Dynamic Alterations of Cerebral Pial Microcirculation During Experimental Subarachnoid Hemorrhage

The study aimed to investigate the involvement of cerebral microcirculation turbulence after subarachnoid hemorrhage (SAH). Wistar rats were divided into non-SAH and SAH groups. Autologous arterial hemolysate was injected into rat’s cisterna magna to induce SAH. Changes of pial microcirculation within 2 h were observed. It was found that there were no obvious changes of the diameters, flow velocity, and fluid state of microvessels in non-SAH group. With the exception of rare linear-granular flow in A4 arteriole, linear flow was observed in most of the arterioles. There was no blood agglutination in any of the arterioles. After SAH, abnormal cerebral pial microcirculation was found. Spasm of microvessels, decreased blood flow, and agglutination of red blood cells occurred. Five minutes following the induction of SAH, the diameters of the arterioles and venules significantly decreased. The decreased diameters persisted for 2 h after cisternal injection. Decreased flow velocity of venules was found from 5 to 90 min after induction of SAH. Spasm of the basilar artery and increased brain malondialdehyde were also found after SAH. We concluded that cerebral microcirculation turbulence plays an important role in the development of secondary cerebral ischemia following SAH.     

Reactive oxygen species may contribute to reduced endothelium-dependent dilation in rats fed high salt

In normotensive rats, an increase in dietary salt leads to decreased arteriolar responsiveness to acetylcholine (ACh) because of suppressed local nitric oxide (NO) activity. We evaluated the possibility that generation of reactive oxygen species in the arteriolar wall is responsible for this loss of NO activity. Arteriolar responses to iontophoretically applied ACh were examined in the superfused spinotrapezius muscle of Sprague-Dawley rats fed a low-salt (LS; 0.45%) or high-salt diet (HS; 7%) for 4-5 wk. Responses to ACh were significantly depressed in HS rats but returned to normal in the presence of the oxidant scavengers superoxide dismutase + catalase or 2,2,6, 6-tetamethylpiperidine-N-oxyl (TEMPO) + catalase. Arteriolar responses to the NO donor sodium nitroprusside were similar in HS and LS rats. Arteriolar and venular wall oxidant activity, as determined by reduction of tetranitroblue tetrazolium, was significantly greater in HS rats than in LS rats. Exposure to TEMPO + catalase reduced microvascular oxidant levels to normal in HS rats. These data suggest that a high-salt diet leads to increased generation of reactive oxygen species in striated muscle microvessels, and this increased oxidative state may be responsible for decreased endothelium-dependent responses associated with high salt intake.     

D(1) dopamine receptor regulation of NHE3 during development in spontaneously hypertensive rats

To determine if the defective interactions among D(1)-like receptors, G proteins, and Na(+)/H(+) exchanger 3 (NHE3) are consequences of hypertension, we studied these interactions in rats, before (2--3 wk) and after (12 wk) the establishment of hypertension. To eliminate the confounding influence of second messenger action on D(1) receptor-NHE3 interaction, studies were performed in renal brush-border membranes (BBM) devoid of cytoplasmic second messengers. NHE3 activity increased with age in Wistar-Kyoto (WKY) rats (3 wk = 1.48 +/- 0.39, n = 13; 12 wk = 2.83 +/- 0.15, n = 16, P < 0.05) but not in spontaneously hypertensive rats (SHRs; 3 wk = 2.52 +/- 0.37, n = 11; 12 wk = 2.81 +/- 0.20, n = 16). D(1) receptor protein tended to decrease, whereas NHE3 protein tended to increase with age in both WKY and SHRs. However, the inhibitory effect of a D(1)-like agonist, SKF-81297, on NHE3 activity increased with age in WKY rats (3 wk = -40.7 +/- 5.3%, n = 10, 12 wk = -58.7 +/- 4.6%, n = 12, P < 0.05) but not in SHRs (3 wk = -27.6 +/- 5.9%, n = 11, 12 wk = -25.1 +/- 3.2%, n = 11). The decreased inhibitory effect of another D(1)-like agonist, fenoldopam, on NHE3 activity in SHRs was not caused by increased activity and binding of G beta gamma to NHE3 as has been reported in young WKY rats. G(s)alpha mediates, in part, the inhibitory effect of D(1)-like agonists on NHE3 activity. In WKY rats, fenoldopam increased G(s)alpha/NHE3 binding to the same extent in 2-wk-old (1.5-fold, n = 4) and adult (1.5-fold, n = 4) rats. In contrast, in SHRs, fenoldopam decreased the amount of G(s)alpha bound to NHE3 in 2-wk-old SHRs and had no effect in 4-wk-old and adult SHRs. These studies indicate that the decreased inhibitory effect of D(1)-like agonists on NHE3 activity in SHRs (compared with WKY rats) precedes the development of hypertension. This may be caused, in part, by a decreased interaction between G(s)alpha and NHE3 in BBM secondary to impaired D(1)-like receptor function.     

