Oxygen regime in rat brain tissues under conditions of acute nitrite methemoglobinemia

Oxygen regime in rat brain tissues was studied under conditions of nitrite hypoxia. The local brain circulation (LCC) and pO₂ were recorded by polargraphic method in microareas of the brain cortex one hour after a subcutaneous injection of NaNO₂ (3 mg/100 g body mass). A LCC decrease by 55% was shown by the 30th min of the nitrite intoxication, with its restoration to 85% of the initial blood-flow by the 60th min. In some brain microareas, a pO₂ increase by 40.7% was observed by the 45th min of the action and its decrease by 32.2% by the 60th min, whereas in other microareas, a pO₂ decrease by 24.5% with its subsequent increase to 78.7% of the initial level, respectively. A statistically significant correlation is revealed between changes of the oxygen pressure in the process of development of nitrite hypoxia and the LCC dynamics. It is concluded that the circulatory disturbances developing at the first moments of the nitrite action lead to an increase of the degree of the pO₂ differentiated distribution in the brain: to hyperoxygenation in some microareas and to severe hypoxia in others, what can be the cause of functional brain disturbances under the effect of nitrogen oxides.     

Comparative-physiological study of leukocyte participation in initiation of lipid peroxidation during nitrite intoxication in rats and muskrats

The study is carried out on Wistar white rats non-adapted to oxygen deficit and on semiaquatic rodents muskrats adapted to periodic arrest of respiration during diving under conditions of Nembutal narcosis. It has been revealed that 1 h after a subcutaneous injection of sodium nitrite (3 mg/100 g body mass), intensification of lipid peroxidation (LPO) in the muskrat brain is absent, the activity of the antioxidant enzyme catalase increasing 16 times (p < 0.01) as compared with control injected with equivalent saline volume. In heart and liver, there was a statistically significant decrease of the content of LPO products active in the test with 2-thiobarbituric acid; in the femoral muscle tissue, the LPO intensity did not change. In rats, unlike muskrats, after injection of sodium nitrite, an increase of LPO is recorded in brain, while a decrease of the LPO product content in the femoral muscle; in liver the LPO intensity did not change. In muskrats, the sodium nitrite administration led to a decrease of the leukocyte spontaneous mobility, of lymphocyte cytokine-producing activity, and of neutrophil bactericidal activity (by the content of cationic proteins in neutrophilic phagocytes), whereas in rats the leukocyte mobility did not change, only the blood neutrophil bactericidal activity decreased. The ability of neutrophils to produce the superoxide anion during the nitrite intoxication did not change both in rats and in muskrats. The obtained data allow concluding that under conditions of Nembutal narcosis the leukocyte functional activity on the background of nitrite intoxication is suppressed to the greater degree in the muskrats genotypically adapted to oxygen deficit than in immunocompetent cells of the rodents not adapted to hypoxia.     

Effects of hypoxic factors on cardiac chronotropic reactions in the muskrat Ondatra zibethicus in free behavior

Effects of natural and artificial hypoxic factors on cardiac chronotropic reactions were studied in the muskrat Ondatra zibethicus naturally adapted to underwater hypoxia under conditions of free behavior. To record cardiac activity, original implanted ECG sensors designed in the laboratory were used. Under observations were muskrats in the states of rest, movement, swimming on the water surface, diving, underwater swimming, forced underwater immersion, and artificial apnea, in the low-pressure chamber during changes of pressure from 100 to 25 kPa (ascent to an altitude of 11 km) and in the atmosphere of hypoxic mixtures with 5–10% O₂ as well as under conditions of hemic nitrite hypoxia after injection of 3 mg/kg NaNO₂. Heart rate (HR) in muskrats is labile and can change within the limits from 15 to 360 beats/min. A characteristic feature of hypoxic action is development in muskrats of bradycardia that can appear either instantly—both as a conditional reflex and from the nose lobe receptors—or gradually at a decrease of pO₂ in inhaled air. Before diving and after coming to the surface a brief tachycardia can also be observed. The gradual development of tachycardia takes place in nitrite hypoxia. Development of bradycardia was eliminated at blockade of M-cholinoreceptors by atropine, and of tachycardia—at blockade of β-adrenoreceptors by propranolol. Blockade of α-adrenoreceptors by phentolamine did not affect cardiac chronotropic reactions, which indicates the absence of their connection with vasoconstriction. Analysis of the cardiac rhythm variability has revealed a large spectrum of slow cardiointerval fluctuations connected with animal functional states. Regulation of cardiac chronotropic reactions in muskrats under effect of hypoxic factors operates along both sympathetic and parasympathetic pathways of the autonomic nervous system, the leading role in these processes being played by vagus influences. Original Russian Text. V. I. Shereshkov, T. E. Shumilova, D. A. Kuzmin, I. N. Yanvareva, and A. D. Nozdrachev, 2006, published in Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, 2006, Vol. 42, No. 4, pp. 371–377.     

