glyburide has been researched along with Hyperemia in 34 studies
Glyburide: An antidiabetic sulfonylurea derivative with actions like those of chlorpropamide
glyburide : An N-sulfonylurea that is acetohexamide in which the acetyl group is replaced by a 2-(5-chloro-2-methoxybenzamido)ethyl group.
Hyperemia: The presence of an increased amount of blood in a body part or an organ leading to congestion or engorgement of blood vessels. Hyperemia can be due to increase of blood flow into the area (active or arterial), or due to obstruction of outflow of blood from the area (passive or venous).
Excerpt | Relevance | Reference |
---|---|---|
"We have previously demonstrated that adenosine-mediated H2O2 production and opening of ATP-sensitive K(+) (KATP) channels contributes to coronary reactive hyperemia." | 7.80 | Metabolic hyperemia requires ATP-sensitive K+ channels and H2O2 but not adenosine in isolated mouse hearts. ( Ledent, C; Mustafa, SJ; Teng, B; Tilley, S; Zhou, X, 2014) |
"Myocardial metabolites such as adenosine mediate reactive hyperemia, in part, by activating ATP-dependent K(+) (K(ATP)) channels in coronary smooth muscle." | 7.79 | Interactions between A(2A) adenosine receptors, hydrogen peroxide, and KATP channels in coronary reactive hyperemia. ( Asano, S; Dick, GM; Ledent, C; Mustafa, SJ; Sharifi-Sanjani, M; Teng, B; Tilley, S; Zhou, X, 2013) |
"The effect of glyburide on coronary reactive hyperemia and dilator responses to adenosine was evaluated in isolated perfused guinea pig hearts and anesthetized dogs." | 7.68 | Coronary reactive hyperemia and adenosine-induced vasodilation are mediated partially by a glyburide-sensitive mechanism. ( Clayton, FC; Grover, GJ; Hess, TA; Smith, MA, 1992) |
"Post-occlusive reactive hyperemia (PORH) following arterial occlusion is widely used to assess cutaneous microvascular function, though the underlying mechanisms remain to be fully elucidated." | 6.94 | Tetraethylammonium, glibenclamide, and 4-aminopyridine modulate post-occlusive reactive hyperemia in non-glabrous human skin with no roles of NOS and COX. ( Fujii, N; Ichinose, M; Kenny, GP; McGarr, GW; Nishiyasu, T, 2020) |
"We have previously demonstrated that adenosine-mediated H2O2 production and opening of ATP-sensitive K(+) (KATP) channels contributes to coronary reactive hyperemia." | 3.80 | Metabolic hyperemia requires ATP-sensitive K+ channels and H2O2 but not adenosine in isolated mouse hearts. ( Ledent, C; Mustafa, SJ; Teng, B; Tilley, S; Zhou, X, 2014) |
"Myocardial metabolites such as adenosine mediate reactive hyperemia, in part, by activating ATP-dependent K(+) (K(ATP)) channels in coronary smooth muscle." | 3.79 | Interactions between A(2A) adenosine receptors, hydrogen peroxide, and KATP channels in coronary reactive hyperemia. ( Asano, S; Dick, GM; Ledent, C; Mustafa, SJ; Sharifi-Sanjani, M; Teng, B; Tilley, S; Zhou, X, 2013) |
"This study was designed to elucidate the contribution of adenosine A(2A) and A(2B) receptors to coronary reactive hyperemia and downstream K(+) channels involved." | 3.76 | Contribution of adenosine A(2A) and A(2B) receptors to ischemic coronary dilation: role of K(V) and K(ATP) channels. ( Berwick, ZC; Dick, GM; Lynch, B; Payne, GA; Sturek, M; Tune, JD, 2010) |