The efficacy of mesenchymal stem cells for the improvement of cerebral microcirculation in spontaneously hypertensive rats

Elaboration of new correction methods for microcirculatory disorders in the brain caused by persistent high blood pressure is important for both medicine and biology. We studied the influence of intracerebral transplantation of human mesenchymal stem cells (hMSCs) on the cerebral microcirculation in young (4 month) and mature (12 month) spontaneously hypertensive rats (SHRs). It was shown that hMSC transplantation increased the density of the microvascular network of young SHRs to 1.6 and 1.9 times the density of the arteriolar area of the microvascular network of the pia. The density of microvascular network of mature SHRs increased by 1.4–1.5 times after hMSC transplantation. The perfusion and tissue saturation of sensorimotor cortex of young SHRs restored to the level of young normotensive rats. In mature SHRs, the perfusion and tissue saturation of sensorimotor cortex did not increase. In conclusion, the intracerebral transplantation of hMSC almost completely restored microcirculation in the sensorimotor cortex of the brain of young SHRs and slightly improved microcirculation in mature SHRs.     

PO2 measurements in the microcirculation using phosphorescence quenching microscopy at high magnification

In phosphorescence quenching microscopy (PQM), the multiple excitation of a reference volume produces the integration of oxygen consumption artifacts caused by individual flashes. We analyzed the performance of two types of PQM instruments to explain reported data on Po2 in the microcirculation. The combination of a large excitation area (LEA) and high flash rate produces a large oxygen photoconsumption artifact manifested differently in stationary and flowing fluids. A LEA instrument strongly depresses Po2 in a motionless tissue, but less in flowing blood, creating an apparent transmural Po2 drop in arterioles. The proposed model explains the mechanisms responsible for producing apparent transmural and longitudinal Po2 gradients in arterioles, a Po2 rise in venules, a hypothetical high respiration rate in the arteriolar wall and mesenteric tissue, a low Po2 in lymphatic microvessels, and both low and uniform tissue Po2. This alternative explanation for reported paradoxical results of Po2 distribution in the microcirculation obviates the need to revise the dominant role of capillaries in oxygen transport to tissue. Finding a way to eliminate the photoconsumption artifact is crucial for accurate microscopic oxygen measurements in microvascular networks and tissue. The PQM technique that employs a small excitation area (SEA) together with a low flash rate was specially designed to avoid accumulated oxygen photoconsumption in flowing blood and lymph. The related scanning SEA instrument provides artifact-free Po2 measurements in stationary tissue and motionless fluids. Thus the SEA technique significantly improves the accuracy of microscopic Po2 measurements in the microcirculation using the PQM.     