Noninvasive Monitoring of Small Intestinal Oxygen in a Rat Model of Chronic Mesenteric Ischemia

We noninvasively monitored the partial pressure of oxygen (pO₂) in rat’s small intestine using a model of chronic mesenteric ischemia by electron paramagnetic resonance oximetry over a 7-day period. The particulate probe lithium octa-n-butoxynaphthalocyanine (LiNc-BuO) was embedded into the oxygen permeable material polydimethyl siloxane by cast-molding and polymerization (Oxy-Chip). A one-time surgical procedure was performed to place the Oxy-Chip on the outer wall of the small intestine (SI). The superior mesenteric artery (SMA) was banded to ~30 % of blood flow for experimental rats. Noninvasive measurement of pO₂ was performed at the baseline for control rats or immediate post-banding and on days 1, 3, and 7. The SI pO₂ for control rats remained stable over the 7-day period. The pO₂ on day-7 was 54.5 ± 0.9 mmHg (mean ± SE). SMA-banded rats were significantly different from controls with a noted reduction in pO₂ post banding with a progressive decline to a final pO₂ of 20.9 ± 4.5 mmHg (mean ± SE; p = 0.02). All SMA-banded rats developed adhesions around the Oxy-Chip, yet remained asymptomatic. The hypoxia marker Hypoxyprobe? was used to validate the low tissue pO₂. Brown cytoplasmic staining was consistent with hypoxia. Mild brown staining was noted predominantly on the villus tips in control animals. SMA-banded rats had an extended region of hypoxic involvement in the villus with a higher intensity of cytoplasmic staining. Deep brown stainings of the enteric nervous system neurons and connective tissue both within layers and in the mesentery were noted. SMA-banded rats with lower pO₂ values had a higher intensity of staining. Thus, monitoring SI pO₂ using the probe Oxy-Chip provides a valid measure of tissue oxygenation. Tracking pO₂ in conditions that produce chronic mesenteric ischemia will contribute to our understanding of intestinal tissue oxygenation and how changes impact symptom evolution and the trajectory of chronic disease.     

Structural changes in the neocortex nervous tissue in rat ontogenesis after hypoxia at various terms of embryogenesis

The performed study has shown that in rats submitted to hypoxia (3 h, 7% O₂) at the 14th day of embryogenesis (E14) as compared with control animals, density of distribution of cells in the brain cortex decreased for the first month of postnatal ontogenesis (maximally by 40.8% by P20). In dying neurons, swelling of the cell body, lyses of or ganoids, and disturbance of the cytoplasm membrane intactness were observed. Two waves of neuronal death by the mechanism of capsize-dependent apoptosis were revealed; the first involved large pyramidal neurons of the layer V (P10–20), the second-small pyramidal and non-pyramidal neurons of the layers II–III (P20–30). In neurosis of molecular layer, a decrease of the mean amount of labile synaptopodin-positive dendrite spines was observed, as compared with control. In rats exposed to hypoxia at E18, no changes of cell composition and structure of the nervous tissue were found in the studied brain cortex areas. Thus, formation of the cortex nervous tissue in postnatal ontogenesis of rats submitted to hypoxia at the period of neuroblast proliferation-migration is accompanied not only by a change of the cell composition of various cortex layers in early ontogenesis, but also by a decrease of the number of the synaptopodin-positive spines in the molecular layer, the decrease being preserved in adult animals.     

