[Mechanism of Panlongqi Tablets intervening in vertebral artery type of cervical spondylosis in rats through PI3K/AKT signaling pathway based on network pharmacology and experimental verification].

This study aimed to further explore the relevant mechanism of action by network pharmacology integrated with animal experimental verification based on previous proven effective treatment of vertebral artery type of cervical spondylosis(CSA) by Panlongqi Tablets. Bionetwork analysis was performed to establish drug-disease interaction network, and it was found that the key candidate targets of Panlongqi Tablets were enriched in multiple signaling pathways related to CSA pathological links, among which phosphatidylinositol 3-kinase(PI3 K)/serine-threonine kinase(AKT/PKB) signaling pathway was the most significant. Further, mixed modeling method was used to build the CSA rat model, and the rats were divided into normal, model, Panlongqi Tablets low-, medium-and high-dose(0.16, 0.32, 0.64 g·kg~(-1)) and Jingfukang Granules(positive drug, 1.35 g·kg~(-1)) groups. After successful modeling, the rats were administered for 8 consecutive weeks. Pathological changes of rat cervical muscle tissues were detected by hematoxylin-eosin(HE) staining, and the content of interleukin-1ß(IL-1ß), tumor necrosis factor-α(TNF-α), vascular endothelial cell growth factor(VEGF) and chemokine(C-C motif) ligand 2(CCL2) in rat serum and/or cervical tissues was determined by enzyme-linked immunosorbent assay(ELISA). Western blot was employed to detect the protein expression levels of chemokine(C-C motif) receptor 2(CCR2), PI3 K, AKT, phosphorylated AKT(p-AKT), I-kappa-B-kinase beta(IKK-beta/IKKß), nuclear factor kappa B(NF-κB P65) and phosphorylated nuclear factor kappa B(NF-κB p-P65) in rat cervical tissues, and positive expression of p-NF-κB P65 in rat cervical muscle tissues was detected by immunofluorescence. The results showed that Panlongqi Tablets at different doses improved the degree of muscle fibrosis and inflammation in cervical muscle tissues of CSA rats, and reduced the content of inflammatory factors IL-1ß, TNF-α, VEGF, CCL2 and CCR2 in serum and/or cervical tissues. The protein expression levels of PI3 K, p-AKT, IKKß and p-NF-κB P65 as well as the nuclear entry of p-NF-κB P65 in cervical tissues were down-regulated. These findings suggest that Panlongqi Tablets can significantly inhibit the inflammatory response of CSA rats, and the mechanism of action may be related to the down-regulation of the activation of PI3 K/AKT signaling pathway.

Nucleus-Targeted Nanoparticles Induce Autophagy of Vascular Endothelial Cells in Cervical Spondylosis of Vertebral Artery Type Through PI3K/Akt/mTOR Signaling Pathway.

Nanoparticles are characterized by their large surface area per unit and high dispersion, with excellent affinity and adhesion to the tissue, which help them to contact drugs with tissues. However, the relationship between nuclear-targeted nanoparticles and PI3K/Akt/mTOR pathway, as well as their roles in cervical spondylosis of vertebral artery type (CSA) remain unclear. bEnd.3 cells were in this study exposed to nuclear-targeted nanoparticles, followed by determination of cell biological processes. The role of nuclear-targeted nanoparticles in CSA in relation to PI3K/Akt/mTOR pathway was then analyzed through detection of autophagy-related proteins pathway-related proteins. Nuclear-targeted nanoparticles led to reduced bEnd.3 cell proliferation with IC50 at indicated time points shown as (12.8±0.67), (8.8±0.43), and (4.6±0.42) µmol/L, respectively. Nuclear-targeted nanoparticles blocked bEnd.3 cells in G2/M phase, and induced apoptosis. In addition, nuclear-targeted nanoparticles inhibited the PI3K/Akt/mTOR pathway in the bEnd.3 cells, as evidenced by reduced PI3K, Akt and mTOR levels. Nuclear-targeted nanoparticles decreased the expression of Beclin-1, LC3, p62, Cathepsin D, and ATG5, and increased expression of GSK-3 and Bcl-2. Our present study demonstrated that the nucleartargeted nanoparticles could regulate the growth of bEnd.3 cells in CSA and promote autophagy of cells through blockage of the PI3K/Akt/mTOR signaling pathway.

