Re-expression of pro-fibrotic, embryonic preserved mediators in irradiated arterial vessels of the head and neck region.

PURPOSE: Surgical treatment of head and neck malignancies frequently includes microvascular free tissue transfer. Preoperative radiotherapy increases postoperative fibrosis-related complications up to transplant loss. Fibrogenesis is associated with re-expression of embryonic preserved tissue developmental mediators: osteopontin (OPN), regulated by sex-determining region Y­box 9 (Sox9), and homeobox A9 (HoxA9) play important roles in pathologic tissue remodeling and are upregulated in atherosclerotic vascular lesions; dickkopf-1 (DKK1) inhibits pro-fibrotic and atherogenic Wnt signaling. We evaluated the influence of irradiation on expression of these mediators in arteries of the head and neck region. MATERIALS AND METHODS: DKK1, HoxA9, OPN, and Sox9 expression was examined immunohistochemically in 24 irradiated and 24 nonirradiated arteries of the lower head and neck region. The ratio of positive cells to total cell number (labeling index) in the investigated vessel walls was assessed semiquantitatively. RESULTS: DKK1 expression was significantly decreased, whereas HoxA9, OPN, and Sox9 expression were significantly increased in irradiated compared to nonirradiated arterial vessels. CONCLUSION: Preoperative radiotherapy induces re-expression of embryonic preserved mediators in arterial vessels and may thus contribute to enhanced activation of pro-fibrotic downstream signaling leading to media hypertrophy and intima degeneration comparable to fibrotic development steps in atherosclerosis. These histopathological changes may be promoted by HoxA9-, OPN-, and Sox9-related inflammation and vascular remodeling, supported by downregulation of anti-fibrotic DKK1. Future pharmaceutical strategies targeting these vessel alterations, e. g., bisphosphonates, might reduce postoperative complications in free tissue transfer.

Radiation-induced afferent arteriolar endothelial-dependent dysfunction involves decreased epoxygenase metabolites.

Chronic kidney disease is a known complication of hematopoietic stem cell transplant (HSCT) and can be caused by irradiation at the time of the HSCT. In our rat model there is a 6- to 8-wk latent period after irradiation that leads to the development of proteinuria, azotemia, and hypertension. The current study tested the hypothesis that decreased endothelial-derived factors contribute to impaired afferent arteriolar function in rats exposed to total body irradiation (TBI). WAG/RijCmcr rats underwent 11 Gy TBI, and afferent arteriolar responses to acetylcholine were determined at 1, 3, and 6 wk. Blood pressure and blood urea nitrogen were not different between control and irradiated rats. Afferent arteriolar diameters were not altered in irradiated rats. Impaired endothelial-dependent responses to acetylcholine were evident at 3 and 6 wk following TBI. Nitric oxide synthase (NOS), cyclooxygenase (COX), and epoxygenase (EPOX) contribution to acetylcholine dilator responses were evaluated. NOS inhibition with N(G)-nitro-l-arginine methyl ester (l-NAME) reduced acetylcholine responses by 50% in controls and 90% in 3-wk TBI rats. COX inhibition with indomethacin did not significantly alter the acetylcholine response in the presence or absence of l-NAME. EPOX inhibition with N-methylsulfonyl-6-(2-propargyloxyphenyl)hexanamide significantly decreased acetylcholine responses (35%) in controls but did not significantly alter acetylcholine responses (4%) in TBI rats. Biochemical analysis revealed decreased urinary EPOX metabolites but no change in COX, NOS, or reactive oxygen species at 3 wk TBI. Taken together, these results indicate that afferent arteriolar endothelial dysfunction involves a decrease in EPOX metabolites that precedes the development of proteinuria, azotemia, and hypertension in irradiated rats.

Role of nitric oxide in responses of pial arterial vessels to low-intensity red laser irradiation.

