Pressure-dependent membrane depolarization in cat middle cerebral artery

Noradrenaline-induced depolarization is smaller in isobaric compared to isometric preparations of rat mesenteric small arteries

The hypothesis was tested that wall tension can influence the membrane potential response to noradrenaline (NA) using isometric and isobaric vessel preparations of rat mesenteric small arteries. The resting membrane potential was significantly less negative in the isobaric (-49.7+/-0.5 mV, S.E.M., n=12 vessels) compared to the isometric preparation (-56.1+/-0.7 mV, n=10), although there was no difference in wall tension. The depolarization induced by 10(-5) M NA was 2.6-fold smaller in the isobaric preparation, where wall tension decreased, compared to the isometric preparation, where wall tension increased. Since wall tension decreases under isobaric conditions, but increases under isometric conditions, the latter finding can be explained by assuming that part of the NA-induced membrane potential change is wall tension dependent.

Relaxation of arterial smooth muscle by calcium sparks

Local increases in intracellular calcium ion concentration ([Ca2+]i) resulting from activation of the ryanodine-sensitive calcium-release channel in the sarcoplasmic reticulum (SR) of smooth muscle cause arterial dilation. Ryanodine-sensitive, spontaneous local increases in [Ca2+]i (Ca2+ sparks) from the SR were observed just under the surface membrane of single smooth muscle cells from myogenic cerebral arteries. Ryanodine and thapsigargin inhibited Ca2+ sparks and Ca(2+)-dependent potassium (KCa) currents, suggesting that Ca2+ sparks activate KCa channels. Furthermore, KCa channels activated by Ca2+ sparks appeared to hyperpolarize and dilate pressurized myogenic arteries because ryanodine and thapsigargin depolarized and constricted these arteries to an extent similar to that produced by blockers of KCa channels. Ca2+ sparks indirectly cause vasodilation through activation of KCa channels, but have little direct effect on spatially averaged [Ca2+]i, which regulates contraction.

Electrophysiological properties of the rat middle cerebral artery at different levels of passive wall tension

1. Simultaneous measurements of intracellular membrane potential and myogenic tone of proximal segments of the rat middle cerebral artery, mounted in a small vessel myograph, were made at two levels of passive wall tension. 2. At low levels of passive tension (less than 0.25 mN/mm) vessels had a resting membrane potential of approximately -65 mV. Addition of KCl (5-60 mmol/L), BaCl2 (0.01-3 mmol/L) or tetraethylammonium (TEA; 0.1-3 mmol/L) resulted in a concentration-dependent depolarization, to approximately -40 mV, generally associated with a contractile response. After the application of high levels of passive tension (to approximately 2 mN/mm maximum) the resting membrane potential of the smooth muscle cells was -40 to -45 mV. This more positive membrane potential was generally associated with an increase in myogenic tone of the vessel. Under these conditions, addition of 5-20 mmol/L KCl resulted in a strong hyperpolarization of the cell along with a concomitant decrease in myogenic tone of the artery. The hyperpolarization and vasorelaxation induced by KCl (5-20 mmol/L) were blocked by BaCl2 (0.5-1 mmol/L). 3. While the addition of ryanodine (10 mumol/L) to vessels under low tension had no effect, when added to a vessel under high tension, this agent caused a rhythmic oscillation in membrane potential. This oscillation was augmented by BaCl2 (1 mmol/L) and inhibited by nifedipine (10 nmol/L) and 4-aminopyridine (1 mmol/L). 4. This study suggests that the electrophysiological and mechanical properties of the isolated rat middle cerebral artery depend on the passive resting conditions under which the vessel is studied. The depolarization of membrane potential observed with increased passive tension appears to result from the closure of an inward rectifying K+ channel. These results indicate that the inward rectifying K+ channel plays an important role in regulating vascular reactivity due to its functional dependence on the mechanical status of the blood vessel.

Resting load regulates vascular sensitivity by a cytosolic Ca(2+)-insensitive mechanism

The cellular mechanism underlying the regulation of the contraction of vascular smooth muscles by resting load is unknown. To determine the effects of changes in the resting load on vascular sensitivity to high K+ and to 9,11-dideoxy-11 alpha, 9 alpha-epoxy-methanoprostaglandin F2 alpha (U-46619), the force and cytosolic calcium concentration ([Ca2+]i) of arterial strips were recorded at resting loads of 200 (optimal load), 50, and 10 mg. A decrease in the resting load elicited a small decrease in the basal [Ca2+]i level without affecting the extent of maximal [Ca2+]i elevation induced by either stimulus. Through a decrease in the resting load, the concentration-response curves for the force development of high K+ or of U-46619 shifted to the right, whereas those for [Ca2+]i did not. We conclude that the basal [Ca2+]i level and the force development, but not the agonist-induced [Ca2+]i signals, of vascular smooth muscles depend on the resting load. We response that the resting load regulates the sensitivity of vascular smooth muscles, irrespective of types of stimuli, through a [Ca2+]i-insensitive mechanism.

Resting load regulates cytosolic calcium-force relationship of the contraction of bovine cerebrovascular smooth muscle

1. We determined the effects of a change in preload, or resting load, on the development of force and on cytosolic calcium concentration ([Ca2+]i) during the contraction induced by high K+ depolarization and by the stable analogue of thromboxane A2, U-46619, using front-surface fluorometry and medial strips of bovine middle cerebral artery loaded with fura-2. 2. Increase in resting load of strips from 0.495 mN (low load; 0.85L(max)) to 1.98 mN (optimal load; L(max)) elevated resting levels of [Ca2+]i slightly, and, significantly, after a delay of a few seconds. The force developed by high K+ depolarization at resting load of 1.98 mN was much greater than that at a resting load of 0.495 mN (191.8% of that at 0.495 mN); however, there was no difference in [Ca2+]i elevation induced by high K+ depolarization between resting loads of 0.495 and 1.98 mN. 3. Both in the presence and absence of extracellular Ca2+, the force developed by U-46619 (0.1 microM) at resting load of 1.98 mN was also much greater than that at a resting load of 0.495 mN. Both in the presence and absence of extracellular Ca2+, there was no difference in the [Ca2+]i transients induced by U-46619 between two different resting loads. 4. The [Ca2+]i-force relationship during the contraction induced by high K+ depolarization was shifted to the left when the resting load was increased from 0.495 to 1.98 mN. At 0.495 mN resting load, this Ca(2+)-force relationship was shifted to the left by U-46619. This left-side shift of the curve by U-46619 was further enhanced by the increase in resting load from 0.495 to 1.98 mN. 5. The augmentation of force development induced by the change in resting load (from 0.495 to 1.98 mN) was not affected by a relatively specific inhibitor of protein kinase C, 1-(5-isoquinolinesulphonyl)-2-methylpiperazine dihydro-chloride (H-7; 10 microM). 6. We conclude that (1) at a given degree of [Ca2+]i elevation, the developed force induced by U-46619 was greater than that induced by high K+ depolarization, and (2) preload, or resting load (below optimal load), regulates contractile responsiveness of cerebrovascular smooth muscle to various stimulations, mainly by modulating the [Ca2+]i-force relationship, without affecting the extent of [Ca2+]i elevation. The results suggest the possibility that Ca(2+)-insensitive pathways may be involved in the stretch-dependent regulation of Ca2+ sensitivity of the contractile apparatus in smooth muscle.