Steady-state cerebral blood flow regulation at altitude: interaction between oxygen and carbon dioxide.

High-altitude ascent imposes a unique cerebrovascular challenge due to two opposing blood gas chemostimuli. Specifically, hypoxia causes cerebral vasodilation, whereas respiratory-induced hypocapnia causes vasoconstriction. The conflicting nature of these two superimposed chemostimuli presents a challenge in quantifying cerebrovascular reactivity (CVR) in chronic hypoxia. During incremental ascent to 4240 m over 7 days in the Nepal Himalaya, we aimed to (a) characterize the relationship between arterial blood gas stimuli and anterior, posterior and global (g)CBF, (b) develop a novel index to quantify cerebral blood flow (CBF) in relation to conflicting steady-state chemostimuli, and (c) assess these relationships with cerebral oxygenation (rSO2). On rest days during ascent, participants underwent supine resting measures at 1045 m (baseline), 3440 m (day 3) and 4240 m (day 7). These measures included pressure of arterial (Pa)CO2, PaO2, arterial O2 saturation (SaO2; arterial blood draws), unilateral anterior, posterior and gCBF (duplex ultrasound; internal carotid artery [ICA] and vertebral artery [VA], gCBF [{ICA + VA} × 2], respectively) and rSO2 (near-infrared spectroscopy). We developed a novel stimulus index (SI), taking into account both chemostimuli (PaCO2/SaO2). Subsequently, CBF was indexed against the SI to assess steady-state cerebrovascular responsiveness (SS-CVR). When both competing chemostimuli are taken into account, (a) SS-CVR was significantly higher in ICA, VA and gCBF at 4240 m compared to lower altitudes, (b) delta SS-CVR with ascent (1045 m vs. 4240 m) was higher in ICA vs. VA, suggesting regional differences in CBF regulation, and (c) ICA SS-CVR was strongly and positively correlated (r = 0.79) with rSO2 at 4240 m.

Role of Vascular Endothelial-Cadherin and p120-Catenin in the Formation of Experimental Intracranial Aneurysm in Animals.

BACKGROUND: Dysfunction of endothelial cells (ECs) constitutes a critical factor in the formation of intracranial aneurysms (IAs). However, little is known about the response of ECs to hemodynamic insults and its contribution to IA formation. METHODS: IAs models were constructed in both adult female New Zealand white rabbits and male Sprague-Dawley rats. Morphologic changes of vessel wall were detected by hematoxylin and eosin staining. Molecular and cellular changes, including p120-catenin (p120ctn) and vascular endothelial-cadherin, in the median sagittal section of the artery bifurcation were analyzed by fluorescent staining. RESULTS: Destructive aneurysmal remodeling and the formation of morphologic IAs were observed at the basilar termini of experimental rabbits and the anterior cerebral artery-olfactory artery bifurcation of rats. The expression of p120ctn colocalized with vascular endothelial-cadherin in ECs decreased. Moreover, the expression of p120ctn colocalized with nucleus of ECs increased. These events suggested that p120ctn was transported from the membrane to the nucleus of ECs. CONCLUSIONS: The potential mechanism, that IAs are always localizing in the bifurcation apices, may be that the endothelium injury of vessel wall can be induced by different hemodynamic conditions. Hemodynamic changes in artery bifurcation may initiate the formation of IAs.

Differences in autonomic innervation to the vertebrobasilar arteries in spontaneously hypertensive and Wistar rats.