Role of gastric microcirculation in the gastroprotection by glucocorticoids released during water-restraint stress in rats

Our previous investigations demonstrated that glucocorticoids released in response to stress protect gastric mucosa against stress-induced ulceration. This study was designed to determine whether gastric microcirculation is involved in the mechanism of gastroprotective glucocorticoid action. For this we evaluated the effects of deficiency of glucocorticoid production during 3 hr water-restraint stress and corticosterone replacement on the stress-induced gastric erosions, gastric microcirculation and arterial pressure in rats. The stress was produced in awake rats and gastric microcirculation and arterial pressure were evaluated in animals anesthetized in 3 hr after the onset of water-restraint stress. An in vivo microscopy technique for the direct visualization of gastric microcirculation was employed. The gastric submucosal and the superficial mucosal microvessels were monitored on television screen through a microscope and the pictures were stored by microfilming for the analysis of red blood cell velocity and vessel diameter. Gastric microcirculation was estimated on the base of both the volume blood flow velocity in submucosal microvessels and the diameter of superficial mucosal venous microvessels. Gastric erosions were quantitated by measuring the area of damage. Plasma corticosterone levels were also measured after 3 hr stress by fluorometry. Water-restraint stress induced an increase in corticosterone level, an appearance of gastric erosions, a decrease in volume blood flow velocity of submucosal microvessels, a dilatation of superficial mucosal microvessels, a decrease in arterial pressure. The deficiency of glucocorticoid production during water-restraint stress promoted the stress-induced gastric ulceration, a dilatation of mucosal microvessels, a decrease of blood flow velocity in submucosal microvessels and of arterial pressure. Corticosterone replacement eliminated the effects of deficiency of glucocorticoid production on all of the parameters under study. Thus, the stress-induced corticosterone rise decreased gastric ulceration, restricted both the reduction of blood flow velocity in submucosal microvessels and a dilatation of superficial mucosal venous microvessels during water-restraint stress. These data suggest that the gastroprotective action of glucocorticoids during stress may be provided by the maintenance of gastric blood flow.     

用显微穿刺技术直接测量微血管压力的伺服零方法研究

本实验制作了尖端的直径为０５－５０μｍ和斜面为２５°的玻璃微插管,成功地建立了用显微穿刺（ｍｉｃｒｏｐｕｎｃｔｕｒｅ）技术直接测量微血管压力（Ｐｍ）的伺服零方法（ｓｅｒｖｏｎｕｌｍｅｔｈｏｄ）,对自发高血压大鼠（ＳＨＲ）和正常血压大鼠（ＷＫＹ）肠系膜Ｐｍ进行了测量研究。结果表明,ＳＨＲ的平均动脉压（ＰＡ）和微动脉的Ｐｍ均明显大于ＷＫＹ的ＰＡ和Ｐｍ;ＰＡ在微动脉中明显降低,最大压降在直径小于５０μｍ的微动脉以及毛细血管中。     

Fibroblast Growth Factor 9 Imparts Hierarchy and Vasoreactivity to the Microcirculation of Renal Tumors and Suppresses Metastases

Tumor vessel normalization has been proposed as a therapeutic paradigm. However, normal microvessels are hierarchical and vasoreactive with single file transit of red blood cells through capillaries. Such a network has not been identified in malignant tumors. We tested whether the chaotic tumor microcirculation could be reconfigured by the mesenchyme-selective growth factor, FGF9. Delivery of FGF9 to renal tumors in mice yielded microvessels that were covered by pericytes, smooth muscle cells, and a collagen-fortified basement membrane. This was associated with reduced pulmonary metastases. Intravital microvascular imaging revealed a haphazard web of channels in control tumors but a network of arterioles, bona fide capillaries, and venules in FGF9-expressing tumors. Moreover, whereas vasoreactivity was absent in control tumors, arterioles in FGF9-expressing tumors could constrict and dilate in response to adrenergic and nitric oxide releasing agents, respectively. These changes were accompanied by reduced hypoxia in the tumor core and reduced expression of the angiogenic factor VEGF-A. FGF9 was found to selectively amplify a population of PDGFRβ-positive stromal cells in the tumor and blocking PDGFRβ prevented microvascular differentiation by FGF9 and also worsened metastases. We conclude that harnessing local mesenchymal stromal cells with FGF9 can differentiate the tumor microvasculature to an extent not observed previously.     

