Blood oxygen transport in rats during lipopolysaccharide administration combined with modification of L-arginine-No system

Lipopolysacharide from Escherichia coli was intravenously administered to rats (5.0 mg/kg). L-arginine-No system was modified by intravenous injection of L-arginine, N(G)-nitro-L-arginine methyl ester or L-lysine-N(G)-acetamidine (nitric oxide synthase (NOS) substrate, nonselective NOS inhibitor, and selective inducible NOS inhibitor, respectively.) Lipopolysacharide-induced disorders of blood oxygen transport were the least during the selective inducible NOS inhibition. The protective effects of L-arginine and N(G)-nitro-L-arginine methyl ester were less prominent. Such features of NOS modification effect on the blood oxygen transport suggest that activation of inducible NOS may change the hemoglobin-oxygen affinity during the lipopolysacharide treatment.     

Effect of pentoxiphylline on oxygen transport during hypothermia

At least two investigators have demonstrated a reduction in O2 extraction during induced hypothermia (Cain and Bradley, J. Appl. Physiol. 55: 1713-1717, 1983; Schumacker et al., J. Appl. Physiol. 63: 1246-1252, 1987). We hypothesized that administration of pentoxiphylline (PTX), a theobromine that lowers blood viscosity and has vasodilator effects, would increase O2 extraction during hypothermia. To test this hypothesis, we studied O2 transport in anesthetized, paralyzed, mechanically ventilated beagles exposed to hypoxic hypoxia during either 1) normothermia (38 degrees C), 2) hypothermia (30 degrees C), or 3) hypothermia + PTX (30 degrees C and PTX, 20 mg.kg-1.h-1). Measurements included arterial and mixed venous PO2, hemoglobin concentration and saturation, cardiac output, systemic vascular resistance (SVR), blood viscosity, and O2 consumption (VO2). Critical levels of O2 delivery (DO2, the product of arterial O2 content and cardiac output) were determined by a system of linear regression. Hypothermia significantly decreased base line cardiac output (-35%), DO2 (-37%), and VO2 (-45%), while increasing SVR and blood viscosity. Addition of PTX increased cardiac output (35%) and VO2 (14%), and returned SVR and blood viscosity to normothermic levels. Hypothermia alone failed to significantly reduce the critical level of DO2, but addition of PTX did [normothermia, 11.4 +/- 4.2 (SD) ml.kg-1.min-1; hypothermia, 9.3 +/- 3.6; hypothermia + PTX, 6.6 +/- 1.3; P less than 0.05, analysis of variance]. The O2 extraction ratio (VO2/DO2) at the critical level of DO2 was decreased during hypothermia alone (normothermia, 0.60 +/- 0.13; hypothermia, 0.42 +/- 0.16; hypothermia + PTX, 0.62 +/- 0.19; P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Gas exchange and oxygen transport during long term hypothermia following a hypothermal apnea in rats

The data obtained show that, at the initial stages of hypothermia, a decrease in the oxygen consumption and carbon dioxide production, cardiac output, and heart rate occurred in accordance with the temperature coefficient. Suppression of the tissue gas exchange was unrelated to disorders in the lung gas exchange but determined rather by a progressing weakening of heart activity, decrease in the cardiac output, and increase in the general vascular peripheral resistance.     

Blood oxygen transport in the house sparrow,Passer domesticus

Journal of Comparative Physiology B - Oxygen equilibrium curves (O2EC's) were generated for the adult house sparrowPasser domesticus at temperatures from 35 to 45 °C using a thin blood...     

Blood circulation and oxygen transport in the fetal guinea pig

Anaesthetized fetal guinea pigs near term were studied under conditions, where maternal placental flow of haemoglobin was maintained within the normal range. The rate of maternal fetal equilibration of intravenously injected 3H2O was found to be similar as in unanaesthetized animals (half time 4 min) indicating that fetal circulation was undisturbed under the present experimental conditions. Umbilical blood flow as determined by a modified 3H2O method was 0.13 ml . min-1 . g-1 of fetal body mass. Radioactive microspheres, injected into the fetal saphenous (jugular) vein, were distributed to the placenta, the lower body, the upper body and the lungs at a ratio of 31(47):27(39):30(6):12(8). From these data, cardiac output was calculated (0.38 ml . min-1 . g-1) and found to be almost equally distributed between the placenta, the lower body and the upper body. There was preferential streaming of the inferior vena caval blood to the upper body. There was no evidence for flow through a ductus venosus. The O2-saturation in the fetal carotid arterial blood was 59 +/- 4%. The O2-supply to the fetal tissues was estimated to be 3 times the oxygen consumption.     