The responses of rat pial vessels to red laser irradiation can be mediated by NO. NO mainly affects major arteries and did not contribute to reactivity of small pial arteries and precortical arterioles.

Novel versus traditional risk markers for diabetic retinopathy.

AIMS/HYPOTHESIS: To explore the relative contribution of novel and traditional risk markers for diabetic retinopathy (DR). METHODS: A clinic-based study of 224 diabetic patients (85 type 1, 139 type 2) from a diabetes clinic was performed. DR was graded from fundus photographs according to the Airlie House Classification system and classified as absent or present (at least ETDRS level 14). Novel risk markers assessed included serum apolipoprotein (Apo) AI and B, skin microvascular responses to acetylcholine (endothelium-dependent) and sodium nitroprusside (endothelium-independent) iontophoresis, flicker-light-induced retinal vasodilation and retinal vascular tortuosity. Relative contribution was determined by semi-partial correlation coefficient generated from a logistic regression model containing all traditional and novel risk markers simultaneously. RESULTS: There were 144 (64.3%) participants with DR. Of the novel markers, ApoAI, flicker-light-induced vasodilation and retinal arteriolar tortuosity were significantly associated with DR, independently of traditional measures (all p < 0.03). Diabetes duration contributed most (51%) to the risk of DR, followed by ApoAI (16%), systolic blood pressure (13%), retinal arteriolar tortuosity (8%) and flicker-light-induced venular and arteriolar dilation (3% and 0.5%, respectively). CONCLUSIONS/INTERPRETATION: ApoAI and retinal arteriolar tortuosity made considerable contributions to DR risk, independently of traditional risk markers. Findings from this study suggest that serum ApoAI and retinal arteriolar tortuosity may be novel and independent risk markers of DR.

Dynamic retinal vessel response to flicker in obesity: A methodological approach.

Obesity and related metabolic disorders affect vascular endothelial function. The use of the Dynamic Vessel Analyzer (DVA) represents a modern methodological approach to analyze vascular function in the retinal microcirculation. Whether the dynamic reaction to flicker stimulation in retinal vessels is altered in obese subjects is investigated. Retinal vessel reactions to flicker stimulation were examined by DVA in 46 obese individuals (49.6±10.0years) and 46 age- and gender-matched healthy controls. The clinical examination included anthropometry, blood pressure measurements and blood sampling. Mean maximal arteriolar dilation in response to flicker was reduced in the obese group (3.2±1.8%) compared to controls (4.1±2.0%, p<0.05) and the time to maximal arteriolar dilation was prolonged (18.0±9.4s vs. 14.6±3.8s, p=0.03). In addition, mean maximal venular dilation was reduced in obese subjects (3.9±1.7% vs. 4.7±1.8%, p<0.05). Among the microvascular parameters, the most significant correlation with waist circumference was found for the "area under the reaction curve 50-80s after stimulation" in arterioles (r=-0.40; p<0.001). Functional retinal arteriolar reactivity to flicker stimulation differs between obese and healthy lean subjects. Time course analysis of retinal vessel response and its quantitative parameters can comprehensively characterize alterations of retinal vessel reactivity in metabolic disease.

Development of a rat model of photothrombotic ischemia and infarction within the caudoputamen.