Cardiovascular manifestations of acute nitrite intoxication in laboratory rats

The systemic and peripheral hemodynamics was studied in male white rats under conditions of acute nitrite hypoxia (subcutaneous administration of sodium nitrite at doses of 1, 3, and 5 mg/100 g body mass). By the electrocardiographic, rheographic, and other methods there were recorded the heart rate (HR), minute circulation volume (MCV), cardiac output (CO), skeletal muscle circulation (SMC), brain circulation (BC), and systemic arterial pressure (AP). Nitrite was shown to produce a fast, dose-dependent AP fall accompanied by a decrease of MCV due to development of bradycardia and a fall of CO. At the phase of the steady hypotension, MCV increased due to a significant rise of CO on the background of the continuing bradycardia. The systemic circulatory effects of NaNO₂ were found to be accompanied by a redistribution of peripheral circulation in the form of a dose-dependent increase of BC and a sharp fall of MCV. It was shown that 1–1.5 h after the nitrite injection the parameters of systemic and peripheral hemodynamics approached the initial levels. Possible triggering mechanisms of the initial stage of the rat cardiovascular adaptation to conditions of acute nitrite hypoxia are discussed.     

Poster Sessions CP13: Hypoxia,Ischemia and Oxidative Stress. Changes of brain nitric oxide production in experimental cerebral ischemia

In order to study the role of nitric oxide (NO) in ischemic brain injury. Global cerebral ischemia was established in SD rats by modified Pulsinelli's method. The activities of constitutive nitric oxide synthase (cNOS), inducible NOS (iNOS), neuronal NOS (nNOS), nitrite (NO₂) and cyclic GMP in cerebral cortex, hippocampus, striatum and cerebellum at different time intervals were measured by radioimmunoassy, NADPH‐d histochemistry and fluorometry methods. The results showed that the activities of cNOS increased at 5 min in four regions and decreased in cortex, hippocampus and striatum at 60 min, in cerebellum at 15 min iNOS increased in cortex and striatum at 15 min, in hippocampus and cerebellum at 10 min, and persisted to 60 min. The expression of nNOS increased after 5 min ischemia in cortex, striatum and hippocampus, and return to normal at 30–60 min. The NO₂ and cGMP also increased after 5–15 min ischemia and returned to normal after 30–60 min ischemia. These results indicated that the NO participated in the pathogenesis of cerebral ischemia injury and different types of NOS play different role in the cerebral ischemia injuries. Selected specific NOS inhibitors to decreased the excessive production of NO at early stage may help to decrease the ischemic injury.     

A Comparative pO2 Probe and [18F]-Fluoro-Azomycinarabino-Furanoside ([18F]FAZA) PET Study Reveals Anesthesia-Induced Impairment of Oxygenation and Perfusion in Tumor and Muscle

Tumor hypoxia can be identified by [¹⁸F]FAZA positron emission tomography, or invasively using oxygen probes. The impact of anesthetics on tumor hypoxia remains controversial. The aim of this comprehensive study was to investigate the impact of isoflurane and ketamine/xylazine anesthesia on [¹⁸F]FAZA uptake and partial oxygen pressure (pO₂) in carcinoma and muscle tissue of air- and oxygen-breathing mice.

Methods

CT26 colon carcinoma-bearing mice were anesthetized with isoflurane (IF) or ketamine/xylazine (KX) while breathing air or oxygen (O₂). We performed 10 min static PET scans 1 h, 2 h and 3 h after [¹⁸F]FAZA injection and calculated the [¹⁸F]FAZA-uptake and tumor-to-muscle ratios (T/M). In another experimental group, we placed a pO₂ probe in the tumor as well as in the gastrocnemius muscle to measure the pO₂ and perfusion.

