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Query: UMLS:C0020440 (hypercapnia)
7,939 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Anaerobic metabolism in the limnic annelid Hirudo medicinalis L. was investigated by direct and indirect calorimetry. During long-term severe hypoxia, the rate of heat dissipation was reduced up to 13% of the aerobic rate. At the same time, the rate of ATP turnover was reduced to about 30% of the aerobic rate, indicating that metabolic depression is an important mechanism to ensure survival of the leech during environmental anaerobiosis. Heat dissipation during hypoxia was monitored under two experimental conditions, favouring either concomitant hypocapnia (continuous N2 bubbling) or hypercapnia (self-induced hypoxia). The reduction in heat dissipation during hypocapnic hypoxia was less pronounced than during hypercapnic hypoxia, indicating that the different experimental conditions may influence anaerobic metabolism and the extent of metabolic depression. Biochemical analysis of known anaerobic substrates and endproducts provided the basis for indirect calorimetry during self-induced hypoxia. From changes in metabolites, the expected heat dissipation was calculated for initial (0-8 ,h) and long-term severe hypoxia (8-72 h). During the initial period, the calculated heat dissipation fully accounted for direct calorimetric determination. During long-term hypoxia, only 71% of the measured heat production could be explained from biochemical analysis of metabolites. Therefore, an additional unknown endproduct cannot be excluded, especially when anaerobic ammonia production and analysis of the carbohydrate balance are considered.
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PMID:Anaerobic metabolism in the leech (Hirudo medicinalis L.): direct and indirect calorimetry during severe hypoxia. 876 66

1. Mechanisms that regulate the cerebral circulation have been intensively investigated in recent years. The role of several vasodilator mechanisms has been examined in the cerebral circulation, including nitric oxide (NO), trigeminal peptides and potassium channels, as well as the potent vasoconstrictor endothelin. These mediators appear to play a role in physiological and pathophysiological responses of the cerebral circulation. In the present review, we will focus on some recent developments in each of these areas. 2. Nitric oxide is an important regulator of cerebral vascular tone. Tonic production of NO maintains the cerebral vasculature in a dilated state. NO appears to be an important vasodilator during activation of neurons by excitatory amino acids, somatosensory stimulation and cortical spreading depression. Tonic production of NO appears to be critical in vasodilatation during hypercapnia, although NO may not directly mediate vasodilatation. NO produced by immunological NO-synthase appears to be important in dilatation following exposure to bacterial endotoxin. 3. Calcitonin gene-related peptide (CGRP), released from trigeminal perivascular sensory nerves in the brain, is an extremely potent dilator of brain vessels. CGRP may limit noradrenaline-induced constriction of cerebral vessels and contribute to dilatation during hypotension (autoregulation), reactive hyperaemia, seizures and cortical spreading depression. 4. Activation of potassium channels leads to hyperpolarization of cerebral vascular smooth muscle and appears to be a major mechanism for dilatation of cerebral arteries. Agents that increase the intracellular concentration of cyclic 3' 5'-adenosine monophosphate (cAMP) produce vasodilatation in part by activation of large conductance calcium-activated potassium channels (BKCa) and ATP-sensitive potassium channels (KATP). Activation of both KATP and BKCa channels also appears to contribute to vasodilatation during hypoxia. In contrast to KATP channels, BKCa channels appears to be active under basal conditions, contributing to tonic dilatation of cerebral blood vessels. 5. Endothelin is produced in the brain, but its role in the physiological regulation of cerebral blood flow is not known. Endothelin may contribute to the spasm of cerebral arteries following subarachnoid haemorrhage.
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PMID:Recent insights into the regulation of cerebral circulation. 880 May 65

Because arginine analogues have been reported to block the vasodilator response to hypercapnia, we investigated the effect of nitro-L-arginine (L-NNA) on the dilation of pial arterioles to arterial hypercapnia induced by inhalation of 3, 5, and 7% CO2 in anesthetized cats equipped with cranial windows. L-NNA at 250 microM, but not at lower concentrations, significantly reduced hypercapnia-induced dilation. This effect could be reversed by L-arginine. However, hypercapnic hyperemia is not the result of increased guanosine 3',5'-cyclic monophosphate via the usual NO-mediated activation of guanylate cyclase, because application of LY-83583, which blocks guanylate cyclase, did not alter the vessel response to CO2. L-NNA at 250 microM also abolished the pial arteriolar dilation in response to cromakalim, minoxidil, and pinacidil, three known openers of ATP-sensitive K+ channels, and this effect could be reversed by L-arginine. Application of glyburide, which blocks ATP-sensitive K+ channels, also reduced the response to CO2. Subsequent application of L-NNA in these experiments had no additional effect. Vasodilation induced by sodium nitroprusside and 3-morpholinosydnonimine, two known NO donors, was unaffected by glyburide. NG-monomethyl-L-arginine had effects similar to those of L-NNA in the cat and rat at concentrations as low as 20 microM. Our findings suggest that arginine analogues inhibit hypercapnic vasodilation by blocking ATP-sensitive K+ channels, independently of activation of guanylate cyclase via increased production of NO. Furthermore, the data suggest that ATP-sensitive K+ channels may have an arginine site that influences their function.
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PMID:Arginine analogues inhibit responses mediated by ATP-sensitive K+ channels. 889 45

