isoproterenol and Hypoxia studies

Isoproterenol: Isopropyl analog of EPINEPHRINE; beta-sympathomimetic that acts on the heart, bronchi, skeletal muscle, alimentary tract, etc. It is used mainly as bronchodilator and heart stimulant.
isoprenaline : A secondary amino compound that is noradrenaline in which one of the hydrogens attached to the nitrogen is replaced by an isopropyl group. A sympathomimetic acting almost exclusively on beta-adrenergic receptors, it is used (mainly as the hydrochloride salt) as a bronghodilator and heart stimulant for the management of a variety of cardiac disorders.

Research Excerpts

Excerpt	Relevance	Reference
"Isoproterenol and hypoxemia-hypercapnia will increase myocardial oxygen demand and could prove to be detrimental in severe asthma."	9.07	The effect of hypercapnia and hypoxemia on the cardiovascular responses to isoproterenol. ( Beasley, R; Bremner, P; Buckly, D; Burgess, C; Crane, J; Galletly, D; McHaffie, D; Purdie, G; Robinson, B, 1994)
"The dynamics of the changes in myocardial phosphorylated compound contents (inorganic phosphate: Pi; phosphocreatine: PCr; ATP) induced by 10(-6)M isoprenaline administration was studied, using 31P-NMR spectroscopy, in hearts isolated from rats adapted for three weeks to normobaric hypoxia (10% of oxygen)."	7.69	Adaptation to chronic hypoxia alters cardiac metabolic response to beta stimulation: novel face of phosphocreatine overshoot phenomenon. ( Aussedat, J; Novel-Chaté, V; Rossi, A; Saks, VA, 1995)
"The role of adenosine in hypoxia-induced vasodilation was examined in the intestine of pentobarbital sodium-anesthetized cats."	7.68	Hypoxia-induced vasodilation of the feline superior mesenteric artery is not adenosine mediated. ( Lautt, WW; Lockhart, LK, 1990)
"The hypothesis of a blunted chronotropic response of cardiac beta-adrenergic receptors in altitude hypoxia was tested in nine subjects at sea level (SL) by infusion of isoproterenol."	7.67	Decreased cardiac response to isoproterenol infusion in acute and chronic hypoxia. ( Baud, P; Kéromès, A; Larmignat, P; Lhoste, F; Rathat, C; Richalet, JP, 1988)
"A decrease in heart rate response to isoproterenol (IP) infusion has been previously described in humans exposed to acute (2-3 days) or chronic (21 days) exposure to altitude hypoxia (J."	7.67	Reversal of hypoxia-induced decrease in human cardiac response to isoproterenol infusion. ( Bouissou, P; Keromes, A; Le-Trong, JL; Merlet, P; Rathat, C; Richalet, JP; Veyrac, P, 1989)
"A hemodynamic study with blood gas analysis was performed so we could observe changes induced by blood volume expansion, dopamine infusion and isoproterenol infusion in 20 adult patients suffering from peritonitis complicated with septic shock and acute respiratory failure."	7.66	Venous admixture in human septic shock: comparative effects of blood volume expansion, dopamine infusion and isoproterenol infusion on mismatching of ventilation and pulmonary blood flow in peritonitis. ( Delille, F; Eveleigh, MC; Gurdjian, F; Jardin, F; Margairaz, A, 1979)
"Some circulatory effects of thoracic epidural analgesia (TEA) were investigated in splenectomized, open-chest sheep during normoxia, hypoxia and isoproterenol administration."	7.66	Cardiovascular effects of epidural analgesia. I. Thoracic epidural analgesia. An experimental study in sheep of the effects on central circulation, regional perfusion and myocardial performance during normoxia, hypoxia and isoproterenol administration. ( Jynge, P; Ottesen, S; Renck, H, 1978)
"6 km/h), we studied the effect of ozone on ventilatory responses to hypercapnia and to hypoxia."	7.66	Mechanism of ozone-induced tachypneic response to hypoxia and hypercapnia in conscious dogs. ( Djokic, TD; Dumont, C; Graf, PD; Lee, LY; Nadel, JA, 1980)
"Myocardial necrosis was induced in male Wistar rats by isoproterenol as described by Rona et al."	7.66	Hypoxic tolerance of rats with isoproterenol-induced myocardial necrosis. ( Bhatia, B; Datta, K; Nijhawan, R, 1980)
" This is true for systemic hypoxia, hemorrhagic shock, and isoproterenol infusion."	7.65	Transmural metabolic gradients of the canine left ventricle in coronary constriction, systemic hypoxia, hemorrhagic shock, and isoproterenol infusion. ( Leunissen, RL, 1975)
"Forty-five normotensive and hypertensive sleep apnea patients (respiratory disturbance index >20) and non-apneic controls."	5.30	The effects of hypoxia and sleep apnea on isoproterenol sensitivity. ( Ancoli-Israel, S; Clausen, J; Dimsdale, JE; Loredo, JS; Mills, PJ, 1998)
"Isoproterenol and hypoxemia-hypercapnia will increase myocardial oxygen demand and could prove to be detrimental in severe asthma."	5.07	The effect of hypercapnia and hypoxemia on the cardiovascular responses to isoproterenol. ( Beasley, R; Bremner, P; Buckly, D; Burgess, C; Crane, J; Galletly, D; McHaffie, D; Purdie, G; Robinson, B, 1994)
" We established an isoproterenol (Iso)-induced myocardial injury mouse model and a hypoxia/reoxygenation (H/R)-induced H9c2 cell injury model, followed by pretreatment with apigenin to explore its protective effects."	4.31	Apigenin alleviates oxidative stress-induced myocardial injury by regulating SIRT1 signaling pathway. ( Dou, L; He, Q; Hei, M; Huang, X; Lan, M; Li, J; Li, W; Liu, B; Shen, T; Sun, S; Tang, W; Wang, H; Wang, J; Xu, K; Yan, M; Yang, Y; Zhang, X; Zhu, K, 2023)
" Here, we investigated the systemic and coronary arterial responses of five anesthetized juvenile American alligators (Alligator mississippiensis) to hypoxia, acetylcholine, adenosine, sodium nitroprusside, isoproterenol, and phenylephrine."	3.83	Coronary blood flow in the anesthetized American alligator (Alligator mississippiensis). ( Crossley, DA; Elfwing, M; Elsey, RM; Jensen, B; Wang, T, 2016)
" were screened with mice model of acute myocardial hypoxia induced by isoproterenol and pituitrin, eight compounds, i."	3.77	Anti-hypoxia activity and related components of Rhodobryum giganteum par. ( Cai, Y; Chen, R; Lu, X; Lu, Y; Wei, Q, 2011)