KEY POINTS: Essential hypertension is associated with hyperactivity of the sympathetic nervous system and hypoperfusion of the brainstem area controlling arterial pressure. Sympathetic and parasympathetic innervation of vertebrobasilar arteries may regulate blood perfusion to the brainstem. We examined the autonomic innervation of these arteries in pre-hypertensive (PHSH) and hypertensive spontaneously hypertensive (SH) rats relative to age-matched Wistar rats. Our main findings were: (1) an unexpected decrease in noradrenergic sympathetic innervation in PHSH and SH compared to Wistar rats despite elevated sympathetic drive in PHSH rats; (2) a dramatic deficit in cholinergic and peptidergic parasympathetic innervation in PHSH and SH compared to Wistar rats; and (3) denervation of sympathetic fibres did not alter vertebrobasilar artery morphology or arterial pressure. Our results support a compromised vasodilatory capacity in PHSH and SH rats compared to Wistar rats, which may explain their hypoperfused brainstem. ABSTRACT: Neurogenic hypertension may result from brainstem hypoperfusion. We previously found remodelling (decreased lumen, increased wall thickness) in vertebrobasilar arteries of juvenile, pre-hypertensive spontaneously hypertensive (PHSH) and adult spontaneously hypertensive (SH) rats compared to age-matched normotensive rats. We tested the hypothesis that there would be a greater density of sympathetic to parasympathetic innervation of vertebrobasilar arteries in SH versus Wistar rats irrespective of the stage of development and that sympathetic denervation (ablation of the superior cervical ganglia bilaterally) would reverse the remodelling and lower blood pressure. Contrary to our hypothesis, immunohistochemistry revealed a decrease in the innervation density of noradrenergic sympathetic fibres in adult SH rats (P < 0.01) compared to Wistar rats. Unexpectedly, there was a 65% deficit in parasympathetic fibres, as assessed by both vesicular acetylcholine transporter (α-VAChT) and vasoactive intestinal peptide (α-VIP) immunofluorescence (P < 0.002) in PHSH rats compared to age-matched Wistar rats. Although the neural activity of the internal cervical sympathetic branch, which innervates the vertebrobasilar arteries, was higher in PHSH relative to Wistar rats, its denervation had no effect on the vertebrobasilar artery morphology or persistent effect on arterial pressure in SH rats. Our neuroanatomic and functional data do not support a role for sympathetic nerves in remodelling of the vertebrobasilar artery wall in PHSH or SH rats. The remodelling of vertebrobasilar arteries and the elevated activity in the internal cervical sympathetic nerve coupled with their reduced parasympathetic innervation suggests a compromised vasodilatory capacity in PHSH and SH rats that could explain their brainstem hypoperfusion.

ß1-Blockade increases maximal apnea duration in elite breath-hold divers.

We hypothesized that the cardioselective ß1-adrenoreceptor antagonist esmolol would improve maximal apnea duration in elite breath-hold divers. In elite national-level divers (n = 9), maximal apneas were performed in a randomized and counterbalanced order while receiving either iv esmolol (150 µg·kg-1·min-1) or volume-matched saline (placebo). During apnea, heart rate (ECG), beat-by-beat blood pressure, stroke volume (SV), cardiac output (CO), and total peripheral resistance (TPR) were measured (finger photoplethysmography). Myocardial oxygen consumption (MV̇o2) was estimated from rate pressure product. Cerebral blood flow through the internal carotid (ICA) and vertebral arteries (VA) was assessed using Duplex ultrasound. Apnea duration improved in the esmolol trial when compared with placebo (356 ± 57 vs. 323 ± 61 s, P < 0.01) despite similar end-apnea peripheral oxyhemoglobin saturation (71.8 ± 10.3 vs. 74.9 ± 9.5%, P = 0.10). The HR response to apnea was reduced by esmolol at 10-30% of apnea duration, whereas MAP was unaffected. Esmolol reduced SV (main effect, P < 0.05) and CO (main effect; P < 0.05) and increased TPR (main effect, P < 0.05) throughout apnea. Esmolol also reduced MV̇o2 throughout apnea (main effect, P < 0.05). Cerebral blood flow through the ICA and VA was unchanged by esmolol at baseline and the last 30 s of apnea; however, global cerebral blood flow was reduced in the esmolol trial at end-apnea (P < 0.05). Our findings demonstrate that, in elite breath-hold divers, apnea breakpoint is improved by ß1-blockade, likely owing to an improved total body oxygen sparring through increased centralization of blood volume (↑TPR) and reduced MV̇o2NEW & NOTEWORTHY The governing bodies for international apnea competition, the Association Internationale pour le Développment de l'Apnée and La Confédération Mondaile des Activités Subaquatiques, have banned the use of ß-blockers based on anecdotal reports that they improve apnea duration. Using a randomized placebo-controlled trial, we are the first to empirically confirm that ß-blockade improves apnea duration. This improvement in apnea duration coincided with a reduced myocardial oxygen consumption.