BACKGROUND AND PURPOSE: Basal ganglia infarction is typically caused by the occlusion of deep arteries and the formation of relatively small lesions called lacunes. In the present study, a rat model of lacunar infarction was induced by photothrombotic occlusion of the small vessels within the caudate-putamen and subsequently characterized. METHODS: Male Sprague-Dawley rats (n=143) were anesthetized, and Rose Bengal dye (20 mg/kg) was intravenously injected. The left caudoputamen was exposed to cold white light for 5 to 10 minutes via a stereotaxically implanted polymethylmethacrylate optic fiber (0.5-0.75 mm diameter). Neurological and morphological changes were assessed at various times during the following 6 weeks. Local cerebral blood flow was measured 90 minutes after photothrombosis by [(14)C]-N-isopropyl-p-iodoamphetamine quantitative autoradiography. The time course of blood-brain barrier opening and ischemic brain edema as well as the effects of aspirin and tissue plasminogen activator treatment were also determined. RESULTS: A virtually round infarct with thrombosed parenchymal vessels surrounded by a layer of selective neuronal death was formed within the caudoputamen; it turned into a cystic cavity (lacune) over 6 weeks. A central zone of markedly reduced blood flow and surrounding oligemic zone were observed 90 minutes after light exposure. Lesion size was proportional to light exposure, and the severity and duration of neurological deficits paralleled infarct size. Early blood-brain barrier opening with edema peaked at day 1. After tissue plasminogen activator treatment, infarction volume and neurological deficits were reduced. CONCLUSIONS: This study describes a new rat model of lacunar infarction by photothrombotic occlusion of the microvessels within the caudoputamen. With this model, infarct size correlates with the severity and duration of the neuropathology and can be varied by altering light exposure.

Glial cells dilate and constrict blood vessels: a mechanism of neurovascular coupling.

Neuronal activity evokes localized changes in blood flow. Although this response, termed neurovascular coupling, is widely used to monitor human brain function and diagnose pathology, the cellular mechanisms that mediate the response remain unclear. We investigated the contribution of glial cells to neurovascular coupling in the acutely isolated mammalian retina. We found that light stimulation and glial cell stimulation can both evoke dilation or constriction of arterioles. Light-evoked and glial-evoked vasodilations were blocked by inhibitors of cytochrome P450 epoxygenase, the synthetic enzyme for epoxyeicosatrienoic acids. Vasoconstrictions, in contrast, were blocked by an inhibitor of omega-hydroxylase, which synthesizes 20-hydroxyeicosatetraenoic acid. Nitric oxide influenced whether vasodilations or vasoconstrictions were produced in response to light and glial stimulation. Light-evoked vasoactivity was blocked when neuron-to-glia signaling was interrupted by a purinergic antagonist. These results indicate that glial cells contribute to neurovascular coupling and suggest that regulation of blood flow may involve both vasodilating and vasoconstricting components.

Radiation induces endothelial dysfunction in murine intestinal arterioles via enhanced production of reactive oxygen species.

OBJECTIVE: Endothelial dysfunction and vascular dysregulation contribute to the pathological effects of radiation on tissues. The objectives of this study were to assess the acute effect of irradiation on acetylcholine (Ach)-induced dilation of gut submucosal microvessels. METHODS AND RESULTS: Rats were exposed in vivo to 1 to 9 cGy in 3 fractions per week on alternate days for 3 successive weeks for a total dose of up to 2250 cGy. Submucosal microvessels were isolated after varying levels of irradiation. Diameters of isolated vessels were measured using videomicroscopy, and the dose-response relationship to Ach was determined. Dihydroethidine and 2', 7'-dichlorodihydrofluorescein diacetate fluorescent probes were used to assess reactive oxygen species (ROS) production. After constriction (30% to 50%) with endothelin, dilation to graded doses of Ach (10(-9)-10(-4) M) was observed in control vessels (maximal dilation [MD] 87+/-3%; n=7). However, Ach-induced dilation was reduced in vessels from irradiated rats (MD=3+/-9%; n=7; P= or <0.05 versus controls). Significant increases in superoxide and peroxides were observed in irradiated microvessels. Irradiated microvessels pretreated with superoxide dismutase-mimetic demonstrated significant improvement in Ach-induced vasodilation compared with irradiation alone, suggesting that superoxide contributes to impaired dilation to Ach after irradiation. CONCLUSIONS: Radiation induces acute microvascular dysfunction in the resistance arterioles of the intestine. Enhanced ROS contribute to this dysfunction and therefore may represent a novel therapeutic target to minimize radiation toxicity in the gut.