Antihypertensive effect of low ethanol intake in spontaneously hypertensive rats

Light to moderate drinking in humans lowers the risk of coronary heart disease and may lower blood pressure. We examined the effect of chronic low daily alcohol consumption on blood pressure, platelet cytosolic free calcium [Ca²⁺]_i, tissue aldehyde conjugates and renal vascular changes in normotensive Wistar-Kyoto (WKY) and spontaneously hypertensive rats (SHR). We also examined the effects of the same weekly amount of alcohol consumption over a one day period each week simulating weekend drinking in humans. Animals, age 7 weeks, were divided into six groups of six animals each and were treated as follows: WKY and SHR control, normal drinking water; WKY and SHR, 0.5% ethanol in drinking water; WKY and SHR, 3.5% ethanol in drinking water one day/week. After 14 weeks systolic blood pressure, platelet [Ca²⁺]_i, liver, kidney and aortic aldehyde conjugates were significantly higher (p < 0.05) in untreated SHRs as compared to untreated WKYs. Daily 0.5% ethanol consumption in SHRs significantly (p < 0.05) attenuated these changes and also attenuated smooth muscle cell hyperplasia and narrowing of the lumen in small arteries and arterioles of the kidney. WKY rats treated with 0.5% ethanol had lower aldehyde conjugates without any significant effect on blood pressure and platelet [Ca²⁺]_i as compared to WKY controls. Consumption of 3.5% ethanol one day/week did not affect blood pressure and associated changes in normotensive WKY rats or hypertensive SHRs as compared to their respective controls. These results suggest that chronic daily low ethanol intake lowers blood pressure in SHRs by lowering tissue aldehyde conjugates and cytosolic free calcium.     

Effect of prostaglandin F2 alpha on the microvessels in a transparent chamber implanted in the rabbit concha auriculae

The television analysing system LEITZ-TAS was employed to evaluate quantitative characteristics of the regeneration of microvessels in a transparent chamber implanted in rabbit ear under the influence of PGF2 alpha. It was established that formation of the microvascular network had been completed by the end of the first month after implantation of the chamber. Chronic injection of PGF2 alpha in the dose applied slowed down the growth of new microvessels and led to the constriction of arterioles and venules.     

Nerve stimulation induced overflow of neuropeptide Y and modulation by angiotensin II in spontaneously hypertensive rats

The sympathetic nervous system and renin-angiotensin system are both thought to contribute to the development and maintenance of hypertension in experimental models such as the spontaneously hypertensive rat (SHR). We demonstrated that periarterial nerve stimulation (NS) increased the perfusion pressure (PP) and neuropeptide Y (NPY) overflow from perfused mesenteric arterial beds of SHRs at 4-6, 10-12, and 18-20 wk of age, which correspond to prehypertensive, developing hypertensive, and maintained hypertensive stages, respectively, in the SHR. NS also increased PP and NPY overflow from mesenteric beds of Wistar-Kyoto (WKY) normotensive rats. NS-induced increases in PP and NPY were greater in vessels obtained from SHRs of all three ages compared with WKY rats. ANG II produced a greater increase in PP in preparations taken from SHRs than WKY rats. ANG II also resulted in a greater increase in basal NPY overflow from 10- to 12-wk-old and 18- to 20-wk-old SHRs than age-matched WKY rats. ANG II enhanced the NS-induced overflow of NPY from SHR preparations more than WKY controls at all ages studied. The enhancement of NS-induced NPY overflow by ANG II was blocked by the AT1 receptor antagonist EMD-66684 and the angiotensin type 2 receptor antagonist PD-123319. In contrast, ANG II greatly enhanced norepinephrine overflow in the presence of PD-123319. Both captopril and EMD-66684 decreased neurotransmitter overflow from SHR mesenteric beds; therefore, we conclude that an endogenous renin-angiotensin system is active in this preparation. It is concluded that the ANG II-induced enhancement of sympathetic nerve stimulation may contribute to the development and maintenance of hypertension in the SHR.     