"In this study, the protective effect of pentoxifylline against hypoxia-reoxygenation injury and the possible involvement of nitric oxide (NO)-mediated pathways in this protection were investigated in isolated rat papillary muscles."	3.73	Pentoxifylline improves reoxygenation-induced contractile recovery through a nitric oxide-dependent mechanism in rat papillary muscles. ( Ahmadi, SH; Dehpour, AR; Ebrahimi, F; Ghasemi, M; Hajrasouliha, AR; Rofoui, BR; Sadeghipour, H; Tavakoli, S, 2006)
" cN-IA overexpression increased adenosine formation and release into the medium caused by simulated hypoxia and by isoproterenol in the absence and presence of inhibitors of adenosine metabolism."	3.72	Metabolic and functional consequences of cytosolic 5'-nucleotidase-IA overexpression in neonatal rat cardiomyocytes. ( Curto, MA; Freeman, NV; Newby, AC; Sala-Newby, GB, 2003)
"The aim of this study was to examine the effects of acute hypoxia on the slow (I(Ks)) and rapid (I(Kr)) components of the native delayed rectifier K+ channel in the absence and presence of the beta-adrenergic receptor agonist isoproterenol (isoprenaline; Iso) using the whole-cell configuration of the patch-clamp technique."	3.72	Differential regulation of the slow and rapid components of guinea-pig cardiac delayed rectifier K+ channels by hypoxia. ( Hool, LC, 2004)
"The depression of excitatory synaptic transmission by hypoxia in area CA1 of the hippocampus is largely dependent upon the activation of adenosine A(1) receptors on presynaptic glutamatergic terminals."	3.72	Adrenoceptor subtype-specific acceleration of the hypoxic depression of excitatory synaptic transmission in area CA1 of the rat hippocampus. ( Frenguelli, BG; Pearson, T, 2004)
"The aim was to study the effects of acidosis and hypoxia on the response of cardiac muscle to inotropic agents which (a) act predominantly by increasing intracellular [Ca2+] (raising extracellular [Ca2+], noradrenaline, isoprenaline) and (b) act partly (phenylephrine) or predominantly (EMD 57033) by increasing myofilament calcium sensitivity."	3.69	Effects of acidosis and hypoxia on the response of isolated ferret cardiac muscle to inotropic agents. ( Lee, JA; Orchard, CH; Shah, N; Than, N; White, J, 1994)
"The dynamics of the changes in myocardial phosphorylated compound contents (inorganic phosphate: Pi; phosphocreatine: PCr; ATP) induced by 10(-6)M isoprenaline administration was studied, using 31P-NMR spectroscopy, in hearts isolated from rats adapted for three weeks to normobaric hypoxia (10% of oxygen)."	3.69	Adaptation to chronic hypoxia alters cardiac metabolic response to beta stimulation: novel face of phosphocreatine overshoot phenomenon. ( Aussedat, J; Novel-Chaté, V; Rossi, A; Saks, VA, 1995)
"Temporal and quantitative relations between cytosolic energy metabolism, adenosine efflux, and coronary flow were examined during 10 min of isoproterenol (ISO) infusion (60 nM) or hypoxia (5% O2) in isolated isovolumic rat heart."	3.68	Adenosine formation and energy metabolism: a 31P-NMR study in isolated rat heart. ( Headrick, JP; Willis, RJ, 1990)
"The role of adenosine in hypoxia-induced vasodilation was examined in the intestine of pentobarbital sodium-anesthetized cats."	3.68	Hypoxia-induced vasodilation of the feline superior mesenteric artery is not adenosine mediated. ( Lautt, WW; Lockhart, LK, 1990)
" The effect was estimated of preliminary adaptation to intermittent hypobaric hypoxia or to short-term stress exposure on the incidence and the pronouncement of delayed after depolarization and of trigger activity induced by a high frequency stimulation against the background of isoproterenol (10(-8) M)."	3.68	[The effect of adaptation to stress exposures and to periodic hypoxia on the cardiomyocyte trigger activity of the papillary muscles in the rat]. ( Meerson, FZ; Vovk, VI, 1991)
" 31P-NMR was used to estimate free cytosolic Mg2+ levels ([Mg2+]free) during hypoxia, isoproterenol stimulation, and graded low-flow ischemia in crystalloid perfused, isovolumic rat hearts."	3.68	Cytosolic free magnesium in stimulated, hypoxic, and underperfused rat heart. ( Headrick, JP; Willis, RJ, 1991)
"A decrease in heart rate response to isoproterenol (IP) infusion has been previously described in humans exposed to acute (2-3 days) or chronic (21 days) exposure to altitude hypoxia (J."	3.67	Reversal of hypoxia-induced decrease in human cardiac response to isoproterenol infusion. ( Bouissou, P; Keromes, A; Le-Trong, JL; Merlet, P; Rathat, C; Richalet, JP; Veyrac, P, 1989)
"The hypothesis of a blunted chronotropic response of cardiac beta-adrenergic receptors in altitude hypoxia was tested in nine subjects at sea level (SL) by infusion of isoproterenol."	3.67	Decreased cardiac response to isoproterenol infusion in acute and chronic hypoxia. ( Baud, P; Kéromès, A; Larmignat, P; Lhoste, F; Rathat, C; Richalet, JP, 1988)
" Therefore, we sought to clarify the role of beta-adrenergic receptor activity in carotid body function by assessing: the ventilatory response to intravenous isoproterenol infusion in awake and anesthetized carotid body intact and carotid body denervated goats, the effect of propranolol on the ventilatory response to isocapnic hypoxemia, and carotid sinus nerve chemoreceptor discharge rate response to isoproterenol and hypoxia."	3.67	Role of beta adrenergic receptors in carotid body function of the goat. ( Bisgard, GE; Hudgel, DW; Kressin, NA; Nielsen, AM, 1986)
"In order to distinguish the effects of beta-receptor stimulation on the ECG from other factors during short-term adjustment to hypoxic aerohypoxia, the ECG of 19 volunteers were compared during moderately acute, stepwise exposure to high altitude (6,000 m) in a low pressure chamber, once with and once without beta-receptor blockade (propranolol), and after isoprenaline inhalation at ground level."	3.67	The ECG changes due to altitude and to catecholamines. ( Koller, EA; Saurenmann, P, 1984)
"To test the hypothesis that the rate of left ventricular relaxation can be dissociated from left ventricular stiffness, indexes of stiffness and relaxation were evaluated during mild hypoxia and hypoxia with isoproterenol or caffeine in isovolumically beating, isolated rat heart preparations."	3.67	Separation of rate of left ventricular relaxation from chamber stiffness in rats. ( Iizuka, M; Momomura, S; Serizawa, T; Sugimoto, T, 1988)