Physiological roles and properties of potassium channels in arterial smooth muscle

This review examines the properties and roles of the four types of K+ channels that have been identified in the cell membrane of arterial smooth muscle cells. 1) Voltage-dependent K+ (KV) channels increase their activity with membrane depolarization and are important regulators of smooth muscle membrane potential in response to depolarizing stimuli. 2) Ca(2+)-activated K+ (KCa) channels respond to changes in intracellular Ca2+ to regulate membrane potential and play an important role in the control of myogenic tone in small arteries. 3) Inward rectifier K+ (KIR) channels regulate membrane potential in smooth muscle cells from several types of resistance arteries and may be responsible for external K(+)-induced dilations. 4) ATP-sensitive K+ (KATP) channels respond to changes in cellular metabolism and are targets of a variety of vasodilating stimuli. The main conclusions of this review are: 1) regulation of arterial smooth muscle membrane potential through activation or inhibition of K+ channel activity provides an important mechanism to dilate or constrict arteries; 2) KV, KCa, KIR, and KATP channels serve unique functions in the regulation of arterial smooth muscle membrane potential; and 3) K+ channels integrate a variety of vasoactive signals to dilate or constrict arteries through regulation of the membrane potential in arterial smooth muscle.

Calcium current in smooth muscle cells from normotensive and genetically hypertensive rats

Genetic hypertension results from numerous phenotypic expressions. We hypothesized that increased calcium current in vascular smooth muscle of genetically hypertensive animals is partly responsible for observed increases in agonist sensitivity, contractility, and calcium influx. Using adult, spontaneously hypertensive stroke-prone rats (SHRSP) and normotensive Wistar-Kyoto (WKY) controls from an inbred colony, we characterized calcium current in smooth muscle cells isolated from cerebral arteries. Calcium current in WKY cells reached a maximum of -27.7 +/- 2.7 pA (n = 32) at +20 mV. Peak inward current at +20 mV in SHRSP cells had a mean amplitude of -44.4 +/- 3.0 pA (n = 72, P < .05). SHRSP cells exhibited a higher calcium current density. Maximal inward current normalized to cell capacitance yielded mean values of 2.07 +/- 0.11 pA/pF for WKY (n = 32) and 2.80 +/- 0.12 pA/pF (n = 79) for SHRSP (P < .05) cells. Transient-type Ca2+ channel current had the same magnitude and current-voltage relation in both cell types, giving an L-type/T-type ratio of 3.85 for WKY and 6.25 for SHRSP cells. The voltage-dependent inactivation curve for SHRSP calcium current was shifted to the right only over the range of -50 to -30 mV, but the half-maximal inactivation voltages and Boltzmann coefficients were not significantly different between cell types. Increased calcium inward current in this model of genetic hypertension could account in part for altered calcium homeostasis and increased vascular reactivity, contributing to hypertension and vasospasm.

The vascular endothelium as a regulator of the ocular circulation: a new concept in ophthalmology?

The endothelium influences local vascular tone by releasing endothelium-derived relaxing factors such as nitric oxide, prostacyclin and a putative hyperpolarizing factor. In isolated ophthalmic arteries and the perfused eye, all endothelial factors importantly contribute to vascular regulation. In larger ophthalmic vessels, this is due to their effects on vascular smooth muscle cells; in smaller vessels, pericytes can be influenced as well. Contracting factors formed include peptide endothelin-1 and cyclooxygenase products, such as thromboxane A2 and prostaglandin H2. In the peripheral circulation endothelial dysfunction occurs under pathological conditions, both in conduit arteries and the microcirculation. An imbalance of endothelium-derived relaxing and contracting factors could be important for the development of vascular ophthalmic complications like hypertension, diabetes, arteriolosclerosis and retinal ischemia. Endothelial dysfunction may also contribute to vasospastic events in retinal migraine and some forms of low tension glaucoma associated with Raynaud phenomenon and migraine.

Role of wall tension in the vasoconstrictor response of cannulated rat mesenteric small arteries

1. We have studied the influence of mechanical loading conditions on the responses of cannulated rat mesenteric small arteries to noradrenaline, vasopressin and potassium. 2. The cross-sectional area (CSA) of vessels was continuously monitored. Isometric loading (CSA-controlled conditions) or isobaric loading (pressure-controlled conditions) was achieved by feedback adjustment of the distending pressure. 3. Noradrenaline (0.3 microM) and vasopressin (0.05 u l-1) induced myogenic responsiveness, resulting in a constant or declining CSA with increasing pressure. Potassium (32 mM) induced weak myogenic responsiveness. 4. At a constant pressure of 60 cmH2O, noradrenaline and vasopressin concentration-response curves were graded, the concentration-response curves of individual vessels being extended over two to three decades. Sensitivity to the vasoconstrictors, expressed as pD2 values (-log10 EC50), averaged 6.45 +/- 0.18 log M and 1.27 +/- 0.20 log u l-1 for the noradrenaline and vasopressin concentration-response curves respectively. The isobaric pD2 for K+ was 1.54 +/- 0.07 log M. 5. During CSA-controlled conditions, noradrenaline and vasopressin induced all-or-none responses to stretch. Potassium induced graded responses to stretch. 6. During CSA-controlled conditions, noradrenaline and vasopressin concentration-response curves also showed all-or-none behaviour. Almost the full response occurred through only a doubling of the concentration. pD2 values were 6.88 +/- 0.38 log M (noradrenaline) and 1.87 +/- 0.43 log u l-1 (vasopressin). Isometric vessels were significantly more sensitive to noradrenaline and vasopressin than isobaric vessels. Isometric K+ curves were gradual. pD2 was 1.54 +/- 0.07 log M, a value not different from the isobaric value. 7. These findings can be explained by assuming that agonist sensitivity is wall tension dependent, such that sensitivity increases with increasing wall tension. This concept accounts for partial regulation of wall tension during pressure-controlled conditions, as well as instability due to a positive feedback loop of active tension development and tension-induced sensitization during CSA-controlled conditions.

The role of the membrane potential of endothelial and smooth muscle cells in the regulation of coronary blood flow

In the mammalian heart the supply of oxygen and energy-rich substrates through the coronary arterioles is continuously adapted to the variations of cardiac work. The coronary resistance arteries and the surrounding myocardium form a functional unit with multiple interactions between coronary endothelial cells, smooth muscle cells, perivascular nerves, and cardiac muscle cells. We describe the mechanisms underlying the electrical and chemical communication between the different cell types, the ionic channels contributing to the resting potential of endothelial and smooth muscle cells, and the mechanisms responsible for modulation of the resting potential. The main conclusion of our analysis is that the membrane potential of coronary endothelial and smooth muscle cells is one of the major determinants of coronary blood flow, and that modulation of the membrane potential provides a way to dilate or constrict coronary resistance arteries. It is proposed that the membrane potential of the myo-endothelial regulatory unit, i.e., of the endothelial cells and the underlying smooth muscle cells in the terminal arterioles, may function as an integrator of the numerous local and global vasodilator and constrictor signals that provide for the adaptation of coronary blood flow to the metabolic demands of the heart.

On the origin and dynamics of the vasomotion of small arteries

A system of differential equations describing stationary vasomotion is formulated. It incorporates the ionic transports, cell-membrane potential, muscle contraction of the vessel smooth muscle cells, and the mechanics of a thick-walled cylinder. It is shown that the interaction of Ca2+ and K+ fluxes mediated by voltage-gated and voltage-calcium-gated channels, respectively, brings about periodicity of those transports. This results on a time-periodic cytoplasmic calcium concentration, myosin light chains phosphorylation, and crossbridges formation with the attending muscle stress. The vessel's transmural pressure determines a hoop stress. The resultant hoop, elastic, and muscle stresses determine the rate of change of the vessel's diameter: vasomotion. The model results agree with the experimental observations. The sensitivity of the vasomotion's dependence on parameter values and its significance to experimental protocols are examined. Further, it is hypothesized that the dependence of calcium-channel openings on voltage is shifted by changes on transmural pressure. Thus, Harder's experimental results are reproduced, among them the decreasing of vessel diameter with increasing pressure. Those behaviors are associated with a pattern of change of the singularities of the system of equations describing the model. This suggests a functional relationship on the interactions of Ca2+ and K+ fluxes responsible for the myogenic response; it may not result from a single molecular mechanism. The model is constructed so that additional experimental information can be readily incorporated.

