propofol and Disease Models, Animal studies

Propofol: An intravenous anesthetic agent which has the advantage of a very rapid onset after infusion or bolus injection plus a very short recovery period of a couple of minutes. (From Smith and Reynard, Textbook of Pharmacology, 1992, 1st ed, p206). Propofol has been used as ANTICONVULSANTS and ANTIEMETICS.
propofol : A phenol resulting from the formal substitution of the hydrogen at the 2 position of 1,3-diisopropylbenzene by a hydroxy group.

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

Research Excerpts

Excerpt	Relevance	Reference
"Propofol has recently attracted increasing attention for its anti-tumor property in cancers, including glioma."	8.31	Propofol Suppresses Glioma Tumorigenesis by Regulating circ_0047688/miR-516b-5p/IFI30 Axis. ( Li, J; Li, Y; Liu, Y; Shu, Y; Zhang, J, 2023)
" Here we aim to explore the immunomodulatory roles of two common anesthetics, propofol and sevoflurane in breast cancer progression."	8.31	Immunomodulatory roles of propofol and sevoflurane in murine models of breast cancer. ( Ma, X; Song, T; Tian, J; Wang, W; Yan, R, 2023)
"Acute ischemic stroke is associated with pulmonary complications, and often dexmedetomidine and propofol are used to decrease cerebral metabolic rate."	8.02	Comparative effects of dexmedetomidine and propofol on brain and lung damage in experimental acute ischemic stroke. ( Antunes, MA; Battaglini, D; Cruz, FF; da Silva, CM; Fernandes, MV; Pelosi, P; Robba, C; Rocco, PRM; Samary, CS; Silva, PL; Sousa, GC; Takyia, C, 2021)
"Propofol (PPF) is reported to play a protective role in ischemia/reperfusion (I/R) injury, including cerebral ischemia-reperfusion injury (CIRI)."	8.02	Propofol Downregulates lncRNA MALAT1 to Alleviate Cerebral Ischemia-Reperfusion Injury. ( Chen, J; Cheng, S; Hu, Y; Ye, C, 2021)
"The aim of this study was to investigate the effects of propofol on intestinal ischemia-reperfusion injury in rats through the nuclear factor-kappa B (NF-κB) pathway."	7.96	Propofol improves intestinal ischemia-reperfusion injury in rats through NF-κB pathway. ( Cui, SM; He, SC; Ma, B; Wu, MB; Zhang, TX; Zhao, K, 2020)
"There is conflicting evidence regarding the impact of propofol on cardiac repolarization and the risk of torsade de pointes (TdP)."	7.96	Propofol abolishes torsade de pointes in different models of acquired long QT syndrome. ( Dechering, DG; Eckardt, L; Ellermann, C; Frommeyer, G; Könemann, H; Rath, B; Reinke, F; Wegner, FK; Willy, K; Wolfes, J, 2020)
"Propofol significantly reduces neurological dysfunction, BBB permeability, brain edema, inflammation, and oxidative stress, all of which were reversed by LY294002."	7.91	Propofol Reduces Inflammatory Brain Injury after Subarachnoid Hemorrhage: Involvement of PI3K/Akt Pathway. ( Chen, Q; Shi, SS; Tu, XK; Zhang, HB, 2019)
"BACKGROUND This study aimed to investigate the molecular mechanisms associated with the effects of propofol in a rat model of pain due to inflammation following subcutaneous injection with complete Freund's adjuvant (CFA)."	7.91	The Molecular Mechanisms Associated with the Effects of Propofol in a Rat Model of Pain Due to Inflammation Following Injection with Complete Freund's Adjuvant. ( Liu, H; Tan, S; Wang, Y; Zhu, S, 2019)
"Both propofol and sevoflurane attenuated the extent of hepatic ischemia/reperfusion injury which is evident from the hisopathological studies and alterations in liver enzymes such as AST and LDH by inhibiting Nuclear factor kappa B (NFx03BA;B) activation and subsequent alterations in inflammatory cytokines interleukin-1(IL-1), interleukin-6(IL-6), tumor necrosis factor-alpha (TNF-α) and increased IL10 release."	7.83	The Effects of Two Anesthetics, Propofol and Sevoflurane, on Liver Ischemia/Reperfusion Injury. ( Qi, F; Wang, H; Wang, Z; Wu, J; Xu, Z; Yu, J, 2016)