" Aortic chemoreceptor responses to steady-state hypoxia (PaO2 range, 100-30 Torr) were measured (a) before and during intravenous infusion of the beta-receptor agonist, isoproterenol (0."	3.67	Adrenergic mechanisms in oxygen chemoreception in the cat aortic body. ( Lahiri, S; Matsumoto, S; McGregor, KH; Mokashi, A; Mulligan, E, 1986)
"The erythropoietic response, measured as RBC-59Fe uptake, in response to either 24-h exposure to hypoxia or administration of dexamethasone, isoproterenol, testosterone, or erythropoietin, was determined in both posthypoxic (PH) and hypertransfused (HT) polycythemic mice."	3.67	Comparison of erythropoietic response to erythropoietin-secreting stimuli in mice following polycythemia induced by transfusion or hypoxia. ( Alippi, RM; Barceló, AC; Bozzini, CE, 1985)
" Aconitine, BaCl2 (less than 2 mmol/l) and hypoxia decrease threshold of ac-arrhythmia and ac-asystole, in both tissues to a similar extent, whereas carbachol and BaCl2 (greater than 2 mmol/l) increase threshold."	3.67	Influence of arrhythmogenic and antiarrhythmic agents on alternating current-induced arrhythmias in guinea-pig heart preparations. ( Borchard, U; Clemm, S; Hirth, C, 1984)
"The electrical and mechanical activities of myocardial strips from Rana pipiens treated with isoproterenol (ISO) were studied during cyanide hypoxia at different bath temperatures (12, 25 and 35 degrees C)."	3.67	Influence of temperature and cyanide on electrical and mechanical activities of isoproterenol-damaged frog heart. ( Pettersson, AS; Volkmann, R, 1985)
"The aim of this study was to examine the electrophysiological effects of isoprenaline, phenylephrine, and noradrenaline on sheep Purkinje fibers in vitro, superfused either with a normal or with a modified physiological salt solution (PSS) designed to mimic some of the conditions occurring during mild myocardial ischemia (hyperkalemia, hypoxia, and acidosis)."	3.67	Cardiac electrophysiological effects of isoprenaline, phenylephrine, and noradrenaline on normal and mildly "ischaemic" sheep Purkinje fibers. ( Boachie-Ansah, G; Kane, KA; Parratt, JR, 1989)
"To determine whether the pulmonary vasodilation produced by isoproterenol is mediated solely by its beta adrenergic effects, we studied the hemodynamic responses to isoproterenol in three groups of dogs with pulmonary vasoconstriction produced by continuous ventilation with 10% oxygen: (a) hypoxia alone, (b) hypoxia and propranolol 0."	3.66	Nonadrenergic effects of isoproterenol in dogs with hypoxic pulmonary vasoconstriction. Possible role of prostaglandins. ( Lazar, JD; Rubin, LJ, 1983)
"Two different conditions responsible for cardiac hypertrophy in the rat were investigated: the first one is isoproterenol-induced myocardial infarct, the second is exposure to hypoxia (0."	3.66	Myocardial hypertrophy in the rat. Correlation between two experimental models. ( Cacciapuoti, AA; Chiariello, M; Condorelli, M; Ferro, G; Genovese, A, 1980)
"Myocardial necrosis was induced in male Wistar rats by isoproterenol as described by Rona et al."	3.66	Hypoxic tolerance of rats with isoproterenol-induced myocardial necrosis. ( Bhatia, B; Datta, K; Nijhawan, R, 1980)
"6 km/h), we studied the effect of ozone on ventilatory responses to hypercapnia and to hypoxia."	3.66	Mechanism of ozone-induced tachypneic response to hypoxia and hypercapnia in conscious dogs. ( Djokic, TD; Dumont, C; Graf, PD; Lee, LY; Nadel, JA, 1980)
"Some circulatory effects of thoracic epidural analgesia (TEA) were investigated in splenectomized, open-chest sheep during normoxia, hypoxia and isoproterenol administration."	3.66	Cardiovascular effects of epidural analgesia. I. Thoracic epidural analgesia. An experimental study in sheep of the effects on central circulation, regional perfusion and myocardial performance during normoxia, hypoxia and isoproterenol administration. ( Jynge, P; Ottesen, S; Renck, H, 1978)
"A hemodynamic study with blood gas analysis was performed so we could observe changes induced by blood volume expansion, dopamine infusion and isoproterenol infusion in 20 adult patients suffering from peritonitis complicated with septic shock and acute respiratory failure."	3.66	Venous admixture in human septic shock: comparative effects of blood volume expansion, dopamine infusion and isoproterenol infusion on mismatching of ventilation and pulmonary blood flow in peritonitis. ( Delille, F; Eveleigh, MC; Gurdjian, F; Jardin, F; Margairaz, A, 1979)
"Resistance to isoproterenol-induced cardiac necrosis (IPRO) was compared in rats exposed to two types of hypoxia (i."	3.65	Experimental cardiac necrosis in hypobaric and anemic hypoxia. ( McGrath, JJ; Ostádal, B; Procházka, J; Rychterova, V; Wachtlova, M, 1975)
" This is true for systemic hypoxia, hemorrhagic shock, and isoproterenol infusion."	3.65	Transmural metabolic gradients of the canine left ventricle in coronary constriction, systemic hypoxia, hemorrhagic shock, and isoproterenol infusion. ( Leunissen, RL, 1975)
"The effects of isoproterenol, glucose, and pH on the responses of isolated rat cardiac muscle to hypoxia (95% N2, 5% CO2) were examined while the muscles were contracting isometrically 12 times a minute at 28 degrees C."	3.65	Factors influencing tolerance of cardiac muscle to hypoxia. ( Apstein, CS; Bing, OH; Brooks, WW, 1975)
" Cardiomegaly has been produced in rats by sideropenic anaemia, by isoprenaline or thyroxine or by the application of both drugs, by artificial increase in resistance to blood flow and by long-term adaptation to hypoxia and physical stress."	3.65	The growth of the muscular and collagenous parts of the rat heart in various forms of cardiomegaly. ( Bartosová, D; Chvapil, M; Korecký, B; Poupa, O; Rakusan, K; Turek, Z; Vízek, M, 1969)
" In addition, in Group A, the effects of hypoxia on the pulmonary circulation were compared and contrasted with those of l-norepinephrine (alpha-receptor stimulator) and isoproterenol (beta-receptor stimulator)."	3.64	Effects of alpha adrenergic blockade and tissue catecholamine depletion on pulmonary vascular response to hypoxia. ( Grover, RF; Silove, ED, 1968)