Modulation of the tumor vasculature functionality by ionizing radiation accounts for tumor radiosensitization and promotes gene delivery.

The ultimate goal of radiotherapy is to induce irreversible damages in genetically unstable, fast-growing cancer cells while minimizing the cytotoxic effects on host tissues. The satus of the tumor vasculature is particular because it is located within the tumor but mostly arises from host cells. The aim of this study was to characterize the effects of low-dose irradiation on the function of endothelial cells lining tumor vessels. Using isolated arterioles mounted on a pressure myograph, we first documented that the nitric oxide (NO)-mediated vasorelaxation that was defective in tumor vessels was completely restored following local tumor irradiation. Immunoblot analyses revealed that this was attributable to an increase in the abundance of the endothelial NO synthase while the expression of its physiological inhibitor, caveolin-1, was reduced. We further showed that the potentiation of the NO-dependent pathway induced a marked increase in tumor blood flow and oxygenation that determined the higher sensitivity of the tumor to further irradiation. Finally, we documented that the NO-mediated effects of irradiation on the tumor vasculature increased the delivery and expression of a reporter gene into the tumor. Thus, low-dose irradiation of endothelial cells within a tumor is a key determinant of the effectiveness of radiotherapy and may offer a new strategy to increase gene and/or drug delivery to the tumor.

Acute vasculitis after endovascular brachytherapy.

PURPOSE: Angioplasty effectively relieves coronary artery stenosis but is often followed by restenosis. Endovascular radiation (beta or gamma) at the time of angioplasty prevents restenosis in a large proportion of vessels in swine (short term) and humans (short and long term). Little information is available about the effects of this radiation exposure beyond the wall of the coronary arteries. METHODS AND MATERIALS: Samples were obtained from 76 minipigs in the course of several experiments designed to evaluate endovascular brachytherapy: 76 of 114 coronary arteries and 6 of 12 iliac arteries were exposed to endovascular radiation from 32P sources (35 Gy at 0.5 mm from the intima). Two-thirds of the vessels had angioplasty or stenting. The vessels were systematically examined either at 28 days or at 6 months after radiation. RESULTS: We found an unexpected lesion: acute necrotizing vasculitis in arterioles located < or =2.05 mm from the target artery. It was characterized by fibrinoid necrosis of the wall, often associated with lymphocytic exudates or thrombosis. Based on the review of perpendicular sections of tissue samples, the arterioles had received between 6 and 40 Gy. This arteriolar vasculitis occurred at 28 days in samples from 51% of irradiated coronary arteries and 100% of irradiated iliac arteries. By 6 months, the incidence of acute vasculitis decreased to 24% around the coronary arteries. However, at that time, healing vasculitis was evident, often with luminal narrowing, in 46% of samples. Vasculitis was not seen in any of 44 samples from unirradiated vessels (0%) and had no relation to angioplasty, stenting, or their sequelae. This radiation-associated vasculitis in the swine resembles the localized lymphocytic vasculitis that we have reported in tissues of humans exposed to external radiation. On the other hand, it is quite different from the various types of systemic vasculitis that occur in nonirradiated humans. CONCLUSION: Endoarterial brachytherapy using 32P results in vascular effects beyond the adventitia of the target vessel. This necrotizing vasculitis is causally related to radiation, but its mechanism is unclear and a dose effect is not evident. Quite possibly, local upregulation of inflammatory cytokines contributes to this radiation-associated vasculitis, which only involved some of the arterioles in each sample. It is likely that radiation-associated vasculitis also occurs around human coronary arteries and may result in foci of ischemia. To our knowledge, this lesion has not been previously recognized, either in experimental models or in human specimens examined after angioplasty/brachytherapy.

Lack of in vivo function of CD31 in vascular thrombosis.