Evidence for altered ETB receptor characteristics during development and progression of ventricular cardiomyocyte hypertrophy

The hypothesis that endothelin (ET) receptor mechanisms are altered during development and progression of left ventricular hypertrophy (LVH) in vivo was tested using spontaneously hypertensive rats (SHRs). Ventricular cardiomyocytes were isolated from SHRs before onset (8 and 12 wk) and during progression (16, 20, and 24 wk) of LVH and compared with age-matched normotensive Wistar-Kyoto (WKY) rats. PreproET-1 mRNA expression was elevated in SHR (P < 0.05) relative to WKY cardiomyocytes at 20-24 wk. ET binding-site density was twofold greater in SHR than WKY cells at 12 wk (P < 0.05) but normalized at 20 wk. ET(B) receptors were detected on SHR cardiomyocytes as early as 8 wk and their affinity increased progressively with age (P < 0.05), whereas ET(B) receptors were not detected on WKY cells until 20 wk. ET-1 stimulated protein synthesis with similar maximum responses between strains (21-30%), in contrast with sarafotoxin 6c, which stimulated protein synthesis in SHR (13-20%) but not WKY cells at 12-20 wk. In SHR but not WKY cells, the ET(B) receptor-selective ligand A-192621 increased protein synthesis progressively with the development of LVH (15% maximum effect). In conclusion, the presence of ET(B) receptors (8-12 wk) coupled with functional responsiveness of SHR cells but not WKY cells to sarafotoxin 6c at 12 wk supports the involvement of ET(B) receptors before the onset of cardiomyocyte hypertrophy, whereas altered ET(B) receptor characteristics during active hypertrophy (16-24 wk) indicate that ET(B) receptor mechanisms may also contribute to disease progression.     

Angiotensin-Converting Enzyme Activity Is Reduced in Brain Microvessels of Spontaneously Hypertensive Rats

Abstract: Angiotensin-converting enzyme (ACE) activity in brain microvessels of spontaneously hypertensive rats (SHR) and Wistar Kyoto (WKY) controls was measured. Cerebral microvessels, prepared from the cerebral cortices by the albumin flotation and glass bead filtration technique, were free of neuronal and glial elements. ACE activity in brain microvessels of SHR was lower than that of WKY. A Woolf-Augustinsson-Hofstee plot showed that the reduction of the enzyme activity in SHR was due to a 30% decrease in V_max without any change in K_m for substrate. The decrease of ACE activity in brain micro-vessels of SHR may indicate an impairment of the central renin-angiotensin system and may be related to cerebral microvascular dysfunctions occurring in hypertension.     

High salt intake reduces endothelium-dependent dilation of mouse arterioles via superoxide anion generated from nitric oxide synthase

In skeletal muscle arterioles of normotensive rats fed a high salt diet, the bioavailability of endothelium-derived nitric oxide (NO) is reduced by superoxide anion. Because the impact of dietary salt on resistance vessels in other species is largely unknown, we investigated endothelium-dependent dilation and oxidant activity in spinotrapezius muscle arterioles of C57BL/6J mice fed normal (0.45%, NS) or high salt (7%, HS) diets for 4 wk. Mean arterial pressure in HS mice was not different from that in NS mice, but the magnitude of arteriolar dilation in response to different levels of ACh was 42-57% smaller in HS mice than in NS mice. Inhibition of nitric oxide synthase (NOS) with N(G) monomethyl L-arginine (L-NMMA) significantly reduced resting diameters and reduced responses to ACh (by 45-63%) in NS mice but not in HS mice. Arteriolar wall oxidant activity, as assessed by tetranitroblue tetrazolium reduction or hydroethidine oxidation, was greater in HS mice than in NS mice. Exposure to the superoxide scavenger 2,2,6,6-tetramethylpiperidine-N-oxyl (TEMPO) + catalase reduced this oxidant activity to normal and restored normal arteriolar responsiveness to ACh in HS mice but had no effect in NS mice. L-NMMA also restored arteriolar oxidant activity to normal in HS mice. ACh further increased arteriolar oxidant activity in HS mice but not in NS mice, and this effect was prevented with L-NMMA. These data suggest that a high salt diet promotes increased generation of superoxide anion from NOS in the murine skeletal muscle microcirculation, thus impairing endothelium-dependent dilation through reduced NO bioavailability.     