PET/CT in giant cell arteritis: High 18F-FDG uptake in the temporal, occipital and vertebral arteries.

18F-FDG PET/CT imaging is useful in patients with fever of unknown origin and can detect giant cell arteritis in extracranial large arteries. However, it is usually assumed that temporal arteries cannot be visualized with a PET/CT scanner due to their small diameter. Three patients with clinical symptoms of temporal arteritis were examined using a standard whole body PET/CT protocol (skull base - mid thighs) followed by a head PET/CT scan using the brain protocol. High 18F-FDG uptake in the aorta and some arterial branches were detected in all 3 patients with the whole body protocol. Using the brain protocol, head imaging led to detection of high 18F-FDG uptake in temporal arteries as well as in their branches (3 patients), in occipital arteries (2 patients) and also in vertebral arteries (3 patients).

Hyperthermia modulates regional differences in cerebral blood flow to changes in CO2.

The purpose of this study was to assess blood flow responses to changes in carbon dioxide (CO2) in the internal carotid artery (ICA), external carotid artery (ECA), and vertebral artery (VA) during normothermic and hyperthermic conditions. Eleven healthy subjects aged 22 ± 2 (SD) yr were exposed to passive whole body heating followed by spontaneous hypocapnic and hypercapnic challenges in normothermic and hyperthermic conditions. Right ICA, ECA, and VA blood flows, as well as left middle cerebral artery (MCA) mean blood velocity (Vmean), were measured. Esophageal temperature was elevated by 1.53 ± 0.09°C before hypocapnic and hypercapnic challenges during heat stress. Whole body heating increased ECA blood flow and cardiac output by 130 ± 78 and 47 ± 26%, respectively (P < 0.001), while blood flow (or velocity) in the ICA, MCA, and VA was reduced by 17 ± 14, 24 ± 18, and 12 ± 7%, respectively (P < 0.001). Regardless of the thermal conditions, ICA and VA blood flows and MCA Vmean were decreased by hypocapnic challenges and increased by hypercapnic challenges. Similar responses in ECA blood flow were observed in hyperthermia but not in normothermia. Heat stress did not alter CO2 reactivity in the MCA and VA. However, CO2 reactivity in the ICA was decreased (3.04 ± 1.17 vs. 2.23 ± 1.03%/mmHg; P = 0.039) but that in the ECA was enhanced (0.45 ± 0.47 vs. 0.95 ± 0.61%/mmHg; P = 0.032). These results indicate that hyperthermia is capable of altering dynamic cerebral blood flow regulation.

Regional changes in brain blood flow during severe passive hyperthermia: effects of PaCO2 and extracranial blood flow.