Intraluminal flow-initiated hyperpolarization and depolarization shift the membrane potential of arterial smooth muscle toward an intermediate level

We examined the effect of intraluminal flow of physiological saline on the membrane potential of vascular smooth muscle cells in isolated rabbit cerebral arteries. Intraluminal flow (20 microL/min) caused a depolarization of 4.8 +/- 0.7 mV in muscle cells with a resting membrane potential of -62.5 +/- 1.2 mV (n = 19). However, when cells were depolarized to -48.7 +/- 1.8 mV using histamine and serotonin, the response to intraluminal flow was the opposite, a hyperpolarization of 5.6 +/- 1.0 mV (n = 9). These opposing effects of flow on membrane potential appear to balance at -57.8 +/- 1.1 mV (n = 31). Our results suggest that intraluminal flow may affect the level of basal tone present in arteries in vivo through modulating the membrane potential of vascular smooth muscle cells by concurrently activated depolarization and hyperpolarization.

Increased Ca2+ influx in the resting state maintains the myogenic tone and activates charybdotoxin-sensitive K+ channels in dog basilar artery

We examined whether Ca2+ channel function in the resting state alters the resting tone and Ca(2+)-activated K+ (KCa) channel function in dog basilar artery: data were compared with findings in the mesenteric artery. Isolated dog basilar artery maintained a myogenic tone; that is, the resting tone decreased when either the Krebs solution was replaced with a Ca(2+)-free solution or nifedipine was added. The basal 45Ca influx in the resting state of the basilar artery was significantly increased compared with that in the mesenteric artery, and this increase in the basilar artery was reduced by nifedipine. The addition of charybdotoxin (ChTX), a blocker of large-conductance KCa channels, to the resting strips caused a concentration-dependent contraction in the basilar artery but not in the mesenteric artery. The ChTX-induced contraction in the basilar artery was abolished by nifedipine. In resting strips preloaded with 86Rb, the basal 86Rb efflux rate constant was significantly greater in the basilar artery than in the mesenteric artery. The addition of nifedipine to the resting strips decreased the basal 86Rb efflux rate constant only in the basilar artery. These results suggest that the transmembrane Ca2+ influx via L-type voltage-dependent Ca2+ channels was significantly increased in the resting state of the basilar artery and that the myogenic tone was therefore maintained and the ChTX-sensitive KCa channels were highly activated.

Modification of myogenic intrinsic tone and [Ca2+]i of rat isolated arterioles by ryanodine and cyclopiazonic acid

The role of the sarcoplasmic reticulum (SR) in regulating myogenic tone and [Ca2+]i was examined with ryanodine and cyclopiazonic acid (CPA) in the rat skeletal muscle arteriole (A(sk)) and mesenteric arteriole (Ams). Arterioles were cannulated at both ends to control luminal pressure in a tissue bath. Luminal diameter was measured with a video-monitored microscopic system. Fura 2-AM was loaded to measure [Ca2+]i using the fluorescence intensity ratio at excitation wavelengths of 340 to 380 nm (F340/380). The myogenic response (luminal pressure was increased from 40 to 100 mm Hg) and the intrinsic tone at 40 mm Hg were observed in A(sk) but not in Ams. Ryanodine (10(-5) M decreased the steady-state diameter of A(sk) from 138 +/- 8 to 85 +/- 9 microns (P < .05) and increased the F340/380 ratio; these effects were reversed by nifedipine or Ca(2+)-free solution. Ryanodine shifted the [Ca2+]o-contraction response curve upward. CPA (10(-5) M) also decreased the steady-state diameter of A(sk) from 131 +/- 7 to 98 +/- 11 microns (P < .05). In contrast, Ams responded to neither ryanodine nor CPA. Caffeine-induced contractions were significantly reduced by either ryanodine or CPA in both arterioles. These results indicate that SR dysfunction increased the susceptibility of the arteriolar tone to [Ca2+]o and enhanced the tone of A(sk). In conclusion, the SR function may play a critical role in regulating [Ca2+]i and the intrinsic tone of A(sk) that was myogenically active at physiological luminal pressure.

Effects of nitric oxide synthesis blockade and angiotensin II on blood flow and spontaneous vasomotion in the rat cerebral microcirculation

The effects of N omega-nitro-L-arginine methyl ester (L-NAME) an inhibitor of NO synthesis, or angiotensin II on the frequency and amplitude of rhythmic variations (vasomotion) in blood flow of the intact rat cerebral circulation were investigated using laser-Doppler flowmetry (LDF). Experiments were performed on Sprague-Dawley rats anaesthetized with alpha-chloralose. The rat's head was fixed on a stereotaxic frame and the microvascular blood flow of the parietal cortex on the right or on both sides was measured via a small hole in the parietal bone, keeping the dura and a thin bone layer intact. Following the intravenous injection of L-NAME, the mean arterial blood pressure (MABP) increased to 123 +/- 1 mmHg (1.25 mg kg-1) or to 144 +/- 3 mmHg (5.0 mg kg-1) but no significant changes in cerebral blood flow (CBF) or vasomotion could be detected. The observed increase in MABP was sustained until L-arginine was administered. In the presence of L-NAME, during stepwise reduction of MABP, CBF remained constant when MABP was kept between 60 and 130 mmHg, the vasomotion frequency was lower when MABP was above 80 mmHg but its amplitude was two times higher than in the control group. In another group of animals, angiotensin was infused to give comparable increments in blood pressure. In contrast to L-NAME, angiotensin II had no effect on either frequency or amplitude of vasomotion, compared to the control group, within the whole range of MABP studied.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of elevated extracellular glucose concentrations on transmembrane calcium ion fluxes in cultured rat VSMC

Blood flow autoregulation is impaired in early diabetes mellitus, predisposing the renal microcirculation to injury. These hemodynamic changes have been strongly implicated in the development and progression of diabetic glomerulopathy. Blood flow autoregulation is predominantly a myogenic reflex which is strongly dependent on Ca2+ uptake by vascular smooth muscle cells (VSMC). Because impaired blood flow autoregulation may be responsive to glycemic control, the present study examined the effects of elevated extracellular glucose concentrations on basal, voltage sensitive and receptor operated Ca2+ uptake by VSMC. Confluent cultured rat VSMC were exposed to: (1) control medium (CM; 5 mM glucose); (2) high glucose medium (HGM; 10 to 30 mM glucose); or (3) osmotic control medium (OCM; glucose 5 mM + L-glucose 25 mM or mannitol 25 mM). A threshold glucose concentration of 15 mM markedly and maximally depressed basal Ca2+ uptake by VSMC (HGM 52% vs. CM). In addition, HGM significantly depressed voltage sensitive Ca2+ uptake by VSMC as determined by responses to BAY K 8644 (10(-7) M) or high extracellular [K+] (65 mM, HGM 50% vs. CM). HGM similarly depressed pressor hormone-stimulated Ca2+ uptake (AVP or Ang II 10(-7) M) by VSMC. The effects of HGM on Ca2+ uptake were time exposure dependent and reversible. Ca2+ uptake by VSMC in the presence of OCM did not differ from CM. Elevated extracellular glucose concentrations thus exert a direct and profound effect on basal, voltage sensitive and receptor operated Ca2+ uptake by VSMC. These observations may provide a biochemical basis for glucose-induced dysregulation of regional blood flow autoregulation in early diabetes mellitus.