"Retinal neovascularization was assessed by CD31 immunohistochemistry."	1.38	Beta-adrenoreceptor agonism influences retinal responses to hypoxia in a model of retinopathy of prematurity. ( Bagnoli, P; Dal Monte, M; Filippi, L; Latina, V; Martini, D; Pavan, B, 2012)
"Hydrogen sulfide (H2S) is a gaseous signaling molecule that appears to be involved in numerous biological processes, including regulation of blood pressure and vascular tone."	1.37	Hydrogen sulfide and cerebral microvascular tone in newborn pigs. ( Basuroy, S; Fedinec, AL; Jaggar, JH; Leffler, CW; Parfenova, H; Umstot, ES, 2011)
"In the anoxia-tolerant crucian carp (Carassius carassius) cardiac activity varies according to the seasons."	1.36	Sinoatrial tissue of crucian carp heart has only negative contractile responses to autonomic agonists. ( Hälinen, M; Haverinen, J; Vornanen, M, 2010)
" Moreover, ACh and Ca(2+) dose-response studies showed that accumulation of cAMP shifted the dose-response curves to the low concentration side, suggesting that it increases Ca(2+) sensitivity in the fusion of the exocytotic cycle."	1.31	cAMP modulation of Ca(2+)-regulated exocytosis in ACh-stimulated antral mucous cells of guinea pig. ( Fujiwara, S; Imai, Y; Katsu, K; Kojima, K; Nakahari, T; Shimamoto, C, 2002)
"Forty-five normotensive and hypertensive sleep apnea patients (respiratory disturbance index >20) and non-apneic controls."	1.30	The effects of hypoxia and sleep apnea on isoproterenol sensitivity. ( Ancoli-Israel, S; Clausen, J; Dimsdale, JE; Loredo, JS; Mills, PJ, 1998)
"Propranolol (0."	1.30	Influence of beta-adrenoceptor agonists on the pulmonary circulation. Effects of a beta3-adrenoceptor antagonist, SR 59230A. ( Advenier, C; Bardou, M; Dumas, JP; Dumas, M; Giudicelli, JF; Rochette, L, 1998)
"1 ml), and dose-response curves to levcromakalim (a KATP channel opener) or isoproterenol were constructed."	1.29	Role of potassium channels in hypoxic relaxation of porcine bronchi in vitro. ( Croxton, TL; Fernandes, LB; Hirshman, CA; Lindeman, KS, 1994)
" Isolated atrial strips showed a right shift of their dose-response curve to isoprenaline in the presence of the highly selective beta 2-AR antagonist ICI 118,551 at concentrations above 1 x 10(-8) mol/L."	1.29	The effects of sympathomimetics on the cardiovascular system of sheep. ( Allen, R; Alley, MR; Baxter, S; Burgess, C; Crane, J; Dallimore, JA; Davie, PS; Kealey, AS; Lapwood, KR; Pack, RJ, 1994)
"We exposed fetuses to high-altitude (3,820 m) hypoxemia from 30 to 130 days gestation, when we measured fetal heart rate, right and left ventricular outputs with electromagnetic flow probes, and arterial blood pressure during an isoproterenol dose-response infusion."	1.29	Effects of isoproterenol on the cardiovascular system of fetal sheep exposed to long-term high-altitude hypoxemia. ( Gilbert, RD; Kamitomo, M; Ohtsuka, T, 1995)
" Dose-response curves were obtained through the sequential injection, via the femoral vein, of increasing doses of methacholine, methoxamine, isoprenaline and substance P."	1.29	Effects of chronic hypoxia on the secretory responses of rat salivary glands. ( Chiarenza, AP; Elverdin, JC; Frid, AB; Giglio, MJ, 1995)
"1982) and that DADs may explain certain arrhythmias such as those evoked by digitalis toxicity (Ferrier, 1977) or reperfusion (Ferrier et al."	1.27	Inhibition by simulated ischemia or hypoxia of delayed afterdepolarizations provoked by cyclic AMP: significance for ischemic and reperfusion arrhythmias. ( Coetzee, WA; Opie, LH; Saman, S, 1988)
" The relatively limited cardiac output response and downward trend at the highest dosage of dopamine occurred with a reduction in heart rate and an increase in systemic vascular resistance."	1.27	Augmentation of cardiac output with intravenous catecholamines in unanesthetized hypoxemic newborn lambs. ( Dreyer, WJ; Fisher, DJ; O'Laughlin, MP; Smith, EO, 1987)
"The effects of 30 min periods of either anoxia or ischemia (stop-flow) on the uptake2 of isoprenaline and on the production of O-methyl-isoprenaline, a major metabolite of isoprenaline formed by catechol-O-methyltransferase (COMT), were examined in the perfused rat heart."	1.27	Effects of anoxia and ischemia on uptake2 of catecholamines in perfused rat heart. ( Fujiwara, M; Hifumi, K; Inoue, M; Kurahashi, K, 1987)
"Furthermore, the resistance to anoxia of their isolated right ventricle was higher than that of virgin females."	1.26	The effect of pregnancy and lactation on the development of experimental heart lesions. ( Faltová, E; Mráz, M; Procházka, J; Sedivý, J, 1980)
"In puppies with oxygen deficiency, insulin levels declined, whereas during epinephrine infusion, they remained stable or increased slightly."	1.26	Beta adrenergic receptor dysfunction in hypoxic inhibition of insulin release. ( Baum, D; Porte, D, 1976)
"When isoproterenol was present in the bathing solution, the decreases in CF and APD produced by hypoxia were accelerated, but ATP and propranolol did not significantly modify the hypoxically induced changes."	1.26	Effects of hypoxia and metabolic inhibitors on the electrical and mechanical activities of isolated guinea pig papillary muscles. ( Asano, T; Kasuya, Y; Shigenobu, K, 1981)
"Reoxygenation after 10 min of anoxia produced equivalent recovery in both groups working against a 52-mmHg aortic afterload, whereas recovery after 20 or 30 min of anoxia, was depressed in diabetic hearts."	1.26	Performance of diabetic rat hearts: effects of anoxia and increased work. ( Hawelu-Johnson, C; Ingebretsen, CG; Ingebretsen, WR; Moreau, P, 1980)
"Although anoxia releases noradrenaline from the heart the effect of anoxia on the VFT was not prevented by beta-adrenoceptor blockade with propranolol or pindolol or by previous treatment with reserpine."	1.25	The effect of anoxia on the ventricular fibrillation threshold in the rabbit isolated heart. ( Murnaghan, MF, 1975)
"Pretreatment with propranolol, 0."	1.25	Cardiovascular responsiveness to beta-adrenergic stimulation and blockade in chronic hypoxia. ( Cymerman, A; Hartley, LH; Maher, JT; Manchanda, SC; Wolfe, DL, 1975)
" The NE dose-response curves shifted to the left."	1.25	Potentiation of the contractile effects of norepinephrine by hypoxia. ( Cooper, T; Epstein, SE; Kent, KM, 1972)