"Glibenclamide, iberiotoxin, and apamin (blockers of ATP-sensitive, large-conductance, and small-conductance Ca(2+)-activated K+ channels, respectively) were infused into the diaphragmatic vasculature of anesthetized indomethacin-treated dogs to assess the contribution of K+ channels to active hyperemia." | 3.69 | Contribution of potassium channels to active hyperemia of the canine diaphragm. ( Chang, HY; Gatensby, AG; Hussain, SN; Vanelli, G, 1994) |
"Glibenclamide, iberiotoxin, and apamin (blockers of ATP-sensitive, large-conductance, and small-conductance Ca(2+)-activated potassium channels, respectively) were infused into the diaphragmatic vasculature of anesthetized dogs to assess the contribution of these channels in the regulation of basal tone and the response to brief occlusions of the left phrenic artery (reactive hyperemia)." | 3.69 | Effects of potassium channel blockers on basal vascular tone and reactive hyperemia of canine diaphragm. ( Hussain, SN; Vanelli, G, 1994) |
" Studies were conducted under control conditions and in the presence of four inhibitors of potential mediators of the reactive hyperemia response: the nitric oxide synthase inhibitor NG-nitro-L-arginine methyl ester (30 microM), the adenosine antagonist 8-(p-sulfophenyl)theophylline (50 microM), the K+ cyclic adenosine triphosphate-dependent channel antagonist glibenclamide (10 microM), and the cyclooxygenase inhibitor indomethacin (10 microM)." | 3.69 | Myocardial reactive hyperemia in experimental chronic heart failure: evidence for the role of K+ adenosine triphosphate-dependent channels and cyclooxygenase activity. ( Dumont, L; Fontaine, E; Jasmin, G; VĂ©ronneau, M; Viau, S, 1997) |
"Post-occlusive reactive hyperemia (PORH) following arterial occlusion is widely used to assess cutaneous microvascular function, though the underlying mechanisms remain to be fully elucidated." | 2.94 | Tetraethylammonium, glibenclamide, and 4-aminopyridine modulate post-occlusive reactive hyperemia in non-glabrous human skin with no roles of NOS and COX. ( Fujii, N; Ichinose, M; Kenny, GP; McGarr, GW; Nishiyasu, T, 2020) |
" After dosing glibenclamide induced a significant (P = 0." | 2.71 | Forearm vascular reactivity is differentially influenced by gliclazide and glibenclamide in chronically treated type 2 diabetic patients. ( Boes, U; Wascher, TC, 2005) |
"Reactive hyperemia was expressed in terms of peak post-occlusive flow, duration of hyperemia and reactive hyperemic volume." | 2.68 | Acute effects of glyburide on the regulation of peripheral blood flow in normal humans. ( Hussain, SN; Kosmas, EN; Levy, RD, 1995) |
" In resistance vessels, venous occlusion plethysmography was used to measure the dilator response to acetylcholine (ACh) [area under ACh dose-response curve (ACh AUC)]." | 1.37 | Postconditioning protects against human endothelial ischaemia-reperfusion injury via subtype-specific KATP channel activation and is mimicked by inhibition of the mitochondrial permeability transition pore. ( Bhavsar, DD; Charakida, M; Deanfield, JE; Loukogeorgakis, SP; MacAllister, RJ; Okorie, MI; Ridout, D, 2011) |
