carbon monoxide and Disease Models, Animal studies

Carbon Monoxide: Carbon monoxide (CO). A poisonous colorless, odorless, tasteless gas. It combines with hemoglobin to form carboxyhemoglobin, which has no oxygen carrying capacity. The resultant oxygen deprivation causes headache, dizziness, decreased pulse and respiratory rates, unconsciousness, and death. (From Merck Index, 11th ed)
carbon monoxide : A one-carbon compound in which the carbon is joined only to a single oxygen. It is a colourless, odourless, tasteless, toxic gas.

Disease Models, Animal: Naturally-occurring or experimentally-induced animal diseases with pathological processes analogous to human diseases.

Research Excerpts

Excerpt	Relevance	Reference
" In the present study, we examined the therapeutic performance of a biomimetic carbon monoxide (CO) delivery system, CO-enriched red blood cells (CO-RBCs), on experimental animal models of an acute kidney injury (AKI) induced by traumatic and nontraumatic rhabdomyolysis, including CS and rhabdomyolysis with massive hemorrhage shock."	7.96	Carbon Monoxide Rescues the Developmental Lethality of Experimental Rat Models of Rhabdomyolysis-Induced Acute Kidney Injury. ( Enoki, Y; Fukagawa, M; Ishima, Y; Maeda, H; Maruyama, T; Matsumoto, K; Nagasaki, T; Nishida, K; Ogaki, S; Ooi, K; Otagiri, M; Sekijima, H; Taguchi, K; Watanabe, H; Yanagisawa, H, 2020)
"BACKGROUND Carbon monoxide (CO) has anti-inflammatory effects and protects the intestinal mucosal barrier in sepsis."	7.96	Carbon Monoxide Inhibits the Expression of Proteins Associated with Intestinal Mucosal Pyroptosis in a Rat Model of Sepsis Induced by Cecal Ligation and Puncture. ( Dong, J; Liu, X; Qin, H; Shao, M; Wang, H; Wu, F; Zhang, H; Zhang, J; Zhang, S; Zhang, W; Zhao, H; Zhao, Y; Zhao, Z, 2020)
"The purpose of the present study was to investigate the effect of carbon monoxide (CO) released from CO‑releasing molecule 2 (CORM‑2) on mice with acute pancreatitis (AP)."	7.91	Carbon monoxide releasing molecule‑2 (CORM‑2)‑liberated CO ameliorates acute pancreatitis. ( Liu, Y; Qin, W; Sun, B; Wang, X; Xu, X, 2019)
"Carbon monoxide (CO) releasing molecule (CORM)-3, a water-soluble CORM, has protective effects against inflammatory and ischemia/reperfusion injury."	7.91	Carbon monoxide-releasing molecule-3 protects against cortical pyroptosis induced by hemorrhagic shock and resuscitation via mitochondrial regulation. ( Fu, L; Kong, XJ; Li, CC; Li, Y; Qi, MM; Song, PP; Wang, XD; Wang, XP; Zhang, DX; Zhang, LM, 2019)
"The aim of this study is to investigate the mechanism underling cardiac dysfunction during sepsis, as well as the possible amelioration of this dysfunction by exogenous carbon monoxide (CO) administration."	7.88	The down-regulation of cardiac contractile proteins underlies myocardial depression during sepsis and is mitigated by carbon monoxide. ( Aki, T; Nagano, S; Uemura, K; Unuma, K; Watanabe, R, 2018)
"The discovery of carbon monoxide (CO) and hydrogen sulfide (H2S) as pathogenic signaling molecules in airway-related diseases has led to significant insights into the pathophysiologic mechanisms underlying the development of allergic rhinitis (AR)."	7.81	Impact of carbon monoxide/heme oxygenase on hydrogen sulfide/cystathionine-γ-lyase pathway in the pathogenesis of allergic rhinitis in guinea pigs. ( Che, N; Ge, R; Yan, Z; Yu, S; Zhang, X, 2015)
"Carbon monoxide (CO) has shown various physiological effects including anti-inflammatory activity in several diseases, whereas the therapeutic efficacy of CO on sepsis-induced acute kidney injury (AKI) has not been reported as of yet."	7.81	Exogenous Carbon Monoxide Decreases Sepsis-Induced Acute Kidney Injury and Inhibits NLRP3 Inflammasome Activation in Rats. ( Chang, R; Huang, J; Huang, Z; Li, Y; Lin, J; Wang, P; Wu, H, 2015)
"Treatment with a carbon monoxide-releasing molecule (tricarbonyldichlororuthenium(II) dimer, CORM-2) or a classical heme oxygenase 1 inducer (cobalt protoporphyrin IX, CoPP) has potent anti-inflammatory effects, but the role played by these treatments in the antinociceptive effects of morphine during acute and chronic pain was not evaluated."	7.79	Effects of treatment with a carbon monoxide-releasing molecule and a heme oxygenase 1 inducer in the antinociceptive effects of morphine in different models of acute and chronic pain in mice. ( Gou, G; Hervera, A; Leánez, S; Pol, O, 2013)
"Clinical reports describe life-threatening cardiac arrhythmias after environmental exposure to carbon monoxide (CO) or accidental CO poisoning."	7.78	Carbon monoxide induces cardiac arrhythmia via induction of the late Na+ current. ( Bernus, O; Boycott, HE; Boyle, JP; Dallas, ML; Duke, A; Elies, J; Milligan, CJ; Peers, C; Reboul, C; Richard, S; Scragg, JL; Steele, DS; Thireau, J; Yang, Z, 2012)
" In this study, we assessed the role of CO donor, methylene chloride (MC), on modulation of lung inflammation during sepsis."	7.76	Methylene chloride protects against cecal ligation and puncture-induced acute lung injury by modulating inflammatory mediators. ( Dou, L; He, J; Pan, X; Pang, Q; Xu, W; Zeng, S; Zeng, Y, 2010)
"To investigate the anti-atherotic effects of heme-L-lysinate in a rabbit model of atherosclerosis and related machanisms."	7.76	[The anti-athetotic effects of heme-L-lysinate in a rabbit model of atherosclerosis]. ( Wang, XB; Wei, WL, 2010)
"Use of metal carbonyl-based compounds capable of releasing carbon monoxide (CO) in biological systems have emerged as a potential adjunctive therapy for sepsis via their antioxidant, anti-inflammatory, and antiapoptotic effects."	7.75	Carbon monoxide rescues mice from lethal sepsis by supporting mitochondrial energetic metabolism and activating mitochondrial biogenesis. ( Decoster, B; Favory, R; Hassoun, SM; Lancel, S; Motterlini, R; Neviere, R, 2009)
"To explore the role of hydrogen sulfide/cystathionine-gamma-lyase (H(2)S/CSE) system in lipopolysaccharide (LPS)- induced acute lung injury (ALI) in rats and the underlying mechanisms."	7.75	[Role of hydrogen sulfide/cystathionine-gamma-lyase system in acute lung injury induced by lipopolysaccharide in rats]. ( Huang, XL; Ling, YL; Tian, FJ; Wei, P; Zhou, XH, 2009)
"The aim of this study is to investigate the effect of heme oxygenase-1 (HO-1)/carbon monoxide (CO) system in pulmonary ischemia-reperfusion injury (PIRI) in rabbits."	7.75	Role of heme oxygenase-1/carbon monoxide system in pulmonary ischemia-reperfusion injury. ( Jia, X; Lin, L; Shi, L; Wang, F; Wang, W, 2009)
"In previous work we have demonstrated that delivery of low concentrations (250 ppm) of carbon monoxide by means of inhalation to donors, recipients, or both protects transplanted lungs from ischemia-reperfusion injury (improved gas exchange, diminished intragraft and systemic inflammation, and retention of graft vascular endothelial cell ultrastructure)."	7.74	Carbon monoxide-saturated preservation solution protects lung grafts from ischemia-reperfusion injury. ( Kohmoto, J; McCurry, KR; Nakao, A; Sugimoto, R; Ueda, H; Wang, Y; Zhan, J, 2008)