We investigated 1) the regional distribution of cerebral blood flow (CBF), 2) the influence of end-tidal Pco2 (PetCO2) on CBF, and 3) the potential for an extracranial blood "steal" from the anterior brain region during passive hyperthermia. Nineteen (13 male) volunteers underwent supine passive heating until a steady-state esophageal temperature of 2°C above resting was established. Measurements were obtained 1) during normothermia (Normo), 2) during poikilocapnic hyperthermia (Hyper), and 3) during hyperthermia with PetCO2 and end-tidal Po2 clamped to Normo levels (Hyper-clamp). Blood flow in the internal carotid (Qica), vertebral (QVA), and external carotid (Qeca) arteries (Duplex ultrasound), blood velocity of the middle cerebral (MCAv) and posterior cerebral (PCAv) arteries (transcranial Doppler), and cutaneous vascular conductance on the cheek (cheek CVC; Doppler velocimetry) were measured at each stage. During Hyper, PetCO2 was lowered by 7.0 ± 5.2 mmHg, resulting in a reduction in Qica (-18 ± 17%), Qva (-31 ± 21%), MCAv (-22 ± 13%), and PCAv (-18 ± 10%) compared with Normo (P < 0.05). The reduction in QVA was greater than that in QICA (P = 0.017), MCAv (P = 0.047), and PCAv (P = 0.034). Blood flow/velocity was completely restored in each intracranial vessel (ICA, VA, MCA, and PCA) during Hyper-clamp. Despite a ∼250% increase in QECA and a subsequent increase in cheek CVC during Hyper compared with Normo, reductions in QICA were unrelated to changes in QECA. These data provide three novel findings: 1) hyperthermia attenuates QVA to a greater extent than QICA, 2) reductions in CBF during hyperthermia are governed primarily by reductions in arterial Pco2, and 3) increased QECA is unlikely to compromise QICA during hyperthermia.

Homocysteine and pulsatility index of cerebral arteries.

BACKGROUND AND PURPOSE: A pulsatility index (PI) represents vascular resistance distal to an examined artery. The purpose of the present study was to evaluate an association between plasma total homocysteine (tHcy) and PIs of the cerebral arteries in patients with ischemic stroke. METHODS: Consecutive patients with ischemic stroke referred to a neurovascular ultrasound laboratory were evaluated from March 2007 to February 2008. PI was defined as (peak systolic velocity-end-diastolic velocity)/mean flow velocity as recommended. Transcranial Doppler was examined in both middle cerebral arteries and vertebral arteries, and basilar arteries. All patients with ischemic stroke were subdivided according to the presence of proximal internal carotid arterial steno-occlusion (ICS). RESULTS: The numbers of patients enrolled for the present analysis as ischemic stroke without and with ICS were 272 and 92, respectively. PIs measured in the cerebral arteries did not show a significant difference in the two groups, in spite of the fact that mean flow velocities of both basilar arteries and vertebral arteries were significantly elevated in the patients with ICS. Plasma tHcy was found to be independently associated with graded increases of PIs in all cerebral arteries in the patients without ICS, even adjusted for the potential confounders. However, there was no association between tHcy and PI in the patients with ICS. CONCLUSION: Plasma tHcy was directly associated with increased cerebral arterial resistance. But in clinical situations when the cerebral arterial hemodynamics were altered as in the patients with ICS, the effect of tHcy on arterial remodeling could be obscured.

An investigation of an autonomic innervation of the vertebral artery using monoamine histofluorescence.

Blood flow to the hindbrain, via the paired vertebral arteries, must be uncompromised for adequate neurological functioning of its vital centres. Therefore, it would seem unlikely that the intracranial vertebral artery would need to vasoconstrict, thus reducing its blood flow. In order to investigate the existence and location of a noradrenaline-mediated constrictor mechanism in the wall of the intracranial vertebral artery, transverse sections of ten baboon and ten monkey vessels were stained with sucrose-potassium phosphate-glyoxylic acid (counterstained with malachite-green). This method allows the visualisation of catecholaminergic nerves when the sections are exposed to ultraviolet light. In this study of primate vascular tissue, however, none of the monkey or baboon vertebral artery sections showed the presence of noradrenergic nerves in the tunica media - tunica adventitia junction or penetrating the tunica media of the arteries. These findings indicate that the intracranial vertebral artery does not have a neurogenic vasomotor function in primates.

