The influence of oxygen tension on membrane potential and tone of canine carotid artery smooth muscle

Endothelial cell dysfunction and abnormal tissue perfusion

OBJECTIVE

To determine the precise role of the myoendothelial regulatory unit in improved tissue perfusion and metabolic regulation.

DATA SOURCES AND STUDY SELECTION

A review of the published literature (MEDLINE and other original articles and reviews) on endothelial cells, vascular reactivity, and tissue perfusion.

DATA EXTRACTION AND SYNTHESIS

According to the concept of intrinsic metabolic regulation, vasodilation in tissues with relatively high metabolic rates competes with sympathetic vasoconstrictor tone, thereby adjusting the balance between local tissue oxygen supply and demand. Although the nature of the oxygen-sensitive structures acting at the local tissue level is not completely understood, endothelial cells in direct contact with blood have a number of properties that confer the potential to act as effective oxygen sensors. The endothelium and smooth muscle of arteries and arterioles seem to be coupled both structurally and functionally. Sensing involves local depolarization and hyperpolarization of the capillary endothelial cell, and communication is achieved by an electronic spread via endothelium-smooth muscle cell-to-cell gap junctions. Therefore, during hypoxic challenge, the ability of a tissue to extract oxygen-and to minimize shunting through areas with a high rate of perfusion relative to their oxygen uptake-may be considered an integrative test of endothelium function and microcirculatory coordination.

CONCLUSION

Endothelial cells seem to play a central role in coordinating the microcirculatory system and promoting tissue perfusion and oxygen supply. In a pathologic situation such as sepsis, abnormal interendothelial cell coupling and an abnormal arteriolar conducted response may account for impaired tissue perfusion and abnormal oxygen extraction.

Endothelin alters the reactivity of vasa vasorum: mechanisms and implications for conduit vessel physiology and pathophysiology

1 The walls of certain large blood vessels are nourished by the vasa vasorum, a network of microvessels that penetrate the adventitia and media of the vessel wall. The purpose of this study was to characterize endothelin-1 (ET-1)-mediated contraction of vasa and to investigate whether threshold concentrations of ET-1 alters the sensitivity to constrictors. Arterial vasa were dissected from the walls of porcine thoracic aorta and mounted in a tension myograph. 2 ET-1 and ETB-selective agonist, sarafotoxin 6c (S6c), produced concentration-dependent contraction. ETA receptor antagonist, BQ123 (10 microM), caused a biphasic rightward shift of ET-1 response curves. ETB receptor antagonist, BQ788 (1 microM), produced a rightward shift of response curves to ET-1 and S6c of 5- and 80 fold respectively. 3 ET-1 responses were abolished in Ca2+-free PSS but unaffected by selective depletion of intracellular Ca2+ stores. Nifedipine (10 microM), an L-type Ca2+ channel blocker, attenuated ET-1 responses by 44%. Inhibition of receptor-operated Ca2+ channels or non-selective cation entry using SKF 96365 (30 microM) and Ni2+ (1 mM) respectively, attenuated ET-1 contractions by 60%. 4 ET-1 (1-3 nM) enhanced responses to noradrenaline (NA) (4 fold) but not to thromboxane A2-mimetic, whilst K+ (10-20 mM) sensitized vasa to both types of constrictor. 5 Therefore, ET-1-induced contraction of isolated vasa is mediated by ETA and ETB receptors and involves Ca2+ influx through L-type and non-L-type Ca2+ channels. Furthermore elevation of basal tone of vasa vasorum alters the profile of contractile reactivity. These results suggest that ET-1 may be an important regulator of vasa vasorum reactivity.

Electrical and mechanical responses of rat middle cerebral arteries to reduced PO2 and prostacyclin

Isolated rat middle cerebral arteries were perfused and superfused with physiological salt solution equilibrated with a control (approximately 140 mmHg) or reduced (approximately 35-40 mmHg) PO2. In other experiments, cerebral arteries were isolated and prostacyclin release was determined by radioimmunoassay for 6-ketoprostaglandin F1alpha. Equilibration of the vessels with reduced PO2 (35 mmHg) solution caused a significant increase in prostacyclin release relative to control PO2 (140 mmHg) conditions. Exposure of middle cerebral arteries to reduced PO2 caused vascular smooth muscle (VSM) hyperpolarization and vessel relaxation, which could be blocked by 1 microM glibenclamide, an inhibitor of the ATP-sensitive K+ channel, but not by 1 mM tetraethylammonium (TEA), an inhibitor of the Ca2+-activated K+ channel. Glibenclamide also inhibited VSM hyperpolarization and vasodilation in response to the stable prostacyclin analog iloprost, but TEA did not affect iloprost-induced dilation of the vessel. Endothelial removal eliminated the electrical and mechanical responses of the arteries to reduced PO2, but vessel responses to iloprost were similar to those of intact vessels. The results of this study are consistent with the hypothesis that hypoxic dilation of rat middle cerebral arteries is due to VSM hyperpolarization mediated by prostacyclin-induced activation of glibenclamide-sensitive K+ channels.