"We aimed to investigate the toxicity of carbon monoxide (CO) in rats with right ventricle (RV) remodeling induced by hypoxic pulmonary hypertension (PHT)."	7.74	Continuous inhalation of carbon monoxide induces right ventricle ischemia and dysfunction in rats with hypoxic pulmonary hypertension. ( Antier, D; Bonnet, P; Eder, V; Gautier, M; Hanton, G; Le Net, JL, 2007)
"To investigate the inhibitory effects of extrinsic carbon monoxide-releasing molecules II on inflammatory responses in liver of mice with severe burns and its potential mechanisms."	7.74	[The inhibitory effects of extrinsic carbon monoxide-releasing molecules II on inflammatory responses in liver of mice with severe burns]. ( Chen, X; Chen, ZY; Gediminas, C; Kazuhiro, K; Sun, BW, 2007)
"Carbon monoxide with hypoxia and hypoxemic hypoxia both result in similar depression of cardiac function."	7.74	Carbon monoxide has direct toxicity on the myocardium distinct from effects of hypoxia in an ex vivo rat heart model. ( Jay, G; Suner, S, 2008)
"To investigate the role of carbon monoxide (CO) in the pathogenesis of asthma."	7.70	[Evidence of increased endogenous carbon monoxide production in asthma]. ( Jiang, D; Li, H; Shi, Y, 1999)
"Pulmonary carbon monoxide (CO) excretion rates (VeCO) were 50% greater, on average, in Bolivian squirrel monkeys (BoSMs) which exhibit a unique fasting hyperbilirubinemia (FH), than in fasted control Brazilian squirrel monkeys (BrSMs)."	7.68	Increased carbon monoxide excretion in Bolivian squirrel monkeys with fasting hyperbilirubinemia. ( Cornelius, CE; Rodgers, PA; Tarkington, BK; Vreman, HJ, 1990)
" Severe carbon monoxide poisoning with fatal levels of HbCO (greater than 50 percent) was found at the end of smoke inhalation."	7.68	The pathophysiology of carbon monoxide poisoning and acute respiratory failure in a sheep model with smoke inhalation injury. ( Li, A; Wang, CZ; Yang, ZC, 1990)
"The influence of carbon monoxide (CO) on the development of systemic hypertension was studied in Dahl rats selectively bred for susceptibility (DS) and resistance (DR) to NaCl-induced hypertension."	7.67	Carbon monoxide enhances development of hypertension in Dahl rats. ( Drew, RT; Shiotsuka, RN; Wehner, RW, 1984)
"Hemorrhagic shock was induced in adult male Sprague‑Dawley rats under sevoflurane anesthesia by bleeding using a heparinized syringe to maintain a mean arterial pressure of 30±5 mmHg for 60 min."	5.56	Exogenous carbon monoxide protects against mitochondrial DNA‑induced hippocampal pyroptosis in a model of hemorrhagic shock and resuscitation. ( Fu, L; Gui, CX; Kang, LQ; Kong, XJ; Li, Y; Liu, FH; Song, YC; Wang, XD; Wang, XP; Zhang, DX; Zhang, LM; Zheng, WC, 2020)
"High salt-induced hypertension is relevant to the levels of pro-inflammatory cytokines (PICs) and oxidative stress in the hypothalamic paraventricular nucleus (PVN)."	5.51	Carbon Monoxide Attenuates High Salt-Induced Hypertension While Reducing Pro-inflammatory Cytokines and Oxidative Stress in the Paraventricular Nucleus. ( Chen, YM; Cui, W; Fu, LY; Gao, HL; Kang, KB; Kang, YM; Liang, YF; Liu, KL; Qi, J; Shi, XL; Xin, GR; Yu, XJ; Zhang, DD, 2019)
"Furthermore, in an in vivo study using acute pancreatitis model mice as a model of an inflammatory disease, a CO-HbV treatment also tended to polarize macrophages toward an M2-like phenotype and inhibited neutrophil infiltration in the pancreas, resulting in a significant inflammation."	5.48	Biomimetic carbon monoxide delivery based on hemoglobin vesicles ameliorates acute pancreatitis in mice via the regulation of macrophage and neutrophil activity. ( Maeda, H; Maruyama, T; Nagao, S; Otagiri, M; Sakai, H; Taguchi, K; Wakayama, T; Watanabe, H; Yamasaki, K; Yanagisawa, H, 2018)
" Although this is in line with previous systemic CO dosing protocols, GI muscular inflammation and transit retardation by small intestinal manipulation, performed at 1 h after gavage of 20 tablets, was not prevented while the positive control - intravenous nitrite - prevented POI."	5.48	Investigation of orally delivered carbon monoxide for postoperative ileus. ( Lefebvre, RA; Meinel, L; Steiger, C; Van Dingenen, J; Zehe, M, 2018)
"Preeclampsia is a pregnancy complication which manifests as new-onset hypertension, proteinuria, and a spectrum of other symptoms."	5.46	Carbon Monoxide Releasing Molecules Blunt Placental Ischemia-Induced Hypertension. ( Arany, M; Cockrell, K; Gadepalli, RSV; George, EM; Granger, JP; Rimoldi, JM; Stec, DE, 2017)
"Carbon monoxide (CO) is a gaseous neurotransmitter in the central nervous system that stimulates VP neuronal firing activity."	5.43	A Functional Coupling Between Carbon Monoxide and Nitric Oxide Contributes to Increased Vasopressin Neuronal Activity in Heart Failure rats. ( Biancardi, VC; Reis, WL; Stern, JE; Zhou, Y, 2016)
"To investigate this, we created a hemorrhagic shock model rat, followed by resuscitation with RBC and CO-RBC."	5.40	Carbon monoxide-bound red blood cell resuscitation ameliorates hepatic injury induced by massive hemorrhage and red blood cell resuscitation via hepatic cytochrome P450 protection in hemorrhagic shock rats. ( Ishima, Y; Maruyama, T; Ogaki, S; Otagiri, M; Taguchi, K; Watanabe, H, 2014)
"Even after successful resuscitation, hemorrhagic shock frequently causes pulmonary inflammation that induces acute lung injury (ALI)."	5.39	Inhalation of carbon monoxide following resuscitation ameliorates hemorrhagic shock-induced lung injury. ( Kawanishi, S; Maeda, S; Matsumi, M; Morimatsu, H; Morita, K; Nakao, A; Omori, E; Sato, K; Shimizu, H; Takahashi, T, 2013)
"Carbon monoxide (CO) is an endogenous gaseous regulatory molecule, and exogenously delivered CO in low concentrations provides potent cytoprotection."	5.36	Ex vivo application of carbon monoxide in UW solution prevents transplant-induced renal ischemia/reperfusion injury in pigs. ( Castillo-Rama, M; Echeverri, GJ; Ekser, B; Ezzelarab, M; Faleo, G; Murase, N; Nakao, A; Nalesnik, MA; Ozaki, KS; Ross, MA; Stolz, DB; Ueki, S; Yoshida, J, 2010)
"CO protects against systemic effects of hemorrhagic shock and resuscitation."	5.33	Carbon monoxide prevents multiple organ injury in a model of hemorrhagic shock and resuscitation. ( Billiar, TR; Gallo, D; Ifedigbo, E; Liu, F; McCloskey, CA; Otterbein, LE; Zuckerbraun, BS, 2005)
"Carbon monoxide (CO) has emerged as a potently protective, homeostatic molecule that prevents the development of vascular disorders when administered prophylactically."	5.33	Carbon monoxide reverses established pulmonary hypertension. ( Billiar, TR; Chin, BY; Czsimadia, E; Ifedigbo, E; Kanno, S; Otterbein, LE; Rao, J; Shimoda, L; Wegiel, B; Zuckerbraun, BS, 2006)
