Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

---

Query: UMLS:C0022116 (ischemia)
91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The isolated perfused working rat heart preparation has been used to study the effects of respiratory acidosis on myocardial metabolism and contractilly. Hearts were perfused with 5 mM glucose and 10(-2) U/ml of insulin in order to enhance metabolsim of glucose relative to that of fatty acids. After perfusion with Krebs bicarbonate medium at pH 6.6, hearts rapidly ceased performing external work and peak left ventricular pressure fell by 75% after 5 minutes. Oxygen consumption, rate of ATP generation and overall glycolytic flux also declined rapidly. After about 2 minutes of perfusion, the fall of glycolytic flux showed a partial reversal, which was largely accounted for by increased lactate production, so that glucose oxidation decreased further. The reversal of glycoltic flux could be accounted for by partial release of H+ inhibition of phospho-fructokinase by increased tissue levels of adenosine 5'-diphosphate (ADP), adenosine monophosphate (AMP) and P1 and decreased levels of adenosine triphosphate (ATP) and creatine phosphate. The increased proportion of glucose uptake converted to lactate together with an increase of the tissue lactate/pyruvate ratio could be accounted for by inhibition of the malate-aspartate cycle combined with tissue hypoxia. Lactate accumulated in the tissue as a result of a decreased permeability of the plasma membrane to lactate. Decreased oxygen delivery to the myocardium was caused by secondary constriction of the coronary vessels. In further experiments, the coronary flow was regulated by an external pump which delivered fluid at a controlled rate into the aortic cannula above the coronary arteries, and the degree of tissue hypoxia was monitored by measuring changes of pyridine nucleotide reduction state by surface fluorescence techniques. The effects of acidosis uncomplicated by possible hypoxia were compared directly with those produced by ischemic hypoxia. The effects of acidosis under these conditions were similar to those described above, and to those produced by ischemia. From these and other data it is concluded that the effects of ischemia are caused by a lowering of the intracellular pH, which decreases the rate of energy production relative to the rate of energy demand. However, it is suggested that the primary cause of the decreased peak systolic pressure with either acidosis or ischemia is not a result of a defect of energy metabolism, but is due to alteration of the calcium cycle of the heart. Possible causes of irreversible heart failure after prolonged ischemia are discussed.
...
PMID:Contribution of tissue acidosis to ischemic injury in the perfused rat heart. 0 93

Cortical reflectance, mean arterial blood pressuees, electroencephalograms, and cortical blood flow were continuously recorded together with fluorescence of reduced pyridine nucleotides (PN) at various carbon dioxide tensions before, during, and following middle cerebral artery occlusion in 10 squirrel monkeys receiving halothane or babiturate anesthesia. Measurements were continued through a nitrogen breathing cycle and to death produced by anoxia. The anesthetic agent produced no detectable differences in PN fluorescence in cerebral tissue during ischemia and anoxia. The known cerebral protective action of barbiturates is apparently unrelated to the intracellular redox state.
...
PMID:Intracellular redox states under halothane and barbiturate anesthesia in normal, ischemic, and anoxic monkey brain. 3 37

Using a time-sharing fluorometer-reflectometer, pyridine nucleotide (NADH) and flavoprotein (Fp) fluorescence, as well as reflected light at the excitation wavelength, were measured and correlated with the electrical activity of an awake cerebral cortex. Exposure of the rat to a nitrogen atmosphere (anoxia) led to an increase in signals representing the reduction of pyridine nucleotides and flavins, with very similar kinetics. Inducement of partial ischemia by bilateral carotid artery ligation led to an increase in NADH, accompanied by a very small effect on the electrical activity (ECoG). In most animals, 2-3h after ligation, the ECoG became flat or depressed. Exposure of this ischemic cerebral cortex to KC1 solution caused depression of the electrical activity without metabolic response probably due to the limitation of oxygen supply. The metabolic state of an awake cerebral cortex was identified by exposing the brain to various levels of oxygen, epileptoform activity, spreading depression, hyperbaric pressure of oxygen and an uncoupler. From our results we conclude that the awake cerebral cortex is close to the resting state, state 4, rather than to the active state, state 3.
...
PMID:Brain energy metabolism of the conscious rat exposed to various physiological and pathological situations. 18 22