"Reactive hyperemia was induced following 30 sec and 300 sec of no-flow ischemia of the heart." | 1.30 | Types of potassium channels involved in coronary reactive hyperemia depend on duration of preceding ischemia in rat hearts. ( Ito, T; Mokuno, S; Murase, K; Okumura, K; Shinoda, M; Toki, Y, 1997) |
"The mechanism underlying reactive hyperemia was investigated in the feline hindquarters vascular bed under natural- and constant-flow conditions." | 1.29 | Role of K+ATP channels and EDRF in reactive hyperemia in the hindquarters vascular bed of cats. ( Kadowitz, PJ; McMahon, TJ; Minkes, RK; Santiago, JA, 1995) |
"In the early phase of reactive hyperemia, all arterial microvessels dilated, and the magnitude of peak dilation was greater in vessels smaller than 100 microns compared with those larger than 100 microns." | 1.28 | Microvascular sites and mechanisms responsible for reactive hyperemia in the coronary circulation of the beating canine heart. ( Akai, K; Ashikawa, K; Kanatsuka, H; Komaru, T; Sato, K; Sekiguchi, N; Takishima, T; Wang, Y, 1992) |
"The mechanism of reactive hyperemia remains unknown." | 1.28 | Blockade of the ATP-sensitive potassium channel modulates reactive hyperemia in the canine coronary circulation. ( Aversano, T; Ouyang, P; Silverman, H, 1991) |
Timeframe | Studies, this research(%) | All Research% |
---|---|---|
pre-1990 | 0 (0.00) | 18.7374 |
1990's | 16 (47.06) | 18.2507 |
2000's | 11 (32.35) | 29.6817 |
2010's | 6 (17.65) | 24.3611 |
2020's | 1 (2.94) | 2.80 |
Authors | Studies |
---|---|
Fujii, N | 1 |
McGarr, GW | 1 |
Ichinose, M | 1 |
Nishiyasu, T | 1 |
Kenny, GP | 1 |
Sharifi-Sanjani, M | 1 |
Zhou, X | 2 |
Asano, S | 1 |
Tilley, S | 2 |
Ledent, C | 2 |
Teng, B | 2 |
Dick, GM | 2 |
Mustafa, SJ | 2 |
Holdsworth, CT | 1 |
Copp, SW | 1 |
Ferguson, SK | 1 |
Sims, GE | 1 |
Poole, DC | 1 |
Musch, TI | 1 |
Matheson, PJ | 1 |
Li, N | 1 |
Harris, PD | 1 |
Zakaria, el R | 1 |
Garrison, RN | 1 |
Berwick, ZC | 1 |
Payne, GA | 1 |
Lynch, B | 1 |
Sturek, M | 1 |
Tune, JD | 1 |
Okorie, MI | 1 |
Bhavsar, DD | 1 |
Ridout, D | 1 |
Charakida, M | 1 |
Deanfield, JE | 2 |
Loukogeorgakis, SP | 2 |
MacAllister, RJ | 2 |
Capecchi, PL | 1 |
Guideri, F | 1 |
Colafati, M | 1 |
Acampa, M | 1 |
Cuomo, A | 1 |
Lazzerini, PE | 1 |
Pasini, FL | 1 |
Farouque, HM | 3 |
Meredith, IT | 3 |
Worthley, SG | 1 |
Wascher, TC | 1 |
Boes, U | 1 |
Schrage, WG | 1 |
Dietz, NM | 1 |
Joyner, MJ | 1 |
Cankar, K | 1 |
Strucl, M | 1 |
Williams, R | 1 |
Panagiotidou, AT | 1 |
Kolvekar, SK | 1 |
Donald, A | 1 |
Cole, TJ | 1 |
Yellon, DM | 1 |
Wang, SY | 1 |
Friedman, M | 1 |
Johnson, RG | 1 |
Zeind, AJ | 1 |
Sellke, FW | 1 |
Minkes, RK | 1 |
Santiago, JA | 1 |
McMahon, TJ | 1 |
Kadowitz, PJ | 1 |
Vanelli, G | 2 |
Chang, HY | 1 |
Gatensby, AG | 1 |
Hussain, SN | 3 |
Yada, T | 1 |
Hiramatsu, O | 1 |
Kimura, A | 1 |
Tachibana, H | 1 |
Chiba, Y | 1 |
Lu, S | 1 |
Goto, M | 1 |
Ogasawara, Y | 1 |
Tsujioka, K | 1 |
Kajiya, F | 1 |
Kosmas, EN | 1 |
Levy, RD | 1 |
Duncker, DJ | 2 |