高压氧暴露大鼠肺组织内PPAR通路分子变化规律

目的:研究高压氧暴露大鼠肺组织内过氧化物酶体增殖因子活化受体(PPAR)通路分子表达变化规律。方法:27只雄性SD大鼠随机分为高压常氧对照组(0.23 MPa空气)、高压氧时间序列处理组(0.23 MPa纯氧,分别暴露2 h、4 h、6 h和8 h),持续小流量通风,维持舱内O2浓度>99%。应用HE染色观察各组大鼠肺组织形态学变化;应用oligo芯片检测各个时间表达谱;应用RT-PCR验证发生改变的部分PPAR通路基因。结果:与高压常氧对照组相比,高压氧时间序列处理组造成的肺损伤逐渐加重;表达谱芯片的基因本体论(Go)富集分析结果中有一类PPAR通路类,包含有多个PPAR通路分子;RT-PCR结果提示PPARδ-和PPARγ-均在较长时间高压氧暴露的肺组织中上调。结论:高压氧长时间暴露造成的肺型氧中毒可引起PPAR通路的激活。     

Transfers between free and combined oxygen flows in determining facilitated transport with membranes on the transport path

The facilitated transport of a species brought about by a diffusible carrier is mediated by the sharing of the total flow between the flow of the free species (fd) and of the species-carrier compound (fc). The presence of membranes impermeable to the carrier on the transport path is accompanied by transfers between fd and fc in regions next to the membranes. These transfers are associated with differences between the current species-carrier concentration and the one that would exist at chemical equilibrium with the free species. These differences determine that the actual facilitated transport is smaller than the possible maximum. Analytic approximations to describe these differences are obtained; they are expressed in terms of physiochemical entities germane to the transport. This leads to a better conceptual understanding of the process. A relatively small system of algebraic equations for the numerical solution of the facilitated transport is formulated. A feature of this approach is that, instead of matching the values of functions at some points, the flows derived from integrals evaluated over some intervals are matched. The expressions for the physicochemical entities obtained contain the parameters explicitly; this permits analysis of the mechanisms involved in the dependence of the facilitated transport on the parameters of the system. It is shown, for instance, that the increase of the "on" chemical coefficient may result in either an increase or a decrease of the facilitated transport, depending on the current values of the parameters.     

A theoretical model for oxygen transport in skeletal muscle under conditions of high oxygen demand.

Oxygen transport from capillaries to exercising skeletal muscle is studied by use of a Krogh-type cylinder model. The goal is to predict oxygen consumption under conditions of high demand, on the basis of a consideration of transport processes occurring at the microvascular level. Effects of the decline in oxygen content of blood flowing along capillaries, intravascular resistance to oxygen diffusion, and myoglobin-facilitated diffusion are included. Parameter values are based on human skeletal muscle. The dependence of oxygen consumption on oxygen demand, perfusion, and capillary density are examined. When demand is moderate, the tissue is well oxygenated and consumption is slightly less than demand. When demand is high, capillary oxygen content declines rapidly with axial distance and radial oxygen transport is limited by diffusion resistance within the capillary and the tissue. Under these conditions, much of the tissue is hypoxic, consumption is substantially less than demand, and consumption is strongly dependent on capillary density. Predicted consumption rates are comparable with experimentally observed maximal rates of oxygen consumption.     