"Oxygen therapy is the specific treatment for CO poisoning, but the treatment of CN toxicity is controversial."	5.29	Combined carbon monoxide and cyanide poisoning: a place for treatment. ( Breen, PH; Isserles, SA; Roizen, MF; Taitelman, UZ; Westley, J, 1995)
"The amiodarone-treated animals showed a significant reduction in the coefficient of diffusion (kCO) and a significant increase in lung hydroxyproline levels as compared to the control group."	5.29	Amiodarone-induced pulmonary fibrosis in Fischer 344 rats. ( Gairola, CG; Lai, YL; Reinhart, PG, 1996)
"Pretreatment with pentobarbital Na (30 mg/kg, i."	5.28	Carbon monoxide (CO)-induced hypoxia in mice: evaluation as an experimental model of cerebral ischemia for drug screening. ( Hiramatsu, Y; Kato, Y; Koida, M; Muguruma, K; Nakamuta, H; Ogawa, Y; Yasuda, K, 1989)
"No myocardial infarctions were observed, and the ECG showed a transitory injury current in only one animal."	5.26	Failure of carbon monoxide to induce myocardial infarction in cholesterol-fed cynomolgus monkeys (Macaca fascicularis). ( Dhindsa, DS; Hill, J; Malinow, MR; McLaughlin, P; McNulty, WP; Metcalfe, J; Ochsner, AJ, 1976)
" In the present study, we examined the therapeutic performance of a biomimetic carbon monoxide (CO) delivery system, CO-enriched red blood cells (CO-RBCs), on experimental animal models of an acute kidney injury (AKI) induced by traumatic and nontraumatic rhabdomyolysis, including CS and rhabdomyolysis with massive hemorrhage shock."	3.96	Carbon Monoxide Rescues the Developmental Lethality of Experimental Rat Models of Rhabdomyolysis-Induced Acute Kidney Injury. ( Enoki, Y; Fukagawa, M; Ishima, Y; Maeda, H; Maruyama, T; Matsumoto, K; Nagasaki, T; Nishida, K; Ogaki, S; Ooi, K; Otagiri, M; Sekijima, H; Taguchi, K; Watanabe, H; Yanagisawa, H, 2020)
"BACKGROUND Carbon monoxide (CO) has anti-inflammatory effects and protects the intestinal mucosal barrier in sepsis."	3.96	Carbon Monoxide Inhibits the Expression of Proteins Associated with Intestinal Mucosal Pyroptosis in a Rat Model of Sepsis Induced by Cecal Ligation and Puncture. ( Dong, J; Liu, X; Qin, H; Shao, M; Wang, H; Wu, F; Zhang, H; Zhang, J; Zhang, S; Zhang, W; Zhao, H; Zhao, Y; Zhao, Z, 2020)
" Alternative experimental strategies to reduce oxygen delivery, including breathing carbon monoxide (600 ppm in air) or severe anemia, can reverse neurological disease."	3.91	Leigh Syndrome Mouse Model Can Be Rescued by Interventions that Normalize Brain Hyperoxia, but Not HIF Activation. ( Ast, T; Brepoels, K; Carmeliet, P; Galkin, A; Goldberger, O; Ichinose, F; Jain, IH; Marutani, E; Mootha, VK; Schleifer, G; Schoonjans, L; Stepanova, A; Wang, H; Wojtkiewicz, GR; Zapol, WM; Zazzeron, L, 2019)
"The present study aimed to investigate the effect of carbon monoxide (CO)‑releasing molecule‑2 (CORM‑2) on pancreatic function in sepsis‑model mice."	3.91	Protective effects of carbon monoxide releasing molecule‑2 on pancreatic function in septic mice. ( Liu, Y; Qin, W; Sun, B; Wang, X; Xu, X, 2019)
"The purpose of the present study was to investigate the effect of carbon monoxide (CO) released from CO‑releasing molecule 2 (CORM‑2) on mice with acute pancreatitis (AP)."	3.91	Carbon monoxide releasing molecule‑2 (CORM‑2)‑liberated CO ameliorates acute pancreatitis. ( Liu, Y; Qin, W; Sun, B; Wang, X; Xu, X, 2019)
"Carbon monoxide (CO) releasing molecule (CORM)-3, a water-soluble CORM, has protective effects against inflammatory and ischemia/reperfusion injury."	3.91	Carbon monoxide-releasing molecule-3 protects against cortical pyroptosis induced by hemorrhagic shock and resuscitation via mitochondrial regulation. ( Fu, L; Kong, XJ; Li, CC; Li, Y; Qi, MM; Song, PP; Wang, XD; Wang, XP; Zhang, DX; Zhang, LM, 2019)
"The aim of this study is to investigate the mechanism underling cardiac dysfunction during sepsis, as well as the possible amelioration of this dysfunction by exogenous carbon monoxide (CO) administration."	3.88	The down-regulation of cardiac contractile proteins underlies myocardial depression during sepsis and is mitigated by carbon monoxide. ( Aki, T; Nagano, S; Uemura, K; Unuma, K; Watanabe, R, 2018)
"The discovery of carbon monoxide (CO) and hydrogen sulfide (H2S) as pathogenic signaling molecules in airway-related diseases has led to significant insights into the pathophysiologic mechanisms underlying the development of allergic rhinitis (AR)."	3.81	Impact of carbon monoxide/heme oxygenase on hydrogen sulfide/cystathionine-γ-lyase pathway in the pathogenesis of allergic rhinitis in guinea pigs. ( Che, N; Ge, R; Yan, Z; Yu, S; Zhang, X, 2015)
"Hemin can reduce blood pressure and urinary protein in rats with gestational hypertension possibly by up-regulating HO activity, enhancing carbon monoxide production, reducing sFlt-1 and increasing VEGF in the placental tissue."	3.81	[Therapeutic effect of hemin on gestational hypertension in rats and the mechanism]. ( Cheng, CX; Li, RZ; Long, ML; Xia, AB, 2015)
"Carbon monoxide (CO) has shown various physiological effects including anti-inflammatory activity in several diseases, whereas the therapeutic efficacy of CO on sepsis-induced acute kidney injury (AKI) has not been reported as of yet."	3.81	Exogenous Carbon Monoxide Decreases Sepsis-Induced Acute Kidney Injury and Inhibits NLRP3 Inflammasome Activation in Rats. ( Chang, R; Huang, J; Huang, Z; Li, Y; Lin, J; Wang, P; Wu, H, 2015)
"Inhaled carbon monoxide (CO) appears to have beneficial effects on endotoxemia-induced impairment of hypoxic pulmonary vasoconstriction (HPV)."	3.81	Inhaled carbon monoxide protects time-dependently from loss of hypoxic pulmonary vasoconstriction in endotoxemic mice. ( Busch, CJ; Busch, T; Jahn, N; Kaisers, UX; Koel-Simmelink, MJ; Lamberts, RR; Loer, SA; Oswald, DD; Teunissen, CE; Voelker, MT; Weimann, J, 2015)
"Treatment with a carbon monoxide-releasing molecule (tricarbonyldichlororuthenium(II) dimer, CORM-2) or a classical heme oxygenase 1 inducer (cobalt protoporphyrin IX, CoPP) has potent anti-inflammatory effects, but the role played by these treatments in the antinociceptive effects of morphine during acute and chronic pain was not evaluated."	3.79	Effects of treatment with a carbon monoxide-releasing molecule and a heme oxygenase 1 inducer in the antinociceptive effects of morphine in different models of acute and chronic pain in mice. ( Gou, G; Hervera, A; Leánez, S; Pol, O, 2013)
"Heme oxygenase-1 (HO-1) and its metabolic by-product, carbon monoxide (CO), protect against intestinal inflammation in experimental models of colitis, but little is known about their intestinal immune mechanisms."	3.79	Carbon monoxide and heme oxygenase-1 prevent intestinal inflammation in mice by promoting bacterial clearance. ( Borst, LB; Hansen, JJ; Kobayashi, T; Mackey, LC; Maharshak, N; Moeser, AJ; Onyiah, JC; Otterbein, LE; Plevy, SE; Rawls, JF; Russo, SM; Sheikh, SZ; Steinbach, EC, 2013)
