Effect of intermittent exposure and drug-free intervals on the in vitro vascular tolerance to nitroglycerin

Recent reports suggest that intermittent nitroglycerin (NTG) treatment, incorporating a daily nitrate-free interval, can avoid the tolerance associated with continuous NTG therapy. This study has investigated whether an in vitro model of NTG tolerance could be used to examine the mechanisms of tolerance avoidance (by intermittent NTG exposure) and tolerance reversal. Isolated rat abdominal aortic rings were exposed to 55 microM NTG at varying intervals over a 60 min period, and the concentration-relaxation curves to NTG were subsequently determined. Intermittent NTG exposure (either 12 x 0.5 min or 3 x 2 min) significantly reduced NTG tolerance compared to continuous exposure over the same period of time (60 min). The diminished tolerance was apparently due to the reduced total exposure time, since the NTG responsiveness of aortic rings exposed to NTG intermittently or continuously for 6 min of the incubation period was not significantly different. Under the present conditions, in vitro NTG tolerance could be reversed if sufficient washout time was allowed. Thus, aortic rings exposed to NTG for the initial, but not the final, 6 min of incubation were not tolerant to NTG. In addition, rings exposed to NTG for 3 min exhibited near-maximal tolerance after 5 min washout, but no tolerance after 60 or 120 min washout. It appears, therefore, that the isolated vessel retains the "repair" mechanism responsible for tolerance reversal under the present conditions. This study suggests that the in vitro model of NTG tolerance may be useful for investigating the characteristics and mechanisms of tolerance avoidance and reversal, as well as tolerance induction.     

Impaired glucose homeostasis after a transient intermittent hypoxic exposure in neonatal rats

This initial report presents a neonatal rat model with exposure to a transient intermittent hypoxia (IH), which results in a persisting diabetes-like condition in the young rats. Twenty-five male pups were treated at postnatal day 1 with IH exposure by alternating the level of oxygen between 10.3% and 20.8% for 5 h. The treated animals were then maintained in normal ambient oxygen condition for 3 week and compared to age-matched controls. The IH treated animals exhibited a significantly higher fasting glucose level than the control animals (237.00 ± 19.66 mg/dL vs. 167.25 ± 2.95 mg/dL; P = 0.003); and a significantly lower insulin level than the control (807.0 ± 72.5 pg/mL vs. 1839.8 ± 377.6 pg/mL; P = 0.023). There was no difference in the mass or the number of insulin producing beta cells as well as no indicative of inflammatory changes; however, glucose tolerance tests showed a significantly disturbed glucose homeostasis. In addition, the amount of C-peptide secreted from the islets harvested from the IH animals were decreased significantly (from 914 pM in control to 809 pM in IH; P = 0.0006) as well. These observations demonstrate that the neonatal exposure to the IH regimen initiates the development of deregulation in glucose homeostasis without infiltration of inflammatory cells.     

Effects of acute and chronic hypercapnia on oxygen tolerance in rats

Groups of 16-52 normal or CO2-adapted rats were exposed top 100% O2 or to O2 with 60 Torr PICO2 (O2-CO2) at pressures of 1.0, 1.5, 2.0, 3.0, and 4.0 ATA. Exposure durations for 50% mortality (LD50) in normal rats at 4.0, 3.0, 2.0, 1.5, and 1.0 ATA O2 were 6.3, 9.3, 17.2, 27.4, and 76.1 h, respectively. Corresponding LD50 values for normal rats exposed to O2-CO2 were 2.0, 2.9, 16.3, 24.8, and 74.8 h. Survival times of CO2-adapted rats exposed to O2 were nearly identical to those of normal rats. LD50 values for CO2-adapted rat exposed to O2-CO2 were 4.1, 7.5, 17.9, 23.6, and 65.4 h, respectively. These data confirm acceleration of O2 intoxication by acute hypercapnia at 4.0 and 3.0 ATA, but they show less prominent effects at 2.0, 1.5, and 1.0 ATA. Hypercapnia adaptation clearly has a protective effect in rats exposed to O2-CO2 at 4.0 and 3.0 ATA. At 2.0, 1.5, and 1.0 ATA, where acute hypercapnia has less effect, the effects of CO2 adaptation are also less prominent. The observed changes in oxygen tolerance can be explained by cerebral vasodilation with increased brain oxygenation in acute hypercapnia and by significant amelioration of this response during chronic hypercapnia.     