Studies of skinned fibers suggest that the rate of ATP turnover in skeletal muscle is depressed by acidosis. To examine whether this occurs in intact muscles, the ATP cost of isometric contractions was measured in ex vivo, arterially perfused cat biceps (predominantly fast-twitch) and soleus (slow-twitch) muscles under normocapnic (5% CO2) and hypercapnic (70% CO2) conditions. Hypercapnia decreased extracellular pH from 7.4 to 6.7 and intracellular pH from 7.1 to 6.5 (soleus) or 6.6 (biceps) but had no significant effect on the phosphocreatine (PCr)-to-ATP ratio in muscles at rest. The ATP cost of contraction was estimated from PCr changes, measured by gating the acquisition of 31P-nuclear magnetic resonance spectra to times before and after brief tetani (1 s at 100 Hz and 2 s at 25 Hz for biceps and soleus, respectively) or 10-s trains of twitches (2 and 1 Hz, respectively). Peak isometric force and the ATP cost of tetanic contraction (PCr/force x time integral) were not significantly different under hypercapnic compared with normocapnic conditions in either muscle (mean: 7.97 and 2.44 micromol x kg(-1) x s(-1) for biceps and soleus, respectively). Twitch force and the ATP cost per twitch decreased by nearly 50% during hypercapnic perfusion in both muscle types. The results indicate that hypercapnic acidosis has no significant effect on the ATPase rate per active myosin head in intact mammalian skeletal muscle.
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PMID:Acidosis has no effect on the ATP cost of contraction in cat fast- and slow-twitch skeletal muscles. 912 91

The relationships between oxygen consumption (Q(O2)) and calculated cytoplasmic ADP concentration ([ADP]) and the free energy of ATP hydrolysis (deltaG(ATP)) were examined in ex vivo arterially perfused cat soleus muscles during repetitive twitch stimulation under normocapnic (5% CO2) and hypercapnic (70% CO2) conditions. Hypercapnia decreased extra- and intracellular pH by over 0.5 but had no significant effect on Q(O2) or phosphocreatine (PCr)/ATP in muscles at rest. The maximum Q(O2) measured during stimulation and the rate constant for PCr recovery after stimulation both decreased during hypercapnic compared with normocapnic perfusion, but the estimated ATP/O2 was unchanged. The change in PCr and deltaG(ATP) with increasing Q(O2) was greater during hypercapnic compared with normocapnic stimulation, as expected from the decrease in maximum Q(O2). However, the relationships between Q(O2) and [ADP] and deltaG(ATP) were both shifted to the left during hypercapnia compared with normocapnia. The results show that changes in cytoplasmic adenine nucleotides and phosphate are not sufficient to explain the control of respiration in skeletal muscle. However, in the context of thermodynamic models of respiratory control, the results can be explained by increased intramitochondrial potential for ATP synthesis at low pH.
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PMID:Effect of acidosis on control of respiration in skeletal muscle. 912 92

We previously have demonstrated that hypocapnia aggravates and hypercapnia protects the immature rat from hypoxic-ischemic brain damage. To ascertain cerebral blood flow (CBF) and metabolic correlates, 7-d postnatal rats were subjected to hypoxia-ischemia during which they were rendered either hypo-(3.5 kPa), normo- (5.1 kPa), or hypercapnic (7.3 kPa) by the inhalation of either 0, 3, or 6% CO2, 8% O2, balance N2. CBF during hypoxia-ischemia was better preserved in the normo- and hypercapnic rat pups; these animals also exhibited a stimulation of cerebral glucose utilization. Brain glucose concentrations were higher and lactate lower in the normo- and hypercapnic animals, indicating that glucose was consumed oxidatively in these groups rather than by anaerobic glycolysis, as apparently occurred in the hypocapnic animals. ATP and phosphocreatine were better preserved in the normo- and hypercapnic rats compared with the hypocapnic animals. Cerebrospinal fluid glutamate, as a reflection of the brain extracellular fluid concentration, was lowest in the hypercapnic rats at 2 h of hypoxia-ischemia. The data indicate that during hypoxia-ischemia in the immature rat, CBF is better preserved during normo- and hypercapnia; the greater oxygen delivery promotes cerebral glucose utilization and oxidative metabolism for optimal maintenance of tissue high energy phosphate reserves. An inhibition of glutamate secretion into the synaptic cleft and its attenuation of N-methyl-D-aspartate receptor activation would further protect the hypercapnic animal from hypoxic-ischemic brain damage.
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PMID:Effect of carbon dioxide on cerebral metabolism during hypoxia-ischemia in the immature rat. 921 33