Results

Ketamine/xylazine-anesthetized mice yielded up to 3.5-fold higher T/M-ratios compared to their isoflurane-anesthetized littermates 1 h, 2 h and 3 h after [¹⁸F]FAZA injection regardless of whether the mice breathed air or oxygen (3 h, KX-air: 7.1 vs. IF-air: 1.8, p = 0.0001, KX-O₂: 4.4 vs. IF-O₂: 1.4, p < 0.0001). The enhanced T/M-ratios in ketamine/xylazine-anesthetized mice were mainly caused by an increased [¹⁸F]FAZA uptake in the carcinomas. Invasive pO₂ probe measurements yielded enhanced intra-tumoral pO₂ values in air- and oxygen-breathing ketamine/xylazine-anesthetized mice compared to isoflurane-anesthetized mice (KX-air: 1.01 mmHg, IF-air: 0.45 mmHg; KX-O₂ 9.73 mmHg, IF-O₂: 6.25 mmHg). Muscle oxygenation was significantly higher in air-breathing isoflurane-anesthetized (56.9 mmHg) than in ketamine/xylazine-anesthetized mice (33.8 mmHg, p = 0.0003).

Conclusion

[¹⁸F]FAZA tumor uptake was highest in ketamine/xylazine-anesthetized mice regardless of whether the mice breathed air or oxygen. The generally lower [¹⁸F]FAZA whole-body uptake in isoflurane-anesthetized mice could be due to the higher muscle pO₂-values in these mice compared to ketamine/xylazine-anesthetized mice. When performing preclinical in vivo hypoxia PET studies, oxygen should be avoided, and ketamine/xylazine-anesthesia might alleviate the identification of tumor hypoxia areals.     

Effects of oxygenation conditions on the respiratory activity generated by medullo-spinal preparations of rats

On isolated medullo-spinal preparations (IMSP) of newborn rats that generate rhythmic respiratory activity, we observed specific features of the reactions to a decrease in the O₂ tension in the superfusing medium (saturation with an isocapnic anoxic gas mixture) manifested in a standard configuration of the preparation, after separation of the rostral part of the medulla and after pH modifications. Using microelectrode amperometric measurements of pO₂ above the ventral medullary surface and of pO₂ profiles into the medullary tissues, we demonstrated the dependence of oxygen supply of IMSP on the rate of superfusion and the existence of hypoxic and anoxic zones in its tissues. The mechanisms of sensitivity of the IMSP-generated respiratory rhythm to hypoxia are discussed.     

Brain adaptation to chronic hypobaric hypoxia in rats.

Rats were exposed to hypobaric hypoxia (0.5 atm) for up to 3 wk. Hypoxic rats failed to gain weight but maintained normal brain water and ion content. Blood hematocrit was increased by 48% to a level of 71% after 3 wk of hypoxia compared with littermate controls. Brain blood flow was increased by an average of 38% in rats exposed to 15 min of 10% normobaric oxygen and by 23% after 3 h but was not different from normobaric normoxic rats after 3 wk of hypoxia. Sucrose space, as a measure of brain plasma volume, was not changed under any hypoxic conditions. The mean brain microvessel density was increased by 76% in the frontopolar cerebral cortex, 46% in the frontal motor cortex, 54% in the frontal sensory cortex, 65% in the parietal motor cortex, 68% in the parietal sensory cortex, 68% in the hippocampal CA1 region, 57% in the hippocampal CA3 region, 26% in the striatum, and 56% in the cerebellum. The results indicate that hypoxia elicits three main responses that affect brain oxygen availability. The acute effect of hypoxia is an increase in regional blood flow, which returns to control levels on continued hypoxic exposure. Longer-term effects of continued moderate hypoxic exposure are erythropoiesis and a decrease in intercapillary distance as a result of angiogenesis. The rise in hematocrit and the increase in microvessel density together increase oxygen availability to the brain to within normal limits, although this does not imply that tissue PO2 is restored to normal.     

Regulation of peripheral and systemic blood circulation in rats in conditions of acute nitrite hypoxia

Regulation of the systemic and peripheral hemodynamics in the conditions of acute nitrite hypoxia (doses of NaNO₂ 10, 30, and 50 mg/kg of the body mass) were studied on white male rats. It was shown that NaNO₂ causes a quick dose-dependent decrease in the blood pressure with an intensification of the parasympathetic tonus and development of bradycardia. The hemodynamics was restored as the oxygen capacity of the blood decreased with an increase in the sympathetic tonus and development of tachycardia. The role of intracardial metasympathetic structures and the renin-angiotensin system in cardiovascular adaptation to hypoxia was established. Adaptation to nitrite hypoxia is accomplished by a coordinated interaction of neurogenic and humoral factors. A combination of pharmacological agents, which include separate links of regulator systems of the organism, leads to failure of the adaptation process.     

