UMLS:C0022116 - FACTA Search

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

Edrophonium (ethyl(m-hydroxyphenyl)dimethylamine) acutely modifies carnitine levels in different rat tissues, increasing hepatic and reducing blood and renal levels. After 2 h edrophonium treatment, the total serum carnitine levels were decreased by 16 (P < 0.001) and 33 (P < 0.001) percent in fed and fasted rats respectively compared to control, and in kidney the levels decreased by 11 (P < 0.05) and 34 (P < 0.001) percent whereas in liver the edrophonium treatment increased the levels by 43 (P < 0.001) and 59 (P < 0.001) percent. The edrophonium action does not depend on the route of administration or on the nutritional state of the animal. Its activity on carnitine levels is neither accompanied by significant variation of serum parameters of carbohydrate, fat and protein metabolism nor of insulin levels. The edrophonium activity is not related to cholinergic action, as physostigmine and ambenonium at concentrations known to increase cholinergic activity do not modify carnitine distribution in tissues. Trimethylphenylammonium (TPA) and trimethyl(p-aminophenyl)ammonium (TPA.NH2), compounds structurally similar to edrophonium, are on the contrary active on levels of carnitine and this effect is not related to their cholinergic potency. In 24 h fasted rats after the TPA and TPA. NH2 treatment, the total serum carnitine levels were decreased by 32 (P < 0.001) and 13 (n.s.) percent respectively compared to control, and in kidney the levels decreased by 15 (P < 0.02) and 5 (n.s.) percent, whereas in liver the treatment increased the levels by 72 (P < 0.001) and 45 (P < 0.01) percent. Moreover atropine, an acetylcholine antagonist, affects carnitine distribution in a way similar to edrophonium. Edrophonium activity on carnitine distribution, probably affects (inter)cellular carnitine transport by direct action on plasma membrane. Effect on capillary endothelium may be responsible for its observed action on muscle contraction force in imminent ischemia.
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PMID:Quaternary nitrogen compounds affect carnitine distribution in rats. Particular emphasis on edrophonium. 855 70

Prosaposin, a 517-amino-acid glycoprotein, not only acts as the precursor of saposin A, B, C, and D but also possesses neurotrophic activity to rescue hippocampal CA1 neurons from ischemic damage in vivo and to promote neurite extension of neuroblastoma cells in vitro. Recently, the trophic activity of prosaposin on human neuroblastoma cells has been shown to reside in the NH2-terminal hydrophilic sequence (LIDNNRTEEILY) of the human saposin C. Here we show that prosaposin, saposin C, and a peptide comprising the 18-amino-acid sequence (18-mer peptide; LSELIINNATEELLIKGL) located in the NH2-terminal hydrophilic sequence of the rat saposin C-domain promoted survival and neurite outgrowth of cultured rat hippocampal neurons in a dose-dependent manner. Moreover, infusion for 7 days of the 18-mer peptide into the lateral ventricle of gerbils, starting either 2 h before or immediately after 3 min of forebrain ischemia, protected ischemia-induced learning disability and hippocampal CA1 neuronal loss. Thus, we ascribe the in vitro and in vivo trophic actions of prosaposin on hippocampal neurons to the linear 18-mer sequence and raise the possibility that this peptide can be used as an agent for the treatment of forebrain ischemic damage.
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PMID:A hydrophilic peptide comprising 18 amino acid residues of the prosaposin sequence has neurotrophic activity in vitro and in vivo. 878 53

This study was designed to investigate 1) whether a protocol employing a gradual reduction in O2 availability to submaximally contracting muscle results in relatively minor disturbances in intracellular homeostasis and 2) the interaction between tissue oxygenation and the proposed regulators of muscle respiration, metabolism, and force production. O2 delivery to isolated submaximally contracting [isometric contractions at 3 Hz; approximately 50% of peak O2 uptake (VO2)] in situ canine gastrocnemius (n = 6) was manipulated by decreasing arterial PO2 (hypoxemia; H) or muscle blood flow (ischemia; I) during three separate periods in each muscle [control (C), H, or I; each separated by 45 min of rest]. O2 delivery was reduced gradually in small steps every 3 min by H or I during two of the contraction periods (6 steps for a total of 21 min; O2 delivery reduced by 67% by the end of 21 min), whereas C was at normal O2 delivery for a 15-min period. Muscle VO2 was maintained at control levels for the first two O2 delivery reduction steps for the H and I conditions and then fell proportionally with O2 delivery to approximately 35% of the initial value by the end of the 21-min contraction period. Muscle force development generally fell in parallel with VO2. There was no significant changes from the values obtained during C contractions in intracellular concentrations of ATP, phosphocreatine, NH3, calculated free ADP, lactate, and redox state ratios as the O2 delivery was reduced, even with the severe decline in VO2 and developed force. These results demonstrated that when O2 availability was reduced gradually to contracting skeletal muscle, 1) developed force (ATP utilization) was reduced through a tight coupling with aerobic ATP supply, such that there was little additional disruption of intracellular homeostasis, and 2) there was an apparent dissociation of some of the proposed regulators of cell respiration and force development from the control of these processes.
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PMID:Effect of gradual reduction in O2 delivery on intracellular homeostasis in contracting skeletal muscle. 892 61