Regulation of cerebral blood flow--a brief review

Cerebral blood flow is largely independent of perfusion pressure when autoregulation is intact. Cerebral circulation is regulated mainly by changes of vascular resistance. Resistance can be modulated by local-chemical and endothelial factors, by autacoids, and by release of transmitters from perivascular nerves. Local-chemical factors such as H(+)-, K(+)-, Ca(2+)-ions, adenosine, and osmolarity are involved in the regulation of cerebrovascular resistance during cortical activation and under pathological conditions such as hypoxia or ischaemia. Endothelial factors such as thromboxane A2, endothelin (ET), endothelium derived constrictor factor and endothelium derived relaxing (EDRF, identified as nitric oxide, NO) or hyperpolarizing (EDHF) factor, and prostacyclin (PGI2), can be released by physical stimuli such as shear stress or haemorrhage, by autacoids, by neurotransmitters, and by cytokines. Several of these factors (NO, PGI2, ET) can also be released from neurons and astrocytes thus enabling a coupling between parenchymal function and flow. Autacoids like histamine, bradykinin, eicosanoids, and free radicals influence cerebrovascular resistance, capacitance vessels and the permeability of the blood-brain barrier under pathological conditions. They are released by trauma, ischaemia, seizures and inflammation. Cerebral arteries are innervated by several systems. The sympathetic-noradrenergic fibres originate from the superior cervical ganglion. By releasing the constricting transmitters norepinephrine and neuropeptide Y this system extends the range of autoregulation. The parasympathetic cholinergic system with the dilating transmitters acetylcholine and vasoactive intestinal polypeptide may prevent ischaemia. Besides the intracerebral noradrenergic and serotonergic perivascular innervation with an unclear function, a trigeminal innervation has been described.(ABSTRACT TRUNCATED AT 250 WORDS)

20-Hydroxyeicosatetraenoic acid is an endogenous vasoconstrictor of canine renal arcuate arteries

Recent studies have indicated that renal arteries can produce 20-hydroxyeicosatetraenoic acid (20-HETE) and suggest the potential involvement of a P450 metabolite of arachidonic acid in the myogenic activation of canine renal arteries. In the present study, the effects of 20-HETE on isolated canine renal arcuate arteries were studied. Administration of 20-HETE to the bath or the lumen at concentrations of 0.01-1 microM produced a graded reduction in the diameter of these vessels. In contrast, 19(R)-HETE was a vasodilator, whereas 19(S)-HETE was relatively inactive. The vasoconstrictor response to 20-HETE was not altered by the cyclooxygenase inhibitor indomethacin, endoperoxide/thromboxane receptor antagonist SQ29548, or combined blockade of the cyclooxygenase, lipoxygenase, and P450 pathways using indomethacin, baicalein, and 7-ethoxyresorufin. The response to 20-HETE was associated with depolarization and a sustained increase in the intracellular calcium concentration in renal vascular smooth muscle cells. Patch-clamp studies indicated that 20-HETE significantly reduced mean open time, the open-state probability, and the frequency of opening of a 117-pS K+ channel recorded from renal vascular smooth muscle cells in the cell-attached mode. Microsomes prepared from the renal cortex of dogs produced 20-HETE and 20-carboxyarachidonic acid when incubated with [14C]arachidonic acid. These results indicate that 20-HETE is an endogenous constrictor of canine renal arcuate arteries. The vasoconstrictor response to 20-HETE resembles the myogenic activation of these vessels after elevations in transmural pressure and suggests a potential role for this substance in the regulation of renal vascular tone.

Nonselective cation channels in cardiac and smooth muscle cells

In cardiac and smooth muscle cells, nonselective cation channels can be activated by hormones and neurotransmitters, by cell stretch, and by changes in membrane potential. Activation of nonselective cation channels can depolarize the cell membrane, induce Ca2+ influx through voltage-gated Ca2+ channels and contraction. Activation of nonselective cation channels may trigger contraction even when membrane depolarization is absent or when voltage-gated Ca2+ channels are blocked, provided the Ca2+ permeability of these channels is sufficiently high.

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.

Electrophysiology of cerebral blood vessels

In spite of the relatively large amount of in vitro and in vivo data indicating that, in a number of ways, cerebral arteries are pharmacologically different from peripheral arteries, the mechanisms responsible for these differences are far from clear. An understanding of these mechanisms is particularly important for a rational approach to the treatment of disorders of the cerebral circulation including migraine, hypertension and the responses of cerebral vessels to subarachnoid haemorrhage. This review outlines electrophysiological data which are available from cerebrovascular smooth muscle cells, including the possibility that inwardly-rectifying potassium channels, active at potentials close to the resting membrane potential, are intimately involved in the changes in smooth muscle tone which couple blood flow to regional changes in nerve cell activity. The membrane potential changes in response to perivascular nerve stimulation, noradrenaline, 5-hydroxytryptamine and endothelium-derived hyperpolarizing factor are also described, together with the underlying membrane mechanisms and their relationship to smooth muscle contraction and relaxation.

Impaired myogenic responsiveness of renal microvessels in Dahl salt-sensitive rats

The mechanisms mediating abnormal renal autoregulation in Dahl salt-sensitive (DS) rats have not been fully defined. In the present study, we assessed myogenic responsiveness of interlobular arteries (ILAs), afferent arterioles (AAs), and efferent arterioles in isolated perfused hydronephrotic Dahl rat kidneys. Dahl rats were divided into four groups according to strain (Dahl salt-resistant [DR] or DS rats) and dietary sodium manipulation (rats fed low or high salt diets). Systolic blood pressure was elevated only in DS rats fed the high salt diet (202 +/- 4 mm Hg, p less than 0.05). Myogenic responses were obtained by stepwise elevation of renal arterial pressure. Vessel diameters were determined by computer-assisted videomicroscopy. Preglomerular microvessels of DS and DR rats responded differently to changes in renal arterial pressure. AAs and ILAs manifested diminished myogenic responsiveness to increasing renal arterial pressure in DS rats compared with DR rats (p less than 0.05). Both AAs and ILAs in DS rats manifested a higher threshold pressure for eliciting myogenic responses and a decrease in maximal pressure-induced vasoconstriction. The sensitivity of the AA myogenic response to nifedipine was enhanced in DS rats compared with DR rats (p less than 0.05). For rats fed the high salt diet, preglomerular vessels exhibited reduced myogenic responsiveness in both strains. In contrast to preglomerular microvessels, efferent arterioles from all four groups of rats failed to exhibit pressure-induced vasoconstriction. Our data suggest that diminished myogenic responsiveness of AAs and ILAs in DS rats contributes to impaired renal autoregulation in this strain.

Cerebral blood-flow velocity and intermittent intracranial pressure elevation during sleep in hydrocephalic children

The clinical importance of intermittent intracranial pressure (ICP) elevations during sleep in hydrocephalic children is unclear. Eight studies of continuous ICP monitoring with simultaneous cerebral blood-flow velocity (CBFV) measurements were recorded during sleep in seven hydrocephalic children aged between one and 10 years. ICP was measured directly through a frontal reservoir. There were two main patterns of CBFV change in response to raised ICP: a progressive decrease in mean flow velocity and increase in resistance index, suggesting impaired haemodynamic compensation to ICP elevation due to reduced circulatory reserve in patients with limited intracranial compliance; and an increase in mean flow velocity with raised ICP, suggesting that appropriate haemodynamic compensation with increased blood-flow can occur to maintain adequate cerebral perfusion in those with sufficient circulatory reserve. Simultaneous CBFV and ICP measurements may help to identify those with reduced circulatory reserve who are at greater risk of ischaemic insult from episodic increases in ICP.