The efficiency of mesenchymal cell intracerebral transplantation for corrections of cerebral microcirculation age-related alterations in rats

Using television-based vital microscopy and immunohistochemical analysis, we have assessed the effect of syngeneic mesenchymal stem-cell (MSC) intracerebral transplantation on the brain cortex structure and microcirculation in the pia mater of old rats. Setting up the “open field” system, we studied the effect of MSC transplantation on the position-finding and discovery behavior of old animals. We found that the density of microvascular network of the pia mater increased by about 1.9-fold in MSC recipients compared to age-matched controls. The density of the arteriolar area of microvascular network of the pia mater approximately doubled. The reactivity of newly developed arterioles was nearly equal to that of native microvessels. The intracerebral transplantation procedure was itself traumatic for rat brain cortex, but it did not affect microcirculation in the contralateral hemisphere. Intracerebral transplantation of MSCs did not improve the locomotor behavior and emotional stage of old rats; neither did it increase their position-finding and discovery activity.     

Resveratrol reduction of infarct size in Long-Evans rats subjected to focal cerebral ischemia

Although vasomotion has been considered a feature of the microvascular bed under physiological conditions, it has also been observed following hypotension in several tissues. In this work, 158 mesenteric microvessels of 36 rats were investigated quantitatively in normovolemic and hemorrhaged animals, focussing on diameter changes, particularly vasomotion incidence and characteristics. The femoral arteries of Wistar rats (body weight BW = 188 +/- 23 g, mean +/- SD) anesthetized with pentobarbital were cannulated for arterial pressure (AP) monitoring and blood withdrawal. The protocol consisted of 15 min control and 30 min of hemorrhagic hypotension (AP = 52 +/- 5 mmHg, hemorrhaged vol. = 17 +/- 4 ml/kg BW). During control normovolemic conditions, analysis of mesenteric microcirculation using intravital videomicroscopy revealed neither arteriolar nor venular vasomotion. During hemorrhagic hypotension (HH) microvascular blood flow reduced to 25% of control. While venules did not show diameter changes during HH, arterioles contracted to 85 +/- 20% of control and arteriolar vasomotion appeared in 42% of the animals and 27% of the arterioles. The amplitude of arteriolar diameter change during HH relative to mean diameter and to control diameter averaged 65 +/- 24% (range: 32-129%) and 41 +/- 10% (range: 25-62%), respectively. Vasomotion analysis showed two major frequency components: 1.7 +/- 0.8 and 7.0 +/- 5.2 cycles/min. Arterioles showing vasomotion had a mean control diameter larger than the remaining arterioles and showed the largest constriction during HH. We conclude that hemorrhagic hypotension does not change venular diameter but induces arteriolar constriction and vasomotion in rat mesentery. This activity is expressed as slow waves with high amplitude and fast waves with low amplitude, and is dependent on vessel size.     