"Propofol is a commonly used intravenous anesthetic that has been demonstrated to be neuroprotective against cerebral ischemia-reperfusion (I/R) injury."	7.81	Propofol prevents neuronal mtDNA deletion and cerebral damage due to ischemia/reperfusion injury in rats. ( Chang, FF; Dong, H; Liu, Y; Lu, SJ; Qian, H; Song, CY; Wang, YF; Yang, WC; Yue, ZY, 2015)
"It has been shown in our previous study that propofol postconditioning enhanced the activity of phosphatidylinositol-3-kinase (PI3K) and prevented the internalization of GluR2 subunit of α-amino-3-hydroxyl-5-methyl-4-isoxazolepropionic acid (AMPA) receptors, thus provided neuroprotection in cerebral ischemia/reperfusion (I/R) injury."	7.81	The effect of propofol postconditioning on the expression of K(+)-Cl(-)-co-transporter 2 in GABAergic inhibitory interneurons of acute ischemia/reperfusion injury rats. ( Liu, S; Wang, G; Wang, H; Zhu, A, 2015)
"This is the first study to assess prolonged effects of sepsis and long-term application of volatile sedatives compared to propofol on survival, cardiovascular, inflammatory and end organ parameters."	7.81	Propofol increases morbidity and mortality in a rat model of sepsis. ( Beck-Schimmer, B; Bonini, MG; Dull, RO; Mao, M; Minshall, RD; Piegeler, T; Schläpfer, M; Schwartz, DE; Z'Graggen, BR, 2015)
"This study aimed to investigate whether propofol pretreatment can protect against liver transplantation-induced acute lung injury (ALI) and to explore whether Nrf2 pathway is involved in the protections provided by propofol pretreatment."	7.80	Propofol activation of the Nrf2 pathway is associated with amelioration of acute lung injury in a rat liver transplantation model. ( Chi, X; Hei, Z; Luo, G; Xia, Z; Yao, W; Zhang, A; Zhu, G, 2014)
"To observe the effects of continuous sedation with propofol on peripheral blood mononuclear cell (PBMC) and intercellular adhesion molecule 1 (ICAM-1) in beagles with combined burn-blast injuries."	7.80	[Effects of continuous sedation with propofol on peripheral blood mononuclear cell and intercellular adhesion molecule in beagles with combined burn-blast injuries]. ( Hou, Y; Hu, Q; Liu, L; Luo, H; Wang, Y; Yang, H, 2014)
"We evaluated whether the short-term use of dexmedetomidine and propofol may attenuate inflammatory response and improve lung morphofunction in experimental acute lung injury (ALI)."	7.80	Effects of short-term propofol and dexmedetomidine on pulmonary morphofunction and biological markers in experimental mild acute lung injury. ( Araújo, MN; Cavalcanti, V; Fernandes, FC; Heil, LB; Morales, MM; Pelosi, P; Rocco, PR; Samary, CS; Santos, CL; Silva, PL; Villela, N, 2014)
"Sixty rats were randomly assigned to four groups: normoglycemia-etomidate, normoglycemia-propofol, hyperglycemia-etomidate, and hyperglycemia-propofol."	7.79	Propofol attenuates renal ischemia-reperfusion injury aggravated by hyperglycemia. ( Jun, JH; Kwak, YL; Lim, BJ; Shim, JK; Yoo, KJ; Yoo, YC, 2013)
" Propofol's disadvantages include the induction of respiratory depression and apnea."	7.79	Coadministration of the AMPAKINE CX717 with propofol reduces respiratory depression and fatal apneas. ( Ding, X; Greer, JJ; Lenal, F; Ren, J; Yang, M, 2013)
"The goal of this study was to confirm whether or not sevoflurane is more effective than propofol in ameliorating the inflammatory response in an animal model of acute respiratory distress syndrome."	7.79	Sevoflurane, but not propofol, reduces the lung inflammatory response and improves oxygenation in an acute respiratory distress syndrome model: a randomised laboratory study. ( Aguilar, G; Belda, FJ; Ferrando, C; Moreno, J; Piqueras, L; Soro, M, 2013)