Regulation of arterial tone by activation of calcium-dependent potassium channels

Blood pressure and tissue perfusion are controlled in part by the level of intrinsic (myogenic) vascular tone. However, many of the molecular determinants of this response are unknown. Evidence is now presented that the degree of myogenic tone is regulated in part by the activation of large-conductance calcium-activated potassium channels in arterial smooth muscle. Tetraethylammonium ion (TEA+) and charybdotoxin (CTX), at concentrations that block calcium-activated potassium channels in smooth muscle cells isolated from cerebral arteries, depolarized and constricted pressurized cerebral arteries with myogenic tone. Both TEA+ and CTX had little effect on arteries when intracellular calcium was reduced by lowering intravascular pressure or by blocking calcium channels. Elevation of intravascular pressure through membrane depolarization and an increase in intracellular calcium may activate calcium-activated potassium channels. Thus, these channels may serve as a negative feedback pathway to control the degree of membrane depolarization and vasoconstriction.

Decreased endothelium-dependent hyperpolarization to acetylcholine in smooth muscle of the mesenteric artery of spontaneously hypertensive rats

The endothelium-dependent vascular relaxation to acetylcholine (ACh) in spontaneously hypertensive rats (SHR) may be impaired because of an imbalance of endothelium-derived relaxing factor and contracting factor. However, the role of the endothelium-dependent hyperpolarization remains undetermined. We examined the ACh-induced hyperpolarization and its contribution to relaxation in arteries of SHR. Membrane potentials were recorded from the mesenteric artery trunk of 6-8-month-old male SHR and also Wistar-Kyoto (WKY) rats. Endothelium-dependent hyperpolarization to ACh was unaffected by NG-nitro-L-arginine, indomethacin, or glibenclamide; was reduced by tetraethylammonium or high K+ solution; and was enhanced by low K+ solution or methylene blue, thereby indicating that hyperpolarization is not mediated by nitric oxide (endothelium-derived relaxing factor) but is presumably mediated by a hyperpolarizing factor and is due to an opening of K+ channels that probably differ from the ATP-sensitive ones. Hyperpolarizations to ACh were markedly reduced in SHR compared with findings in WKY rats (maximum, 8 +/- 1 versus 17 +/- 1 mV). In addition, under conditions of depolarization with norepinephrine (10(-5) M), the ACh-induced hyperpolarization was even less and transient in SHR, while it was large and sustained in WKY rats (6 +/- 1 versus 29 +/- 2 mV). Endothelium-dependent relaxations to ACh in arterial rings precontracted with 10(-5) M norepinephrine were far less in SHR than in WKY rats, even in the presence of indomethacin. Furthermore, high K+ solution showed smaller inhibitory effects on the relaxations in SHR than in WKY rats. Endothelium-independent hyperpolarizations and relaxations to cromakalim, a K+ channel opener, were similar between SHR and WKY rats. It would thus appear that the endothelium-dependent hyperpolarization to ACh is reduced in SHR and this would, in part, account for the impaired relaxation to ACh in SHR mesenteric arteries.

Endothelium-derived contracting factors

The endothelium not only mediates relaxation but is a source of contracting factors. Endothelium-dependent contractions are elicited by physical and chemical stimuli (i.e., hypoxia, pressure, and stretch) and autacoids, local and circulating hormones. The mechanism of endothelium-dependent contractions to hypoxia involves withdrawal of nitric oxide. The endothelial cyclooxygenase pathway can produce thromboxane A2, prostaglandin H2, and superoxide anions. The peptide endothelin is a potent contracting factor; its production is stimulated by vasopressor hormones, platelet-derived factors, coagulation products, and cytokines, whereas endothelium-derived nitric oxide, prostacyclin, and a smooth muscle cell-derived inhibitory factor reduce endothelin production. In hypertension, the release of cyclooxygenase-dependent endothelium-derived contracting factors to stretch, acetylcholine, and platelet-derived products is augmented. Vascular endothelin production in hypertension remains controversial but appears mostly normal; it is augmented in the presence of vascular disease or renal insufficiency. The endothelium-dependent inhibition of endothelin-induced contractions is reduced in hypertension while the reactivity of vascular smooth muscle may be normal, increased, or reduced. The potentiating effects of low concentrations of endothelin on contractions to norepinephrine are augmented with aging and hypertension. In atherosclerosis, the production of the cyclooxygenase-dependent endothelium-derived contracting factors and endothelin is enhanced. Thus, endothelium-derived contracting factors can profoundly affect vascular tone and counteract relaxing factors produced within the endothelium. In hypertension and atherosclerosis, the role of contracting factors appears to become more dominant, leading to an imbalance of endothelium-dependent vascular regulation.

Hypoxic pulmonary vasoconstriction in the adult respiratory distress syndrome

Increased pulmonary vascular resistance (PVR) and microvascular hyperpermeability resulting in lung edema and arterial hypoxemia are mainstays in the development of adult respiratory distress syndrome (ARDS). The proposed pathophysiologic mechanisms include activation of complement and polymorphonuclear leukocytes secreting lysosomal enzymes, toxic oxygen metabolites (TOM) and eicosanoids. Platelets and coagulation factors are also involved, and in the most severe cases even monocytes are activated as reflected in release of thromboplastin. The latter may elicit disseminated intravascular coagulation (DIC). Under physiologic conditions lung blood flow is diverted from poorly to better oxygenated areas by way of hypoxic pulmonary vasoconstriction (HPV), thereby counteracting a decrease in arterial oxygenation. Many vasoactive substances have been proposed and again refuted as possible mediators of HPV. In this study we have focused on the following: histamine, catecholamines, arachidonates, calcium, phosphoinositides and TOM as well as endothelium-derived relaxing and constricting factors. Whether HPV is present in ARDS and whether it is advantageous or not seems to depend on the stage and extent of disease. We discuss possible interactions between HPV and ARDS mediators and between HPV and various vasoactive agents tested for therapeutic effects. Out of the abundance of mediators released, prostacyclin, prostaglandin E1, activated complement and platelet activating factor have been shown explicitly to inhibit HPV whereas others are suspected of doing so. In therapeutical use, prostacyclin has proved to reduce PVR and at the same time enhance cardiac output and oxygen delivery. In mild to moderate ARDS, improvement of arterial oxygenation has also been obtained employing almitrine bismesylate, a potentiator of HPV. Experimentally, adenosine effectively reduces increments in PVR and microvascular permeability with modest effects on systemic circulation. However, further investigations are warranted to decide whether adenosine or more specific blockers as, for instance, monoclonal antibodies against tumor necrosis factor should be integrated in ARDS therapy in the future.