van Zon, NS | 1 |
Pavek, TJ | 1 |
Herrlinger, SK | 1 |
Bache, RJ | 2 |
Saito, Y | 1 |
McKay, M | 1 |
Eraslan, A | 1 |
Hester, RL | 1 |
Gidday, JM | 1 |
Maceren, RG | 1 |
Shah, AR | 1 |
Meier, JA | 1 |
Zhu, Y | 1 |
Shinoda, M | 1 |
Toki, Y | 1 |
Murase, K | 1 |
Mokuno, S | 1 |
Okumura, K | 1 |
Ito, T | 1 |
Viau, S | 1 |
Fontaine, E | 1 |
VĂ©ronneau, M | 1 |
Jasmin, G | 1 |
Dumont, L | 1 |
Iwata, F | 1 |
Koo, A | 1 |
Itoh, M | 1 |
Lam, K | 1 |
Leung, JW | 1 |
Leung, FW | 1 |
Ishibashi, Y | 1 |
Zhang, J | 1 |
Bank, AJ | 1 |
Sih, R | 1 |
Mullen, K | 1 |
Osayamwen, M | 1 |
Lee, PC | 1 |
Phillis, JW | 1 |
Song, D | 1 |
O'Regan, MH | 1 |
Shimizu, K | 1 |
Bari, F | 1 |
Busija, DW | 1 |
Kanatsuka, H | 1 |
Sekiguchi, N | 1 |
Sato, K | 1 |
Akai, K | 1 |
Wang, Y | 1 |
Komaru, T | 1 |
Ashikawa, K | 1 |
Takishima, T | 1 |
Clayton, FC | 1 |
Hess, TA | 1 |
Smith, MA | 1 |
Grover, GJ | 1 |
Aversano, T | 1 |
Ouyang, P | 1 |
Silverman, H | 1 |
Trial | Phase | Enrollment | Study Type | Start Date | Status | ||
---|---|---|---|---|---|---|---|
A Randomised Controlled Trial of the Effect of Remote Ischaemic Conditioning on Coronary Endothelial Function in Patients With Angina.[NCT02666235] | Phase 2 | 60 participants (Actual) | Interventional | 2011-07-31 | Completed | ||
Effect of Intermittent Hypoxia on Ischemia-reperfusion Injury in Healthy Individuals[NCT05423470] | 41 participants (Actual) | Interventional | 2019-05-30 | Completed | |||
The Effect of Remote Ischemic Conditioning (RIC) on Inflammatory Biomarkers and Outcomes in Patients With TBI[NCT03899532] | 120 participants (Anticipated) | Interventional | 2019-09-24 | Recruiting | |||
The Effect of Remote Ischemic Preconditioning on Myocardial Injury After Noncardiac Surgery in Patients at a High Risk of Cardiac Events[NCT05733208] | 766 participants (Anticipated) | Interventional | 2023-05-06 | Recruiting | |||
[information is prepared from clinicaltrials.gov, extracted Sep-2024] |
1 review available for glyburide and Hyperemia
Article | Year |
---|---|
ATP-sensitive K+ channels, adenosine, and nitric oxide-mediated mechanisms account for coronary vasodilation during exercise.
Topics: Adenosine; Adenosine Triphosphate; Animals; Coronary Disease; Coronary Vessels; Dogs; Enzyme Inhibit | 1998 |
5 trials available for glyburide and Hyperemia
Article | Year |
---|---|
Tetraethylammonium, glibenclamide, and 4-aminopyridine modulate post-occlusive reactive hyperemia in non-glabrous human skin with no roles of NOS and COX.
Topics: 4-Aminopyridine; Adult; Glyburide; Humans; Hyperemia; Male; Nitric Oxide Synthase; Prostaglandin-End | 2020 |
Acute effects of glibenclamide on reactive hyperaemia in the lower limbs in humans.
Topics: Adult; Area Under Curve; Female; Glyburide; Humans; Hyperemia; Ischemia; Ischemic Preconditioning; L | 2002 |
Forearm vascular reactivity is differentially influenced by gliclazide and glibenclamide in chronically treated type 2 diabetic patients.
Topics: Adult; Analysis of Variance; Cross-Over Studies; Diabetes Mellitus, Type 2; Dose-Response Relationsh | 2005 |
The effect of glibenclamide on cutaneous laser-Doppler flux.