"CORM-3 and CORM-A1 inhibited thrombosis in vivo, however CORM-A1, which slowly releases carbon monoxide, and displayed a relatively weak hypotensive effect had a more pronounced antithrombotic effect associated with a stronger inhibition of platelet aggregation associated with a decrease in active plasminogen activator inhibitor-1 concentration."	3.78	Antithrombotic properties of water-soluble carbon monoxide-releasing molecules. ( Brzoska, T; Buczko, W; Chlopicki, S; Fedorowicz, A; Grochal, E; Kramkowski, K; Leszczynska, A; Mann, B; Mogielnicki, A; Motterlini, R; Urano, T, 2012)
"Clinical reports describe life-threatening cardiac arrhythmias after environmental exposure to carbon monoxide (CO) or accidental CO poisoning."	3.78	Carbon monoxide induces cardiac arrhythmia via induction of the late Na+ current. ( Bernus, O; Boycott, HE; Boyle, JP; Dallas, ML; Duke, A; Elies, J; Milligan, CJ; Peers, C; Reboul, C; Richard, S; Scragg, JL; Steele, DS; Thireau, J; Yang, Z, 2012)
" In this study, we assessed the role of CO donor, methylene chloride (MC), on modulation of lung inflammation during sepsis."	3.76	Methylene chloride protects against cecal ligation and puncture-induced acute lung injury by modulating inflammatory mediators. ( Dou, L; He, J; Pan, X; Pang, Q; Xu, W; Zeng, S; Zeng, Y, 2010)
"To investigate the anti-atherotic effects of heme-L-lysinate in a rabbit model of atherosclerosis and related machanisms."	3.76	[The anti-athetotic effects of heme-L-lysinate in a rabbit model of atherosclerosis]. ( Wang, XB; Wei, WL, 2010)
"Use of metal carbonyl-based compounds capable of releasing carbon monoxide (CO) in biological systems have emerged as a potential adjunctive therapy for sepsis via their antioxidant, anti-inflammatory, and antiapoptotic effects."	3.75	Carbon monoxide rescues mice from lethal sepsis by supporting mitochondrial energetic metabolism and activating mitochondrial biogenesis. ( Decoster, B; Favory, R; Hassoun, SM; Lancel, S; Motterlini, R; Neviere, R, 2009)
"To explore the role of hydrogen sulfide/cystathionine-gamma-lyase (H(2)S/CSE) system in lipopolysaccharide (LPS)- induced acute lung injury (ALI) in rats and the underlying mechanisms."	3.75	[Role of hydrogen sulfide/cystathionine-gamma-lyase system in acute lung injury induced by lipopolysaccharide in rats]. ( Huang, XL; Ling, YL; Tian, FJ; Wei, P; Zhou, XH, 2009)
"The aim of this study is to investigate the effect of heme oxygenase-1 (HO-1)/carbon monoxide (CO) system in pulmonary ischemia-reperfusion injury (PIRI) in rabbits."	3.75	Role of heme oxygenase-1/carbon monoxide system in pulmonary ischemia-reperfusion injury. ( Jia, X; Lin, L; Shi, L; Wang, F; Wang, W, 2009)
"In previous work we have demonstrated that delivery of low concentrations (250 ppm) of carbon monoxide by means of inhalation to donors, recipients, or both protects transplanted lungs from ischemia-reperfusion injury (improved gas exchange, diminished intragraft and systemic inflammation, and retention of graft vascular endothelial cell ultrastructure)."	3.74	Carbon monoxide-saturated preservation solution protects lung grafts from ischemia-reperfusion injury. ( Kohmoto, J; McCurry, KR; Nakao, A; Sugimoto, R; Ueda, H; Wang, Y; Zhan, J, 2008)
"We aimed to investigate the toxicity of carbon monoxide (CO) in rats with right ventricle (RV) remodeling induced by hypoxic pulmonary hypertension (PHT)."	3.74	Continuous inhalation of carbon monoxide induces right ventricle ischemia and dysfunction in rats with hypoxic pulmonary hypertension. ( Antier, D; Bonnet, P; Eder, V; Gautier, M; Hanton, G; Le Net, JL, 2007)
" Potential cerebroprotective vascular effects of CORM-A1 (2 mg/kg ip, 30 min before seizures) were tested 2 days after bicuculline-induced epileptic seizures (late postictal period)."	3.74	Cerebroprotective effects of the CO-releasing molecule CORM-A1 against seizure-induced neonatal vascular injury. ( Fedinec, AL; Leffler, CW; Parfenova, H; Tcheranova, D; Zimmermann, A, 2007)
"To investigate the inhibitory effects of extrinsic carbon monoxide-releasing molecules II on inflammatory responses in liver of mice with severe burns and its potential mechanisms."	3.74	[The inhibitory effects of extrinsic carbon monoxide-releasing molecules II on inflammatory responses in liver of mice with severe burns]. ( Chen, X; Chen, ZY; Gediminas, C; Kazuhiro, K; Sun, BW, 2007)
"Carbon monoxide with hypoxia and hypoxemic hypoxia both result in similar depression of cardiac function."	3.74	Carbon monoxide has direct toxicity on the myocardium distinct from effects of hypoxia in an ex vivo rat heart model. ( Jay, G; Suner, S, 2008)
" The use of tin mesoporphyrin (SnMP) has been proposed for interdicting the development of severe hyperbilirubinemia in a variety of conditions."	3.73	The effectiveness of oral tin mesoporphyrin prophylaxis in reducing bilirubin production after an oral heme load in a transgenic mouse model. ( Contag, CH; DeSandre, GH; Morioka, I; Stevenson, DK; Wong, RJ, 2006)
"Recently, heme oxygenase-carbon monoxide (HO-CO) pathway has been reported to be involved in the development of lipopolysaccharide (LPS) fever."	3.73	Central heme oxygenase-carbon monoxide pathway participates in the lipopolysaccharide-induced tolerance in rats. ( Branco, LG; Dias, MB; Raffaini, MS, 2006)
"To investigate the role of carbon monoxide (CO) in the pathogenesis of asthma."	3.70	[Evidence of increased endogenous carbon monoxide production in asthma]. ( Jiang, D; Li, H; Shi, Y, 1999)
"Effective alveolar volume, diffusing capacity for carbon monoxide (DCOsb), volume-corrected diffusing capacity (D/VA), static lung compliance (Cst), and lung distensibility were measured in 16 sheep seropositive for maedi-visna virus (MVV) immediately before they were killed."	3.69	Pathophysiologic correlations in lymphoid interstitial pneumonia. ( Begara, I; Collie, DD; Luján, L; Warren, PM; Watt, NJ, 1994)
"Pulmonary carbon monoxide (CO) excretion rates (VeCO) were 50% greater, on average, in Bolivian squirrel monkeys (BoSMs) which exhibit a unique fasting hyperbilirubinemia (FH), than in fasted control Brazilian squirrel monkeys (BrSMs)."	3.68	Increased carbon monoxide excretion in Bolivian squirrel monkeys with fasting hyperbilirubinemia. ( Cornelius, CE; Rodgers, PA; Tarkington, BK; Vreman, HJ, 1990)
" Severe carbon monoxide poisoning with fatal levels of HbCO (greater than 50 percent) was found at the end of smoke inhalation."	3.68	The pathophysiology of carbon monoxide poisoning and acute respiratory failure in a sheep model with smoke inhalation injury. ( Li, A; Wang, CZ; Yang, ZC, 1990)
"The influence of carbon monoxide (CO) on the development of systemic hypertension was studied in Dahl rats selectively bred for susceptibility (DS) and resistance (DR) to NaCl-induced hypertension."	3.67	Carbon monoxide enhances development of hypertension in Dahl rats. ( Drew, RT; Shiotsuka, RN; Wehner, RW, 1984)