Augmentation of endothelium-independent flow constriction in pial arteries at high intravascular pressures

The effects of an increase in intraluminal pressure and flow on the diameter and active smooth muscle tone of pial arteries was studied in perfused segments. Resistance arteries (approximately 250-300 microns i.d.) were perfused under controlled pressure and flow conditions, and changes in arterial diameter registered with an automated video device. In any particular segment, diameter measurements were normalized to that observed at 5 mm Hg. Changes in active wall force were determined by relating the observed diameter under a particular set of conditions to the diameter at the same intramural pressure when smooth muscle tone was inhibited (calcium-free physiological saline solution) and to the diameter when smooth muscle cells were activated close to maximum (KCl; 89 mM). At 60 mm Hg, the diameter decrease of 21% in the absence of flow represented stretch-induced tone. No additional changes in diameter were encountered with a flow of 20 microliters/min. Diameter decreased a further 7% at 100 microliters/min. When intraluminal pressure was 90 mm Hg, diameter decreased 39% without flow. Additional constriction of 10% and 19% occurred at flows of 20 and 100 microliters/min, respectively. At the higher pressure, the vasoconstriction occasioned by flow was significantly greater than that at the lower pressure. After endothelium inactivation by passing hypo-osmotic Krebs' solution followed by air through the segment, mean diameter was less at each combination of pressure and flow, although this difference did not reach statistical significance. The diameter reductions to increases in pressure from 60 to 90 mm Hg and to flow at 40 microliters/min were not altered by endothelium inactivation.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibitors of cytochrome P-450 attenuate the myogenic response of dog renal arcuate arteries

The role of cytochrome P-450 in the myogenic response of isolated, perfused renal arcuate arteries of dogs to elevations in transmural pressure was examined. The phospholipase A2 inhibitor oleyloxyethylphosphorylcholine (1 and 10 microM) inhibited the greater than threefold increase in active wall tension in these arteries after an elevation in perfusion pressure from 80 to 160 mm Hg. Inhibition of cyclooxygenase activity with indomethacin (1 or 10 microM) had no effect on this response. The cytochrome P-450 inhibitors ketoconazole (10 and 100 microM) and beta-diethyl-aminoethyldiphenylpropylacetate (SKF 525A, 10 and 100 microM) also inhibited the myogenic response. At a pressure of 160 mm Hg, SKF 525A (10 microM) and ketoconazole (100 microM) reduced active wall tension in renal arteries by approximately 70%. Partial inhibition of the myogenic response was obtained after perfusion of the vessels with mechanism-based inhibitors of P-450, 1-aminobenzotriazole (75 microM) and 12-hydroxy-16-heptadecynoic acid (20 microM). The thromboxane receptor antagonist SQ 29,548 (1 or 10 microM) had no effect on the pressure-induced increase in active wall tension in renal arteries. Arachidonic acid (50 microM) constricted isolated perfused renal arteries and potentiated the myogenic response in the presence of indomethacin. This response was completely reversed by ketoconazole (100 microM) or SKF 525A (100 microM). Microsomes (1 mg/ml) prepared from small renal arteries (200-500 microns) and incubated with [1-14C]arachidonic acid (0.5 mu Ci, 50 microM) produced a metabolite that coeluted with 20-hydroxyeicosatetraenoic acid (20-HETE) during reversed-phase high-performance liquid chromatography. The formation of this product was inhibited by both ketoconazole and SKF 525A at concentrations of 10 and 100 microM. These results are consistent with the involvement of the vasoconstrictor 20-HETE and other cytochrome P-450 metabolites of endogenous fatty acids in the myogenic response.

Mechanosensitive adenylate cyclase activity in coronary vascular smooth muscle cells

The purpose of the present study was to test the hypothesis that adenylate cyclase activity of porcine coronary artery smooth muscle cells is sensitive to mechanical stretch. Cultured vascular smooth muscle cells were stretched at 24% maximal strain at 60 cycles/min for 30 minutes. Both basal and maximal catalytic activity of adenylate cyclase (as assessed by stimulation by 100 microM forskolin with 5 mM manganese chloride) were reduced by 30% (P less than 0.05) in membranes obtained from stretch versus unstretched cells. The magnitude of the stretch-induced reduction in Gpp(NH)p was identical over the entire time course studied (5-30 minutes). Furthermore, basal adenylate cyclase activity was inversely related to the magnitude of stretch. Thus, cyclic stretch can influence adenylate cyclase activity in coronary vascular smooth muscle cells. These data provide important information concerning potential biochemical mechanisms involved in the myogenic response of vascular smooth muscle and also suggest a potential mechanism by which the coronary circulation may adapt to chronically reduced perfusion pressure.

Calcium channels, potassium channels, and voltage dependence of arterial smooth muscle tone

Resistance arteries exist in a maintained contracted state from which they can dilate or constrict depending on need. In many cases, these arteries constrict to membrane depolarization and dilate to membrane hyperpolarization and Ca-channel blockers. We discuss recent information on the regulation of arterial smooth muscle voltage-dependent Ca channels by membrane potential and vasoconstrictors and on the regulation of membrane potential and K channels by vasodilators. We show that voltage-dependent Ca channels in the steady state can be open and very sensitive to membrane potential changes in a range that occurs in resistance arteries with tone. Many synthetic and endogenous vasodilators act, at least in part, through membrane hyperpolarization caused by opening K channels. We discuss evidence that these vasodilators act on a common target, the ATP-sensitive K (KATP) channel that is inhibited by sulfonylurea drugs. We propose the following hypotheses that presently explain these findings: 1) arterial smooth muscle tone is regulated by membrane potential primarily through the voltage dependence of Ca channels; 2) many vasoconstrictors act, in part, by opening voltage-dependent Ca channels through membrane depolarization and activation by second messengers; and 3) many vasodilators work, in part, through membrane hyperpolarization caused by KATP channel activation.

Neuropeptide Y in cerebrovascular function: comparison of membrane potential changes and vasomotor responses evoked by NPY and other vasoconstrictors in the guinea pig basilar artery

The membrane depolarization and vasomotor response evoked by NPY and other vasoconstrictors were compared in guinea pig basilar artery. Concentrations below the pD2 value of amines and PGF2 alpha induced contractions without significant membrane depolarization, while higher agonist concentrations depolarized the membrane slightly. Potassium-induced contractions were paralleled by strong depolarization. NPY evoked a slow depolarization which correlated to vasoconstriction over a wide concentration range. The mechanism of activation did not appear to involve the endothelium. The results suggest that NPY induces prolonged cerebrovascular smooth muscle tone by evoking longlasting depolarization, at least partly in conjunction with activation of voltage-operated calcium channels.

Role of the vascular endothelium in regulating the response of small arteries of the dog kidney to transmural pressure elevation and reduced PO2

The goal of this study was to determine the role of the vascular endothelium in regulating the response of small renal arteries to increased transmural pressure and reduced PO2. Canine small renal arteries (496 +/- 32 microns) were isolated, cannulated with micropipettes, and mounted in an in vitro chamber that allowed transmural pressure, tissue bath PO2, and vessel lumen PO2 to be controlled. In intact arteries, elevation of transmural pressure caused contractile activation and a progressive depolarization (0.17 +/- 0.09 mV/mm Hg pressure increase) of the vascular smooth muscle cells. Endothelial damage by air perfusion caused a 13-14% reduction in resting diameter and an 18 +/- 3 mV depolarization of the vascular smooth muscle, but eliminated the progressive contraction and depolarization that occurred in intact vessels in response to transmural pressure elevation. Reduction of either tissue bath O2 concentration or vessel lumen PO2 significantly enhanced norepinephrine-induced contractions of the arteries. Endothelial damage prevented the enhancement of norepinephrine-induced contractions by reduced PO2 in the vessels. The results of this study suggest that the vascular endothelium regulates both myogenic contraction and the enhancement of norepinephrine-induced contractions by reduced PO2 in small arteries of the dog kidney.

Endothelium-derived contractile factors

1. Vascular endothelium releases different substances (endothelium-derived contractile factors, EDCFs), which mediate vasoconstrictor responses induced by several agents. 2. Clear differences have been reported in endothelium-dependent contractions, which suggest at least three distinct EDCFs, named EDCF1, EDCF2 and EDCF3, respectively. 3. EDCF1 is a cyclooxygenase metabolite(s) of arachidonic acid. EDCF2 is a polypeptide released from cultured endothelial cells. It has been isolated and identified as a 21-amino acid peptide called endothelin, which is described as the most potent vasoconstrictor agent known to date. EDCF3 is an unidentified contractile factor(s), which is neither EDCF1 nor EDCF2. 4. The physiological role of these endothelial contractile factors is not yet clear. However, they have been implicated in the local mechanisms involved in blood flow regulation, as well as in some pathological conditions, such as hypertension or cerebral vasospasm.