Study of distribution of the spine apparatus protein synaptopodin in cortical brain parts of rats exposed to hypoxia at different periods of embryogenesis

A comparative study of the nervous tissue and distribution of the spine apparatus protein synaptopodin was performed in all layers of the brain sensorimotor cortex and hippocampal CAl area in control rats and in the rats exposed to hypoxia at E14 and E18. It was found that beginning from the 20th day of postnatal development, a statistically significant decrease of the mean number of labile synaptopodin-positive spines in the stratum radiatum moleculare of the hippocampal area CAl was observed in rats exposed to hypoxia both at E14 and E18. The decrease of the number of labile spines in the sensorimotor brain cortex was revealed only in the I layer beginning from the 20th day after birth in the rats exposed to hypoxia at E14. Maximal differences in the studied brain areas were observed in adult rats exposed to hypoxia at E14 in the neocortex—a decrease by 23 ± 10%, in hippocampus—by 24 ± 8%, respectively. However, no increased degeneration of neurons was detected in adult animals. It is suggested that disturbances in cognitive functions and in the capability for learning observed in rats after prenatal hypoxia can be due to a decrease of the amount of the labile synaptopodin-positive spines, which leads to a change of the structural-functional properties of neuronal networks and to a decrease of their plasticity.     

Quantitative imaging of pO2 in orthotopic murine gliomas: hypoxia correlates with resistance to radiation

Hypoxia is considered one of the microenvironmental factors associated with the malignant nature of glioblastoma. Thus, evaluating intratumoural distribution of hypoxia would be useful for therapeutic planning as well as assessment of its effectiveness during the therapy. Electron paramagnetic resonance imaging (EPRI) is an imaging technique which can generate quantitative maps of oxygen in vivo using the exogenous paramagnetic compound, triarylmethyl and monitoring its line broadening caused by oxygen. In this study, the feasibility of EPRI for assessment of oxygen distribution in the glioblastoma using orthotopic U87 and U251 xenograft model is examined. Heterogeneous distribution of pO₂ between 0 and 50?mmHg was observed throughout the tumours except for the normal brain tissue. U251 glioblastoma was more likely to exhibit hypoxia than U87 for comparable tumour size (median pO₂; 29.7 and 18.2?mmHg, p?=?.028, in U87 and U251, respectively). The area with pO₂ under 10?mmHg on the EPR oximetry (HF10) showed a good correlation with pimonidazole staining among tumours with evaluated size. In subcutaneous xenograft model, irradiation was relatively less effective for U251 compared with U87. In conclusion, EPRI is a feasible method to evaluate oxygen distribution in the brain tumour.     

Adaptation to intermittent hypoxia restricts nitric oxide overproduction and prevents beta-amyloid toxicity in rat brain

This study tested the hypothesis that adaptation to intermittent hypoxia (AIH) can prevent overproduction of nitric oxide (NO) in brain and neurodegeneration induced by beta-amyloid (Aβ) toxicity. Rats were injected with a Aβ protein fragment (25–35) into the nucleus basalis magnocellularis. AIH (simulated altitude of 4000 m, 14 days, 4 h daily) was produced prior to the Aβ injection. A passive, shock-avoidance, conditioned response test was used to evaluate memory function. Degenerating neurons were visualized in stained cortical sections. NO production was evaluated in brain tissue by the content of nitrite and nitrate. Expression of nNOS, iNOS, and eNOS was measured in the cortex and the hippocampus using Western blot analysis. 3-Nitrotyrosine formation, a marker of protein nitration, was quantified by slot blot analysis. Aβ injection impaired memory of rats; AIH significantly alleviated this disorder. Histological examination confirmed the protective effect of AIH. Degenerating neurons, which were numerous in the cortex of Aβ-injected, unadapted rats, were essentially absent in the brain of hypoxia-adapted rats. Injections of Aβ resulted in significant increases in NOx and in expression of all NOS isoforms in brain; AIH blunted these increases. NO overproduction was associated with increased amounts of 3-nitrotyrosine in the cortex and hippocampus. AIH alone did not significantly influence tissue 3-nitrotyrosine, but significantly restricted its increase after the Aβ injection. Therefore, AIH affords significant protection against experimental Alzheimer’s disease, and this protection correlates with restricted NO overproduction.     