Skin microvascular adaptations during maturation and aging of hairless mice

Using intravital fluorescence microscopy in the ears of hairless mice, we determined skin microvascular adaptations during the process of aging from juvenile to adult and senescent life (6-78 wk). Despite an increase of ear area within the first 36 wk, the number and branching pattern of both arteriolar and venular microvessels remained constant during the whole life period. Both arterioles and venules exhibited an increase in length, diameter, and intervascular distance up to the age of 36 wk. With the increase of the size of the ears, the observation that cutaneous capillary density remained unchanged implied new capillary formation. During aging to 78 wk, capillary density in the ears was reduced to approximately 40%. Functional analysis revealed an appropriate hyperemic response to a 2-min period of ischemia during late juvenile and adult life, which, however, was markedly reduced during senescence. Thus, except for capillaries, there is no indication for age-related new vessel formation. The process of aging from adult to senescent life does not cause any significant remodeling but is associated with a decrease of nutritive perfusion and a functional impairment to respond to stimuli such as ischemia.     

Terminal lymphatics: the potential "lethal corner" in the distribution of tissue pO2

BACKGROUND: Terminal lymphatic fluid is the compartment furthest removed from the oxygen supply, and therefore should present the lowest pO(2) in the tissue due to oxygen consumption by the tissue and the lymphatic vessel wall. METHODS AND RESULTS: The distribution of pO(2) was determined in the tissue, the lymphatic microvessels, and arterioles and venules of the hamster chamber window model, which is studied without anesthesia with the tissue isolated from the environment. Lymphatic fluid pO(2) was measured with the phosphorescence oxygen quenching method. Small terminal lymphatic fluid pO(2) was 18.4 +/- 2.6 mmHg, and 18.0 +/- 2.4 mmHg in collecting lymphatics. Tissue pO(2) averaged 24.6 +/- 2.7 mmHg. The significant difference between tissue and intralymphatic pO(2) was due in part to the presence of an oxygen gradient across the lymphatic wall, which ranged from 3.7 +/- 1.3 mmHg for terminal lymphatics, to 6.0 +/- 1.2 mmHg for collecting lymphatics. This gradient is assumed to be due to the oxygen consumption by the cellular component of the lymphatic wall. CONCLUSION: The increased vessels wall gradient found in collecting lymphatics was reconciled by the findings that these microlymphatic vessels tend to be contiguous to the arterioles, whereas the terminal lymphatics are dispersed in the tissue. These findings indicate that terminal lymphatic present the lowest oxygen tension in the tissue, and therefore are the locations at risk to develop anoxia when the microvascular oxygen supply becomes limited.     

Leukocyte-endothelium interaction in pial arterioles and venules following cerebral ischaemia of rat

With the help of contact optic system leukocytes interaction to endothelium of both pial arterioles and venules was investigated during cerebral ischaemia caused by bilateral occlusion of carotids, in vivo. The data received on 40 arterioles and 30 venules (diameter under 40 microns) of pia matter of Wistar rats (n = 7) under ischemic conditions following 5 hours up to respiratory arrest were analyzed. In this experiment, significant differences in adhesiveness of leukocytes to endothelium of arterial and venous microvessels during hypoxia development were shown.     

Effect of hypoxia on pulmonary blood flow-segmental vascular resistance relationship in perfused cat lungs

To investigate the effect of alveolar hypoxia onthe pulmonary blood flow-segmental vascular resistance relationship, wedetermined the longitudinal distribution of vascular resistance whileincreasing blood flow during hyperoxia or hypoxia in perfused catlungs. We measured microvascular pressures by the micropipetteservo-null method, partitioned the pulmonary vessels into threesegments [i.e., arterial (from main pulmonary artery to 30- to50-µm arterioles), venous (from 30- to 50-µm venules to leftatrium), and microvascular (between arterioles and venules)segments] and calculated segmental vascular resistance. Duringhyperoxia, total resistance decreased with increased blood flow becauseof a reduction of microvascular resistance. In contrast, duringhypoxia, not only microvascular resistance but also arterial resistancedecreased with increase of blood flow while venous resistance remainedunchanged. The reduction of arterial resistance was presumably causedby arterial distension induced by an elevated arterial pressure duringhypoxia. We conclude that, during hypoxia, both microvessels andarteries >50 µm in diameter play a role in preventing furtherincreases in total pulmonary vascular resistance with increased bloodflow.