Research

Studies (303)

Authors

Clinical Trials (2)

Trial Overview

Trial Outcomes

6 Minute Walk Test

Timeframe	Studies, this research(%)	All Research%
pre-1990	222 (73.27)	18.7374
1990's	45 (14.85)	18.2507
2000's	20 (6.60)	29.6817
2010's	12 (3.96)	24.3611
2020's	4 (1.32)	2.80

Authors	Studies
Harter, TS	1
Clifford, AM	1
Tresguerres, M	1
Seaayfan, E	1
Nasrah, S	1
Quell, L	1
Radi, A	1
Kleim, M	1
Schermuly, RT	1
Weber, S	1
Laghmani, K	1
Kömhoff, M	1
Xu, K	1
Yang, Y	1
Lan, M	1
Wang, J	1
Liu, B	1
Yan, M	1
Wang, H	1
Li, W	1
Sun, S	1
Zhu, K	1
Zhang, X	1
Hei, M	1
Huang, X	1
Dou, L	1
Tang, W	1
He, Q	1
Li, J	1
Shen, T	1
Fernández-Morales, JC	1
Morad, M	1
Mahat, B	1
Mauger, JF	1
Imbeault, P	1
Stephens, OR	1
Weiss, K	1
Frimel, M	1
Rose, JA	1
Sun, Y	1
Asosingh, K	1
Farha, S	1
Highland, KB	1
Prasad, SVN	1
Erzurum, SC	1
Mahmud, H	1
Candido, WM	1
van Genne, L	1
Vreeswijk-Baudoin, I	1
Yu, H	1
van de Sluis, B	1
van Deursen, J	1
van Gilst, WH	1
Silljé, HH	1
de Boer, RA	1
Jensen, B	1
Elfwing, M	1
Elsey, RM	1
Wang, T	1
Crossley, DA	1
Béguin, PC	1
El-Helou, V	1
Assimakopoulos, J	1
Clément, R	1
Gosselin, H	1
Brugada, R	1
Villeneuve, L	1
Rohlicek, CV	2
Del Duca, D	1
Lapointe, N	1
Rouleau, JL	1
Calderone, A	1
Guan, Y	1
Gao, L	1
Ma, HJ	1
Li, Q	1
Zhang, H	1
Yuan, F	1
Zhou, ZN	1
Zhang, Y	1
Vornanen, M	1
Hälinen, M	1
Haverinen, J	1
Cai, Y	1
Lu, Y	1
Chen, R	1
Wei, Q	1
Lu, X	1
Leffler, CW	1
Parfenova, H	1
Basuroy, S	1
Jaggar, JH	1
Umstot, ES	1
Fedinec, AL	1
Marino, M	1
Bény, JL	1
Peyter, AC	1
Diaceri, G	1
Tolsa, JF	1
Lindgren, I	1
Crossley, D	1
Villamor, E	1
Altimiras, J	1
Dal Monte, M	1
Martini, D	1
Latina, V	1
Pavan, B	1
Filippi, L	1
Bagnoli, P	1
Naggar, I	1
Uchida, S	1
Kamran, H	1
Lazar, J	1
Stewart, M	1
Tabarov, MS	1
Kudryashov, YA	1
Hynie, S	1
Sída, P	1
Klenerová, V	1
Asemu, G	1
Ost'ádal, B	1
Hrbasová, M	1
Novotny, J	1
Hejnová, L	1
Kolár, F	1
Neckár, J	1
Svoboda, P	1
Sala-Newby, GB	1
Freeman, NV	1
Curto, MA	1
Newby, AC	1
Bartlett, IS	1
Marshall, JM	1
HALMAGYI, DF	1
COLEBATCH, HJ	1
STARZECKI, B	1
HORNER, GJ	1
HAWKING, F	1
FERRANS, VJ	1
HIBBS, RG	1
BLACK, WC	1
WEILBAECHER, DG	1
BLATTEIS, CM	1
SEGAL, S	1
CUMMING, GR	1
KORB, G	1
FOLLE, LE	2
AVIADO, DM	2
Pei, JM	2
Kravtsov, GM	1
Wu, S	1
Das, R	1
Fung, ML	3
Wong, TM	3
Hool, LC	1
Eigel, BN	1
Gursahani, H	1
Hadley, RW	1
Pearson, T	1
Frenguelli, BG	1
Viau, S	1
Trieu, P	1
Hébert, TE	1
Worthley, MI	1
Horowitz, JD	1
Zeitz, CJ	1
Schwenke, DO	1
Pearson, JT	1
Mori, H	1
Shirai, M	1
Ebrahimi, F	1
Hajrasouliha, AR	1
Tavakoli, S	1
Sadeghipour, H	1
Ghasemi, M	1
Rofoui, BR	1
Ahmadi, SH	1
Dehpour, AR	1
Waddell, JA	1
Emerson, PA	1
Gunstone, RF	1
Cowsert, MK	1
Carrier, O	1
Leszkovszky, GP	1
Gál, G	1
Tardos, L	1
Pisanty, J	1
Thilenius, OG	1
Candiolo, BM	1
Beug, JL	1
Dobson, JG	3
Schrader, J	1
Saurenmann, P	1
Koller, EA	1
Titus, EO	1
Wojtczak, J	1
Mir, AK	1
Pallot, DJ	1
Nahorski, SR	1
Rubin, LJ	1
Lazar, JD	1
Genovese, A	1
Chiariello, M	1
Ferro, G	1
Cacciapuoti, AA	1
Condorelli, M	1
Faltová, E	2
Mráz, M	2
Procházka, J	5
Sedivý, J	1
Borchard, U	1
Clemm, S	1
Hirth, C	1
Voelkel, NF	1
Walker, BR	2
Reeves, JT	4
Rabinovitch, M	1
Keane, JF	1
Norwood, WI	1
Castaneda, AR	1
Reid, L	1
Balazs, T	1
Johnson, G	1
Joseph, X	1
Ehrreich, S	1
Bloom, S	1
Cooper, MW	1
Lombardini, JB	1
Carlsten, A	2
Ericson, LE	1
Poupa, O	5
Baum, D	2
Porte, D	2
Ingebretsen, CG	1
Moreau, P	1
Hawelu-Johnson, C	1
Ingebretsen, WR	1
Dantzker, DR	1
Patten, GA	1
Bower, JS	1
Furman, WR	1
Summer, WR	1