Insulin tolerance in rats.

Insulin tolerance was studied in young (8- to 10-week-old) Wistar rats: a) after the administration of mounting doses of long-acting insulin (10, 40, 160 and 320 units/kg bw.) to animals fed ad libitum on two different diets); b) after the administration of long-acting insulin (1 and 5 units/kg b.w.) to animals which had fasted for different lengths of time. In rats fed ad libitum on the two diets, graded doses of insulin induced (except for the smallest dose) hypoglycaemia of roughly the same intensity, but varying in duration in correlation to the dose. The administration of insulin to fasting rats showed differences in insulin tolerance which were correlated to the duration of the fast. A significant decrease in insulin tolerance was already found after 6 hours. During the given testing period (72 hours), the lowest insulin tolerance was found after a 12 hours' fast and the highest after 48 hours. Insulin tolerance after 24 and 72 hours' fasting was approximately the same; it was higher than after 12 hours, but lower than after 48 hours. The initial blood sugar level (before administering insulin) was not in any way correlated to insulin tolerance determined at various intervals during fasting.     

Effect of intermittent chronic exposure to hypoxia on feeding behaviour of rats

Healthy albino male rats were exposed to a simulated high altitude (HA) equivalent to 25000 ft (7620 m) for 6 h daily, continuously for 21 days to study the feeding behaviour. The 24-h food and water intake and body weight once in 3 days were recorded. Blood samples were drawn once a week from the retro-orbital venous plexus for blood sugar analysis. All the parameters were recorded before, during and after exposure to simulated HA. The results show a decrease in 24-h food and water intake and decreased gain in body weight during hypoxic exposure, which showed a tendency to come back to control during the post-exposure period. The blood sugar reflected a state of mild hyperglycaemia during exposure to HA.     

Thermal acclimation of broiler birds by intermittent heat exposure

Heat stress impairs the performance of broilers which increases the economic losses. Effect of duration of heat exposure on performance and acclimatory responses in broiler birds was investigated. At 21 d of age 160 Hubbard birds (80 males+80 females) were equally distributed into 5 treatments (T). The T1, T2, T3 and T4 were acclimated by daily exposure to heat (38±1 °C, 62±2% RH) for 1, 2, 3 and 4 h/d, respectively, for 14 d. T0 was the non-acclimated control (kept at 22±2 °C, 65±2% RH). At 36 d of age the thermotolerance of all birds was evaluated under simulated heat wave conditions by exposing them to an acute heat stress (43±1 °C, 55±3% RH) for 4 h. Body weight (BW), average daily gain (ADG) and average daily feed intake (ADFI) were not affected in T2 and T3, while T3 and T4 showed significant reductions in BW, ADG and ADFI compared to the control. Daily changes in ADFI/kg of metabolic BW (ADFI/BW^0.75), rectal temperature (Tr), rate of increase in rectal temperature (RITr) and evaporative water loss (EWL) showed biphasic patterns of acclimatory responses. The 2 phases were distinctly differentiated by plateau days. Phase 1 characterized by a sharp decline in ADFI/BW^0.75 followed by a gradual increase until the plateau, while Tr, RITr and EWL increased sharply followed by gradual decreases until the plateau. Beyond the plateau (phase 2), homeostatic responses in ADFI/BW^0.75, Tr, RITr and EWL were observed toward the end of the study. Acclimated birds were able to withstand the simulated heat wave with 0% mortality, lower Tr, and longer survival time compared to the control. In conclusion, acclimation could protect birds from acute heat waves and associated heat stress mortality until marketing age. However, applicability of these results towards the industry needs further investigations.     