Topics: Adult; Blood Flow Velocity; Cold Temperature; Dose-Response Relationship, Drug; Female; Glyburide; H | 2008 |
Acute effects of glyburide on the regulation of peripheral blood flow in normal humans.
Topics: Administration, Oral; Adult; Cross-Over Studies; Femoral Vein; Glyburide; Humans; Hyperemia; Leg; Ma | 1995 |
28 other studies available for glyburide and Hyperemia
Article | Year |
---|---|
Interactions between A(2A) adenosine receptors, hydrogen peroxide, and KATP channels in coronary reactive hyperemia.
Topics: Adenosine; Animals; Catalase; Coronary Circulation; Coronary Vessels; Glyburide; Hydrogen Peroxide; | 2013 |
Metabolic hyperemia requires ATP-sensitive K+ channels and H2O2 but not adenosine in isolated mouse hearts.
Topics: Adenosine; Adenosine A2 Receptor Antagonists; Animals; Coronary Circulation; Free Radical Scavengers | 2014 |
Acute inhibition of ATP-sensitive K+ channels impairs skeletal muscle vascular control in rats during treadmill exercise.
Topics: Animals; Arterial Pressure; Glyburide; Hyperemia; Male; Muscle, Skeletal; Physical Exertion; Rats; R | 2015 |
Glucose-induced intestinal vasodilation via adenosine A1 receptors requires nitric oxide but not K(+)(ATP) channels.
Topics: Adenosine A1 Receptor Antagonists; Animals; Glucose; Glyburide; Hyperemia; Intestinal Absorption; Je | 2011 |
Contribution of adenosine A(2A) and A(2B) receptors to ischemic coronary dilation: role of K(V) and K(ATP) channels.
Topics: 4-Aminopyridine; Adenosine; Adenosine A2 Receptor Agonists; Adenosine A2 Receptor Antagonists; Anima | 2010 |
Postconditioning protects against human endothelial ischaemia-reperfusion injury via subtype-specific KATP channel activation and is mimicked by inhibition of the mitochondrial permeability transition pore.
Topics: Acetylcholine; Adult; Analysis of Variance; Brachial Artery; Cyclosporine; Endothelium, Vascular; Fe | 2011 |
Effects of inhibition of ATP-sensitive potassium channels on metabolic vasodilation in the human forearm.
Topics: Adenosine Triphosphate; Adult; Dose-Response Relationship, Drug; Female; Forearm; Gliclazide; Glybur | 2003 |
Inhibition of vascular ATP-sensitive K+ channels does not affect reactive hyperemia in human forearm.
Topics: Adenosine Triphosphate; Adult; Blood Vessels; Diazoxide; Female; Forearm; Glyburide; Humans; Hyperem | 2003 |
Effect of ATP-sensitive potassium channel inhibition on coronary metabolic vasodilation in humans.
Topics: Adenosine Triphosphate; Aged; Angioplasty, Balloon, Coronary; Cardiac Catheterization; Cardiac Pacin | 2004 |
Effects of combined inhibition of ATP-sensitive potassium channels, nitric oxide, and prostaglandins on hyperemia during moderate exercise.
Topics: Adenosine Triphosphate; Adult; Enzyme Inhibitors; Exercise; Female; Forearm; Glyburide; Humans; Hype | 2006 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Transient limb ischemia induces remote preconditioning and remote postconditioning in humans by a K(ATP)-channel dependent mechanism.
Topics: Adult; Aged; Atherosclerosis; Brachial Artery; Endothelium, Vascular; Female; Forearm; Glyburide; He | 2007 |
Adenosine triphosphate-sensitive K+ channels mediate postcardioplegia coronary hyperemia.
Topics: Adenosine Triphosphate; Animals; Coronary Circulation; Coronary Vessels; Glyburide; Guanidines; Hear | 1995 |
Role of K+ATP channels and EDRF in reactive hyperemia in the hindquarters vascular bed of cats.