A murine model of endothelial cell injury-based vascular thrombosis was used to test the role of platelet-endothelial cell adhesion molecule-1 (PECAM-1, CD31) in blood cell aggregate formation and vessel occlusion in vivo. Photochemically-induced thrombus formation was analyzed in detail using intravital fluorescence microscopy of individual microvessels in cremaster muscle preparations of CD31-deficient and wildtype mice. In venules, epi-illumination induced rapid thrombus formation with first platelet deposition after 0.56 +/- 0.11 min and complete vessel occlusion within 5.05 +/- 0.45 min. In arterioles, thrombus formation was markedly delayed with first platelet deposition after 3.03 +/- 0.47 min and complete vessel occlusion within 10.04 +/- 1.26 min. Kinetics of thrombus formation in both venules (first platelet deposition: 0.52 +/- 0.1 min; vessel occlusion: 5.03 +/- 0.52 min) and arterioles (first platelet deposition: 3.06 +/- 0.68 min; vessel occlusion: 10.02 +/- 1.38 min) of CD31-deficient mice was found almost identical compared with that in wildtype animals. Tail bleeding time was 233 +/- 24 s in wildtype and 243 +/- 32 s in CD31-deficient mice. Moreover, CD31-deficient and wildtype mice revealed comparable interaction of leukocytes to endothelium. This study shows for the first time in vivo that CD31 is not critically involved in blood cell thrombus formation upon endothelial cell injury.

Radiosensitivity of vascular tissue. I. Differential radiosensitivity of capillaries: a quantitative in vivo study.

The effects of single doses of X radiation ranging from 200 to 2000 rad were studied by direct morphometry in vivo of the mature, stable microvasculature in rabbit ear chambers. Reproducible observations in vivo of the mature microvasculature were obtained by photomicrography of identical 0.033-mm2 sites in each ear chamber prior to and 1 and 5 days following single doses of X radiation. Measurements were made directly on color photomicrographs at a total magnification of 2000X. The microvessels were divided into two groups according to size: vessels greater than 10 microns in diameter (arterioles and venules), and vessels less than or equal to 10 microns in diameter (capillaries). Vascular length and outer and inner surface areas were measured directly on the projected photomicrographs, and vascular volumes and diameters were calculated from these measured parameters. Measurements of capillary length per unit surface area disclosed a decrease in capillary density with increasing dose, resulting in a calculated intercapillary distance in excess of 300 microns, conceivably associated with a decrease in oxygen delivery by the microvasculature. With this method, radiosensitivity of the capillaries was found to be significantly greater than that of larger vessels. Computerized histogram analysis of vascular length, surface area, and volume as a function of increasing diameter (1-micron bins) confirmed the significant difference in reduction of these measured parameters between the capillaries and the larger vessels. The total microvascular volume profile dominated by the volume of larger vessels did not change much 5 days after irradiation, although capillary volume was markedly reduced. Furthermore, the basic profile of the microvasculature showed a shift to larger diameters following irradiation, thus confirming the calculated dilatation of surviving vessels. Qualitative morphologic observations revealed considerable extravasation from the microvessels and formation of micropetechiae at the site of disrupted capillaries with subsequent inflammatory changes.

Connexin expression and conducted vasodilation along arteriolar endothelium in mouse skeletal muscle.