Environmental stresses such as hypoxia or hypercapnia are known to cause acid-base disturbances and in several organisms they lead to metabolic depression. The present study was undertaken to quantify the influence of these changes in acid&shyp;base parameters on metabolic rate. We determined the rate of oxygen consumption in a non-perfused preparation of the body wall musculature of the marine worm Sipunculus nudus at various levels of extra- and intracellular pH (pHe and pHi, respectively), PCO2 and [HCO3-]. The acid&shyp;base status of the tissue was modified and clamped by long-term exposure to media set to specific values of extracellular pH, PCO2 and [HCO3-]. At a pHe of 7.90, which is equivalent to the normoxic normocapnic in vivo extracellular pH, and an ambient PCO2 of 0.03 kPa (control conditions), pHi was 7.26±0.02 (mean ± s.d., N=5). A reduction of extracellular pH from 7.90 to 7.20 resulted in a significant decrease of pHi to 7.17±0.05 at 0.03 kPa PCO2 (normocapnia) and to 7.20±0.02 at 1.01 kPa PCO2 (hypercapnia). At the same time, the rate of oxygen consumption of the tissue was significantly depressed by 18.7±4.7 % and 17.7±3.0 %, respectively. A significant depression of oxygen consumption by 13.7±4.7 % also occurred under hypercapnia at pHe 7.55 when pHi was elevated above control values (7.32±0.01). No significant changes in oxygen consumption were observed when pHe was either drastically elevated to 8.70 under normocapnia (pHi 7.36±0.05) or maintained at 7.90 during hypercapnia (pHi 7.37±0.03). ATP and phospho-l-arginine concentrations, as well as the Gibbs free energy change of ATP hydrolysis (dG/dATP), were maintained at high levels during all treatments, indicating an equilibrium between energy supply and demand. We conclude that the depression of aerobic energy turnover in isolated body wall musculature of S. nudus is induced by low extracellular pH. A model is proposed which could explain a reduced ATP cost of pHi regulation during extracellular acidosis, thus contributing to metabolic depression.
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PMID:Metabolic depression during environmental stress: the role of extracellular versus intracellular pH in Sipunculus nudus 931 9

Changes in the rates of oxygen consumption and ammonium excretion, in intra- and extracellular acid-base status and in the rate of H+-equivalent ion transfer between animals and ambient water were measured during environmental hypercapnia in the peanut worm Sipunculus nudus. During exposure to 1 % CO2 in air, intracellular and coelomic plasma PCO2 values rose to levels above those expected from the increase in ambient CO2 tension. Simultaneously, coelomic plasma PO2 was reduced below control values. The rise in PCO2 also induced a fall in intra- and extracellular pH, but intracellular pH was rapidly and completely restored. This was achieved during the early period of hypercapnia at the expense of a non-respiratory increase in the extracellular acidosis. The pH of the extracellular space was only partially compensated (by 37 %) during long-term hypercapnia. The net release of basic equivalents under control conditions turned to a net release of protons to the ambient water before a net, albeit reduced, rate of base release was re-established after a new steady state had been achieved with respect to acid-base parameters. Hypercapnia also affected the mode and rate of metabolism. It caused the rate of oxygen consumption to fall, whereas the rate of ammonium excretion remained constant or even increased, reflecting a reduction of the O/N ratio in both cases. The transient intracellular acidosis preceded a depletion of the phosphagen phospho-l-arginine, an accumulation of free ADP and a decrease in the level of Gibbs free energy change of ATP hydrolysis, before replenishment of phosphagen and restoration of pHi and energy status occurred in parallel. In conclusion, long-term hypercapnia in vivo causes metabolic depression, a parallel shift in acid-base status and increased gas partial pressure gradients, which are related to a reduction in ventilatory activity. The steady-state rise in H+-equivalent ion transfer to the environment reflects an increased rate of production of protons by metabolism. This observation and the reduction of the O/N ratio suggest that a shift to protein/amino acid catabolism has taken place. Metabolic depression prevails, with completely compensated intracellular acidosis during long-term hypercapnia eliminating intracellular pH as a significant factor in the regulation of metabolic rate in vivo. Fluctuating levels of the phosphagen, of free ADP and in the ATP free energy change values independent of pH are interpreted as being correlated with oscillating ATP turnover rates during early hypercapnia and as reflecting a tight coupling of ATP turnover and energy status via the level of free ADP.
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PMID:Acid-base regulation, metabolism and energetics in sipunculus nudus as a function of ambient carbon dioxide level 939 Sep 35