Recovery from ischemic renal injury is accompanied by enhanced DNA synthesis and a typical immediate early (IE) gene response. These two processes occur in distinct cell populations, suggesting that the IE gene response does not serve a proliferative function directly. As cellular stress induces an IE response through activation of the stress-activated protein kinases (SAPK) that is not proliferative and can be inhibited by N-acetyl-L-cysteine (NAC), we determined whether the Jun NH2-terminal kinases (JNK), members of the SAPKs, are activated during ischemia and whether NAC administration reduces the IE response and/or the induction of JNK activity. NAC (6 mM/kg body wt) infused 1 h prior to and 1 h following renal ischemia reduced c-fos and c-jun expression by 50 and 70%, respectively. Ischemia increased JNK activity, and this increase was inhibited by NAC. NAC infused animals had a higher glomerular filtration rate at 1 day (NAC, 0.9 +/- 0.2, vs. control, 0.05 +/- 0.01 ml/min, P < 0.001) and 7 days (NAC, 2.0 +/- 0.1, vs. control, 1.2 +/- 0.1, P < 0.001) after the induction of ischemia. NAC did not reduce the extent of proximal tubule necrosis at 24 h after reperfusion but improved histological appearance of the kidney at 7 days. The mechanism by which NAC ameliorates the loss of renal function is unknown but may involve its general properties as an antioxidant or a possible interaction with NAC and NO. We conclude that the IE gene response of the kidney to ischemia reperfusion is a consequence of the stress-activated kinase pathway and that part of the response is deleterious to kidney function and cellular integrity.
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PMID:N-acetyl cysteine ameliorates ischemic renal failure. 908 70

Cytokines and various cellular stresses are known to activate c-Jun NH2-terminal kinase (JNK), which plays a role in conveying signals from the cytosol to the nucleus. Here we investigate the translocation and activation of JNK1 during ischemia and reperfusion in perfused rat heart. Ischemia induces the translocation of JNK1 from the cytosol fraction to the nuclear fraction in a time-dependent manner. Immunohistochemical observation also shows that JNK1 staining in the nucleus is enhanced after ischemia. During reperfusion after ischemia, further nuclear translocation of JNK1 is apparently inhibited. In contrast, JNK1 activity in the nuclear fraction does not increased during ischemia but increases significantly during reperfusion with a peak at 10 min of reperfusion. The activation of JNK1 is confirmed by the phosphorylation of endogenous c-Jun (Ser-73) with similar kinetics. The level of c-jun mRNA also increases during reperfusion but not during ischemia. Based on fractionation and immunohistochemical analyses, an upstream kinase for JNK1, SAPK/ERK kinase 1 (SEK1), is constantly present in both the nucleus and cytoplasm throughout ischemia and reperfusion, whereas an upstream kinase for mitogen-activated protein kinase, MAPK/ERK kinase 1, remains in the cytosol. Furthermore, phosphorylation at Thr-223 of SEK1, necessary for its activation, rapidly increases in the nuclear fraction during postischemic reperfusion. These findings demonstrate that JNK1 translocates to the nucleus during ischemia without activation and is then activated during reperfusion, probably by SEK1 in the nucleus.
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PMID:A novel mechanism of JNK1 activation. Nuclear translocation and activation of JNK1 during ischemia and reperfusion. 919 81