Mechanisms of action of endothelin on isolated feline cerebral arteries: in vitro pharmacology and electrophysiology

Vascular endothelium has been found to produce a strong and potent vasoconstrictor peptide, endothelin. In this study, we have examined basic mechanisms underlying the contractile response of cerebral vessels to endothelin using in vitro pharmacology and electrophysiology. It was found that endothelin produced strong concentration-dependent contractions of circular segments of the feline middle cerebral artery. The response was slow in onset and long lasting. The vessels showed a remarkably strong tachyphylactic reaction upon repeated exposure to endothelin. The contractile effect of endothelin was not modified by the alpha-adrenoceptor antagonist phentolamine (10(-6) M) or the 5-hydroxytryptamine antagonist ketanserin (10(-6) M). Mechanical removal of the endothelium decreased potassium contractions while the maximum response to endothelin was only slightly reduced. There was no change in sensitivity of the cerebral artery to endothelin. The addition of a calcium antagonist (10(-6) M diltiazem or 3 X 10(-8) M nimodipine) or removal of extracellular calcium from the buffer solution did not change the sensitivity of the artery to endothelin but the maximum response to endothelin was reduced by between 40 and 60% by these procedures. The resting membrane potential of the cat middle cerebral artery was -62.8 +/- 3.5 mV. There was no significant depolarization in conjunction with cumulative administration of endothelin in concentrations below 1 X 10(-9) M. However, bursts of excitatory junction potentials were occasionally seen in response to high concentrations of endothelin (5 X 10(-9) M).(ABSTRACT TRUNCATED AT 250 WORDS)

Endothelium-dependent dilation of feline cerebral arteries: role of membrane potential and cyclic nucleotides

The objective of this study was to characterize the role of membrane potential and cyclic nucleotides in endothelium-dependent dilation of cerebral arteries. Middle cerebral arteries isolated from cats were depolarized and constricted in response to serotonin or when subjected to transmural pressures greater than 50 mm Hg. Acetylcholine (ACh) and ADP caused vasodilation and a sustained, dose-dependent hyperpolarization of up to 20 mV in this artery. The membrane potential change preceded the vasodilation by approximately 6 s. Hyperpolarizations and dilations to ACh and ADP did not occur in preparations without endothelium. The hyperpolarizations were abolished by ouabain (10(-5) M), which also blocked the dilator response to ACh. However, dilations to ADP were unaffected by ouabain. Methylene blue (5 x 10(-5) M), a guanylate cyclase inhibitor, had no effect on the responses to ACh or ADP in the presence or absence of ouabain. Cyclic guanosine monophosphate (cGMP) levels were not altered in cerebral arteries exposed to ACh or ADP. However, ADP did increase cyclic adenosine monophosphate levels in these blood vessels. We conclude that although membrane hyperpolarizations may be adequate to cause vasodilation, at least one other pathway of endothelium-dependent vasodilation also is present in feline cerebral arteries. Cyclic GMP does not appear to be involved in this alternate pathway of dilation.

Vasomotion frequency and amplitude related to intraluminal pressure and temperature in the wing of the intact, unanesthetized bat

Spontaneous arteriolar vasomotion and its relation to intraluminal pressure and temperature were studied in the wing of the intact, unanesthetized bat, using intravital microscopy. Vasomotion was observed in all arterioles, terminal arterioles, and precapillary sphincters. Vasomotion was of the on-off-type in precapillary sphincters. No correlation existed between vasomotion amplitude and frequency. Stepwise changes in arterial and venous pressures, ranging from zero to +100 mm Hg and zero to -75 mm Hg, resulted in progressive decrease in rhythmic vasomotion frequency and amplitude. There was no change in the amplitude of vasomotion due to temperature elevation but there was an increase in vasomotion frequency. The precapillary vessels studied have similar vasomotion frequency and amplitude in control conditions, which are consistent and can be restored after interventions such as changes in intraluminal pressure and temperature. In addition, both vasomotion frequency and amplitude decrease in a similar fashion during stepwise changes in intraluminal pressure. These findings support the hypothesis that vasomotion, in these vessels, is due to a vascular pacemaker, which acts as a local oscillator that can be affected by temperature and by intraluminal pressure in a graded fashion.

Pressure-dependent contraction of rat juxtamedullary afferent arterioles

Pressure-diameter relations were studied in rat afferent arterioles using an isolated, juxtamedullary nephron preparation perfused with a saline solution containing 5% albumin. Angiotensin I (10 microM), angiotensin II (0.1 microM), and norepinephrine (10 microM) increased perfusion pressure, and norepinephrine, but not angiotensin I or II, contracted afferent arterioles, indicating that the vessels are reactive. The control diameter of the afferent arterioles that exhibited pressure-dependent contraction (n = 58) averaged 30.8 +/- 1.1 micron at perfusion pressure of 80 mm Hg. When pressure was increased from 80 to 120 and then to 180 mm Hg, the diameter of these arterioles decreased by 16.4 +/- 2.1%. Glomerular capillary pressure was well autoregulated and averaged 45.2 +/- 2.2, 50.2 +/- 2.4, and 53.0 +/- 3.0 mm Hg, respectively, at perfusion pressures of 80, 120, and 180 mm Hg. Administration of vasodilators or a Ca2+-free solution eliminated the contractile response to pressure elevations; rather, the diameter of these vessels increased significantly by 17.5 +/- 5.1% and 32.0 +/- 9.4%, respectively, when pressure was increased from 80 to 180 mm Hg. Blocking tubuloglomerular feedback mechanism, with furosemide or by removal of the renal papilla (which interrupts the delivery of fluid to the macula densa), eliminated the pressure-dependent contraction of the afferent arterioles. Instead the diameter of these vessels increased by 27.0 +/- 7.8% and 36.0 +/- 5.6%, respectively, when the pressure was increased from 80 to 120 and then to 180 mm Hg. These results demonstrate that juxtamedullary nephrons perfused in vitro autoregulate glomerular capillary pressure.(ABSTRACT TRUNCATED AT 250 WORDS)

Stretch-activated ion channels in smooth muscle: a mechanism for the initiation of stretch-induced contraction

As in many smooth muscle tissue preparations, single smooth muscle cells freshly dissociated from the stomach of the toad Bufo marinus contract when stretched. Stretch-activated channels have been identified in these cells using patch-clamp techniques. In both cell-attached and excised inside-out patches, the probability of the channel being open (Po) increases when the membrane is stretched by applying negative pressure to the extracellular surface through the patch pipette. The increase in Po is mainly due to a decrease in closed time durations, but an increase in open time duration is also seen. The open-channel current-voltage relationship shows inward rectification and is not appreciably altered when K+ is substituted for Na+ as the charge-carrying cation in Ca2+-free (2 mM EGTA) pipette solutions bathing the extracellular surface of the patch. The inclusion of physiological concentrations of Ca2+ (1.8 mM) in pipette solutions (containing high concentrations of Na+ and low K+) significantly decreases the slope conductance as well as the unitary amplitude. The channel also conducts Ca2+, since inward currents were observed using pipette solutions in which Ca2+ ions were the only inorganic cations. When simulating normal physiological conditions, we find that substantial ionic current is conducted into the cell when the channel is open. These characteristics coupled with the high density of the stretch-activated channels point to a key role for them in the initiation of stretch-induced contraction.