"This experimental study aimed to investigate the antioxidant effects of propofol anesthesia at induction doses in a rat skeletal muscle ischemia/reperfusion injury model."	7.78	Antioxidant effects of propofol on tourniquet-induced ischemia-reperfusion injury: an experimental study. ( Bostan, B; Erkorkmaz, U; Ozkan, F; Ozyurt, H; Senayli, Y, 2012)
" To test our hypothesis that anesthetics interact with the intrinsic parameters of ECT to differentially regulate its therapeutic efficacy, we investigated the effects of the anesthetic propofol and the stimulus intensities of ECT on behavior and hippocampal brain-derived neurotrophic factor (BDNF) in a rodent model of depression."	7.78	Propofol interacts with stimulus intensities of electroconvulsive shock to regulate behavior and hippocampal BDNF in a rat model of depression. ( Liu, Y; Luo, J; Min, S; Wei, K; Zhang, J, 2012)
"Propofol has been demonstrated to improve hepatic perfusion in a rabbit model; however, the effects of propofol on hepatic ischemia/reperfusion injury are unknown."	7.78	Propofol attenuates hepatic ischemia/reperfusion injury in an in vivo rabbit model. ( Luo, CZ; McCluskey, SA; Pang, QY; Ye, L; Zhu, T, 2012)
"Monitoring of exhaled pentane may be useful for evaluating the severity of hepatic ischemia-reperfusion injury and aid in predicting the outcome; propofol may improve the outcome in this situation."	7.78	Breath pentane as a potential biomarker for survival in hepatic ischemia and reperfusion injury--a pilot study. ( Gong, Y; He, Y; Li, E; Li, J; Li, P; Liu, D; Liu, S; Luo, A; Shi, J; Sun, B; Wang, C; Xu, G, 2012)
"To explore the effects of propofol on the outcomes of rats with sepsis."	7.77	Effects of propofol on the outcomes of rats with sepsis. ( Bao, HG; Li, S, 2011)
"To observe the influence of propofol on corticosteroid, and cytokines in rats after hemorrhagic shock and resuscitation, as well as its protective effects on vital organs."	7.75	[The influences of propofol on corticosteroid and immunity of rats after hemorrhagic shock and resuscitation]. ( Cao, SH; Ji, X, 2009)
" Although its mechanism of smooth muscle relaxation is unknown, propofol has been associated with less bronchoconstriction during anaesthetic induction."	7.74	Investigation of the relaxant effects of propofol on ovalbumin-induced asthma in guinea pigs. ( Bagcivan, I; Cevit, O; Gursoy, S; Kaya, T; Mimaroglu, C; Yildirim, MK; Yildirim, S, 2007)
"We previously found that propofol attenuated the mortality rate and inflammatory responses during endotoxemia in rats; however, whether propofol retains its antiinflammatory effects during hypothermia has not been determined."	7.74	The antiinflammatory effects of propofol in endotoxemic rats during moderate and mild hypothermia. ( Kanakura, H; Taniguchi, T, 2007)
"We have previously demonstrated, in the isolated rat heart, that propofol attenuates hydrogen peroxide-induced damage and ischaemia-reperfusion injury, and that the beneficial effect of propofol is correlated with reduction of the lipid peroxidation."	7.74	Propofol attenuates ischaemia-reperfusion injury in the rat heart in vivo. ( Kobayashi, I; Kokita, N; Namiki, A, 2008)
"To study the therapeutic effect and its mechanisms of propofol on gastric mucosal injury after hemorrhagic shock with reperfusion in rabbits."	7.74	[Effect of propofol on gastric mucosal injury after hemorrhagic shock and reperfusion in rabbits]. ( Li, HY; Lü, YX; Wang, LL; Zhang, LF, 2008)
"To explore whether propofol plays a protective role in kidney injury during acute respiratory distress syndrome (ARDS) by affecting the expression of Gq/11 protein."	7.73	[Influence of propofol on Gq/11 protein in kidney during acute respiratory distress syndrome]. ( Abasi, K; Jialili, A; Li, XJ; Zhang, L, 2006)
"Although TIVA is less prone than isoflurane anaesthesia to primary cardiovascular depression leading to asphyxia, TIVA is associated with reduced effectiveness of CPR in which resuscitation because of asphyxic haemodynamic depression occurs."	7.72	Comparison of isoflurane and propofol-fentanyl anaesthesia in a swine model of asphyxia. ( Kazama, T; Kurita, T; Morita, K; Sato, S, 2003)