Reactive oxygen species in the plasticity of respiratory behavior elicited by chronic intermittent hypoxia.

Long-term facilitation (LTF) of breathing elicited by episodic hypoxia (EH) is an extensively studied example of plasticity of respiratory motor behavior. Previous studies employed the paradigm of EH wherein each episode of hypoxia was 5 min. This paradigm is rarely encountered in nature. Brief episodes of hypoxia are encountered frequently with recurrent apneas, wherein hypoxic episodes last a few seconds only. Recent studies suggest that chronic intermittent hypoxia (CIH) represents a form of oxidative stress involving reactive O(2) species. The objectives of the present study were to determine 1) whether acute, repeated, brief EH (15 s) elicit LTF in breathing and 2) whether prior conditioning with CIH modulates acute EH-induced LTF of breathing, and if so whether reactive O(2) species are involved. Experiments were performed on anesthetized, vagotomized, paralyzed, and mechanically ventilated rats, and efferent phrenic nerve activity was monitored as an index of respiratory motor output. In control animals, acute EH (15-s hypoxia; 10 episodes; n = 9) increased minute neural respiration, which persisted during 60 min of the posthypoxic period, suggesting LTF of breathing. EH-induced LTF of respiration was markedly augmented in CIH-conditioned animals (15-s hypoxia, 9 episodes/h, 8 h/day for 10 days; n = 9). By contrast, conditioning with a comparable, cumulative duration of sustained hypoxia (4-h hypoxia; n = 8) did not augment LTF elicited by acute EH. Systemic administration of manganese (III) tetrakis (1-methyl-4-pyridyl) porphyrin pentachloride (5 mg. kg(-1). day(-1) for 10 days), a potent scavenger of O(2)(-)*, prevented CIH-induced potentiation of LTF (n = 9). These results demonstrate that 1) acute, brief EH elicits LTF in respiratory motor output; 2) prior conditioning with CIH, but not with comparable, cumulative duration of sustained hypoxia, augments LTF elicited by acute EH; and 3) O(2)(-)* radical scavenger prevents CIH-induced potentiation of LTF of respiration.     

间歇性低压低氧预处理对脑缺血大鼠海马p-p38 MAPK表达的影响

目的:本文旨在观察间歇性低压低氧(IH)预处理诱导脑缺血耐受过程中,大鼠海马CA1区磷酸化p38MAPK(p-p38 MAPK)的表达以及表达p-p38 MAPK的星形胶质细胞数量。方法:将30只健康雄性Wistar大鼠随机分为6组(n=5):假手术(sham)0 min组、IH+sham 0 min组、sham 7 d组、IH+sham 7 d组、损伤性缺血(Is)7 d组、IH+Is 7 d组。通过硫堇染色对各组大鼠海马CA1区锥体神经元进行神经病理学评价;免疫组织化学染色观察pp38 MAPK的表达;免疫荧光双标法观察表达p-p38 MAPK的星形胶质细胞数量。结果:IH预处理可以诱导脑缺血耐受,同时引起大鼠海马CA1区p-p38 MAPK的表达明显增加,且上调星形胶质细胞中p-p38 MAPK的表达。结论:低压低氧预处理促大鼠海马CA1区锥体神经元和星形胶质细胞中p-p38MAPK上调可能是IH预处理保护脑的一个途经。     

Induction of metallothionein by exposure to normobaric 100% oxygen atmosphere in rats with different zinc supply

The objective of this study was to determine the effects of an oxygen enriched environment on the induction of the metalloprotein metallothionein (MT) and its relation to zinc metabolism in rats supplied with different levels of dietary zinc. Male albino rats were fed purified diets based on maize starch, egg white, saccharose and soybean oil differing in the concentration of zinc (1; 20; 100; 500 mg Zn/kg diet). At a dietary zinc supply of 1 mg/kg, the rats developed a zinc deficiency indicated by visual and biochemical parameters. At the end of the 37-day feeding period, half of the rats were exposed to 100% oxygen for 12 h.