Blood oxygen transport in common map turtles during simulated hibernation

We assessed the effects of cold and submergence on blood oxygen transport in common map turtles (Graptemys geographica). Winter animals were acclimated for 6-7 wk to one of three conditions at 3 degrees C: air breathing (AB-3 degrees C), normoxic submergence (NS-3 degrees C), and hypoxic (PO2=49 Torr) submergence (HS-3 degrees C). NS-3 degrees C turtles exhibited a respiratory alkalosis (pH 8.07; PCO2=7.9 Torr; [lactate]=2.2 mM) relative to AB-3 degrees C animals (pH 7.89; PCO2=13.4 Torr; [lactate]=1.1 mM). HS-3 degrees C animals experienced a profound metabolic acidosis (pH 7.30; PCO2=7.9 Torr; [lactate]=81 mM). NS-3 degrees C turtles exhibited an increased blood O2 capacity; however, isoelectric focusing revealed no seasonal changes in the isohemoglobin (isoHb) profile. Blood O2 affinity was significantly increased by cold acclimation; half-saturation pressures (P50's) for air-breathing turtles at 3 degrees and 22 degrees C were 6.5 and 18.8 Torr, respectively. P50's for winter animals submerged in normoxic and hypoxic water were 5.2 and 6.5 Torr, respectively. CO2 Bohr slopes (Delta logP50/Delta pH) were -0.15, -0.16, and -0.07 for AB-3 degrees C, NS-3 degrees C, and HS-3 degrees C turtles, respectively; the corresponding value for AB-22 degrees C was -0.37. The O2 equilibrium curve (O2EC) shape was similar for AB-3 degrees C and NS-3 degrees C turtles; Hill plot n coefficients ranged from 1.8 to 2.0. The O2EC shape for HS-3 degrees C turtles was anomalous, exhibiting high O2 affinity below P50 and a right-shifted segment above half-saturation. We suggest that increases in Hb-O2 affinity and O2 capacity enhance extrapulmonary O2 uptake by turtles overwintering in normoxic water. The anomalous O2EC shape and reduced CO2 Bohr effect of HS-3 degrees C turtles may also promote some aerobic metabolism in hypoxic water.     

Neurotransmitter mediation of morphine hypothermia in rats.

Subcutaneous (sc) injections of morphine (10 mg/kg) caused transient falls in body temperature of rats. The hypothermic responses to morphine were inhibited by the prior intracerebroventricular (icv) administration of methysergide or phentolamine. Methysergide treatment also prevented hypothermic responses to icv 5-hydroxytryptamine (5-HT), but not responses to icv norepinephrine or dopamine. Phentolamine inhibited responses to icv norepinephrine and dopamine, but not to 5-HT. Haloperidol, which inhibited responses to icv dopamine, did not alter the hypothermia induced by sc or icv morphine. The results indicate that both 5-HT and norepinephrine participate as central mediators of morphine-induced hypothermia.     

Biogenesis of transport intermediates in the endocytic pathway.

Evidence is accumulating that membrane traffic between organelles can be achieved by different types of intermediates. Small (< 100 nm) and short-lived vesicles mediate transport from the plasma membrane or the trans-Golgi network to endosomes, and formation of these vesicles depends on specific adapter complexes. In contrast, transport from early to late endosomes is achieved by relatively large (approximately 0.5 microm), long-lived and multivesicular intermediates, and their biogenesis depends on endosomal COP-I proteins. Here, we review recent work on the formation of these different transport intermediates, and we discuss, in particular, coat proteins, sorting signals contained in cargo molecules and the emerging role of lipid in vesicle biogenesis.     

Ca2+ transport in the sarcolemma of the myometrium under its chemical modification

The effect of some chemical modifying agents of the sarcolemma surface--dicyclohexicarbodiimide, trinitrobenzolsulphuric acid, dithiotreitol and nitrit-anions on passive transsarcolemmic accumulation of Ca2+ by the pig myometrium sarcolemma property oriented vesicules was studied. The comparative analysis of these substances action under proton transmembrane gradient dispersion is presented. The significance of surface amino-, carboxy groups and disulphide membrane bounds in Ca2+ transport mechanisms as a corresponding aspect to some contemporary ideas about Ca(2+)-channel has been defined. The hypothesis is made that the proton transmembrane gradient dissipation leads to dislocation of carboxyl groups and disulphid bounds in relation to the membrane surface resulting in increasing Ca(2+)-permeability of the sarcolemma. The increase of sarcolemma permeability for Ca2+ under the action of 10 nM NO-2 was demonstrated. On the base of experimental data the supposition was made that NO-2 modified amino- and carboxylate groups of the sarcolemma surface. Under the chemical modification of these groups the nitrit-anions inhibit transsarcolemmic Ca2+ movement. NO-2 is not a result of sarcolemma surface SH-groups oxidation, while possibly NO2- protects some functionally important disulphide bridges of Ca(2+)-channel from their chemical restoration.