"Propofol in this model was more arrhythmogenic than thiopental, as manifested by a longer duration of induced arrhythmias, particularly AFI."	7.72	Comparative effects of thiopental and propofol on atrial vulnerability: electrophysiological study in a porcine model including acute alcoholic intoxication. ( Almendral, J; Anadón, MJ; González, P; Navia, J; Zaballos, M, 2004)
"Intrathecal administration of propofol had analgesic effects on inflammation-induced acute and facilitated pain but not on thermally-induced acute pain."	7.72	Intrathecal propofol has analgesic effects on inflammation-induced pain in rats. ( Hanaoka, K; Matsukawa, T; Nishiyama, T, 2004)
"To compare the effects of pentobarbital and propofol on the outcome of focal cerebral ischemia model, and to evaluate the availability of propofol in setting the focal cerebral ischemia."	7.72	[Comparison of pentobarbital and propofol on the outcome of focal cerebral ischemia model in rats]. ( Kang, QY; Li, J; Liu, Y; Zhang, PB; Zhao, JJ, 2004)
"We investigated the effects of selective and non-selective endothelin (ET) antagonists on warm ischemia-reperfusion injury of the early phase in the murine liver under propofol anesthesia."	7.70	[Effects of endothelin antagonists on isolated perfused murine livers in the early phase of warm ischemia-reperfusion injury under propofol anesthesia]. ( Karasawa, F; Sato, T; Tanaka, K, 1999)
"It has been suggested that propofol has the protective effect on cerebral ischemia-reperfusion injury."	7.70	Effectiveness of propofol pretreatment on the extent of deranged cerebral mitochondrial oxidative enzyme system after incomplete forebrain ischemia/reperfusion in rats. ( Chung, C; Lee, Y; Oh, YS, 2000)
"Propofol is an intravenous anesthetic that is commonly used during intravascular embolectomy following acute ischemic stroke."	5.56	Propofol Attenuates α-Synuclein Aggregation and Neuronal Damage in a Mouse Model of Ischemic Stroke. ( Cui, V; Tian, D; Wang, H; Wang, Y; Wei, C; Wu, A; Yue, Y; Zhu, Y, 2020)
"Propofol was injected for anesthesia (n = 22)."	5.48	The recovery from transient cognitive dysfunction induced by propofol was associated with enhanced autophagic flux in normal healthy adult mice. ( Baik, HJ; Cho, S; Han, JI; Jung, YJ; Lee, GY; Lee, KE; Suh, EC, 2018)
"Propofol is an intravenous sedative-hypnotic agent that is commonly used to induce and maintain general anaesthesia."	5.43	Effects of Propofol on Oxidative Stress Parameters in Selected Parts of the Brain in a Rat Model of Parkinson Disease. ( Birkner, E; Chwalińska, E; Hudziec, E; Nowak, P; Prudel, B; Romuk, E; Skowron, M; Szczurek, W, 2016)
"Propofol is a short-acting, intravenous general anesthetic that is widely used in clinical practice for short procedures; however, it causes depressed cognitive function for several hours thereafter."	5.40	(R)-alpha-methylhistamine suppresses inhibitory neurotransmission in hippocampal CA1 pyramidal neurons counteracting propofol-induced amnesia in rats. ( Cheng, LZ; Li, WW; Raya, AD; Shi, XY; Tian, ML; Wang, Y; Zhang, H; Zou, Z, 2014)
"Propofol treatment reduced infarct volume and improved the neurological functions."	5.39	Propofol protects against focal cerebral ischemia via inhibition of microglia-mediated proinflammatory cytokines in a rat model of experimental stroke. ( Liu, F; Tan, Y; Tang, X; Wu, X; Yang, Z; Zhou, R, 2013)
"Pretreatment with propofol significantly decreased writhing responses induced by visceral pain, suppressed the visceral pain-induced aspartate and glutamate release, and reversed the decreased release of γ-amino butyric acid in the cerebrospinal fluid."	5.36	Effects of anesthetic propofol on release of amino acids from the spinal cord during visceral pain. ( Fang, L; Liu, Y; Mu, X; Wang, Y; Wu, A; Wu, J; Yue, Y; Zhang, Y, 2010)