"The role of increased heme catabolism in neonatal hyperbilirubinemia was investigated in rhesus (Macaca mulatta) neonates through the measurement of carbon monoxide excretion rates (VECO), blood carboxyhemoglobin content (HbCO), and plasma bilirubin concentrations."	3.67	Carbon monoxide excretion as an index of bilirubin production in rhesus monkeys. ( Gale, R; Rodgers, PA; Stevenson, DK; Vreman, HJ, 1989)
"Rats prenatally exposed to a low concentration of carbon monoxide which results in carboxyhemoglobin levels equivalent to those maintained by human cigarette smokers, show reduced birth weight and decreased weight gain."	3.65	Toxicity of mild prenatal carbon monoxide exposure. ( Annau, Z; Fechter, LD, 1977)
"In a porcine model of hemorrhagic shock, the administration of rhIL-11 at the start of resuscitation significantly improved the cardiac output and blood pressure."	2.71	Administration of recombinant interleukin-11 improves the hemodynamic functions and decreases third space fluid loss in a porcine model of hemorrhagic shock and resuscitation. ( Alam, HB; Honma, K; Keith, JC; Koles, NL; Olsen, C; Pollack, M; Rhee, P; Rollwagen, FM, 2005)
" Although the effectiveness of HbVs, including their physicochemical characteristics and pharmacological effects, has been reported, data on the pharmacokinetic properties of HbVs are limited."	2.58	[Safety Evaluation of Cellular-type Artificial Blood Based on Pharmacokinetic Analysis and Its Use in Medical Gas Delivery]. ( Taguchi, K, 2018)
"Carbon monoxide (CO) is a product of HO catalysis of heme."	2.49	Therapeutic applications of carbon monoxide. ( Haslip, M; Knauert, M; Lee, PJ; Vangala, S, 2013)
"Idiopathic pulmonary fibrosis (IPF) is a fatal interstitial lung disease with limited therapeutic options."	1.72	Tartrate-resistant acid phosphatase 5 promotes pulmonary fibrosis by modulating β-catenin signaling. ( Deng, Y; Hu, Y; Liu, J; Wang, Q; Wang, Y; Xiong, W; Xu, Y; Yu, J; Zhang, L; Zhou, Q, 2022)
"Hemorrhagic shock was induced in adult male Sprague‑Dawley rats under sevoflurane anesthesia by bleeding using a heparinized syringe to maintain a mean arterial pressure of 30±5 mmHg for 60 min."	1.56	Exogenous carbon monoxide protects against mitochondrial DNA‑induced hippocampal pyroptosis in a model of hemorrhagic shock and resuscitation. ( Fu, L; Gui, CX; Kang, LQ; Kong, XJ; Li, Y; Liu, FH; Song, YC; Wang, XD; Wang, XP; Zhang, DX; Zhang, LM; Zheng, WC, 2020)
"High salt-induced hypertension is relevant to the levels of pro-inflammatory cytokines (PICs) and oxidative stress in the hypothalamic paraventricular nucleus (PVN)."	1.51	Carbon Monoxide Attenuates High Salt-Induced Hypertension While Reducing Pro-inflammatory Cytokines and Oxidative Stress in the Paraventricular Nucleus. ( Chen, YM; Cui, W; Fu, LY; Gao, HL; Kang, KB; Kang, YM; Liang, YF; Liu, KL; Qi, J; Shi, XL; Xin, GR; Yu, XJ; Zhang, DD, 2019)
"Ischemia reperfusion injury (IRI) is the predominant tissue insult associated with organ transplantation."	1.48	Carbon monoxide protects the kidney through the central circadian clock and CD39. ( Câmara, NOS; Correa-Costa, M; Csizmadia, E; Gallo, D; Gomperts, E; Hauser, CJ; Ji, X; Lieberum, JL; Otterbein, LE; Robson, SC; Wang, B, 2018)
"Furthermore, in an in vivo study using acute pancreatitis model mice as a model of an inflammatory disease, a CO-HbV treatment also tended to polarize macrophages toward an M2-like phenotype and inhibited neutrophil infiltration in the pancreas, resulting in a significant inflammation."	1.48	Biomimetic carbon monoxide delivery based on hemoglobin vesicles ameliorates acute pancreatitis in mice via the regulation of macrophage and neutrophil activity. ( Maeda, H; Maruyama, T; Nagao, S; Otagiri, M; Sakai, H; Taguchi, K; Wakayama, T; Watanabe, H; Yamasaki, K; Yanagisawa, H, 2018)
" Although this is in line with previous systemic CO dosing protocols, GI muscular inflammation and transit retardation by small intestinal manipulation, performed at 1 h after gavage of 20 tablets, was not prevented while the positive control - intravenous nitrite - prevented POI."	1.48	Investigation of orally delivered carbon monoxide for postoperative ileus. ( Lefebvre, RA; Meinel, L; Steiger, C; Van Dingenen, J; Zehe, M, 2018)
"Preeclampsia is a pregnancy complication which manifests as new-onset hypertension, proteinuria, and a spectrum of other symptoms."	1.46	Carbon Monoxide Releasing Molecules Blunt Placental Ischemia-Induced Hypertension. ( Arany, M; Cockrell, K; Gadepalli, RSV; George, EM; Granger, JP; Rimoldi, JM; Stec, DE, 2017)
"Carbon monoxide (CO) is a gaseous neurotransmitter in the central nervous system that stimulates VP neuronal firing activity."	1.43	A Functional Coupling Between Carbon Monoxide and Nitric Oxide Contributes to Increased Vasopressin Neuronal Activity in Heart Failure rats. ( Biancardi, VC; Reis, WL; Stern, JE; Zhou, Y, 2016)
"Hemolytic anemia is a major side effect of ribavirin antiviral treatment for chronic hepatitis C."	1.43	Rapid CO breath test screening of drugs for protective effects on ribavirin-induced hemolysis in a rabbit model: a pilot study. ( Cao, P; Du, LT; Huang, JL; Ji, KM; Ji, YQ; Ma, YJ; Wu, CH; Zang, DY; Zhang, HD; Zhu, GL, 2016)
"Hydrogen (H2) has anti-inflammation, anti-apoptosis, and anti-oxidative stress effects."	1.42	H2 Treatment Attenuated Pain Behavior and Cytokine Release Through the HO-1/CO Pathway in a Rat Model of Neuropathic Pain. ( Chen, H; Chen, Y; Li, Y; Liu, L; Wang, G; Xie, K; Yu, Y, 2015)
"Inhaled carbon monoxide (CO) gas has therapeutic potential for patients with acute respiratory distress syndrome if a safe, evidence-based dosing strategy and a ventilator-compatible CO delivery system can be developed."	1.42	Effects of inhaled CO administration on acute lung injury in baboons with pneumococcal pneumonia. ( Baron, RM; Choi, AM; Davies, JD; Fredenburgh, LE; Harris, RS; Hess, DR; Kraft, BD; Piantadosi, CA; Roggli, VL; Stenzler, A; Suliman, HB; Thompson, BT; Welty-Wolf, KE; Winkler, T; Wolf, MA, 2015)
"To investigate this, we created a hemorrhagic shock model rat, followed by resuscitation with RBC and CO-RBC."	1.40	Carbon monoxide-bound red blood cell resuscitation ameliorates hepatic injury induced by massive hemorrhage and red blood cell resuscitation via hepatic cytochrome P450 protection in hemorrhagic shock rats. ( Ishima, Y; Maruyama, T; Ogaki, S; Otagiri, M; Taguchi, K; Watanabe, H, 2014)
"Acute necrotizing pancreatitis was induced by retrograde intraductal injection of sodium taurocholate in rats."	1.39	Heme oxygenase 1-generated carbon monoxide and biliverdin attenuate the course of experimental necrotizing pancreatitis. ( Berberat, PO; Bergmann, F; Ceyhan, GO; Fischer, L; Friess, H; Giese, N; Künzli, BM; Mitkus, T; Nuhn, P, 2013)
"Carbon monoxide (CO) is an important effector-signaling molecule involved in various pathophysiological processes."	1.39	Low dose of carbon monoxide intraperitoneal injection provides potent protection against GalN/LPS-induced acute liver injury in mice. ( Li, F; Liu, Y; Wen, T; Wen, Z, 2013)