Changes in steady-state levels of reduced pyridine nucleotide (PN) recorded by continuous monitoring of surface fluorescence were correlated with changes in physiological function of perfused rat kidneys when subjected to anoxia, ischemia, hypothermia, variations in perfusion pressure, inhibition of Na-K ATPase, and uncoupling of oxidative phosphorylation. Biphasic responses of PN reduction and oxidation during ischemic cycles at varying temperatures and anoxic cycles at different perfusion pressures demonstrated the presence of two different cell populations in the kidney cortex, those with sufficient oxygen and those without. The magnitude of PN fluorescence change during ischemia increased with decreasing temperature demonstrating better tissue oxygenation during hypothermia. The measurement of mitochondrial NADH oxidation in the perfused kidney during transitions from CO anoxia to normoxia was made possible by flash photolytic activation of mitochondrial electron transport. The half time for NADH oxidation (125 ms) was independent of the rate of oxygen delivery while the initial rate and extent of reaction was faster and steeper, respectively, at higher perfusion pressure, due to a better tissue oxygenation and faster CO washout.
...
PMID:Oxygen delivery in perfused rat kidney: NADH fluorescence and renal functional state. 18 9

The fluorescence of the reduced form of the endogenous pyridine nucleotide nicotinamide adenine dinucleotide was used to map regions of ischemia in cat brain. A remarkably microheterogeneous pattern of increased fluorescence resulted from a critical level of incomplete cerebral ischemia. The fluorescence pattern suggests that ischemia occurs initially in microwatershed zones between penetrating cerebral arteries.
...
PMID:Regions of cerebral ischemia located by pyridine nucleotide fluorescence. 20 Oct 26

A direct, noninvasive method of assessing the oxidation-reduction potential of an intramyocardial respiratory chain component is described. The technique is based on the differences in spectral properties between the oxidized and reduced forms of nicotinamide adenine dinucleotide (NADH). The tissue surface fluorescence from intracellular NADH may be measured and documented photographically. Noose occlusion of a coronary artery produced detectable NADH fluorescence in 15 seconds in the subtended ischemic epicardium. This fluorescence of reduced pyridine nucleotide resolved following 60 seconds of reperfusion of the ischemic myocardium. The reduction of epicardial NADH with ischemia is a rapid and reversible process. A subsequent noose reocclusion resulted in a reproducible pattern of fluorescence. The technique of NADH fluorescence photography appears superior to current methods of assessing tissue oxygen supply:demand.
...
PMID:Evaluation of cardiac ischemia by NADH fluroescence photography. 20 34

The energy production (heat + work) of cardiac muscle must be interpreted in terms of the major ATPases underwriting cardiac contraction; these are the Ca2+ and Na+-K+ transport ATPases and actomyosin ATPase. It is possible to apply the classical phenomenological subdivisions to cardiac energy production; when this is done, certain properties immediately distinguish cardiac muscle from skeletal muscle. Little or no temporal distinction exists between initial (anaerobic) and recovery (oxidative) metabolism. Even at temperatures as low as 20 degrees C most of the recovery heat is released within the time course of a single contraction. Cardiac muscle is characterized by a high resting heat rate, the magnitude of which varies between species and depends on the metabolic substrate. In isometric contractions there is a slightly curvilinear relationship between developed force and heat production. There is a tension-independent or activation component, the magnitude of which reflects the prevailing level of contractility and is probably associated with calcium release and retrieval. In isotonic contractions energy production is maximal when the muscle is heavily loaded but falls steeply when the size of the load is reduced. The enthalpy:load relation is probably similar to that found in twitch contractions of skeletal muscle working at room temperature or above; but, unlike for skeletal muscle, there are families of such curves: At any instant of time the relation depends upon the prevailing physiological conditions (e.g. stimulus rate, substrate supply, humoral agents, extracellular ionic concentrations, initial length). Cardiac energy production can be estimated by a variety of other techniques (such as high-energy phosphate utilization, oxygen consumption, and changes in tissue fluorescence related to pyridine nucleotide oxidation levels). At the present time there is considerable agreement between heat measurements and results obtained with these different techniques. We should like to conclude on a cautionary note. First, there is considerable variability in the properties of cardiac muscle from different species. Significant variations occur at nearly all levels of cellular function--e.g. shape of action potential, electrical and mechanical dependence upon stimulus history, mechanisms of excitation-contraction coupling, actomyosin ATPase activity, metabolic regulation, and differential sensitivity to anoxia or ischemia. Second, the types of contractions readily studied in isolated papillary muscles (i.e. isometric or isotonic twitches) may not necessarily be the best mechanical paradigms for understanding myocardial energetics in vivo. The particular geometric demands of individual research techniques require the use of a wide variety of myocardial preparations from a wide variety of species. This necessarily produces a pastiche view of cardiac muscle rather than an integrated picture of some hypothetically typical mammalian myocardium.
...
PMID:Cardiac heat production. 21 64