Highly reproducible rat model of reversible forebrain ischemia--modified four-vessel occlusion model and its metabolic feature.

BACKGROUND: The four-vessel occlusion method introduced by Pulsinelli et al. is widely used as an experimental model for reversible forebrain ischemia in rats. METHOD: In this study, we further developed highly reproducible model of reversible forebrain ischemia. Under the microscope the visible vertebral arteries at the second vertebra could be easily electrocauterized and completely cut to yield complete cessation of circulation of both vertebral arteries. After 24 hours, male Wistar rats were subjected to 15, 30 and 45 minutes of forebrain ischemia by occluding both common carotid arteries with Sugita's temporary clips. (31)P-magnetic resonance spectra ((31)P-MRS) and (1)H-magnetic resonance images ((1)H-MRI) were obtained with a 6.3-T spectrometer to investigate sequential change of the in vivo brain metabolism. Electroencephalogram and the cortical blood flow by laser Doppler flowmetry were measured during ischemia and recirculation. Determination of endogenous superoxide scavenging activity in the brain cortex was performed by electron spin resonance spectrometry. FINDINGS: Brain water contents evaluated by the dry-wet weight method were increased at 1 hour and 48 hours after recirculation, which were demonstrated by (1)H-MRI. The superoxide scavenging activity showed a significant decrease at 45 minutes of recirculation and a significant increase at 12 hours of recirculation. The present modified model demonstrated that the mortality rates by 72 hours were 8.3% (15 minutes ischemia), 15.0% (30 minutes ischemia), and 42.9% (45 minutes ischemia), all of which were higher than that of the original method described by Pulsinelli et al. INTERPRETATION: In conclusion, this modified four-vessel occlusion method gives a high level of success in producing reversible forebrain ischemia.

Localization of dopamine D1 and D2 receptor mRNAs in the rat systemic and pulmonary vasculatures.

The present study was designed to evaluate the expression of dopamine D1 and D2 receptor mRNAs in systemic and pulmonary vasculatures. Using specific antisense riboprobes for dopamine D1 and D2 receptor cDNAs, in situ hybridization histochemistry was performed in the aorta, common carotid artery, vertebral artery, pulmonary artery, and superior vena cava of the adult male Sprague Dawley rat. In the case of the aorta, common carotid artery, and vertebral artery, dopamine D1 receptor mRNAs localized mainly in the smooth muscle cells of the tunica media. However, the signals of dopamine D2 receptor mRNAs were found in the endothelium and subendothelial layer of tunica intima, and interstitial cells of tunica adventitia. In the case of the pulmonary artery, signals of dopamine D1 receptor mRNAs were detected within the tunica intima, media, and adventitia. Expression of D2 receptor mRNAs was detected in the walls of small blood vessels within the tunica adventitia of the pulmonary artery. There were no detectable signals of dopamine D1 and D2 receptor mRNAs in the vein. The uneven distribution of dopamine D1 and D2 receptor mRNAs in the rat systemic vasculatures and pulmonary artery suggests that dopamine differentially regulates the vasodilation of the systemic and pulmonary arteries through the differential stimulation of dopamine D1 and D2 receptor.

Acetylcholine induces contraction in vergebral arteries from treated hypertensive patients.

Endothelium-dependent vasodilatation to acetylcholine is abnormal in animal models of hypertension. This abnormality reflects a change in the balance of relaxing and contracting factors produced in the vascular wall. In human cerebral arteries, endothelin has been implicated in the abnormal vasoconstrictor response following subarachnoid hemorrhage. This study tests the hypothesis that cerebral arteriolar dilatation to acetylcholine reduced in clinical hypertension due to an overproduction of endothelin. Our results show that at high concentrations of muscarinic agonist (0.3-3 microM), human vertebral arteries from hypertensive patients contract whereas those from normotensive patients remain maximally dilated. We conclude that the normal dilator response to acetylcholine is abrogated in vertebral arteries from treated hypertensive patients but endothelin-1 does not contribute to the abnormal responsiveness.

