane potential and calcium responses in primary cultured cells from human resistance arteries. Lastly, we demonstrate functional physiologic modulation of myogenic tone via GABAA receptor activation in human and mouse arteries. Together, these studies demonstrate a previously unrecognized role for GABAA receptors in the modulation of myogenic tone in mouse and human resistance arteries.

A quantitative description of the diffusion of noradrenaline in the media of blood vessels following its release from sympathetic varicosities

A quantitative model is provided which describes how noradrenaline (NAd), released from varicosities at the adventitial surface of an artery, either diffuses into the media of the vessel to reach the intimal surface, diffuses into the volume of solution surrounding the artery, or is removed by the uptake 1 process in the varicosities. These predictions are then compared with experimental evaluations of the extent of changes in NAd to be found at the adventitial and intimal surfaces of the rat-tail artery, during and after trains of impulses, as determined using amperometry. In the model of the blood vessel there is a sequential decrease in the diffusion constant of NAd from the surrounding solution, to the adventitia, to the media, to the endothelium, to rise again in the lumen of the vessel; there is also an uptake 1 NAd pump in the varicosities described by Michaelis-Menten kinetics. This model is shown to provide a quantitative account of the spatial and temporal changes in NAd observed following trains of impulses at different frequencies of stimulation (5-40 Hz) for different periods of times (10-40 s). Changes in the spatio-temporal distribution of NAd observed following block of the uptake 1 NAd pump were also successfully predicted by the model. It is concluded that, within the context of the model, there is no need to evoke special mechanisms of buffering at the sympathetic varicosities, nor distinctions on the basis that only secreting varicosities utilize the uptake 1 mechanism, in order to describe the dynamics of NAd distribution in arteries during nerve activity.

Effects of sevoflurane on sympathetic neurotransmission in human omental arteries and veins

BACKGROUND

Sevoflurane reduces blood pressure, the regulation of which requires an intact sympathetic neurotransmission. This study was designed to evaluate the effect of sevoflurane on the coupling between peripheral sympathetic neurones and vascular smooth muscle in isolated human omental vessels.

METHODS

Segments of arteries and veins were exposed to sevoflurane 1%, 2% and 4% (corresponding to approximately 0.5, 1 and 2 MAC in humans, respectively). The vessels were studied in vitro to determine the effects on (i) isometric contraction during electrical field stimulation (EFS) or in the presence of exogenous norepinephrine (NE); (ii) electrical field stimulated release of [(3)H]-NE from vessel segments previously incubated with [(3)H]-NE; (iii) uptake of [(3)H]-NE.

RESULTS

In artery segments, sevoflurane 4% attenuated the contraction induced by both EFS and exogenous NE. In vein segments, sevoflurane 4% attenuated only the EFS-induced contractions. Sevoflurane 1% and 2% had no effect. The release of [(3)H]-NE was inhibited by sevoflurane 2% and 4% in arteries and by sevoflurane 1%, 2% and 4% in veins. Sevoflurane had no effect on the uptake of [(3)H]-NE in either vessel.

CONCLUSIONS

Sevoflurane depresses sympathetic neuromuscular transmission in human omental vessels by reducing neuronal NE release and NE sensitivity in arteries and by reducing NE release in veins. This could contribute to the hypotension seen during sevoflurane anaesthesia, at least at concentrations above 1 MAC.