"Propofol has inhibited the hepatic NF-kappaB activation and the pro-inflammatory cytokine response during polymicrobial sepsis in rats."	5.35	Effects of propofol on pro-inflammatory cytokines and nuclear factor kappaB during polymicrobial sepsis in rats. ( Li, JG; Liang, H; Song, XM; Wang, CY; Wang, YL; Zhang, ZZ; Zhou, Q, 2009)
"Rats underwent 2 h of middle cerebral artery occlusion (MCAO) followed by 22 h of reperfusion were randomly divided into nine groups (n=15 each): sham-operated group, MCAO group, propofol 10, 20 and 35 mg x kg(-1) x h(-1) group (propofol 10, 20, 35 mg x kg(-1) x h(-1) infused at the onset of reperfusion for 30 min), wortmannin group (wortmannin 0."	5.35	The role of phosphoinositide-3-kinase/Akt pathway in propofol-induced postconditioning against focal cerebral ischemia-reperfusion injury in rats. ( Wang, GL; Wang, HY; Wang, Y; Yu, YH, 2009)
"Propofol has been demonstrated to ameliorate cerebral ischemic injury and attenuate changes in multiple links of molecular reaction included in the paths to apoptosis."	5.35	Effect of propofol on pathologic time-course and apoptosis after cerebral ischemia-reperfusion injury. ( Chen, L; Jiang, H; Xue, Z, 2008)
"Status epilepticus is commonly refractory to first-line therapy, and thus better treatments are needed."	5.31	Propofol in subanesthetic doses terminates status epilepticus in a rodent model. ( Holtkamp, M; Tong, X; Walker, MC, 2001)
" Morphine, pethidine and fentanyl, which showed a biphasic dose-response relationship with respect to seizure modulation, abolished the anticonvulsant activity of propofol to exhibit their own intrinsic activity in proconvulsant doses."	5.29	Interactions between opioid drugs and propofol in laboratory models of seizures. ( Ahmad, I; Pleuvry, BJ, 1995)
"Propofol has recently attracted increasing attention for its anti-tumor property in cancers, including glioma."	4.31	Propofol Suppresses Glioma Tumorigenesis by Regulating circ_0047688/miR-516b-5p/IFI30 Axis. ( Li, J; Li, Y; Liu, Y; Shu, Y; Zhang, J, 2023)
" Here we aim to explore the immunomodulatory roles of two common anesthetics, propofol and sevoflurane in breast cancer progression."	4.31	Immunomodulatory roles of propofol and sevoflurane in murine models of breast cancer. ( Ma, X; Song, T; Tian, J; Wang, W; Yan, R, 2023)
"Sedation with propofol or dexmedetomidine starting at return of spontaneous circulation improved survival in hypothermia-treated mice (propofol [13 of 16, 81%] vs."	4.12	Post-cardiac arrest Sedation Promotes Electroencephalographic Slow-wave Activity and Improves Survival in a Mouse Model of Cardiac Arrest. ( Amorim, E; Ichinose, F; Ikeda, T; Kato, R; Malhotra, R; Marutani, E; Miyazaki, Y; Silverman, MG; Solt, K, 2022)
"Acute ischemic stroke is associated with pulmonary complications, and often dexmedetomidine and propofol are used to decrease cerebral metabolic rate."	4.02	Comparative effects of dexmedetomidine and propofol on brain and lung damage in experimental acute ischemic stroke. ( Antunes, MA; Battaglini, D; Cruz, FF; da Silva, CM; Fernandes, MV; Pelosi, P; Robba, C; Rocco, PRM; Samary, CS; Silva, PL; Sousa, GC; Takyia, C, 2021)
"Delayed emergence from anesthesia was previously reported in a case study of a child with Glycine Encephalopathy."	4.02	Elevated preoptic brain activity in zebrafish glial glycine transporter mutants is linked to lethargy-like behaviors and delayed emergence from anesthesia. ( Bindernagel, R; Buglo, E; Dallman, JE; Engert, F; Kelz, MB; Meng, QC; Randlett, O; Sloan, SA; Stark, MJ; Sumathipala, SH; Syed, S; Venincasa, MJ; Yan, Q; Züchner, S, 2021)
