Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0022116 (ischemia)
 91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ischemic incubation significantly increased amino acid release from rat striatal slices. Reoxygenation (REO) of the ischemic slices, however, enhanced only taurine and citrulline levels in the medium. Ischemia-induced increases in glutamate, taurine and GABA outputs were accompanied with a similar amount of decline in their tissue levels. Tissue final aspartic acid level, however, was doubled by ischemia. Lactate dehydrogenase (LDH) leakage was not altered by ischemia, but enhanced during REO. Presence of tetrodotoxine (TTX) during ischemic period caused significant decline in ischemia-induced glutamate output, but not altered REO-induced LDH leakage. Although omission of extracellular calcium ions from the medium during ischemic period protected the slices against REO-induced LDH leakage, this treatment failed to alter ischemia-induced glutamate and GABA outputs. The release of other amino acids, however, declined 50% in calcium-free medium. Blockade of the glutamate uptake transporter by L-trans-PDC, on the other hand, doubled ischemia induced glutamate and aspartic acid outputs. These results indicate that more than one mechanisms probably support the ischemia-evoked accumulation of glutamate and other amino acids in the extracellular space. Although LDH leakage enhanced during REO, processes involved in this increment were found to be dependent on extracellular calcium ions during ischemia but not REO period.
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PMID:Ischemia and reoxygenation induced amino acid release release and tissue damage in the slices of rat corpus striatum. 1530 72

Increased release of glutamate is thought to contribute to ischemia-induced neuronal damage. Since general anesthetics such as thiopental and ketamine are thought to provide some degree of cerebral protection, this study was intended to 1) compare the effectiveness of ketamine and thiopental on ischemia-induced tissue damage; and, if so, 2) determine whether attenuation of the increased amino acid release is the sole mechanism for the protective effects demonstrated. Striatal slices prepared from Wistar Albino rats were incubated in an ischemic medium for 1 hour followed by 5 hours in a reoxygenation (REO) medium. Ketamine and thiopental were added medium during ischemia and/or REO periods, and the medium was collected at the end of each incubation period for measurement of amino acid release and lactate dehydrogenase (LDH) leakage. Ischemia significantly increased amino acid release without altering LDH leakage. Ischemia-induced increments in glutamate and aspartic acid releases returned to control levels during REO, but LDH leakage increased (P > 0.001) during this period. Although ketamine (100 microM) and thiopental (100 microM) failed to decrease ischemia-induced excitatory amino acid release, they protected the slices against REO-induced LDH leakage. Ketamine, but not thiopental, was effective even if added after ischemia (P < 0.05). These results indicate that ketamine and thiopental protect the slices against REO-induced LDH leakage. However, mechanisms other than attenuation of the enhanced glutamate release might be responsible for their protective effects.
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PMID:Effects of ketamine and thiopental on ischemia reoxygenation-induced LDH leakage and amino acid release from rat striatal slices. 1563 38

We investigated the effects of an Na(+)/H(+) exchanger inhibitor, sabiporide, on excitotoxicity in cultured neuronal cells and in vivo. Sabiporide attenuated glutamate- or NMDA (N-methyl-d-aspartic acid)-induced neuronal cell death. Sabiporide also reduced glutamate or NMDA-induced increase in [Ca(2+)](i). In in vivo brain ischemia model, sabiporide produced protective effects, decreasing the infarct size and edema volume. Our results suggest that sabiporide elicits neuroprotective effect both in vitro and in vivo.
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PMID:Effects of sabiporide, a specific Na+/H+ exchanger inhibitor, on neuronal cell death and brain ischemia. 1622 53

Metabolic and functional effects of a hypocalcium reperfusion solution (RS) with low oxygen content containing d-glucose, trisamine, d-mannitol and I-aspartic acid have been studied in isolated rat hearts. The hearts were initially perfused for 20 min with the Krebs solution under constant left atrial filling pressure of 15 mm Hg and aortic perfusion pressure of 60 mm Hg. Then they were subjected to 30-min total normothermic ischemia followed by 30-min of reperfusion. The Krebs solution (control, n=16) or RS (n=11) were infused in retrograde mode with a rate of 4 ml/min during first 5 min of reperfusion. After that the hearts of both groups were reperfused in antegrade mode with the Krebs solution for 25 min under initial conditions. Short-term infusion of RS markedly improved postischemic functional recovery of cardiac function. After 30-min reperfusion coronary flow, an index of contractile function intensity, expressed as the left ventricle developed pressure-heart rate product, and cardiac work, calculated as the minute volume-aortic perfusion pressure product, recovered up to 92+/-1%, 77+/-1% and 61+/-1% of baseline values, respectively. In the control group the same indices were significantly lower and were 74+/-3%, 48+/-5% and 33+/-2%, respectively (p<0.001). At the end of reperfusion hearts treated with RS compared with the control hearts showed higher myocardial levels of ATP, phosphocreatine (PCr) and total creatine (SCr). These metabolic findings indicate better recovery of energy state and lesser sarcolemmal damage of postischemic cardiomyocytes after RS infusion. Thus, optimization of administration mode and composition of reperfusion solutions is a promising tool to attenuate functional and metabolic disturbances of the postischemic heart.
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PMID:[Controlled reperfusion improves the metabolic and functional recovery of the isolated heart in rats after total ischemia]. 1671 Jan 99