Hemodynamics in the Microcirculation System of the Rat Cerebral Cortex in Nitrite Methemoglobinemia

Effects of sodium nitrite on the blood flow rate (V) in microvessels of rat cerebral cortex (5–15 µm in diameter), arterial pressure (AP), plasma osmotic pressure (P _osm), and hematological parameters were studied. The mean V and AP in 15 min after administration of NaNO₂ (3 mg/100 g mass) decrease by 36% and 45%, while in 30 and 45 min they increase by 14% and 7% and by 20% and 19% as compared with minimal values, respectively. At the end of the experiment, on the background of an elevation of P _osm (3%), a decrease of total hemoglobin concentration and of the number of erythrocytes was accompanied by a decrease of the discocyte number from 81 to 35% and a reduction of cell diameters by 7%. It is concluded that NaNO₂ produces block of local active mechanisms of the cerebral blood flow regulation. Compensatory responses in this case are provided by passive mechanisms (rheological blood properties) and systemic reactions.     

Tissue oxygen partial pressure in organs of chickens in the second half of embryogenesis and first days after hatching

The aim of this study is to measure the oxygen partial pressure (pO₂) in developing chicken tissues, namely, in the cerebral hemispheres, liver, m. pectoralis, and m. gastrocnemius, and to estimate the correlation of pO₂ with the earlier measured values (laser Doppler flowmetry) of volume blood flow (BF) in these organs. We have studied 10-, 15-, and 19-day-old embryos and 4-day-old chickens anesthetized with urethane. The pO₂ has been measured in the surface layers of organs with a membrane amperometric Clark-type O₂ electrode (cathode diameter of approximately 50 μm) placed in the center of the sensor unit (outer diameter of 3.4 mm). Noticeable distinctions between both the tissue pO₂ values in different organs and the dynamics of their changes during the observation time have been recorded. The following differences are the most important: (1) the lowest pO₂} {cm(and BF) is observed in the brain and, especially, in the liver of 10-day-old embryos; (2) in the subsequent period of embryogenesis, the pO₂ in the brain increases 1.9-fold (BF also increases), falls 1.7-fold in m. pectoralis, and displays minor changes in the liver and m. gastrocnemius on the background of constant BF value in the liver and both muscles; and (3) after hatching, pO₂ in the liver and m. pectoralis increases severalfold (BF increases too) but does not change in a statistically significant manner in the brain and m. gastrocnemius despite an increase in BF (more pronouncedly in the muscle). Two possible mechanisms underlying the changes in the tissue pO₂ in developing chicken organs have been proposed: one is determined by the specific features of intracardiac blood flows and the other is associated with the oxyhemoglobin dissociation pattern in the blood capillary circulation in the organs, determined by the specific features in its oxidative metabolism.     

Ethylene-Induced Activation of Xylanase in Adventitious Roots of Maize as a Response to the Stress Effect of Root Submersion

Submersion of roots of ten-day-old maize (Zea maysL.) seedlings was accompanied by a decrease in pO₂and an increase in pCO₂of the medium adjacent to the roots. These changes stimulated ethylene evolution in intact plants. Enhanced biosynthesis of ethylene was accompanied by xylanase activation in adventitious roots. As a result, an enhanced formation of aerenchyma was observed in the cortex of adventitious roots. Therefore, these processes resulted in the development of a ventilation system by which O₂can reach the root system exposed to hypoxia. The volume of aerenchyma was assessed by the volume of gas cavities (porosity). In contrast to the main root, the growth of adventitious roots was not inhibited under these conditions. Enlargement of the stem base and increase in the number of aerenchymatous adventitious roots facilitated the oxygen supply to the submerged organs of the plants.     