Morphology of cerebral arteries.

A comparison of the major cerebral arteries between humans and rats shows many similarities, including anomalies in their general organization, the structure of these vessels at the light and electron microscope levels and their morphological changes associated with cerebral vascular diseases. The general organization of the major cerebral arteries shows the following main differences between humans and rats. In rats, the internal carotid arteries have become an integral part of the circle of Willis. In the anterior cerebral arteries, a common variation in humans is the underdevelopment of one of the two arteries, whereas in rats, buttonhole-like structures are common in one or both arteries. The anterior communicating artery present in humans is absent in rats. The olfactory artery is prominent in rats, but absent in humans. The posterior communicating artery in humans is the most variable component of the circle of Willis, being asymmetric in its origin, diameters and branches. Similarly, the posterior cerebral arteries in rats often exhibit asymmetrical origin from the basilar artery. There was some confusion in the literature regarding the name of the posterior cerebral arteries in rats, but this was caused mainly by misquotations and incorrect interpretations of the papers. In humans, most aneurysms occur in the anterior half of the circle of Willis, and the incidence is higher in females than males; the middle cerebral artery is most often the one to become occluded, and the vertebral arteries are common sites for thrombosis. The various channels that constitute collateral circulation in humans provide a margin of safety, so that in case of cerebral occlusion due to thrombosis, atherosclerosis, or vasospasm related to hemorrhage, blood supply to the affected area can be maintained through these collaterals. Collateral circulation is also present in rats. However, in rats, information on the presence of various types of aneurysms, their location and frequency in normal and experimental models of hypertension and stroke is still lacking. Cerebral arteries from humans and rats are characterized by the absence of external elastic lamina, as compared with systemic arteries. A type of multipolar cell resembling the interstitial cell of Cajal is present in the cerebral arteries of humans. Its function is unknown. Earlier reports of cerebral valves have been shown to represent intimal cushions near the branching points of the cerebral arteries. Intravascular bridges present in human cerebral arteries, have not been reported in rats. Finally, the presence of vascular remodeling, as found in the cerebral arterioles of hypertensive rats, remains to be established in the cerebral arterioles of human hypertensives.(ABSTRACT TRUNCATED AT 400 WORDS)

Human cerebrovascular nerve fibers immunoreactive for synaptophysin, chromogranin A and tyrosine hydroxylase.

The innervation of human cerebral blood vessels has been examined using synaptophysin, a marker of synaptic vesicles, and chromogranin A, a marker of large dense-core vesicles. The catecholaminergic marker tyrosine hydroxylase was used for comparison. Synaptophysin and tyrosine hydroxylase demonstrated a similar distribution of nerve fibers whereas chromogranin A terminals were only sparsely evident. Our results suggest that there is not a subset of nerve fibers in existence which has a distribution different than that of catecholaminergic fibers. Furthermore, in view of its unexpected sparse distribution, chromogranin A in the nervi vasorum is not likely to be a significant contributor to cerebral blood flow regulation.

Lesions of the tunica media in traumatic rupture of vertebral arteries: histologic and biochemical studies.

Discontinuous non-circumferential lesions of tunica media were observed in four cases of traumatic rupture of the vertebral artery. We hypothesize that these lesions were due to mechanical disruption of smooth muscle cells and the liberation of catabolic enzymes with subsequent degradation of the arterial media. To test this hypothesis, healthy vertebral arteries were incubated with crude extracts of bovine smooth muscle cytosol in attempt to reproduce the histological changes of the arterial media in traumatized vertebral arteries. We observed cytosol-induced degradation of tunica media, characterized by pallor of staining with the Masson's Trichrome method, which was due to catabolic enzyme activity that was effectively inhibited by heat inactivation of the cytosol. The cytosol-induced tinctorial changes were similar to the lesions of the tunica media in naturally-occurring cases of traumatic vertebral artery rupture. We conclude that although vertebral arteries can be ruptured by physical distortion alone, associated lesions of the tunica media are due to in situ trauma-associated release of heat-labile catabolic enzymes.