Programmed cell death (apoptosis) is a ubiquitous means utilized by multicellular organisms for elimination of unwanted cells during development and homeostasis. Dysregulated apoptosis is implicated in an array of clinical disorders including cancer, autoimmune diseases, neurodegenerative disorders, and ischemia. During programmed cell death, a series of proteases, known as caspases, with different specificities play crucial roles in the apoptotic process. Caspase-3, a group II cysteine aspartate protease, recognizes and cleaves substrates harboring the amino acid sequence aspartic acid-glutamic acid-valine-aspartic acid (DEVD), and it plays an important role in the terminal phase of apoptosis. Here we report the development of a novel imaging platform for sensing the activation of cellular proteases. A recombinant chimeric protein was constructed, composed of a cell-surface-targeted single-chain antibody (sFv) fused to a Golgi retention signal. The DEVD tetrapeptide sequence was included between the single-chain antibody and the Golgi retention signal as a caspase-3 protease cleavage site. When expressed in cultured cells this fusion protein was localized to Golgi bodies and was not detected on the cell surface. Induction of apoptosis resulted in cleavage of the fusion protein releasing the single-chain antibody from the Golgi retention signal in a caspase-dependent manner. As a result, in cells undergoing apoptosis the single-chain antibody was visualized at the cell surface by immunofluorescence microscopy. The expression of sFv on the surface of cells in a protease-dependent manner provides a unique opportunity for real-time imaging through the use of targeted nanoparticles. This methodology may provide for a multimodal noninvasive real-time imaging of apoptosis and a new opportunity for high-throughput screening of cell-death-modulating therapeutic agents.
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PMID:Imaging of proteolytic activity using a conditional cell surface receptor. 1695 27

Cardiac myosin binding protein C (cMyBP-C) has three phosphorylatable serines at its N terminus (Ser-273, Ser-282, and Ser-302), and the residues' phosphorylation states may alter thick filament structure and function. To examine the effects of cMyBP-C phosphorylation, we generated transgenic mice with cardiac-specific expression of a cMyBP-C in which the three phosphorylation sites were mutated to aspartic acid, mimicking constitutive phosphorylation (cMyBP-C(AllP+)). The allele was bred into a cMyBP-C null background (cMyBP-C((t/t))) to ensure the absence of endogenous dephosphorylated cMyBP-C. cMyBP-C(AllP+) was incorporated normally into the cardiac sarcomere and restored normal cardiac function in the null background. However, subtle changes in sarcomere ultrastructure, characterized by increased distances between the thick filaments, indicated that phosphomimetic cMyBP-C affects thick-thin filament relationships, and yeast two-hybrid data and pull-down studies both showed that charged residues in these positions effectively prevented interaction with the myosin heavy chain. Confirming the physiological relevance of these data, the cMyBP-C(AllP+:(t/t)) hearts were resistant to ischemia-reperfusion injury. These data demonstrate that cMyBP-C phosphorylation functions in maintaining thick filament spacing and structure and can help protect the myocardium from ischemic injury.
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PMID:Cardiac myosin binding protein C phosphorylation is cardioprotective. 1707 52

Isolated perfused hearts of Wistar rats subjected to total ischemia and reperfusion were used to examine the possibility of moderating damage to cardiomyocyte membranes with reperfusion solution containing l-aspartic acid, d-glucose, and d-mannitol. During the first 5 minutes of reperfusion, this solution significantly improved recovery of the pumping and contractile functions of the heart compared to the control and reduced the release of lactate dehydrogenase and systems generating short-living ROS into the effluent. To the end of reperfusion, the content of ATP and phosphocreatine was higher and the loss of total creatine was lower in hearts perfused with the test solution compared to the control. It is hypothesized that better integrity of the myocyte sarcolemma in hearts perfused with the test solution results from better preservation of macroergic phosphates and inhibition of ROS generation in this solution.
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PMID:Moderation of postischemic damage to cardiomyocytic membranes with reperfusion solution. 1801 2