Contribution of oxygen-sensitive neurons of the rostral ventrolateral medulla to hypoxic cerebral vasodilatation in the rat

1. We sought to determine whether hypoxic stimulation of neurons of the rostral ventrolateral reticular nucleus (RVL) would elevate regional cerebral blood flow (rCBF) in anaesthetized paralysed rats. 2. Microinjection of sodium cyanide (NaCN; 150-450 pmol) into the RVL rapidly (within 1-2 s), transiently, dose-dependently and site-specifically elevated rCBF1 measured by laser Doppler flowmetry, by 61.3 +/- 22.1% (P < 0.01), increased arterial pressure (AP; +30 +/- 8 mmHg; P < 0.01)1 and triggered a synchronized 6 Hz rhythm of EEG activity. 3. Following cervical spinal cord transection, NaCN and also dinitrophenol (DNP) significantly (P < 0.05) elevated rCBF and synchronized the EEG but did not elevate AP; the response to NaCN was attenuated by hyperoxia and deepening of anaesthesia. 4. Electrical stimulation of NaCN-sensitive sites in the RVL in spinalized rats increased rCBF measured autoradiographically with 14C iodoantipyrine (Kety method) in the mid-line thalamus (by 182.3 +/- 17.2%; P < 0.05) and cerebral cortex (by 172.6 +/- 15.6%; P < 0.05) regions, respectively, directly or indirectly innervated by RVL neurons, and in the remainder of the brain. In contrast regional cerebral glucose utilization (rCGU), measured autoradiographically with 14C-2-deoxyglucose (Sokoloff method), was increased in proportion to rCBF in the mid-line thalamus (165.6 +/- 17.8%, P < 0.05) but was unchanged in the cortex. 5. Bilateral electrolytic lesions of NaCN sensitive sites of RVL, while not altering resting rCBF or the elevation elicited by hypercarbia (arterial CO2 pressure, Pa,CO2, approximately 69 mmHg), reduced the vasodilatation elicited by normocapnic hypoxaemia (arterial O2 pressure, Pa,O2, approximately 27 mmHg) by 67% (P < 0.01) and flattened the slope of the Pa,O2-rCBF response curve. 6. We conclude that the elevation of rCBF produced in the cerebral cortex by hypoxaemia is in large measure neurogenic, mediated trans-synaptically over intrinsic neuronal pathways, and initiated by excitation of oxygen sensitive neurons in the RVL.

ATP-sensitive K+ channels mediate alpha 2D-adrenergic receptor contraction of arteriolar smooth muscle and reversal of contraction by hypoxia

Evidence in rat skeletal muscle suggests that local metabolic control of blood flow is facilitated by the reliance on alpha 2D-adrenergic receptors (ARs) for constriction of arterioles, together with the strong sensitivity of this constriction to inhibition by hypoxia. The present study examined the role of ATP-sensitive K+ (KATP) channels in the selective interaction between alpha 2D-ARs and hypoxia. Arterioles from rat cremaster muscle that possess both alpha 1D (alpha 1A/D)- and alpha 2D-AR subtypes were microcannulated, pressurized, and isolated in a tissue bath for measurement of changes in lumen diameter. Three studies first examined whether stimulation of alpha 2D- and alpha 1D-ARs involves inhibition of the KATP channel. Concentration-dependent constriction by the KATP antagonists glibenclamide (GLB, 0.01 to 10 mumol/L) and disopyramide (0.001 to 1 mmol/L) were abolished during alpha 2D stimulation but unaffected during alpha 1D stimulation. Activation of the KATP channel by cromakalim inhibited alpha 2D constriction with greater potency than alpha 1D (EC50, 7.0 +/- 0.2 versus 6.3 +/- 0.1). Finally, GLB (0.5 mumol/L) abolished dose-dependent alpha 2D constriction, whereas alpha 1D was unaffected. These data suggest that alpha 2D but not alpha 1D stimulation is "coupled" with closure of the KATP channel, leading to depolarization and contraction of vascular smooth muscle. In a second series, hypoxic (PO2, 6 mm Hg) inhibition of intrinsic smooth muscle tone was completely reversed by 0.1 mumol/L GLB, concentration-dependent GLB constriction was enhanced during hypoxia, and hypoxia reversed GLB constriction. These data confirm reports by others that hypoxia potentiates the activation of KATP channels, leading to hyperpolarization and relaxation. Finally, GLB constriction, which was abolished by concomitant alpha 2D stimulation, was completely restored by simultaneous activation of KATP channels with hypoxia. These findings suggest that the sensitivity of alpha 2D-AR constriction to inhibition by hypoxia arises through "antagonistic coupling" between these two stimuli, by which the alpha 2D-AR inhibits and hypoxia activates KATP channels.