Kennedy, TP	1
Sylvester, JT	1
Rothaul, AL	2
Broadley, KJ	3
De Mey, JG	1
Vanhoutte, PM	1
Giglio, MJ	2
Santoro, RC	1
Bozzini, CE	2
Lahiri, S	2
Pokorski, M	1
Davies, RO	1
Shigenobu, K	2
Asano, T	1
Kasuya, Y	2
Isawa, T	1
Teshima, T	1
Hirano, T	1
Ebina, A	1
Shiraishi, K	1
Konno, K	1
Lee, LY	1
Djokic, TD	1
Dumont, C	1
Graf, PD	1
Nadel, JA	1
Rawlings, CA	1
Bhatia, B	1
Datta, K	1
Nijhawan, R	1
Elverdin, JC	1
Chiarenza, AP	1
Frid, AB	1
Kamitomo, M	1
Ohtsuka, T	1
Gilbert, RD	2
Hasegawa, J	1
Watanabe, M	1
Matsumoto, T	1
Manabe, I	1
Doi, T	1
Kotake, H	1
Mashiba, H	1
Lin, PJ	2
Chang, CH	2
Yao, PC	2
Hsieh, HC	1
Hsieh, MJ	1
Kao, CL	1
Tsai, KT	2
Pack, RJ	2
Alley, MR	2
Davie, PS	1
Kealey, AS	1
Baxter, S	1
Allen, R	1
Dallimore, JA	2
Lapwood, KR	2
Crane, J	3
Burgess, C	3
McIntyre, RC	1
Banerjee, A	1
Hahn, AR	1
Agrafojo, J	1
Fullerton, DA	1
Hisatome, I	1
Arita, M	1
Bremner, P	1
McHaffie, D	1
Robinson, B	1
Galletly, D	1
Buckly, D	1
Beasley, R	1
Purdie, G	1
Than, N	1
Shah, N	1
White, J	1
Lee, JA	1
Orchard, CH	1
Heydeck, D	1
Roigas, J	1
Roigas, C	1
Papies, B	1
Lun, A	1
Lindeman, KS	1
Fernandes, LB	2
Croxton, TL	1
Hirshman, CA	1
Lee, SC	2
Downey, HF	2
Birnkrant, DJ	1
Davis, PB	1
Ernsberger, P	1
Steinberg, SF	1
Alter, A	1
Kwiatkowska-Patzer, B	1
Patzer, JA	1
Heller, LJ	1
Russ, RD	1
Novel-Chaté, V	1
Aussedat, J	1
Saks, VA	1
Rossi, A	1
Resink, T	1
Buravkova, L	1
Mirzapoyazova, T	1
Köhler, E	1
Erne, P	1
Tkachuk, V	1
Mallet, RT	1
Sun, LS	1
Du, F	1
Quaegebeur, JM	1
Browne, VA	1
Stiffel, VM	1
Pearce, WJ	1
Longo, LD	1
Priest, RM	1
Robertson, TP	1
Leach, RM	1
Ward, JP	1
Dumas, M	1
Dumas, JP	1
Bardou, M	1
Rochette, L	1
Advenier, C	1
Giudicelli, JF	1
Wolfel, EE	1
Selland, MA	1
Cymerman, A	3
Brooks, GA	1
Butterfield, GE	1
Mazzeo, RS	1
Grover, RF	3
León-Velarde, F	2
Richalet, JP	6
Chavez, JC	1
Kacimi, R	2
Rivera-Chira, M	1
Palacios, JA	1
Clark, D	1
Eddahibi, S	1
Raffestin, B	1
Le Monnier de Gouville, AC	1
Adnot, S	1
Yu, BH	1
Mills, PJ	2
Ziegler, MG	1
Dimsdale, JE	2
Fukuda, S	1
Toriumi, T	1
Xu, H	1
Kinoshita, H	1
Nishimaki, H	1
Kokubun, S	1
Fujiwara, N	1
Fujihara, H	1
Shimoji, K	1
de Glisezinski, I	1
Crampes, F	1
Harant, I	1
Havlik, P	1
Gardette, B	1
Jammes, Y	1
Souberbielle, JC	1
Rivière, D	1
Yu, XC	2
Zhou, JJ	1
Cheung, CS	1
Wong, NS	1
Leung, MP	1
Bourin, MC	1
Germack, R	1
Mohammadi, K	1
Crozatier, B	1
Sakuma, T	1
Tuchihara, C	1
Ishigaki, M	1
Osanai, K	1
Nambu, Y	1
Toga, H	1
Takahashi, K	1
Ohya, N	1
Kurihara, T	1
Matthay, MA	1
Ancoli-Israel, S	1
Clausen, J	1
Loredo, JS	1
Vianen, GJ	1
Obels, PP	1
van den Thillart, GE	1
Zaagsma, J	1
Nakahari, T	1
Fujiwara, S	1
Shimamoto, C	1
Kojima, K	1
Katsu, K	1
Imai, Y	1
Shan, J	1
Silove, ED	3
Volyntseva, VA	1
Kositskiĭ, GI	1
Kupriianov, VS	1
Bing, OH	4
Apstein, CS	2
Brooks, WW	3
Mentzer, RM	1
Alegre, CA	1
Nolan, SP	1
Larsson, S	1
Bartsch, W	2
Sponer, G	1
Dietmann, K	1
Svedmyr, N	1
Deehan, R	2
Swanton, JG	4
Lewis, MJ	1
Grey, AC	1
Henderson, AH	1
Belardinelli, L	2
Vogel, SM	1
Sperelakis, N	2
Rubio, R	1
Berne, RM	1
Lucchese, FA	1
Okazaki, T	1
Okazaki, A	1
Reisman, RE	1
Arbesman, CE	1
Delaunois, AL	1
Van Rompu, E	1
Vanderheeren, F	1
Sekar, TS	1
Doherty, GB	1
Moorthi, DS	1
Namsirikul, P	1
Subramony, D	1
MacDonnell, KF	1
Irmer, M	1
Köhler, G	1
Friedrichs, H	1
Eschenbruch, E	1
Döring, HJ	1
O'Brien, JA	1
Strange, RC	1
Ross, J	1
Mayer, SE	1
Matsuki, N	1
Zwillich, CW	1
Matthay, M	1
Potts, DE	1
Adler, R	1
Hofeldt, F	1
Weil, JV	2
Maher, JT	2
Manchanda, SC	1
Wolfe, DL	2
Hartley, LH	1