We previously reported that novel protein kinase C (nPKC) epsilon and N-methyl-d-aspartic acid (NMDA) receptors participated in morphine preconditioning (MP)-induced neuroprotection. In this study, we used Western blot analysis, 2,3,5-triphenyltetrazolium chloride (TTC) staining and lactate dehydrogenase (LDH) leakage assay to determine the involvement of conventional PKC isoforms (cPKC) in MP-induced neuroprotection against oxygen-glucose deprivation (OGD). Hippocampus slices (400-microm thickness) from healthy male BALB/c mice exposed to OGD for 5-45 min to mimic mild, moderate and severe ischemia in the presence of MP pretreatment. We found that OGD-induced damage in neuronal cell survival rate and LDH leakage could be improved by MP pretreatment (3 microM) within 20 min of OGD, which was abolished by concomitant incubation with non-selective opioid receptor antagonist naloxone (Nal, 50 microM). The results of Western blot analysis showed that only cPKCgamma membrane translocation, not alpha, betaI and betaII, increased under the condition of OGD 10 min and 2h reperfusion (OGD/2h), and this increment of cPKCgamma membrane translocation was inhibited by MP pretreatment. To further elucidate the role of cPKCgamma in MP-induced neuroprotection, we found that cPKCgamma membrane translocation inhibitor, Go6983 (6 nM) did not affect MP-induced neuroprotection while Go6983 alone exhibited a significant inhibition on OGD-induced increment in LDH leakage and decrease in cell survival rate. These phenomena were defined by the results that Go6983 could restore OGD-induced cPKCgamma membrane translocation, but had no further effect on MP-induced inhibition of cPKCgamma membrane translocation. These results demonstrated that MP can reduce OGD-induced neuronal injuries, and the down-regulation of cPKCgamma membrane translocation might be involved in the neuroprotection.
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PMID:Inhibition of PKCgamma membrane translocation mediated morphine preconditioning-induced neuroprotection against oxygen-glucose deprivation in the hippocampus slices of mice. 1870 78

A biodegradable positron-emitting dendritic nanoprobe targeted at alpha(v)beta(3) integrin, a biological marker known to modulate angiogenesis, was developed for the noninvasive imaging of angiogenesis. The nanoprobe has a modular multivalent core-shell architecture consisting of a biodegradable heterobifunctional dendritic core chemoselectively functionalized with heterobifunctional polyethylene oxide (PEO) chains that form a protective shell, which imparts biological stealth and dictates the pharmacokinetics. Each of the 8 branches of the dendritic core was functionalized for labeling with radiohalogens. Placement of radioactive moieties at the core was designed to prevent in vivo dehalogenation, a potential problem for radiohalogens in imaging and therapy. Targeting peptides of cyclic arginine-glycine-aspartic acid (RGD) motifs were installed at the terminal ends of the PEO chains to enhance their accessibility to alpha(v)beta(3) integrin receptors. This nanoscale design enabled a 50-fold enhancement of the binding affinity to alpha(v)beta(3) integrin receptors with respect to the monovalent RGD peptide alone, from 10.40 nM to 0.18 nM IC(50). Cell-based assays of the (125)I-labeled dendritic nanoprobes using alpha(v)beta(3)-positive cells showed a 6-fold increase in alpha(v)beta(3) receptor-mediated endocytosis of the targeted nanoprobe compared with the nontargeted nanoprobe, whereas alpha(v)beta(3)-negative cells showed no enhancement of cell uptake over time. In vivo biodistribution studies of (76)Br-labeled dendritic nanoprobes showed excellent bioavailability for the targeted and nontargeted nanoprobes. In vivo studies in a murine hindlimb ischemia model for angiogenesis revealed high specific accumulation of (76)Br-labeled dendritic nanoprobes targeted at alpha(v)beta(3) integrins in angiogenic muscles, allowing highly selective imaging of this critically important process.
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PMID:Biodegradable dendritic positron-emitting nanoprobes for the noninvasive imaging of angiogenesis. 1912 98

Therapeutic vascularization remains a significant challenge in regenerative medicine applications. Whether the goal is to induce vascular growth in ischemic tissue or scale up tissue-engineered constructs, the ability to induce the growth of patent, stable vasculature is a critical obstacle. We engineered polyethylene glycol-based bioartificial hydrogel matrices presenting protease-degradable sites, cell-adhesion motifs, and growth factors to induce the growth of vasculature in vivo. Compared to injection of soluble VEGF, these matrices delivered sustained in vivo levels of VEGF over 2 weeks as the matrix degraded. When implanted subcutaneously in rats, degradable constructs containing VEGF and arginine-glycine-aspartic acid tripeptide induced a significant number of vessels to grow into the implant at 2 weeks with increasing vessel density at 4 weeks. The mechanism of enhanced vascularization is likely cell-demanded release of VEGF, as the hydrogels may degrade substantially within 2 weeks. In a mouse model of hind-limb ischemia, delivery of these matrices resulted in significantly increased rate of reperfusion. These results support the application of engineered bioartificial matrices to promote vascularization for directed regenerative therapies.
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PMID:Bioartificial matrices for therapeutic vascularization. 2008 May 69


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