"Propofol (PPF) is reported to play a protective role in ischemia/reperfusion (I/R) injury, including cerebral ischemia-reperfusion injury (CIRI)."	4.02	Propofol Downregulates lncRNA MALAT1 to Alleviate Cerebral Ischemia-Reperfusion Injury. ( Chen, J; Cheng, S; Hu, Y; Ye, C, 2021)
" Here we show that surgical dissection of primary tumors in mice under anesthesia with sevoflurane leads to significantly more lung metastasis than with propofol in both syngeneic murine 4T1 and xenograft human MDA-MB-231 breast cancer models."	3.96	Distinct effects of general anesthetics on lung metastasis mediated by IL-6/JAK/STAT3 pathway in mouse models. ( Huang, Y; Li, R; Lin, J, 2020)
"The aim of this study was to investigate the effects of propofol on intestinal ischemia-reperfusion injury in rats through the nuclear factor-kappa B (NF-κB) pathway."	3.96	Propofol improves intestinal ischemia-reperfusion injury in rats through NF-κB pathway. ( Cui, SM; He, SC; Ma, B; Wu, MB; Zhang, TX; Zhao, K, 2020)
"There is conflicting evidence regarding the impact of propofol on cardiac repolarization and the risk of torsade de pointes (TdP)."	3.96	Propofol abolishes torsade de pointes in different models of acquired long QT syndrome. ( Dechering, DG; Eckardt, L; Ellermann, C; Frommeyer, G; Könemann, H; Rath, B; Reinke, F; Wegner, FK; Willy, K; Wolfes, J, 2020)
"Propofol significantly reduces neurological dysfunction, BBB permeability, brain edema, inflammation, and oxidative stress, all of which were reversed by LY294002."	3.91	Propofol Reduces Inflammatory Brain Injury after Subarachnoid Hemorrhage: Involvement of PI3K/Akt Pathway. ( Chen, Q; Shi, SS; Tu, XK; Zhang, HB, 2019)
"Taken together, propofol contributed to liver protection against d-GalN/LPS-induced liver injury in mice by inhibiting inflammation, oxidative stress and hepatocyte apoptosis through regulating TLR4/NF-κB/NLRP3 pathway."	3.91	Propofol attenuates inflammatory response and apoptosis to protect d-galactosamine/lipopolysaccharide induced acute liver injury via regulating TLR4/NF-κB/NLRP3 pathway. ( Jiang, K; Tian, L; Zhang, Z, 2019)
"BACKGROUND This study aimed to investigate the molecular mechanisms associated with the effects of propofol in a rat model of pain due to inflammation following subcutaneous injection with complete Freund's adjuvant (CFA)."	3.91	The Molecular Mechanisms Associated with the Effects of Propofol in a Rat Model of Pain Due to Inflammation Following Injection with Complete Freund's Adjuvant. ( Liu, H; Tan, S; Wang, Y; Zhu, S, 2019)
"After approval by the institutional animal care and use committee, 36 Japanese White rabbits underwent partial hepatic ischemia for 90 min either under sevoflurane or propofol anesthesia."	3.88	Interaction between anesthetic conditioning and ischemic preconditioning on metabolic function after hepatic ischemia-reperfusion in rabbits. ( Kosugi, S; Kotake, Y; Morisaki, H; Nagata, H; Suzuki, T; Yamada, T, 2018)
"In animal models, both sevoflurane and propofol protect against acute lung injury (ALI), especially when administered prior to ALI onset."	3.85	Sevoflurane Posttreatment Attenuates Lung Injury Induced by Oleic Acid in Dogs. ( Du, G; Li, Z; Liu, J; Wang, S, 2017)
"Both propofol and sevoflurane attenuated the extent of hepatic ischemia/reperfusion injury which is evident from the hisopathological studies and alterations in liver enzymes such as AST and LDH by inhibiting Nuclear factor kappa B (NFx03BA;B) activation and subsequent alterations in inflammatory cytokines interleukin-1(IL-1), interleukin-6(IL-6), tumor necrosis factor-alpha (TNF-α) and increased IL10 release."	3.83	The Effects of Two Anesthetics, Propofol and Sevoflurane, on Liver Ischemia/Reperfusion Injury. ( Qi, F; Wang, H; Wang, Z; Wu, J; Xu, Z; Yu, J, 2016)