Trial	Phase	Enrollment	Study Type	Start Date	Status
Pulmonary Arterial Hypertension Treatment With Carvedilol for Heart Failure[NCT01586156]		30 participants (Actual)	Interventional	2012-12-31	Completed
Hemodynamics and Extravascular Lung Water in Acute Lung Injury: A Prospective Randomized Controlled Multicentered Trial of Goal Directed Treatment of EVLW Versus Standard Management for the Treatment of Acute Lung Injury[NCT00624650]	Phase 2	33 participants (Actual)	Interventional	2008-02-29	Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

We hypothesized that carvedilol would not worsen 6 minute walk distance. (NCT01586156)
Timeframe: 6 months

Beta-Adrenergic Receptor (Alprenolol Binding Assay)

Intervention	meters (Mean)
	baseline	3 months	6 months
Escalation-dose Carvedilol	438	438	450
Low-fixed-dose Carvedilol	504	504	486
Placebo Arm	404	412	453

We hypothesize that use of carvedilol in patients with PAH will increase beta- adrenergic receptor availability, and this will be measurable as a increase in alprenolol binding over time of drug use. (NCT01586156)
Timeframe: 6 months

Cardiac Glucose Uptake in FDG-PET (Fluorodeoxyglucose-Positron Emission Tomography)

Intervention	abritrary units (Mean)
	baseline	6 months
Escalation-dose Carvedilol	82779	83730
Low-fixed-dose Carvedilol	85230	84554
Placebo Arm	92254	79083

We hypothesize that use of carvedilol in patients with PAH (Pulmonary Arterial Hypertension) will decrease the cardiac glucose utilization, and this will be measurable as a drop in fasting FDG-PET standardized uptake values of the heart at 6 months as compared to baseline (NCT01586156)
Timeframe: 6 months

Echocardiogram Left Ventricular Cardiac Output

Intervention	standardized uptake value (SUV) (Median)
	baseline FDG-PET	6 month FDG-PET
Escalation-dose Carvedilol	0.9	0.7
Low-fixed-dose Carvedilol	0.6	0.6
Placebo Arm	1.0	0.8

We hypothesized that carvedilol would be safe and tolerable and thus that Left ventricular cardiac output, a measure of heart function, would not decrease in participants on carvedilol. (NCT01586156)
Timeframe: 6 months

Echocardiogram Right Ventricular Systolic Pressure (RVSP)

Intervention	L/min (Mean)
	baseline	3 months	6 months
Escalation-dose Carvedilol	4.5	4.8	4.9
Low-fixed-dose Carvedilol	5.2	4.6	4.7
Placebo Arm	4.7	4.7	4.5

We hypothesized that RVSP might decrease in participants on carvedilol. (NCT01586156)
Timeframe: 6 months

NT-proBNP (N-terminal Pro-B Type Natriuretic Peptide)

Intervention	mm Hg (Mean)
	baseline	3 months	6 months
Escalation-dose Carvedilol	63	54	64
Low-fixed-dose Carvedilol	63	59	51
Placebo Arm	76	78	66