Functional hyperemia requires the coordination of smooth muscle cell relaxation along and between branches of the arteriolar network. Vasodilation is conducted from cell to cell along the arteriolar wall through gap junction channels composed of connexin protein subunits. Within skeletal muscle, it is unclear whether arteriolar endothelium, smooth muscle, or both cell layers provide the cellular pathway for conduction. Furthermore, the constitutive profile of connexin expression within the microcirculation is unknown. We tested the hypothesis that conducted vasodilation and connexin expression are intrinsic to the endothelium of arterioles (17 +/- 1 microm diameter) that supply the skeletal muscle fibers in the cremaster of anesthetized C57BL/6 mice. ACh delivered to an arteriole (500 ms, 1-microA pulse; 1-microm micropipette) produced local dilation of 17 +/- 1 microm; conducted vasodilation observed 1 mm upstream was 9 +/- 1 microm (n = 5). After light-dye treatment to selectively disrupt endothelium (250-microm segment centered 500 microm upstream, confirmed by loss of local response to ACh while constriction to phenylephrine and dilation to sodium nitroprusside remained intact), we found that conducted vasodilation was nearly abolished (2 +/- 1 microm; P < 0.05). Whole-mount immunohistochemistry for connexins revealed punctate labeling at borders of arteriolar endothelial cells, with connexin40 and connexin37 in all branches and connexin43 only in the largest branches. Immunoreactivity for connexins was not apparent in smooth muscle or in capillary or venular endothelium, despite robust immunolabeling for alpha-actin and platelet endothelial cell adhesion molecule-1, respectively. We conclude that vasodilation is conducted along the endothelium of mouse skeletal muscle arterioles and that connexin40 and connexin37 are the primary connexins forming gap junction channels between arteriolar endothelial cells.

Focal hepatic ablation using interstitial photon radiation energy.

BACKGROUND: Intratumoral ablative therapy is being used increasingly for the treatment of primary and secondary hepatic malignancies. The interstitial point-source photon radiosurgery system (PRS) is a novel ablative technique that uses radiation therapy similar in dosimetry to interstitial brachytherapy. STUDY DESIGN: To determine the feasibility, toxicity, and local tissue destructive capabilities of the PRS in the liver, preliminary studies in a nontumor-bearing canine model were examined. A 6-month survival study was conducted. Each animal received three radiation treatments, in the right, central, and left hepatic regions. Three low-dose treatments were delivered to each of six animals (group A), generating a 2.0-cm-diameter radiated sphere with a dose of 20 Gy at the lesion edge. Three high-dose treatments were delivered to each of six animals (group B), generating a 3.0-cm-diameter radiated sphere with 20 Gy at the lesion edge. RESULTS: The treatment reproducibly generated sharply demarcated hepatic ablative lesions proportional to the administered dose. Mean lesion diameter at 1 month was 1.6+/-0.2 cm in group A and 3.4+/-1.0 cm in group B. Lesion size was independent of intrahepatic location, including near vascular structures. PRS therapy, when applied to portal structures, resulted in hilar damage. Hilar damage appeared to be associated with arteriolar thrombosis and bile duct injury. Treatment of regions adjacent to large hepatic veins and the IVC was not associated with vessel thrombosis or stricture. CONCLUSIONS: PRS ablation is a generally well-tolerated method that results in consistent, well-demarcated, symmetric lesions of complete necrosis with minimal adjacent parenchymal injury. Application of such an approach for the treatment of liver tumors is promising.

Laser fluence for permanent damage of cutaneous blood vessels.

Treatment of vascular disorders may be improved by a more thorough understanding of laser-blood vessel interaction. In this study, the probability of permanent damage to a given type and size of blood vessel was determined as a function of fluence at the top (superficial edge) of the vessel lumen. A 532 nm wavelength, 10 ms pulse duration, 3 mm spot size laser was used to perform approximately 250 irradiations of subdermal blood vessels in the hamster dorsal skin flap preparation. The radiant exposure required for a 50% probability of permanent damage was calculated using a probit analysis of experimental results. Threshold radiant exposure increased with larger blood vessel diameters and was greater for arterioles than venules. Monte Carlo modeling of a typical blood vessel geometry revealed that fluence at the top of the blood vessel lumen was amplified by a factor of approximately 2.4 over tissue surface radiant exposure, due to light scattering in the tissue and internal reflection at the skin-air interfaces.

The effects of photodynamic therapy using differently substituted zinc phthalocyanines on vessel constriction, vessel leakage and tumor response.