The oxygen treatment significantly reduced plasma zinc in the zinc supplemented rats and reduced it in tendency in the zinc deficient rats. The MT concentration was increased in the zinc supplemented groups in the liver, kidney and lung. The oxygen treatment elevated the metallothionein concentration in the two high zinc supplemented groups (100 and 500 mg Zn/kg diet) in the liver. The response of the zinc concentration in plasma and of hepatic metallothionein levels to oxygen exposure indicates a role of metallothionein in zinc distribution or interactions with other trace elements to support antioxidant capacity, rather than an impact on direct scavenging activity of free radicals.     

Studies on organ weights in naproxen treated rats after intermittent exposure to simulated high altitude

Rats were exposed intermittently for 8h per day over 6 days at simulated high altitude of 20 000 feet. One group of altitude-exposed animals was treated with naproxen, a prostaglandin inhibiting drug. Significant reduction in body weight gain was observed in both altitude-exposed and drug-treated altitude-exposed animals compared to the control group. Right and left ventricular weights and weights of the adrenal glands were increased significantly in altitude-exposed and altitude-exposed drug-treated animals. The weight of the spleen was increased significantly in altitude-exposed animals whereas no such increase of splenic weight was observed in drug-treated altitude-exposed group of animals. On the other hand, the weight of the liver was decreased significantly in both cases. In drug-treated altitude-exposed animals, the unaltered splenic weight was thought to be due to inhibition of the erythropoietic activity.     

Selected Contribution: Improved anoxic tolerance in rat diaphragm following intermittent hypoxia.

Intermittent hypoxia (IH), associated with obstructive sleep apnea, initiates adaptive physiological responses in a variety of organs. Little is known about its influence on diaphragm. IH was simulated by exposing rats to alternating 15-s cycles of 5% O2 and 21% O2 for 5 min, 9 sets/h, 8 h/day, for 10 days. Controls did not experience IH. Diaphragms were excised 20-36 h after IH. Diaphragm bundles were studied in vitro or analyzed for myosin heavy chain isoform composition. No differences in maximum tetanic stress were observed between groups. However, peak twitch stress (P < 0.005), twitch half-relaxation time (P < 0.02), and tetanic stress at 20 or 30 Hz (P < 0.05) were elevated in IH. No differences in expression of myosin heavy chain isoforms or susceptibility to fatigue were seen. Contractile function after 30 min of anoxia (95% N2-5% CO2) was markedly preserved at all stimulation frequencies during IH and at low frequencies after 15 min of reoxygenation. Anoxia-induced increases in passive muscle force were eliminated in the IH animals (P < 0.01). These results demonstrate that IH induces adaptive responses in the diaphragm that preserve its function in anoxia.     

Growth inhibitory factor prevents neurite extension and the death of cortical neurons caused by high oxygen exposure through hydroxyl radical scavenging

Growth inhibitory factor (GIF), a brain-specific member of the metallothionein family (MT-III), has been characterized as a inhibitory substance for neurotrophic factors in Alzheimer's disease brains. However, the function of GIF, other than the inhibition of neurotrophic factors, remains unknown. We demonstrate here that exogenous GIF prevents neurite extension of cortical neurons in the early period of differentiation and the death of differentiated neurons caused by high oxygen exposure. Down-regulation of GIF in cortical neurons with antisense S-oligonucleotides promoted neuronal death under high oxygen conditions. ESR spin-trapping studies demonstrated that GIF at 2-6 microm scavenged hydroxyl radicals generated by a Fenton-type reaction or the photolysis of hydrogen peroxide much more effectively than the same concentration of metallothionein I+II. GIF did not scavenge either superoxide produced by the xanthine/xanthine oxidase reaction or NO generated from 1-hydroxy-2-oxo-3-(N-methyl-3-aminopropyl)-3-methyl-1-triazene. Moreover, GIF at 40-80 microm inhibited tyrosine nitration by peroxynitrite as efficiently as metallothionein I+II at the same concentration. These results indicate that GIF prevents neurite extension of neurons in the early period of differentiation and supports the survival of differentiated neurons by scavenging hydroxyl radicals.