"BACKGROUND The present study explored the effects of propofol on hippocampal autophagy and synaptophysin in depression-model rats undergoing electroconvulsive shock (ECS)."	3.83	Propofol Mitigates Learning and Memory Impairment After Electroconvulsive Shock in Depressed Rats by Inhibiting Autophagy in the Hippocampus. ( Hao, XC; Li, P; Luo, J; Lv, F; Min, S; Wei, K, 2016)
"Propofol is a commonly used intravenous anesthetic that has been demonstrated to be neuroprotective against cerebral ischemia-reperfusion (I/R) injury."	3.81	Propofol prevents neuronal mtDNA deletion and cerebral damage due to ischemia/reperfusion injury in rats. ( Chang, FF; Dong, H; Liu, Y; Lu, SJ; Qian, H; Song, CY; Wang, YF; Yang, WC; Yue, ZY, 2015)
"It has been shown in our previous study that propofol postconditioning enhanced the activity of phosphatidylinositol-3-kinase (PI3K) and prevented the internalization of GluR2 subunit of α-amino-3-hydroxyl-5-methyl-4-isoxazolepropionic acid (AMPA) receptors, thus provided neuroprotection in cerebral ischemia/reperfusion (I/R) injury."	3.81	The effect of propofol postconditioning on the expression of K(+)-Cl(-)-co-transporter 2 in GABAergic inhibitory interneurons of acute ischemia/reperfusion injury rats. ( Liu, S; Wang, G; Wang, H; Zhu, A, 2015)
"This is the first study to assess prolonged effects of sepsis and long-term application of volatile sedatives compared to propofol on survival, cardiovascular, inflammatory and end organ parameters."	3.81	Propofol increases morbidity and mortality in a rat model of sepsis. ( Beck-Schimmer, B; Bonini, MG; Dull, RO; Mao, M; Minshall, RD; Piegeler, T; Schläpfer, M; Schwartz, DE; Z'Graggen, BR, 2015)
" The effects of isoflurane, propofol, apnea, and hypotension on lower extremity MEPs were studied."	3.81	Methodology of motor evoked potentials in a rabbit model. ( Bombien, R; Goodwin, E; Haji, F; Juan, V; Khoynezhad, A; Lapchak, PA; Rastegar, M; Waterford, SD, 2015)
"The natural compounds carvacrol and thymol completely prevented seizures in the 6 Hz, 32 mA partial seizure model."	3.80	Seizure prevention by the naturally occurring phenols, carvacrol and thymol in a partial seizure-psychomotor model. ( Baker, MT; Mishra, RK, 2014)
"This study aimed to investigate whether propofol pretreatment can protect against liver transplantation-induced acute lung injury (ALI) and to explore whether Nrf2 pathway is involved in the protections provided by propofol pretreatment."	3.80	Propofol activation of the Nrf2 pathway is associated with amelioration of acute lung injury in a rat liver transplantation model. ( Chi, X; Hei, Z; Luo, G; Xia, Z; Yao, W; Zhang, A; Zhu, G, 2014)
"To observe the effects of continuous sedation with propofol on peripheral blood mononuclear cell (PBMC) and intercellular adhesion molecule 1 (ICAM-1) in beagles with combined burn-blast injuries."	3.80	[Effects of continuous sedation with propofol on peripheral blood mononuclear cell and intercellular adhesion molecule in beagles with combined burn-blast injuries]. ( Hou, Y; Hu, Q; Liu, L; Luo, H; Wang, Y; Yang, H, 2014)
"We evaluated whether the short-term use of dexmedetomidine and propofol may attenuate inflammatory response and improve lung morphofunction in experimental acute lung injury (ALI)."	3.80	Effects of short-term propofol and dexmedetomidine on pulmonary morphofunction and biological markers in experimental mild acute lung injury. ( Araújo, MN; Cavalcanti, V; Fernandes, FC; Heil, LB; Morales, MM; Pelosi, P; Rocco, PR; Samary, CS; Santos, CL; Silva, PL; Villela, N, 2014)
"Sixty rats were randomly assigned to four groups: normoglycemia-etomidate, normoglycemia-propofol, hyperglycemia-etomidate, and hyperglycemia-propofol."	3.79	Propofol attenuates renal ischemia-reperfusion injury aggravated by hyperglycemia. ( Jun, JH; Kwak, YL; Lim, BJ; Shim, JK; Yoo, KJ; Yoo, YC, 2013)