"Carbon monoxide (CO) treatment improves pathogenic outcome of autoimmune diseases by promoting tolerance."	1.39	Carbon monoxide-treated dendritic cells decrease β1-integrin induction on CD8⁺ T cells and protect from type 1 diabetes. ( Anegon, I; Bach, JM; Blancou, P; Piaggio, E; Pogu, S; Rémy, S; Rigaud, K; Simon, T; Tardif, V, 2013)
"Even after successful resuscitation, hemorrhagic shock frequently causes pulmonary inflammation that induces acute lung injury (ALI)."	1.39	Inhalation of carbon monoxide following resuscitation ameliorates hemorrhagic shock-induced lung injury. ( Kawanishi, S; Maeda, S; Matsumi, M; Morimatsu, H; Morita, K; Nakao, A; Omori, E; Sato, K; Shimizu, H; Takahashi, T, 2013)
"Carbon monoxide (250 ppm) was given for 1 hour after termination of CPB."	1.37	Postconditioning of the lungs with inhaled carbon monoxide after cardiopulmonary bypass in pigs. ( Brehm, K; Goebel, U; Loop, T; Priebe, HJ; Schibilsky, D; Schlensak, C; Schwer, CI; Siepe, M, 2011)
"Carbon monoxide (CO) is an endogenous gaseous regulatory molecule, and exogenously delivered CO in low concentrations provides potent cytoprotection."	1.36	Ex vivo application of carbon monoxide in UW solution prevents transplant-induced renal ischemia/reperfusion injury in pigs. ( Castillo-Rama, M; Echeverri, GJ; Ekser, B; Ezzelarab, M; Faleo, G; Murase, N; Nakao, A; Nalesnik, MA; Ozaki, KS; Ross, MA; Stolz, DB; Ueki, S; Yoshida, J, 2010)
"Up to 60% of the mice showed dyspnea, airway obstruction and hypoxemia and died between days 7 and 12 post-infection."	1.36	VEGF promotes malaria-associated acute lung injury in mice. ( Ataíde, R; Campos, MG; Carapau, D; Costa-Silva, A; Dias, S; Epiphanio, S; Félix, N; Marinho, CR; Monteiro, CA; Mota, MM; Pamplona, A; Pena, AC, 2010)
" These studies highlight the complexity of interspecies variation of dose-response relationships of CO to COHb levels and to the anti-inflammatory functions of CO."	1.36	Evaluation of inhaled carbon monoxide as an anti-inflammatory therapy in a nonhuman primate model of lung inflammation. ( Channell, MM; Choi, AM; McDonald, JD; Mitchell, LA; Royer, CM; Ryter, SW, 2010)
"Carbon monoxide (CO) is a biologically active molecule produced in the body by the stress-inducible enzyme, heme oxygenase."	1.35	Carbon monoxide modulates alpha-smooth muscle actin and small proline rich-1a expression in fibrosis. ( Alber, S; Choi, AM; Kaminski, N; Lin, L; Morse, D; Watkins, S; Zheng, L; Zhou, Z, 2009)
"Acute lung injury (ALI) and acute respiratory distress syndrome (ARDS) are major causes of morbidity and mortality in the intensive care unit, but despite continuing research few effective therapies have been identified."	1.33	Effects of inhaled carbon monoxide on acute lung injury in mice. ( Choudhury, S; Falusi, B; Ghosh, S; Goddard, ME; Marczin, N; Takata, M; Wilson, MR; Yamamoto, H, 2005)
"CO protects against systemic effects of hemorrhagic shock and resuscitation."	1.33	Carbon monoxide prevents multiple organ injury in a model of hemorrhagic shock and resuscitation. ( Billiar, TR; Gallo, D; Ifedigbo, E; Liu, F; McCloskey, CA; Otterbein, LE; Zuckerbraun, BS, 2005)
"In a model of acute lung injury in mice, CO blocked expression of Egr-1, a central mediator of inflammation, and decreased tissue damage; inhibition of PPARgamma abrogated both effects."	1.33	Carbon monoxide orchestrates a protective response through PPARgamma. ( Bach, FH; Bilban, M; Chin, BY; d'Avila, JC; Esterbauer, H; Ifedigbo, E; Otterbein, LE; Otterbein, SL; Robson, SC; Usheva, A; Wagner, O, 2006)
"Carbon monoxide (CO) has emerged as a potently protective, homeostatic molecule that prevents the development of vascular disorders when administered prophylactically."	1.33	Carbon monoxide reverses established pulmonary hypertension. ( Billiar, TR; Chin, BY; Czsimadia, E; Ifedigbo, E; Kanno, S; Otterbein, LE; Rao, J; Shimoda, L; Wegiel, B; Zuckerbraun, BS, 2006)
"Sepsis was induced in male Sprague-Dawley rats by cecal ligation and puncture (CLP)."	1.32	Inhibition of heme oxygenase ameliorates sepsis-induced liver dysfunction in rats. ( Iwasashi, H; Kondo, N; Matsuno, S; Oikawa, M; Suzuki, M; Unno, M; Utiyama, T, 2003)
"Carbon monoxide (CO) has long been considered a toxic substance."	1.32	[The effects of inhaled carbon monoxide on lung injury in rats caused by lipopolysaccharide]. ( Fujimoto, J; Kudoh, I; Miyazaki, H; Ohta, M; Tazawa, T; Yamada, H, 2003)
"Human emphysema is a progressive, destructive lung disease that produces morphologic and functional heterogeneity throughout its course."	1.32	Physiologic responses of sheep to two different methods of papain exposure. ( Henderson, AC; Hoffman, A; Ingenito, E; Tsai, L, 2003)
"In models of smoke inhalation injury and carbon monoxide poisoning blood carboxy-hemoglobin (COHb) levels decrease faster than predicted by the generally recognized half-life of COHb."	1.31	Half-life of blood carboxyhemoglobin after short-term and long-term exposure to carbon monoxide. ( Goodwin, CW; Ikeuchi, H; Mason, AD; Pruitt, BA; Shimazu, T; Sugimoto, H, 2000)
"A diffuse nonspecific interstitial pneumonitis was present in lungs of immunodeficient mice, and flow cytometry indicated that both lymphocytes and macrophages were activated."	1.30	Pulmonary mechanical and immunologic dysfunction in a murine model of AIDS. ( Cohen, DA; Gillespie, MN; Hartsfield, CL; Lai, YL; Lipke, D, 1997)
"Oxygen therapy is the specific treatment for CO poisoning, but the treatment of CN toxicity is controversial."	1.29	Combined carbon monoxide and cyanide poisoning: a place for treatment. ( Breen, PH; Isserles, SA; Roizen, MF; Taitelman, UZ; Westley, J, 1995)
" Loss of organic anion accumulation and release into the incubation medium of tubular enzymes, mainly from the soluble fraction, are the toxic effects of the solvent."	1.29	In-vitro mechanisms of 1,2-dichloropropane nephrotoxicity using the renal cortical slice model. ( Maso, S; Meneghetti, P; Trevisan, A; Troso, O, 1993)
"The amiodarone-treated animals showed a significant reduction in the coefficient of diffusion (kCO) and a significant increase in lung hydroxyproline levels as compared to the control group."	1.29	Amiodarone-induced pulmonary fibrosis in Fischer 344 rats. ( Gairola, CG; Lai, YL; Reinhart, PG, 1996)
"Pretreatment with pentobarbital Na (30 mg/kg, i."	1.28	Carbon monoxide (CO)-induced hypoxia in mice: evaluation as an experimental model of cerebral ischemia for drug screening. ( Hiramatsu, Y; Kato, Y; Koida, M; Muguruma, K; Nakamuta, H; Ogawa, Y; Yasuda, K, 1989)
"No myocardial infarctions were observed, and the ECG showed a transitory injury current in only one animal."	1.26	Failure of carbon monoxide to induce myocardial infarction in cholesterol-fed cynomolgus monkeys (Macaca fascicularis). ( Dhindsa, DS; Hill, J; Malinow, MR; McLaughlin, P; McNulty, WP; Metcalfe, J; Ochsner, AJ, 1976)