Nodule structure and nitrogenase activity ofCoriaria arborea in response to varying pO2

When excised root nodules ofCoriaria arborea are assayed for nitrogenase activity at various pO₂ they show a broad optimum between 20 and 40 kPa O₂, with some evidence for adaptation. Continuous flow assays of nodulated root systems of intact plants indicate that Coriaria shows an acetylene induced decline in nitrogenase activity. When root systems were subject to step changes in pO₂ nitrogenase activity responded with a steep decline followed by a slower rise in activity both at lower and higher than ambient pO₂. Thus Coriaria nodules are able to adapt rapidly to oxygen levels well above and well below ambient. Measurement of nodule diffusion resistance showed that the adaptation is accompanied by rapid increase in resistance at above ambient pO₂ and decrease in resistance at below ambient pO₂. Plants grown with root systems at pO₂ from 5–40 kPa O₂ did not differ in growth or nodulation. The anatomy of Coriaria nodules shows they have a dense periderm which encircles the nodule and also closely invests the infected zone. The periderm is both thicker and more heavily suberised in nodules grown at high pO₂ than at low pO₂. Vacuum infiltration of India ink indicates that oxygen diffusion is entirely through the lenticel and via a small gap adjacent to the stele.     

[11C]WAY 100635: A radioligand for imaging 5-HT1A receptors with positron emission tomography

The potent and selective 5-HT_1A antagonist WAY 100635 (N-[2-[4-(2-methoxyphenyl)-1-piperazinyl]ethyl]-N-(2-pyridinyl)cyclohexanecarboxamide) was radiolabeled with ¹¹C in high specific activity, and the in vivo properties of this radioligand were assessed in the brains of rats and monkeys. Following i.v. tail vein injection in rats, [¹¹C]WAY 100635 rapidly penetrated into brain tissue and was retained over a 30–90 min time period in a manner consistent with the known distribution of 5-HT_1A receptors. Pretreatment of rats with the selective 5-HT_1A agonist (±)-8-OH-DPAT effectively blocked the retention of radioactivity in brain regions known to contain high densities of 5-HT_1A receptors. The hippocampus-to-cerebellum radioactivity concentration ratio reached a maximum of 16:1 at 60 min post injection. Following i.v. injection of [¹¹C]WAY 100635 in rhesus monkeys, the concentrations of radioactivity in brain regions were consistent with the reported distribution of 5-HT_1A receptors in primates, and the frontal cortex-to-cerebellum ratio reached 5.5:1 at 80 min post injection. Pretreatment of the monkeys with (±)-8-OH-DPAT reduced this ratio to 1.4:1, and injection of (±)-8-OH-DPAT 20 min after the injection of [¹¹C]WAY 100635 significantly displaced frontal cortex binding. The in vivo properties of [¹¹C]WAY 100635 in rats and monkeys strongly support the future utility of this radioligand for imaging 5-HT_1A receptors using positron emission tomography (PET).     

Transient Increase in Rab 3A and Synaptobrevin Immunoreactivity After Mild Hypoxia in Neonatal Rats

1. In the present work we describe the short term effects of mild neonatal hypoxia on the synapse as assessed by the immunoreactivity (IR) of twosynaptic proteins: rab 3A and synaptobrevin (VAMP).2. Using the sensitive methodology of immunoblotting, we measured rab 3A andVAMP-IR in homogenates from the cerebral cortex, hippocampus, and corpus striatum of control (breathing room air) and hypoxiated (breathing 95.5% N₂–6.5% O₂ for 70 min) 4-day-old rats at 1, 2, and 6 h after the end of the hypoxia. Immunostaining with examination by light microscopy was performed using the synaptic protein-specific antibodies on fixed brain sections from animals belonging to the same litter and submitted to hypoxia.3. A transient increase of VAMP-IR was observed in the hippocampus and corpus striatum, and for rab 3A in the striatum, 1 h after initiating reoxygenation.At the following time points the values returned to control levels. This effectwas less clearly observed in the immunostained sections.4. Mild hypoxia has an effect on sensitive brain regions, eliciting an increase in the IR of at least two proteins involved in the synaptic vesicle cycle. The transient nature of this effect possibly indicates the activation of endogenous neuroprotective mechanisms.