In cerebral ischemia, brain oxygen supply is totally exhausted within seconds. This necessitates cessation of mitochondrial electron transfer and energy (ATP) production. After certain periods of ATP deficiency of from 5 to 90 min, irreversible damage of mitochondrial membranes occurs. This results in decreased mitochondrial function, characterized by inhibited State 3 respiratory rates, low respiratory control ratios, and inhibited Ca2+ transport activities. A 30-min recirculation period of the ischemic brain tissue induces total restitution of mitochondrial respiratory capacity after complete ischemia, but not after incomplete ischemia. Regional in situ measurements of brain pyridine nucleotide redox levels, tissue ATP, and lactate concentrations indicate variable metabolic responses of different brain regions to oligemia. Macroheterogeneity from region to region, as well as microheterogeneity within a region are demonstrated. Contrary to the effect of tissue ischemia involving reduced or zero cerebral blood flow and tissue oxygenation, sublethal hypoxia alone at normal or increased levels of blood flow induces adaptation of the mitochondrial enzyme system to a new level of respiratory capacity, without any indications of inhibited mitochondrial energy production. Acute hypoxia induces increased respiratory capacities within 30-60 min. Under chronic conditions, alterations of mitochondrial cytochrome concentrations accompany the increased respiratory capacities. Instead of the decreased efficiency of mitochondrial energy-producing mechanisms induced by ischemia, hypoxia induces increased efficiency of energy production.
...
PMID:Mitochondrial function in cerebral ischemia and hypoxia: comparison of inhibitory and adaptive responses. 23 75

A combination of K+/DC surface electrode and a fiberoptic fluorometric probe are applied to measurements in brain during cerebral ischemia. The kinetics of the responses of extracellular K+ activity and intracellular NADH fluorescence in the gerbil cerebrum following reversible carotid ligation are measured. K+e shows a two-phase response to carotid occlusion and an extended recovery phase following recirculation. The length of the recovery phase is dependent on the duration and severity of the ischemic period. In the gerbil model the degree of communication in the anterior circulation is variable, whereas a bilateral carotid occlusion is presumed to give complete cerebral ischemia. Pyridine nucleotide fluorescence serves as an indicator of the degree of ischemia. Bilateral carotid occlusions of up to 35 minutes in duration were performed. K+e reaches 30--50 mEq/liter in the extracellular space within the first two minutes. This represents cell depolarization and equilibration of K+ activity levels. Recovery appears to be complete in terms of the ability of the system to clear raised levels of K+e from the extracellular space.
...
PMID:The dynamics of K+ leakage and recovery in cerebral ischemia. 23 40

Neurotrophic factors regulate neuronal survival and neurite growth in development and following injury. Oxidative stress produced in neurons as a consequence of primary injury, or during reperfusion following ischemia, may contribute to cell death. Here, the effects of nerve growth factor (NGF) on the response to H2O2 injury were examined in the PC12 rat pheochromocytoma cell line. Specifically, the effect of NGF on cell viability after H2O2 injury was measured. Pretreatment with NGF enhanced survival after H2O2 treatment, as measured by Trypan blue dye exclusion, radiolabeled amino acid incorporation, tetrazolium salt reduction, or cytoplasmic enzyme release. One early event associated with H2O2 treatment was a rapid decrease in NAD+. Although initial decreases in NAD+ levels were similar in control and NGF-treated cells, the latter recovered more rapidly and extensively. The decline in total NAD observed after NGF treatment was almost equal in magnitude to the measured increase in NADP. Inhibition of poly(ADP-ribose) polymerase also enhanced viability following H2O2 injury. Treatment with both NGF and an inhibitor of this enzyme resulted in a greater reduction of H2O2 toxicity than was observed with either agent alone. These data suggest that NGF protection is multifactorial and that a significant component of the NGF effect is due to its regulatory role in the metabolism of pyridine nucleotides.
...
PMID:Nerve growth factor effects on pyridine nucleotides after oxidant injury of rat pheochromocytoma cells. 145 Sep 13


1 2 3 4 5 6 7 Next >>

---