The conclusion that cyclic 3'-5 guanosine monophosphate (cGMP) functions in a 'permissive' manner in promoting cerebrovasodilation during hypercapnia was based on findings showing that the nitric oxide synthase (NOS) inhibitor-induced repression of the CO2 response could be reversed upon addition of exogenous cGMP. We hypothesized that the action of cGMP revealed in those studies does not define its normal role in hypercapnic cerebral vasodilation, but rather is a unique function of the artificial situation of NOS inhibition coupled with cGMP repletion. Thus, although CO2 reactivity may be the same in normal versus cGMP-repleted animals, the factors contributing to that response may differ. To test that possibility, the effects of calcium-dependent (KCa) or ATP-sensitive (KATP) potassium channel blockers on pial arteriolar CO2 reactivity, in vivo, were evaluated in the presence and absence of NOS inhibition plus administration of a cGMP analogue. Pial arteriolar diameter changes in hypercapnia were measured in three principal groups of anesthetized rats: (I) KCa channel-inhibited (via iberiotoxin); (II) KATP channel-inhibited (via glibenclamide); and (III) controls. Group I and II rats were further divided into: (a) those treated with the neuronal NOS (nNOS) inhibitor, 7-nitroindazole (7-NI), followed by successive suffusions of the cGMP analogue, 8-bromo-cGMP (8Br-cGMP) and 8Br-cGMP+K-channel blocker; and (b) rats where 7-NI and 8Br-cGMP applications were omitted. Group III rats were divided into time and 8Br-cGMP controls. Hypercapnia (PCO2 congruent with60 mmHg, 3 min)-induced dilations were reduced by 70-80% following 7-NI and restored by 8Br-cGMP. That restoration was reversed by both K-channel blockers. In the absence of 7-NI and exogenous cGMP, CO2 reactivity was unaffected by K-channel inhibition. These findings confirmed that nNOS-derived NO is critically important to the hypercapnic reactivity of cerebral arterioles, and that cGMP repletion, following NOS inhibition, could restore CO2 reactivity. The observation that KCa and KATP channel blockade did not alter CO2 reactivity under baseline conditions, but attenuated CO2 reactivity only in the presence nNOS inhibition (and cGMP repletion), suggests that multiple, redundant, and interactive mechanisms participate in CO2-induced vasodilation. These results also imply that current strategies for revealing permissive actions of cGMP (or NO) may need to be re-evaluated.
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PMID:Calcium-dependent and ATP-sensitive potassium channels and the 'permissive' function of cyclic GMP in hypercapnia-induced pial arteriolar relaxation. 963 Jun 23

In the immature brain, postischemic metabolism may be influenced beneficially by the effect of inducing hypercarbia or hypothermia. With use of 31P nuclear magnetic resonance spectroscopy, intracellular pH (pHi) and cellular energy metabolites in ex vivo neonatal rat cerebral cortex were measured before, during, and after substrate and oxygen deprivation in in vitro ischemia. Early postischemic hypothermia (fall in temperature -3.2 +/- 1.0 degrees C) delayed the normalization of pHi after ischemia by inducing an acid shift in pHi (P < 0.01). Postischemic hypercarbia (Krebs-Henseleit bicarbonate buffer equilibrated with 10% carbon dioxide in oxygen) and hypothermia induced separate, but potentially additive, reversible decreases in pHi, each of approximately -0.16 pH unit (P < 0.05). When these postischemic perturbations were applied in isolation, there was significant improvement of approximately 20% in the recovery of beta-ATP (P < 0.05). In combination, however, hypercarbia and hypothermia worsened recovery in ATP by approximately 20% (P < 0.05). In control tissue, which had not been exposed to ischemia, ATP content was also significantly reduced by co-administration of the two treatments (P < 0.05), an effect that persisted even after discontinuing the perturbing conditions. Therefore, in this vascular-independent neonatal preparation, early postischemic modulation of metabolism by hypercarbia or hypothermia appears to confer improved bioenergetic recovery, but only if they are not administered together.
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PMID:Hypercarbia and mild hypothermia, only when not combined, improve postischemic bioenergetic recovery in neonatal rat brain slices. 1072 25

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