Evaluation of vasculogenic impotence by monitoring of cavernous oxygen tension

Color coded duplex sonography, regarded as the gold standard in penile vascular evaluation, does not yield data on cavernous oxygenation itself. In addition to using color coded duplex sonography to measure peak flow velocity in cavernous arteries after injection of 20 micrograms. prostaglandin E1 in 34 unselected patients with impotence, we monitored cavernous oxygen tension with oxygen-sensitive Eppendorf needle electrode. During flaccidity the mean cavernous oxygen tension of 38 mm. Hg increased to 61 mm. Hg after injection of prostaglandin E1. Peak flow shown with color coded duplex sonography and maximal oxygen tension correlated well in 24 men (71%). However, in 10 men (29%) normal peak flow did not result in a cavernous oxygen tension of greater than 65 mm. Hg, so this might have been isolated cavernous perfusion defects. In contrast, there was no case of impaired arterial inflow and high oxygen tension. Monitoring of cavernous oxygen tension allows for characterization of patients with cavernous perfusion deficiency. This new and simple diagnostic method might help to improve diagnosis and followup after penile vascular surgery. However, more data on patients and controls will be required to define normal ranges.

Vasomotion in the rat cerebral microcirculation recorded by laser-Doppler flowmetry

In the present study, changes in frequency and amplitude of the rhythmic variations (vasomotion) in blood flow in the intact cerebral circulation of the rat were investigated using laser-Doppler flowmetry (LDF) during stepwise decrease in mean arterial blood pressure (MABP) and hyper- and hypocapnia. Experiments were performed on 12 adult Sprague-Dawley rats of either sex, anesthetized with alpha-chloralose. The rat's head was fixed on a stereotaxic frame and a small hole was made in the parietal bone but the dura and a thin inner bone layer were kept intact. The microvascular blood flow of the parietal cortex on the right or on both sides was continuously recorded by the laser-Doppler flowmeter (Periflux PF2B, Perimed, Stockholm, Sweden). The cerebral circulation of the rat exhibited vasomotion in control conditions with a frequency of 8-10 cycles per minute (cpm) and an amplitude of 5-10% of the cerebral blood flow (CBF). No significant changes in CBF could be detected when the MABP was above 60 mmHg, but it decreased significantly when MABP was reduced below 50 mmHg. However, during stepwise pressure reduction the vasomotion frequency decreased progressively while its amplitude showed a reversed U-shaped curve with a peak at 60-80 mmHg. During hypercapnia, the rhythmical oscillations showed a decrease in both frequency and amplitude, whereas during hypocapnia their frequency did not change but their amplitude increased. These results support the hypothesis that the vasomotion frequency might be dependent of the wall tension and cellular pH while its amplitude could be related to decreased tissue oxygenation.

Effects of endothelium-derived nitric oxide on cerebral circulation during normoxia and hypoxia in the rat

The aim of this study was to determine the effects of endogenous nitric oxide (NO) on cerebral blood flow (CBF) and cerebrovascular resistance (CVR) under conditions of normoxia and hypoxia. Experiments were performed on anesthetized, mechanically ventilated Wistar rats. CBF was measured using the intracarotid 133Xe injection technique. NO formation was inhibited by NG-monomethyl-L-arginine (L-NMMA). Administration of L-NMMA (100 mg kg-1 i.v.) during normoxia resulted in an increase in mean arterial blood pressure from 113 +/- 4 to 145 +/- 4 mm Hg (p less than 0.001), a decrease in CBF of 21% (from 91 +/- 4 to 75 +/- 5 ml 100 g-1 min-1, p less than 0.001), and an increase in CVR of 53% (from 1.3 +/- 0.1 to 2.0 +/- 0.2 mm Hg ml-1 100 g min, p less than 0.001). These effects were reversed by i.v. administration of 300 mg kg-1 of L-arginine but not D-arginine. Moreover, the administration of L-NMMA abolished the enhancement of CBF and the diminution in CVR observed during intracarotid infusion of acetylcholine (ACh). The increase in CBF and decrease in CVR during hypoxia in the group of rats that received L-NMMA were similar to that in the control group, although CBF and CVR levels attained during hypoxia in both groups were different. The results show that NO is involved in the maintenance of basal CBF and CVR, and is responsible for the ACh-elicited increase in CBF and the decrease in CVR in rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Potassium channel activation in vascular smooth muscle