The effects of four different zinc phthalocyanines were studied during and after photodynamic therapy (PDT). Measurements of vessel constriction, vessel leakage, tumor interstitial pressure, eicosanoid release, and tumor response of chondrosarcoma were made in Sprague-Dawley rats. Animals were injected intravenously with 1 mumol/kg of mono-, di-, or tetrasulfonated zinc phthalocyanine, or 1 mumol/kg of a zinc phthalocyanine substituted with four tertiary butyl groups. Tissues were exposed to 400 J/cm2 670 nm light 24 h after photosensitizer injection. An additional group of animals was given indomethacin before treatment. The use of the monosulfonated and tertiary butyl substituted zinc phthalocyanines in PDT caused the release of specific eicosanoids, caused vessel constriction, and induced venule leakage and increases in tumor interstitial pressure. Tumor cures of 27% and 7% were observed. Photodynamic therapy using the disulfonated zinc phthalocyanine did not induce vessel constriction or the release of eicosanoids, however, tumor cure was 43%. The use of the tetrasulfonated zinc phthalocyanine caused intermediate effects between the mono- and disulfonated compounds. The administration of indomethacin to animals completely inhibited the effects of PDT using the monosulfonated compound but had minimal effects on treatment using the disulfonated compound. This suggests that the monosulfonated and disulfonated compounds act by different mechanisms of destruction.

Acute and protracted radiation effects on small intestinal morphological parameters.

PURPOSE: To compare the responses of small intestinal morphological parameters after acute and protracted doses of radiation. MATERIALS AND METHODS: Male C57BL6 mice were examined 6, 24 and 72 h after whole body gamma-irradiation, given either as an acute 5 Gy dose, or as a protracted (continuous) dose of 20 cGy per day for 25 days to a total dose of 5 Gy. Many different structural parameters at both the light microscopical and ultrastructural levels were assessed quantitatively. RESULTS: At different time points following both schedules there were changes in the number of villous enterocytes, goblet cells, lamina propria cells and mitotic figures. Ultrastructural changes occurred in the epithelium. Many of the parameters that showed changes following the protracted schedule appeared to be returning to normal within 3 days of the cessation of radiation, a finding which was in contrast with the acute dose. The protracted schedule produced increases in the number of Paneth cells and in the length of enterocyte microvilli. CONCLUSIONS: Many of the responses that occurred after the protracted schedule suggest that adaptive mechanisms may be being triggered following persistent exposure to radiation.

[Changes in the microcirculatory bed of the mesentery in the rat in the intestinal form of acute radiation disease (experimental morphologic study)]. / Izmeneniia mikrososudistogo rusla bryzheiki krys pri kishechnoi forme ostroi luchevoi bolezni (éksperimental'no-morfologicheskoe issledovanie).

Total mesentery preparations of the rat after single total irradiation at the dose levels of 15 and 30 Gy were examined by V. V. Kupriyanov 's method and staining by N.E. Yarigin and S.V. Panchenko . Monotonous pathomorphological changes characteristic of microcirculation disorders were revealed such as blood overdistribution into the venous part of microvasculature prestasis , stasis and lymphostasis. Apart from these qualitative alterations, morphometry of certain parts of microvasculature was performed and some indexes and ratios were calculated. Changes of quantitative parameters were as follows: increase of the capillaries, postcapillaries and venules diameter, increase of their surface and volume, increase of diameter of pericapillary diffusion zone; decrease of the correlation ratio between total arteriolar influx and total venular blood passage within a mesentery segment; decrease of the calculated linear speed of blood in capillaries, postcapillaries and venulas .

[Characteristics of thrombus formation in arterioles and venules]. / Osobennosti tromboobrazovaniia v arteriolakh i venulakh.

The model of laser-induced thrombosis revealed a greater thromboresistance in arterioles rather than in venules of the rat small intestine mesentery, which accounts for a less frequent thrombosis and a lesser size of thrombus along the blood flow direction, whereas their greater thrombogenic potential accounts for a faster growth of thrombus and a shorter time of the primary hemostasis.