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)

1. Influence of ischemia on the biochemical properties of the sarcoplasmic reticulum (SR) was studied in the experimental myocardial infarction in the dog. 2. Ca2+ -uptake rate of SR decreased at around 90 minutes after coronary occlusion. This reduction was roughly in parallel with the reduction in the Ca+ -Mg2+ -stimulated ATPase activity. However, Ca2+ -binding rate of SR was kept within the range of that of the non-infarcted tissue through the time course of myocardial infarction. 3. Ca2+ -Mg2+ -stimulated ATPase activity decreased at around 3 hours after coronary occlusion to about 50% of that of the non-infarcted portion. 4. In SDS gel electrophoresis, the protein band with the largest molecular weight among three major components decreased at 3 hours after coronary occlusion, which is suggestive of ATPase. At 48 hours after coronary occlusion, the protein with the smallest molecular weight in the major proteins also decreased. 5. Ca2+ -uptake rate, Ca2+ -Mg2+ -stimulated ATPase activity and the substructural changes return to the normal level and pattern at around 28 days after coronary occlusion.
...
PMID:Studies of the cardiac sarcoplasmic reticulum in myocardial infarction. 15 53

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

The effect of transient renal ischemia on renal concentration and distribution of 99mTc-HEDP, 99mTc-DMSA, and 99mTc-DTPA was compared in rabbits with acute tubular necrosis. Scintigrams were obtained after injection in normal rabbits or ones with unilateral or bilateral ischemia. 99mTc-HEDP concentration in ischemic tissue was 8 to 18 times normal 1--4 hours after injection, and the resulting images delineated the morphological changes in the ischemic kidneys more accurately than those obtained with DMSA or DTPA. Calcium concentration in the ischemic kidneys increased sixfold. 99mTc-HEDP may be useful in evaluation of renal failure secondary to tubular injury.
...
PMID:Renal hyperconcentration of 99mTc-HEDP in experimental acute tubular necrosis. 22 Jun 70

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

This article is a short review of newer findings concerning the physiological and biochemical bases of the heart's tolerance to ischemia. The following themes are discussed. I. Energy-pool, energy-demand, and efficiency of anaerobic metabolism, the essential determinants of reanimation time and the heart's tolerance to ischemia. II. Experimental results of ischemic heart arrest and the heart arrest induced by a sodium-poor calcium-free, procaine-containing cardioplegic solution, developed by the author. III. Equivalents of function, metabolism and structure during the anaerobic period of the myocardium. IV. The myocardium's capability to recover in dependence on the metabolic state of ischemia and summary of the most important points of gaining a long time of tolerated ischemia. V. Survey and prospects.
...
PMID:Myocardial resistance and tolerance to ischemia: physiological and biochemical basis. 23 2

The etiology of sudden-death ischemic heart disease (SDIHD) remains an enigma. Data will be presented which suggest that SDIHD may be due to hypomagnesemia in and around the coronary arterial and arteriolar vessels. We have found that blood vessels (especially arteries and arterioles) deficient with respect to Mg can undergo constriction and spasm; the greater the reduction in Mg2+, the greater the magnitude of the spontaneous contractile responses. The higher the Ca2+:Mg2+ ratio, the greater are the magnitudes of these contractile responses. A severe deficit in surface membrane Mg2+, in particular, results in intense vasospasm. Using direct in situ high resolution microscopy (3000 x), we have found that a lowering of Mg2+ around perfused arterioles (15--20 microns i.d.) will also result in spontaneous vasoconstriction and, in addition, increased arteriolar resistance, tissue ischemia and reduced venous outflow. We have also found that the constrictor actions of certain circulating vasoconstrictor hormones (i.e., angiotensin, serotonin, acetylcholine) are enhanced when [Mg2+] is lowered below the levels normally found in plasma. Other direct studies, from our laboratory, indicate that [Mg2+]o regulates calcium exchange and content of vascular smooth muscle. In summary, the concept to be presented suggests that a deficiency in dietary Mg2+ is a key factor in the high incidence of mortality noted in SDIHD in nations of the Western world. The hypomagnesemia produces progressive vasoconstriction, vasospasm and ischemia, which, given time, will lead to SDIHD.
...
PMID:Sudden-death ischemic heart disease and dietary magnesium intake: is the target site coronary vascular smooth muscle? 39 Mar 30