Exercise-induced downsloping ST-segment depression is a common manifestation of severe myocardial ischemia. Although greater downsloping ST-segment depression is suspected to indicate more severe ischemia, its exact relationship to regional myocardial blood flow (RMBF) has not yet been clarified. We investigated the relationship between the magnitude of downsloping ST-segment depression and exercise-induced changes in RMBF and collateral perfusion. Nitrogen-13 ammonia positron emission tomography was performed in 6 healthy volunteers and 72 patients with angiographically proven coronary artery disease. The left ventricle was divided into 11 regions of interest, and RMBF in each region was measured at rest and during low-level supine bicycle exercise. Downsloping ST-segment depression of 0.1 mV or more at 80 milliseconds after the J point was accepted as significant. Low-level exercise induced downsloping depression of 0.1 to 0.2 mV in 10 patients (group D1) and downsloping depression of 0.2 mV or more in 8 patients (group D2). Multivessel disease was common in both group D1 (80% of patients) and group D2 (88% of patients). Collateral circulation was significantly more frequent in group D1 (90%) than in group D2 (13%, p < 0.01). Ischemic areas were larger and cardiac function was worse in group D2 than in group D1. The RMBF increased sufficiently in all regions (56 +/- 30%) with exercise in the healthy group. In group D1, RMBF was unchanged or decreased in ischemic areas (10 +/- 23%) but increased sufficiently in surrounding areas (50 +/- 32%). In group D2, RMBF was unchanged in ischemic areas (17 +/- 24%) and increased insufficiently in surrounding areas (41 +/- 21%). Therefore, exercise-induced downsloping ST-segment depression of 0.1 to 0.2 mV may reflect an underlying change in blood flow in viable myocardium with collateral perfusion, and downsloping depression of 0.2 mV or more may reflect more severely impaired myocardium without collateral perfusion.
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PMID:Significance of downsloping ST-segment depression induced by low-level exercise in severe coronary artery disease. Assessment with myocardial ischemia and collateral perfusion. 920 Nov 8

Free fatty acid (FFA) accumulation during cerebral ischemia has been described as an indicator of ischemic damage. Furthermore arachidonic acid (AA) metabolites, liberated from glycerophospholipids, have been confirmed to induce disturbances of membrane functions. Are there differences in AA levels in the hippocampus of normo- and hypothermic gerbils following ischemia-reperfusion? In an attempt to answer this question, we first studied the time course of changes in the amount of AA liberated from glycerophospholipids using gerbils subjected to 5 min of ischemia-reperfusion under normo- and mild hypothermia. FFAs (including AA) were separated from total lipids by Bond Elut (NH2) column chromatography and analyzed by gas-liquid chromatography. Mild intra-ischemic hypothermia (MIH) did not affect the ischemia-induced AA accumulation following of 5 min of forebrain ischemia. The accumulated AA amounts under MIH tend to decrease more slowly to baseline levels from 15 to 30 min of reperfusion than do the levels under normothermia. These results suggested that MIH reduced the rate of metabolism of AA after reperfusion and might suppress the generation of free radical, eicosanoids and other bioactive metabolites.
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PMID:Mild hypothermia reduces the rate of metabolism of arachidonic acid following postischemic reperfusion. 947 1

Activation of stress-activated protein kinases, including the p38 and the c-Jun NH2-terminal kinases (JNK), have been associated with the onset of cardiac hypertrophy and cell death in response to hemodynamic overload and ischemia/reperfusion injury. Upon infection of cultured neonatal rat cardiac myocytes with recombinant adenoviral vectors expressing a wild type and a constitutively active mutant of MKK7 (or JNKK2), JNK was specifically activated without affecting other mitogen-activated protein kinases, including extracellular signal-regulated protein kinases and p38. Specific activation of the JNK pathway in cardiac myocytes induced characteristic features of hypertrophy, including an increase in cell size, elevated expression of atrial natriuretic factor, and induction of sarcomere organization. In contrast, co-activation of both JNK (by MKK7) and p38 (by MKK3 or MKK6) in cardiomyocytes led to an induction of cytopathic responses and suppression of hypertrophic responses. These data provide the first direct evidence that activation of JNK alone is sufficient to induce characteristic features of cardiac hypertrophy, thereby supporting an active role for the JNK pathway in the development of cardiac hypertrophy. The cytopathic response, as a result of co-activation of both JNK and p38, may contribute to the loss of contractile function and viability of cardiomyocytes following hemodynamic overload and cardiac ischemia/reperfusion injury.
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PMID:Cardiac hypertrophy induced by mitogen-activated protein kinase kinase 7, a specific activator for c-Jun NH2-terminal kinase in ventricular muscle cells. 948 59