Timeframe	Studies, this research(%)	All Research%
pre-1990	19 (7.60)	18.7374
1990's	22 (8.80)	18.2507
2000's	78 (31.20)	29.6817
2010's	116 (46.40)	24.3611
2020's	15 (6.00)	2.80

Trial	Phase	Enrollment	Study Type	Start Date	Status
A Phase 2 Multi-center, Randomized, Double-blind, Comparator-Controlled Dose Finding Study to Evaluate MP4CO for the Acute Treatment of Vaso-occlusive Crises in Subjects With Sickle Cell Disease[NCT01925001]	Phase 2	0 participants (Actual)	Interventional	2013-10-31	Withdrawn (stopped due to Sangart ceased operations)
A Phase Ib Trial of Inhaled Carbon Monoxide for the Treatment of Pneumonia and Sepsis-Induced Acute Respiratory Distress Syndrome (ARDS)[NCT04870125]	Phase 1	36 participants (Anticipated)	Interventional	2023-12-06	Recruiting
A Phase II Trial of Inhaled Carbon Monoxide for the Treatment of Acute Respiratory Distress Syndrome (ARDS)[NCT03799874]	Phase 2	32 participants (Anticipated)	Interventional	2019-07-01	Active, not recruiting
An Open-Label, Pilot Study to Evaluate the Safety, Tolerability, and Efficacy of 5-Aminolevulinic Acid Phosphate and Sodium Ferrous Citrate (5-ALA-Phosphate + SFC) in Subjects With SARS-CoV-2 Infection (COVID-19)[NCT04542850]		15 participants (Actual)	Interventional	2020-11-15	Completed
The Effect of Blood Carboxyhemoglobin Levels on Total Antioxidant (Tas), Total Oxidant(Tos), Hypoxia Inducible Factor-1a (hif1a) During Low-flow and Normal-flow Anesthesia[NCT05661045]		130 participants (Anticipated)	Observational	2023-01-02	Not yet recruiting
Comparison of the Concentration of Estrogen and Testosterone Ratio in Male Patients With Cirrhosis and Hypotension Compared to Male Cirrhosis Patients Without Hypotension[NCT05051293]		0 participants (Actual)	Observational	2021-08-22	Withdrawn (stopped due to Study will be changed from prospective to retrospective)
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Article	Year
Carbon monoxide: An emerging therapy for acute kidney injury. Medicinal research reviews, 2020, Volume: 40, Issue:4 Topics: Acute Kidney Injury; Animals; Carbon Monoxide; Clinical Trials as Topic; Disease Models, Animal; Dru	2020
To solve our new emergency care crisis, let's start with the old one. The American journal of emergency medicine, 2020, Volume: 38, Issue:10 Topics: Animals; Argon; Carbon Monoxide; Disease Models, Animal; Emergency Medical Services; Helium; Humans;	2020
The role of carbon monoxide and heme oxygenase in the prevention of sickle cell disease vaso-occlusive crises. American journal of hematology, 2017, Volume: 92, Issue:6 Topics: Anemia, Sickle Cell; Animals; Carbon Monoxide; Clinical Trials as Topic; Disease Models, Animal; Hem	2017
Is hydrogen sulfide a potential novel therapy to prevent renal damage during ureteral obstruction? Nitric oxide : biology and chemistry, 2018, 02-28, Volume: 73 Topics: Animals; Carbon Monoxide; Disease Models, Animal; Fibrosis; Gasotransmitters; Humans; Hydrogen Sulfi	2018
Could Heme Oxygenase-1 Be a New Target for Therapeutic Intervention in Malaria-Associated Acute Lung Injury/Acute Respiratory Distress Syndrome? Frontiers in cellular and infection microbiology, 2018, Volume: 8 Topics: Acute Lung Injury; Animals; Capillary Permeability; Carbon Monoxide; Cytokines; Disease Models, Anim	2018
[Safety Evaluation of Cellular-type Artificial Blood Based on Pharmacokinetic Analysis and Its Use in Medical Gas Delivery]. Yakugaku zasshi : Journal of the Pharmaceutical Society of Japan, 2018, Volume: 138, Issue:11 Topics: Acute Disease; Animals; Blood Substitutes; Carbon Monoxide; Disease Models, Animal; Drug Carriers; D	2018
Gaseous therapeutics in acute lung injury. Comprehensive Physiology, 2011, Volume: 1, Issue:1 Topics: Acute Lung Injury; Administration, Inhalation; Animals; Carbon Monoxide; Disease Models, Animal; Hum	2011
The health effects of exercising in air pollution. Sports medicine (Auckland, N.Z.), 2014, Volume: 44, Issue:2 Topics: Air Pollution; Animals; Carbon Monoxide; Cardiovascular Diseases; Cognition Disorders; Disease Model	2014
Therapeutic applications of carbon monoxide. Oxidative medicine and cellular longevity, 2013, Volume: 2013 Topics: Animals; Carbon Monoxide; Clinical Trials as Topic; Disease Models, Animal; Humans	2013
Redox mechanisms of the beneficial effects of heme oxygenase in hypertension. Journal of hypertension, 2014, Volume: 32, Issue:7 Topics: Animals; Bilirubin; Biliverdine; Carbon Monoxide; Disease Models, Animal; Heme Oxygenase-1; Humans;	2014
Heme oxygenase-1 as a target for the design of gene and pharmaceutical therapies for autoimmune diseases. Current gene therapy, 2014, Volume: 14, Issue:3 Topics: Animals; Autoimmune Diseases; Carbon Monoxide; Cell Survival; Disease Models, Animal; Gene Targeting	2014
Localized delivery of carbon monoxide. European journal of pharmaceutics and biopharmaceutics : official journal of Arbeitsgemeinschaft fur Pharmazeutische Verfahrenstechnik e.V, 2017, Volume: 118 Topics: Administration, Cutaneous; Administration, Inhalation; Administration, Oral; Animals; Biliverdine; C	2017
A central role for free heme in the pathogenesis of severe malaria: the missing link? Journal of molecular medicine (Berlin, Germany), 2008, Volume: 86, Issue:10 Topics: Animals; Carbon Monoxide; Disease Models, Animal; Heme; Heme Oxygenase-1; Hemoglobins; Humans; Malar	2008
Regulation of vulnerable plaque development by the heme oxygenase/carbon monoxide system. Trends in cardiovascular medicine, 2010, Volume: 20, Issue:2 Topics: Animals; Carbon Monoxide; Coronary Artery Disease; Disease Models, Animal; Heme Oxygenase (Decyclizi	2010
The role of heme oxygenase and carbon monoxide in inflammatory bowel disease. Redox report : communications in free radical research, 2010, Volume: 15, Issue:5 Topics: Animals; Carbon Monoxide; Disease Models, Animal; Enzyme Activation; Gastrointestinal Tract; Heme Ox	2010
The hyperdynamic circulation of chronic liver diseases: from the patient to the molecule. Hepatology (Baltimore, Md.), 2006, Volume: 43, Issue:2 Suppl 1 Topics: Adrenomedullin; Animals; Biological Factors; Blood Pressure; Cannabinoid Receptor Modulators; Carbon	2006
Therapeutic applications of carbon monoxide in lung disease. Current opinion in pharmacology, 2006, Volume: 6, Issue:3 Topics: Administration, Inhalation; Animals; Anti-Inflammatory Agents; Apoptosis; Asthma; Bleomycin; Carbon	2006
[Hypertension in obese Zucker rat]. Nihon rinsho. Japanese journal of clinical medicine, 2006, Volume: 64 Suppl 5 Topics: Animals; Carbon Monoxide; Disease Models, Animal; Hypertension; Insulin Resistance; Leptin; Natriure	2006
The heme oxygenase-carbon monoxide system: regulation and role in stress response and organ failure. Intensive care medicine, 2008, Volume: 34, Issue:4 Topics: Animals; Carbon Monoxide; Critical Illness; Disease Models, Animal; Gene Expression Regulation, Enzy	2008
Carbon monoxide: innovative anti-inflammatory properties of an age-old gas molecule. Antioxidants & redox signaling, 2002, Volume: 4, Issue:2 Topics: Allergens; Animals; Anti-Inflammatory Agents, Non-Steroidal; Carbon Monoxide; Cell Hypoxia; Disease	2002
Atherosclerosis in new world monkeys. Primates in medicine, 1976, Volume: 9 Topics: Age Factors; Alouatta; Animals; Aorta; Arteriosclerosis; Callitrichinae; Carbon Monoxide; Cholelithi	1976