Topics: Adamantane; Adenosine Triphosphate; Animals; Arginine; Cats; Glyburide; Hindlimb; Hyperemia; Ischemi | 1995 |
Contribution of potassium channels to active hyperemia of the canine diaphragm.
Topics: 1-Methyl-3-isobutylxanthine; Animals; Apamin; Blood Gas Analysis; Diaphragm; Dogs; Electric Stimulat | 1994 |
Direct in vivo observation of subendocardial arteriolar response during reactive hyperemia.
Topics: Adenosine; Animals; Arginine; Arterioles; Coronary Circulation; Coronary Vessels; Dogs; Female; Glyb | 1995 |
Endogenous adenosine mediates coronary vasodilation during exercise after K(ATP)+ channel blockade.
Topics: Adenosine; Animals; Coronary Circulation; Diastole; Dogs; Glyburide; Guanidines; Hemodynamics; Hyper | 1995 |
Effects of potassium channel blockers on basal vascular tone and reactive hyperemia of canine diaphragm.
Topics: Animals; Apamin; Arteries; Constriction; Dogs; Glyburide; Hyperemia; Peptides; Potassium Channel Blo | 1994 |
Functional hyperemia in striated muscle is reduced following blockade of ATP-sensitive potassium channels.
Topics: Adenosine Triphosphate; Animals; Arterioles; Cricetinae; Electric Stimulation; Glyburide; Hyperemia; | 1996 |
KATP channels mediate adenosine-induced hyperemia in retina.
Topics: 8-Bromo Cyclic Adenosine Monophosphate; Adenosine; Adenosine Triphosphate; Adenylyl Cyclases; Animal | 1996 |
Types of potassium channels involved in coronary reactive hyperemia depend on duration of preceding ischemia in rat hearts.
Topics: 4-Aminopyridine; Adenosine Diphosphate; Animals; Apamin; Charybdotoxin; Glyburide; Hyperemia; In Vit | 1997 |
Myocardial reactive hyperemia in experimental chronic heart failure: evidence for the role of K+ adenosine triphosphate-dependent channels and cyclooxygenase activity.
Topics: Animals; Cardiac Output, Low; Chronic Disease; Coronary Circulation; Cricetinae; Disease Models, Ani | 1997 |
Functional evidence linking potassium channels and afferent nerve-mediated mucosal protection in rat stomach.
Topics: Animals; Capsaicin; Ethanol; Gastric Acid; Gastric Mucosa; Glyburide; Hyperemia; Male; Neurons, Affe | 1997 |
Vascular ATP-dependent potassium channels, nitric oxide, and human forearm reactive hyperemia.
Topics: Adenosine Triphosphate; Adult; Analysis of Variance; Enzyme Inhibitors; Female; Forearm; Glyburide; | 2000 |
Mechanisms involved in coronary artery dilatation during respiratory acidosis in the isolated perfused rat heart.
Topics: Acidosis, Respiratory; Animals; Carbon Dioxide; Coronary Circulation; Glyburide; GTP-Binding Protein | 2000 |
Glibenclamide enhances cortical spreading depression-associated hyperemia in the rat.
Topics: Animals; Cerebral Cortex; Charybdotoxin; Cortical Spreading Depression; Glyburide; Hyperemia; Indome | 2000 |
Microvascular sites and mechanisms responsible for reactive hyperemia in the coronary circulation of the beating canine heart.
Topics: Adenosine; Adenosine Triphosphate; Animals; Blood Flow Velocity; Coronary Circulation; Coronary Vess | 1992 |
Coronary reactive hyperemia and adenosine-induced vasodilation are mediated partially by a glyburide-sensitive mechanism.
Topics: Adenosine; Animals; Coronary Circulation; Dogs; Female; Glyburide; Guinea Pigs; Hyperemia; In Vitro | 1992 |
Blockade of the ATP-sensitive potassium channel modulates reactive hyperemia in the canine coronary circulation.
Topics: Acetylcholine; Adenosine; Adenosine Triphosphate; Animals; Calcium Channels; Coronary Circulation; D | 1991 |