Interactions between circulating peptides and the central nervous system in hemodynamic regulation.

Enkephalins and endothelins are endogenous peptides, which, at least at pharmacologic doses, produce complex hemodynamic responses after intravenous administration. The enkephalins, when injected into conscious animal models and humans, increase blood pressure, heart rate and minute ventilation. This response occurs by activation of specific opiate receptors located outside the bloodbrain barrier; the actual mechanism involves an increase in adrenergic autonomic nervous system tone and a decrease in cholinergic tone. These opiate receptors may activate afferent fibers, perhaps nicotinic cholinoceptors; in many ways their properties are suggestive of chemoreceptors. Furthermore, enkephalin responses appear to be modulated by gamma-aminobutyric acid complexes, in that the reversal of the excitatory hemodynamic responses seen in the conscious state to vasodepressor responses after barbiturate anesthesia may result from alteration of the state of activation of the gamma-aminobutyric acid complex. The enkephalin receptors are localized to the vertebral artery vascular distribution; the specific site may be the area postrema, a blood-brain barrier-deficient circum-ventricular organ demonstrated to modulate heart rate and blood pressure and to represent a target site for circulating angiotensin II. Endothelin increases heart rate and blood pressure when infused slowly into conscious or anesthetized dogs, although barbiturates do blunt the increase in heart rate. The mechanism appears to involve modification of autonomic tone, but also some element of direct vasoconstrictor activity. Interestingly, rapid bolus doses of endothelin produce only vasodepressor responses, suggesting that the rate and concentration at which circulating endothelin reaches afferent receptors or vasoconstrictor sites on vascular smooth muscle may determine the net hemodynamic response observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Homeostatic regulation of potassium excretion.

Multiple systems participate in the homeostatic regulation of potassium excretion. Changes in plasma potassium, above a baseline value, will directly stimulate potassium excretion. Acute variations in aldosterone may have only small and perhaps insignificant effects in stimulating potassium excretion when aldosterone is present within its normal plasma range, but may be highly significant in determining the kaliuretic response to changes in plasma potassium or tubular flow rate. Elevation of plasma aldosterone to supraphysiological levels appears to produce increases in potassium excretion. Chronic variations in aldosterone are important, but not unique in determining renal potassium adaptation to chronic variations in potassium uptake. New lines of evidence point to sensors of potassium intake located in the hepatic portal vein or liver, or in enteric locations. A reflex control of potassium excretion, first demonstrated by Aizman and Finkenshtein et al. [120-123] in the dog, and independently suggested in a more general form for the sheep, may be integral in the regulation of potassium excretion in response to intake. With this feedforward control system, potassium excretion may be regulated without changes in systemic plasma potassium concentration. From diverse lines of investigation we find that there is a compelling argument for an important role for the brain in regulating both potassium excretion and its ICF/ECF ratio. One may speculate, albeit on the basis of preliminary information, that separate but analogous systems exist for sodium and for potassium, each involving the brain and each acting through specific humoral factors. For sodium, evidence is accumulating for a ouabain-like humoral agent, perhaps originating in the brain, which modulates renal sodium excretion and the sodium concentration of ICF. Both of these actions have been proposed to have an important influence on blood pressure regulation. The evidence presented here is compatible with a similar system for potassium. On the basis of these studies reviewed here, it is intriguing to speculate that an analogous humoral factor is involved in the regulation of potassium homoeostasis, and that its effects, when understood, may help to resolve current debates regarding the role of potassium in blood pressure regulation.