Mitochondria isolated from rat kidney subject to in vitro ischemia at various time intervals demonstrated a continuous decline of the ability to accumulate calcium following a high initial stable phase of accumulation of calcium which is dependent both on ATP and respiration. This decline occurs during the reversible phase of cell injury and appears to be a sensitive indicator of membrane changes in a binding and/or transport protein or of other membrane permeability characteristics. The morphology of mitochondrial densities related to calcium accumulation in mitochondria varied. Any form of calcium accumulation, resulted in marked swelling of mitochondria. Control renal mitochondria in sucrose were highly condensed. Partially inhibited calcium accumulation in the presence of phosphate was also associated with numerous small spheric or punctate deposits in close relationship to the inner membrane. Uninhibited calcium accumulation resulted in the formation of needle-like structures radiating from such inner membrane associated sites.
...
PMID:Studies on the pathogenesis of ischemic cell injury. VI. Accumulation of calcium by isolated mitochondria of ischemic rat kidney cortex. 41 33

In line with studies on the metabolism of the ischemic myocardium, the effectiveness of diltiazem hydrochloride, a potent calcium antagonist, in reducing the effects of ischemia was evaluated. Nonischemic and ischemic tissue samples were examined in two groups of dogs--Group I, dogs receiving no drug and killed after 60 minutes of regional ischemia, and Group II, dogs given diltiazem after 10 minutes of ischemia and killed 50 minutes later. Administration of diltiazem proved beneficial in several ways: The decrease in adenosine-5'-triphosphate in the ischemic region was halved, inhibition of anaerobic glycolysis was reduced, tissue levels of lactic acid and free fatty acids were lowered and the contractility of glycerinated heart muscle fibers was improved. However, administration of the drug did not influence mitochondrial function. Mitochondrial oxygen consumption and respiratory control were reduced by equal amounts in both groups, as was mitochondrial calcium ion binding. These observations demonstrate that diltiazem is capable of minimizing the consequences of acute ischemic, although the beneficial effects do not extend to all aspects of myocardial metabolism.
...
PMID:Effect of diltiazem, a calcium antagonist, on myocardial ischemia. 44 73

Nifedipine, a slow-channel calcium blocker, is thought to provide useful myocardial protection during prolonged total ischemia and reperfusion. An isolated, isovolumic, feline heart model was used to asses the effectiveness of nifedipine in both cardioplegic (100 microgram/10 ml) and noncardioplegic (10 microgram/10 ml) doses for providing myocardial preservation during 90 minutes of hypothermic ischemic arrest and 45 minutes of normothermic reperfusion. Use of nifedipine was compared to hypothermia (27 degrees C) alone and to hypothermia with potassium cardioplegia. Ventricular function was assessed by recovery of isovolumic left ventricular developed pressure and dP/dt. Myocardial carbon dioxide tension (PCO2) and myocardial oxygen tension (PO2) were measured by mass spectrometry. Potassium cardioplegia and the higher dose of nifedipine resulted in immediate asystole. The rates of rise of PCO were greatest in the group receiving 10 microgram nifedipine and in the control group. The rates of rise in the two cardioplegic groups were significantly lower. Recovery of ventricular function was significantly lower with low-dose nifedipine than with potassium cardioplegia. Higher dose nifedipine resulted in a return of function, which was no different than with potassium cardioplegia. Morphologic protection was better with higher dose nifedipine and potassium cardioplegia than with either low-dose cardioplegia or hypothermia alone. These results demonstrate that nifedipine in a cardioplegic dose results in preservation of myocardial structure and function that is similar to that obtained with potassium cardioplegia. In lower noncardioplegic dose, nifedipine does not appear to offer additional protection compared to hypothermia alone. Whether persistent depression of ventricular contractility will limit nifedipine's clinical usefulness as a myocardial protection agent will require further study.
...
PMID:Comparison of myocardial protection with nifedipine and potassium. 44 71

The effectiveness of the calcium antagonist nifedipine in preserving postischemic myocardial function and structural integrity was experimentally demonstrated in isolated rabbit hearts, in conscious dogs subjected to myocardial infarction, in open chest anesthetized dogs with normothermic regional ischemia induced for 1 to 2 hours and in dogs undergoing hypothermic global ischemia for 2 hours followed by 2 hours of reperfusion. Nifedipine had a beneficial effect on postischemic myocardial stiffness and mitochondrial calcium accumulation, which were correlated. Administration of nifedipine at the onset of myocardial infarction increased blood flow to ischemic zones of myocardial infarction and resulted in less loss of creatine kinase. It reduced by two- to three-fold the volume of the ischemia-reperfusion injury induced by left anterior descending coronary arterial occlusion and release and preserved indexes of hemodynamic function. Nifedipine was found effective in protecting myocardial performance and structure after 2 hours of global ischemia during hypothermic cardiopulmonary bypass. It is suggested that this agent may be useful as an adjunct to cold cardioplegia in man for enhanced myocardial protection during cardiac surgery.
...
PMID:Nifedipine: a myocardial protective agent. 49 88


<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>

---