1. Numerous compounds and changes in physical state functions shift the membrane potential of vascular smooth muscle to more negative values. The consequence is a vasodilatation because Ca2+ channels are closed. K+ channel opening frequently causes the hyperpolarization. 2. Acidification of the blood substitute solution and a fall in O2 partial pressure dilate arterial vessels. Acidosis is associated with a rise in K+ permeability and a simultaneous fall in Na+ permeability. Prostacyclin has a 20-30% share, and EDHF a 70-80% share, in hypoxic vasodilatation. Experiments with iloprost (PGI2 analogue) confirmed the K+ channel opening properties of this drug. A voltage-dependent K+ channel and a Ca(2+)-activated K+ channel, via the influence of cA-PK or cG-PK, are responsible for the hyperpolarization with iloprost and with oxygen deficiency. 3. Cicletanine and ajoene cause a concentration-dependent membrane hyperpolarization and are potent vasodilators. A cicletanine concentration, which is attained by the dosage given to patients, is sufficient to produce these effects. Ajoene exerts a hyperpolarizing and vasodilating influence even in a concentration which may occur in the extracellular space by the administration of a single garlic clove. 4. The stationary activation curve 'developed force vs. membrane potential' satisfactorily explains the effects of K+ channel openers. The tight electromechanical coupling expressed by this curve comprises a 50% vasorelaxation for a 2.5 mV hyperpolarization. In the linear part of the curve, the coupling ratio is 5.1 mV/g. 5. In the vascular smooth muscle, vasorelaxation can be evoked by membrane hyperpolarization which is linked to a simultaneous increase in K+ outward current and 42K+ efflux. In the case of substances whose influence is solely or partially receptor-mediated, cyclic nucleotides may be involved in vasorelaxation. Since cyclic nucleotides also hyperpolarize through an increase in K+ conductance, the resulting dilatation often cannot be divided into its single components. Therefore, it is sensible not to give the term "K+ channel opener" too fine a definition. The term should be applied to all substances and changes in physical states which predominantly increase the open probability of K+ channels finally via a conformational change in the cell membrane. For example, giving an acidic blood substitute solution (acidosis) is an intervention opening K+ channels. Which K+ channel and which single channel conductance is concerned in a particular case, and which 'mediator' may participate, become secondary questions.

Endothelial cells as part of a vascular oxygen-sensing system: hypoxia-induced release of autacoids

Higher developed organisms are equipped with many central and local control mechanisms, which enable an adequate blood and oxygen supply to tissues over a wide range of demands. Global adaptive responses include changes in the circulatory and ventilatory system as well as increases in the oxygen carrying capacity of the blood. At the level of the specialized organs there exist additional control systems for the regulation of local blood flow. Most systems make use of highly specialized cells which are able to sense the oxygen partial pressure of the transport medium, blood, and within the tissues. In the past years, it has been shown that the vascular endothelium lining the entire circulatory system can actively modulate the vascular tone and platelet functions by the release of autacoids, among them prostacyclin and endothelium-derived nitric oxide (EDRF). Recent experiments demonstrate that the release of EDRF is PO2-dependent, which suggests that endothelial cells may act as functional local oxygen sensors within the vascular system.

The interaction between oxygen and vascular wall

In vascular strips of canine carotid arteries stepwise lowering of oxygen tension from hyperoxic levels of 550 mmHg to 20 mmHg caused in preparations with endothelium a dose-dependent hyperpolarization and relaxation of smooth muscle cells when oxygen tensions between approximately 150 mmHg and 35 mmHg were attained. Pronounced hypoxia with oxygen tensions below 30 mmHg induced a depolarisation and an increase in force generation. During comparable investigations on vessel preparations without endothelium only a slight hyperpolarization and relaxation of the smooth muscle were observed when decreasing the oxygen tension from 550 mmHg to approx. 35 mmHg. In the presence of indomethacin (10(-5) M) a small but significant reduction in the hypoxia-induced hyperpolarization and decrease in smooth muscle tone was found in intact vascular strips with endothelium. Depolarisation and contraction occurred at oxygen tensions below approx. 50-60 mmHg.