Elevations in arterial pressure induce the formation of spontaneous action potentials and alter neurotransmission in canine ileum arteries

Arterial segments (less than 250 micron o.d.) excised from canine ileum were mounted in a chamber that permitted arterial transmural pressure (TMP) to be altered and measured. Subsequently, the periarterial nerves were field stimulated with single pulses (0.1 msec, 70 V), and the resting membrane potential (Em) as well as the nerve-mediated alterations in smooth muscle Em were measured using intracellular microelectrodes at TMPs between 0 and 160 mm Hg. The resting Em was greatest at TMPs of 40 mm Hg (-54.7 +/- 2.6 mV) and depolarized as the TMP was increased, reaching a value of -44.8 +/- 3.1 mV at 160 mm Hg. At TMP greater than or equal to 60 mm Hg, a proportion of the preparations exhibited spontaneous electrical activity (SA) consisting of constant rhythmic oscillations in Em or action potentials (APs) or of trains of rhythmic APs that progressively decreased in amplitude, interrupted by periods of hyperpolarization. SA stopped when the TMP was lowered to 40 mm Hg and was reestablished when the TMP was reelevated to TMPs above 60 mm Hg. Nerve stimulation evoked excitatory junction potentials (ejps) or APs. At constant stimulus parameters, ejps of maximum amplitude having the greatest rate of potential rise and fall were produced at TMP of 100 mm Hg. At TMPs greater than 100 mm Hg or less than 100 mm Hg, the amplitude and the rate of rise and fall of the ejps decreased. Ejps formed in response to a constant single pulse stimulus (0.1 msec, 70 V) elicited APs only at TMPs greater than or equal to 60 mm Hg. Neither ejps nor APs were inhibited by alpha-receptor-blocking agents. These studies indicate that the TMP at which an artery is maintained plays an important role in determining the resting Em, the occurrence of spontaneous action potentials, and the alterations in Em associated with nerve stimulation.

Increased sensitivity of cat cerebral arteries to serotonin upon elevation of transmural pressure

Segments of middle cerebral artery (MCA) were isolated from cat brains and cannulated allowing manipulation of transmural pressure (TP). These cannulated vessel segments were mounted in a specially fabricated myograph allowing measurement of internal diameter with the aid of a high resolution binocular microscope and a video imaging system. Internal diameter was then measured as a function of topically applied serotonin at 3 different levels of TP: 60, 100, and 140 mmHg. As TP was elevated from 60 to 140 mmHg the sensitivity to serotonin increased from an ED50 value of 1.3 x 10(-8) to 3.5 x 10(-10) M. We have yet to explore the mechanisms involved in the "pressure-mediated" increase in cerebrovascular sensitivity to serotonin; however, it may be related to the muscle membrane depolarization we have observed previously in response to elevations in TP. Such findings may account for the discrepancies in dose ranges for serotonin thought to be active in vivo vs. the higher concentrations needed to elicit responses in isolated vessels.

Contractile properties during development of hypertrophy of the smooth muscle in the rat portal vein

Structural and mechanical alterations during hypertrophy of the rat portal vein were investigated. Growth of the vessel was induced by a partial ligature of the vessel causing an increased transmural pressure. Vessel segments from animals kept with ligature for 1, 3, 5 and 7 days, were compared with vessels from sham-operated animals. Maximal active force and vessel cross-sectional area increased with time in the ligated group. On day 7, force and cross-sectional area at the optimal length, were markedly increased in the ligated group (21.1 +/- 1.0 mN, 0.55 +/- 0.04 mm2, n = 9) compared with the control vessels (11.7 +/- 1.0 mN, 0.30 +/- 0.02 mm2, n = 7). Light and electron microscopy of preparations fixed at optimal length showed that the amount of smooth muscle and the cross-sectional area of cell profiles were almost doubled in the ligated group on day 7, consistent with hypertrophy of the smooth muscle. The force per smooth muscle cell area was similar in the two groups (ligated: 132 +/- 15; control: 145 +/- 16 mN mm-2, n = 4-5). The maximal shortening velocity was significantly lower in the hypertrophied group (ligated: 0.28 +/- 0.02; control: 0.41 +/- 0.01 optimal length s-1, n = 6). In chemically skinned preparations, activated by maximal thiophosphorylation of the myosin light chains, force was higher in the ligated group compared to the controls but no difference in maximal shortening velocity was observed. In conclusion, the increased transmural pressure is associated with a rapid increase in the amount of smooth muscle in the portal vein. The mechanical data show that after 7 days the force generating ability of the contractile system has increased in proportion to the smooth muscle cell mass. The unaltered maximal shortening velocity in the skinned hypertrophied preparations suggests that the kinetic properties of the maximally activated contractile system are unaltered. The decreased maximal shortening velocity in the intact hypertrophied preparations may reflect alterations in the excitation-contraction coupling.

Active, passive and myogenic characteristics of isolated rat intramural coronary resistance arteries

We have investigated the active, passive and myogenic tension-internal circumference relations of rat intramural coronary and, as controls, mesenteric small arteries (internal diameter ca. 200 micron) using an isometric myograph. The active tensions of the vessels (when fully activated with 30 microM serotonin in K-saline) reached a maximum (2.54 N/m, coronary; 3.39 N/m, mesenteric) at an internal circumference, L0, where the passive tensions (measured in Ca-free solution) were 0.80 N/m (coronary) and 0.74 N/m (mesenteric). Below 0.8 L0 and above 1.2 L0 the active tensions fell linearly, the zero tension intercepts being 0.37 L0 and 1.74 L0 (coronary) and 0.40 L0 and 1.72 L0 (mesenteric). The passive wall tensions of the vessels rose exponentially as a function of internal circumference, the wall tension at 1.5 L0 being 10.0 N/m (coronary) and 8.5 N/m (mesenteric). In normal physiological salt solution, the coronary vessels had a Ca2+ dependent myogenic tone which was also dependent on the internal circumference. Maximum myogenic tone (0.54 N/m) was obtained at 1.18 L0. The mesenteric vessels had no such myogenic tone. Histological examination showed that the media/lumen ratios of both vessel types were the same, and that the smooth muscle content of the media was greater in the coronary (81%) than in the mesenteric (72%) vessels. The smaller active tension of the coronary vessels could not therefore be ascribed to a reduced smooth muscle content, but possibly in part to an observed heterogeneous arrangement of the smooth muscle cells in the coronary vessels.

Variations in middle cerebral artery blood flow investigated with noninvasive transcranial blood velocity measurements

Observations on blood velocity in the middle cerebral artery using transcranial Doppler ultrasound and on the ipsilateral internal carotid artery flow volume were obtained during periods of transient, rapid blood flow variations in 7 patients. Five patients were investigated after carotid endarterectomy. A further 2 patients having staged carotid endarterectomy and open heart surgery were investigated during nonpulsatile cardiopulmonary bypass. The patient selection permitted the assumption that middle cerebral artery flow remained proportional to internal carotid artery flow. The integrated time-mean values from consecutive 5-second periods were computed. The arithmetic mean internal carotid artery flow varied from 167 to 399 ml/min in individual patients, with individual ranges between +/- 15% and +/- 35% of the mean flow. The mean middle cerebral artery blood velocity varied from 32 to 78 cm/sec. The relation between flow volume and blood velocity was nearly linear under these conditions. Normalization of the data as percent of the individual arithmetic means permitted a composite analysis of data from all patients. Linear regression of normalized blood velocity (V') on normalized flow volume (Q') showed V' = 1.05 Q' - 5.08 (r2 = 0.898).