carbon monoxide and Disease Models, Animal

Research Excerpts

Research

Studies (250)

Authors

Clinical Trials (6)

Trial Overview

Reviews

Trials

Other Studies

Authors	Studies
Watabe, Y	1
Taguchi, K	6
Sakai, H	4
Enoki, Y	2
Maruyama, T	5
Otagiri, M	5
Kohno, M	1
Matsumoto, K	2
Hu, Y	1
Wang, Q	1
Yu, J	2
Zhou, Q	1
Deng, Y	1
Liu, J	1
Zhang, L	1
Xu, Y	1
Xiong, W	1
Wang, Y	2
Xu, Q	1
Rose, JJ	1
Chen, X	3
Wang, L	1
DeMartino, AW	1
Dent, MR	1
Tiwari, S	1
Bocian, K	1
Huang, XN	1
Tong, Q	1
McTiernan, CF	1
Guo, L	1
Alipour, E	1
Jones, TC	1
Ucer, KB	1
Kim-Shapiro, DB	1
Tejero, J	1
Gladwin, MT	1
Xue, Y	1
Zhang, D	1
Wei, Y	1
Guo, C	1
Song, B	1
Cui, Y	1
Zhang, C	1
Xu, D	1
Zhang, S	2
Fang, J	3
Jain, IH	1
Zazzeron, L	2
Goldberger, O	1
Marutani, E	1
Wojtkiewicz, GR	1
Ast, T	1
Wang, H	5
Schleifer, G	1
Stepanova, A	1
Brepoels, K	1
Schoonjans, L	1
Carmeliet, P	1
Galkin, A	1
Ichinose, F	1
Zapol, WM	2
Mootha, VK	1
Yang, X	1
de Caestecker, M	1
Otterbein, LE	15
Wang, B	2
Ogaki, S	2
Nagasaki, T	1
Yanagisawa, H	2
Nishida, K	1
Maeda, H	5
Sekijima, H	1
Ooi, K	1
Ishima, Y	2
Watanabe, H	4
Fukagawa, M	1
Joe, Y	6
Chen, Y	6
Park, J	3
Kim, HJ	4
Rah, SY	1
Ryu, J	2
Cho, GJ	3
Choi, HS	1
Ryter, SW	11
Park, JW	2
Kim, UH	3
Chung, HT	6
Fu, L	2
Zhang, DX	2
Zhang, LM	2
Song, YC	1
Liu, FH	1
Li, Y	6
Wang, XP	2
Zheng, WC	1
Wang, XD	2
Gui, CX	1
Kong, XJ	2
Kang, LQ	1
Kim, J	2
Song, HC	1
Zheng, M	2
Surh, YJ	3
Zhao, H	1
Qin, H	2
Zhang, J	1
Dong, J	1
Zhang, H	1
Liu, X	1
Zhao, Z	1
Zhao, Y	1
Shao, M	1
Wu, F	1
Zhang, W	2
Baugh, JJ	1
White, BA	1
Biddinger, PD	1
Raja, AS	1
Wittbold, KA	1
Sonis, JD	1
Yun, BJ	1
Sakihama, H	1
Lee, GR	1
Chin, BY	3
Csizmadia, E	3
Gallo, D	6
Qi, Y	1
Gagliani, N	1
Bach, FH	3
Jiang, M	1
Deng, Z	1
Zeng, S	2
Hao, J	1
Iqbal, J	1
Chamberlain, J	1
Alfaidi, M	1
Hughes, M	1
Alizadeh, T	1
Casbolt, H	1
Evans, P	1
Mann, B	2
Motterlini, R	9
Francis, S	1
Gunn, J	1
Gomperts, E	3
Belcher, JD	4
Coates, TD	1
Wood, J	1
Skolnick, BE	1
Levy, H	2
Vercellotti, GM	4
George, EM	1
Cockrell, K	1
Arany, M	1
Stec, DE	2
Rimoldi, JM	1
Gadepalli, RSV	1
Granger, JP	1
Kim, SK	2
Park, SU	1
Ha, Y	1
Lee, Y	1
Suh, M	1
Crocker, GH	1
Kwon, J	1
Kass, PH	1
Jones, JH	1
Mangano, K	1
Cavalli, E	1
Mammana, S	1
Basile, MS	1
Caltabiano, R	1
Pesce, A	1
Puleo, S	1
Atanasov, AG	1
Magro, G	1
Nicoletti, F	1
Fagone, P	1
Unuma, K	1
Aki, T	1
Nagano, S	1
Watanabe, R	1
Uemura, K	1
Lin, S	1
Juriasingani, S	1
Sener, A	1
Wu, J	4
Zhang, R	1
Hu, G	1
Zhu, HH	1
Gao, WQ	1
Xue, J	1
Correa-Costa, M	1
Lieberum, JL	1
Hauser, CJ	1
Ji, X	1
Câmara, NOS	1
Robson, SC	2
Chen, C	3
Nguyen, J	3
Abdulla, F	2
Zhang, P	1
Nguyen, H	1
Nguyen, P	1
Killeen, T	1
Miescher, SM	1
Brinkman, N	1
Nath, KA	1
Steer, CJ	1
Nagao, S	2
Yamasaki, K	2
Wakayama, T	2
Pereira, MLM	1
Marinho, CRF	1
Epiphanio, S	3
Serban, KA	1
Petrache, I	1
Van Dingenen, J	1
Steiger, C	3
Zehe, M	1
Meinel, L	3
Lefebvre, RA	1
Kiser, ZM	1
Nikam, A	1
Manin, S	1
Ollivier, A	1
Wilson, JL	1
Djouadi, S	1
Muchova, L	2
Martens, T	1
Rivard, M	1
Foresti, R	2
McRae, KE	1
Peterson, N	1
Dickson, MA	1
Smith, GN	2
Zheng, G	1
Zhan, Y	1
Luo, Z	1
Zheng, F	1
Zhou, Y	2
Wu, Y	2
Wang, S	1
Xiang, G	1
Xu, C	1
Xu, H	1
Tian, N	1
Zhang, X	2
Wollborn, J	1
Ruetten, E	1
Benk, C	1
Kari, FA	1
Wunder, C	3
Buerkle, H	2
Schick, MA	2
Goebel, U	4
Liu, Y	3
Wang, X	6
Xu, X	2
Qin, W	2
Sun, B	2
Slawik, A	1
Platt, N	1
Urban, JT	1
Yang, P	1
Huang, Y	1
Lu, S	1
Xu, F	1
Zhang, DD	1
Liang, YF	1
Qi, J	1
Kang, KB	1
Yu, XJ	1
Gao, HL	1
Liu, KL	1
Chen, YM	1
Shi, XL	1
Xin, GR	1
Fu, LY	1
Kang, YM	1
Cui, W	1
Qi, MM	1
Li, CC	1
Song, PP	1
Hervera, A	1
Gou, G	1
Leánez, S	1
Pol, O	1
Collino, M	1
Pini, A	1
Mugelli, N	1
Mastroianni, R	1
Bani, D	1
Fantozzi, R	1
Papucci, L	1
Fazi, M	1
Masini, E	2
Wang, QM	1
Yin, XY	1
Duan, ZJ	1
Guo, SB	1
Sun, XY	1
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Suzuki, H	1
Fukuta, T	1
Muguruma, K	2
Nakamuta, H	2
Tsuji, M	1
Yanagita, K	1
Koida, M	2
Manno, K	1
Narama, I	1
Ogawa, Y	2
Hiramatsu, Y	2
Vasil'ev, GA	1
Khaĭtsev, NV	1
Doolittle, DJ	1
Rahn, CA	1
Lee, CK	1
Rodgers, PA	2
Cornelius, CE	1
Vreman, HJ	2
Tarkington, BK	1
Gering, SA	1
Folts, JD	1
Wang, CZ	1
Li, A	1
Yang, ZC	1
Yasuda, K	1
Kato, Y	1
Gale, R	1
Young, JS	1
Upchurch, MB	1
Kaufman, MJ	1
Demaria Pesce, VH	1
Stupfel, M	1
Gourlet, V	1
Lemercerre, C	1
Bloch, WN	1
Lewis, TR	1
Busch, KA	1
Orthoefer, JG	1
Stara, JF	1
Pushpakom, R	1
Hogg, JC	1
Woolcock, AJ	1
Angus, AE	1
Macklem, PT	1
Thurlbeck, WM	1
Bertranou, E	1
Bourassa, MG	1
Grondin, P	1