We hypothesized that carvedilol would be safe and tolerable and thus that NT-BNP, a measure of heart failure, would not increase in participants on carvedilol. (NCT01586156)
Timeframe: 6 months

Urinary cAMP (Cyclic Adenosine Monophosphate)/Creatinine

Intervention	pg/ml (Median)
	baseline	1 month	3 months	6 months
Escalation-dose Carvedilol	127	120	169	146
Low-fixed-dose Carvedilol	57	92	79	52
Placebo Arm	170	183	152	293

We hypothesize that use of carvedilol in patients with PAH will increase beta adrenergic receptor function and this will be measurable as an increase in cAMP measured in the urine at 6 months in participants in dose escalation carvedilol. (NCT01586156)
Timeframe: 6 months

Article	Year
A molecular biologic approach to cardiac toxicology. Advances in experimental medicine and biology, 1983, Volume: 161 Topics: Acrylamides; Animals; Calcium; Cnidarian Venoms; Coronary Disease; Doxorubicin; Egtazic Acid; Electr	1983
Long-term treatment with beta2-adrenostimulants in asthma. Side effects, selectivity, tolerance, and routes of administration. Acta medica Scandinavica. Supplementum, 1977, Volume: 608 Topics: Administration, Oral; Adrenergic beta-Agonists; Aerosols; Albuterol; Arrhythmias, Cardiac; Asthma; E	1977
Adrenergic stimulants and asthma mortality. Scandinavian journal of respiratory diseases. Supplementum, 1977, Volume: 101 Topics: Adrenergic beta-Agonists; Adrenergic beta-Antagonists; Arrhythmias, Cardiac; Asthma; Bronchi; Chloro	1977
Alterations of myocardial adenine nucleotide metabolism. Recent advances in studies on cardiac structure and metabolism, 1975, Volume: 7 Topics: Adenine Nucleotides; Adenosine Diphosphate; Adenosine Monophosphate; Adenosine Triphosphate; Animals	1975
The pathophysiologic vulnerability of the subendocardium of the left ventricle. Advances in cardiology, 1973, Volume: 9 Topics: Arrhythmias, Cardiac; Capillaries; Cardiomegaly; Coronary Disease; Coronary Vessels; Endocardium; He	1973
Advances in asthma. Treatment. British medical journal, 1969, Nov-08, Volume: 4, Issue:5679 Topics: Adrenal Cortex Hormones; Adrenocorticotropic Hormone; Asthma; Bronchodilator Agents; Carbon Dioxide;	1969
A review of current concepts and research in shock. The Ohio State medical journal, 1968, Volume: 64, Issue:6 Topics: Blood Transfusion; Extracellular Space; Homeostasis; Humans; Hypoxia; Isoproterenol; Mephentermine;	1968
Management of arrhythmias in acute myocardial infarction. American family physician, 1971, Volume: 4, Issue:1 Topics: Acid-Base Equilibrium; Adams-Stokes Syndrome; Arrhythmias, Cardiac; Atropine; Bradycardia; Cardiac O	1971
Effects of hypoxia and ischemia on myocardial contraction. Alterations in the time course of force and ischemia-dependent inhomogeneity of contractility. Cardiology, 1971, Volume: 56, Issue:1 Topics: Animals; Coronary Disease; Heart; Heart Ventricles; Humans; Hypoxia; In Vitro Techniques; Isoprotere	1971

Article	Year
The effect of hypercapnia and hypoxemia on the cardiovascular responses to isoproterenol. Clinical pharmacology and therapeutics, 1994, Volume: 56, Issue:3 Topics: Adult; Analysis of Variance; Carbon Dioxide; Cardiovascular System; Humans; Hypercapnia; Hypoxia; Is	1994
O2 extraction maintains O2 uptake during submaximal exercise with beta-adrenergic blockade at 4,300 m. Journal of applied physiology (Bethesda, Md. : 1985), 1998, Volume: 85, Issue:3 Topics: Adrenergic beta-Agonists; Adrenergic beta-Antagonists; Adult; Altitude; Blood Gas Analysis; Diet; Ex	1998
Decrease of subcutaneous adipose tissue lipolysis after exposure to hypoxia during a simulated ascent of Mt Everest. Pflugers Archiv : European journal of physiology, 1999, Volume: 439, Issue:1-2 Topics: Adipose Tissue; Adrenergic Agonists; Adrenergic beta-Agonists; Adult; Altitude; Body Composition; Ep	1999
Effects of adrenergic stimulation on ventilation in man. The Journal of clinical investigation, 1972, Volume: 51, Issue:6 Topics: Adult; Analysis of Variance; Angiotensin II; Carbon Dioxide; Chemoreceptor Cells; Clinical Trials as	1972
Effect of drugs, hypoxia, and ventilatory maneuvers on lung diffusion for CO in man. Journal of applied physiology, 1972, Volume: 32, Issue:6 Topics: Adult; Carbon Monoxide; Clinical Trials as Topic; Epinephrine; Humans; Hyperventilation; Hypoxia; Is	1972
Lung function in provoked asthma: responses to inhaled urea, methacholine and isoprenaline. Clinical science, 1972, Volume: 43, Issue:6 Topics: Adolescent; Adult; Aged; Airway Resistance; Asthma; Carbon Dioxide; Female; Humans; Hypoxia; Isoprot	1972
Effects of isoprenaline plus phenylephrine by pressurized aerosol on blood gases, ventilation, and perfusion in chronic obstructive lung disease. British medical journal, 1970, Dec-05, Volume: 4, Issue:5735 Topics: Adult; Aerosols; Aged; Carbon Dioxide; Cardiac Output; Chronic Disease; Clinical Trials as Topic; Fe	1970
Comparison of the effect on blood gases, ventilation, and perfusion of isoproterenol-phenylephrine and salbutamol aerosols in chronic bronchitis with asthma. The Journal of allergy and clinical immunology, 1972, Volume: 49, Issue:2 Topics: Adult; Aerosols; Aged; Asthma; Blood Gas Analysis; Bronchitis; Bronchodilator Agents; Carbon Dioxide	1972

isoproterenol and Hypoxia