Positron emission tomography (PET) is a powerful tool for in vivo measurements of physiologic processes such as regional myocardial blood flow and metabolism. Myocardial blood flow is often studied using radioactive labeled ammonia (13NH3) while myocardial metabolism can be investigated using 18F-fluorodeoxyglucose (FDG). Moreover, the use of appropriate kinetic models allows quantification of these processes. In this study, myocardial viability in both chronic and acute heart disease was investigated by the use of positron emission tomography. In this context, viable refers to dysfunctioning areas of the myocardium in which functional recovery is observed after revascularization. In patients suffering chronic coronary artery disease, PET findings of flow and metabolism were correlated with myocardial ultrastructure. In dysfunctional myocardial segments, normal 13NH3 uptake or decreased 13NH3 uptake with relatively increased FDG uptake (PET mismatch) indicates the possibility for functional recovery after bypass surgery. Since absence of scar tissue in these segments is likely to be required for functional recovery, it was not surprising that little fibrosis was found in myocardial biopsies taken in PET mismatch areas. The biopsies also revealed the presence of viable myocardial cells showing a variable loss of contractile material. The contractile material was replaced by glycogen. One could wonder about the time course needed for functional recovery after restoration of blood flow in the presence of a considerable amount of cells lacking a normal contractile apparatus. It would therefore be interesting to study functional recovery at different time points in patients with variable amounts of these myolytic cells. Probably, recovery of contractility would be slower in myocardial areas with a larger amount of abnormal cells. Another question that arises is the meaning of the increased FDG signal in dysfunctional, though viable myocardium. At first sight, glycogen storage in myolytic cells seems an excellent candidate to explain the increased intake of FDG in PET mismatch areas. However, in this study, in areas considered nonviable by PET, similar amounts of myolytic cells were found. Histologically altered cells might represent a structural and protective adaptation to long term hypoperfusion or to repetitive episodes of ischemia. Another possibility for the increased FDG uptake is an enhancement of glucose utilization in the mismatch areas not only in the myolytic cells, but also in the morphologically normal cell fractions. In patients with a PET mismatch pattern, significant recovery of flow and function was observed after surgery with a significant decrease in glucose utilization. Although it would have been interesting to histologically study the fate of myolytic cells in these recovered areas, this was not possible for obvious ethical reasons. In areas considered non viable by PET expressing a concordant decrease of 13NH3 and FDG uptake (PET match), no recovery of function, flow or metabolism was noted at follow-up. Another study was conducted in our department in infarct patients in which regional myocardial blood was measured within 24 hours after successful thrombolysis. The aim was to investigate the presence of impaired tissue perfusion in the acute stage and to evaluate its effect on recovery of flow, metabolism and function. In about 30% of patients with a TIMI 3 patent vessel, seriously impaired tissue flow was observed in the acute stage. Whether this impairment was due to irreversible damage to capillaries or myocytes, to reperfusion injury or to the presence of multiple distal thrombi remains unknown. Most patients showing severely impaired regional myocardial blood flow in the acute stage revealed absence of viable myocardium on follow-up PET NH3/FDG scans.
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PMID:[Hibernating myocardium and the 'no reflow' phenomenon: a study of absolute regional myocardial perfusion and glucose metabolism using positron emission tomography in chronic and acute heart disorders]. 949 Sep 15

Superior mesenteric artery occlusion (SMAO) is often fatal. An indicator which enables the early diagnosis of SMAO is needed. As we think putrefaction products must appear and increase in the blood and ascites in SMAO, changes in the concentrations of ammonia, one of the putrefaction products, were measured in this study. Thirteen adult mongrel dogs were used for the in vitro experiment. The jejunum, ileum, and ascending colon were resected and incubated in saline. Changes in ammonia concentrations in the saline were examined at various incubation times. In the in vivo experiment, 11 mongrel dogs comprised the SMAO group and another 10 mongrel dogs comprised the control group. Changes in ammonia concentrations in the blood and ascites were examined in both groups. In the in vitro experiment, ammonia concentrations in the saline bath increased in all samples. It was highest in the sample from around the ascending colon, and lowest from around the jejunum. However, at the end of experiment, this difference became insignificant. In the in vivo experiment, ammonia concentrations in samples of the blood increased early and significantly in the SMAO group, compared with the control group. Ammonia concentrations in samples of the ascites also increased significantly. The in vitro experiment showed that ammonia leaked from the ischemic intestines, and secondarily, a large amount of ammonia was produced from intestinal putrefaction. The in vivo experiment revealed that the ammonia level in the blood could be used as a good early indicator of acute mesenteric ischemia.
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PMID:Ammonia determination as an early indicator in experimental superior mesenteric artery occlusion. 953 66

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