" Propofol's disadvantages include the induction of respiratory depression and apnea."	3.79	Coadministration of the AMPAKINE CX717 with propofol reduces respiratory depression and fatal apneas. ( Ding, X; Greer, JJ; Lenal, F; Ren, J; Yang, M, 2013)
"The goal of this study was to confirm whether or not sevoflurane is more effective than propofol in ameliorating the inflammatory response in an animal model of acute respiratory distress syndrome."	3.79	Sevoflurane, but not propofol, reduces the lung inflammatory response and improves oxygenation in an acute respiratory distress syndrome model: a randomised laboratory study. ( Aguilar, G; Belda, FJ; Ferrando, C; Moreno, J; Piqueras, L; Soro, M, 2013)
"During CPB, isoflurane, in contrast to propofol, significantly contributes to a general increase in fluid shifts from the intravascular to the interstitial space with edema formation and a possible negative impact on postoperative organ function."	3.79	Isoflurane in contrast to propofol promotes fluid extravasation during cardiopulmonary bypass in pigs. ( Brekke, HK; Hammersborg, SM; Haugen, O; Husby, P; Kvalheim, VL; Lundemoen, S; Mongstad, A, 2013)
"To evaluate the effects of pretreatment, midazolam (M), propofol (P), ziprasidone (Z), and two combinations of [(midazolam plus propofol (MP); midazolam plus ziprasidone (MZ)] in mice models in the prevention of seizures, and death due to acute cocaine toxicity."	3.79	Assessment of propofol, midazolam and ziprasidone, or the combinations for the prevention of acute cocaine toxicity in a mouse model. ( Erdur, B; Ergin, A; Kortunay, S; Yuksel, A, 2013)
"Under both normovolemia and hypovolemia, glucose levels in rats anesthetized with sevoflurane were significantly higher than those in rats anesthetized with propofol, and insulin levels in rats anesthetized with sevoflurane were significantly lower than those in rats anesthetized with propofol."	3.78	The involvement of adenosine triphosphate-sensitive potassium channels in the different effects of sevoflurane and propofol on glucose metabolism in fed rats. ( Kawamura, G; Kitamura, T; Sato, K; Yamada, Y, 2012)
"This experimental study aimed to investigate the antioxidant effects of propofol anesthesia at induction doses in a rat skeletal muscle ischemia/reperfusion injury model."	3.78	Antioxidant effects of propofol on tourniquet-induced ischemia-reperfusion injury: an experimental study. ( Bostan, B; Erkorkmaz, U; Ozkan, F; Ozyurt, H; Senayli, Y, 2012)
" To test our hypothesis that anesthetics interact with the intrinsic parameters of ECT to differentially regulate its therapeutic efficacy, we investigated the effects of the anesthetic propofol and the stimulus intensities of ECT on behavior and hippocampal brain-derived neurotrophic factor (BDNF) in a rodent model of depression."	3.78	Propofol interacts with stimulus intensities of electroconvulsive shock to regulate behavior and hippocampal BDNF in a rat model of depression. ( Liu, Y; Luo, J; Min, S; Wei, K; Zhang, J, 2012)
"Propofol has been demonstrated to improve hepatic perfusion in a rabbit model; however, the effects of propofol on hepatic ischemia/reperfusion injury are unknown."	3.78	Propofol attenuates hepatic ischemia/reperfusion injury in an in vivo rabbit model. ( Luo, CZ; McCluskey, SA; Pang, QY; Ye, L; Zhu, T, 2012)
"Monitoring of exhaled pentane may be useful for evaluating the severity of hepatic ischemia-reperfusion injury and aid in predicting the outcome; propofol may improve the outcome in this situation."	3.78	Breath pentane as a potential biomarker for survival in hepatic ischemia and reperfusion injury--a pilot study. ( Gong, Y; He, Y; Li, E; Li, J; Li, P; Liu, D; Liu, S; Luo, A; Shi, J; Sun, B; Wang, C; Xu, G, 2012)
"These results show that the anesthetics propofol and 2,6-di-sec-butylphenol may be substituted in the para position with a 1-hydroxy-2,2,2-trifluoroethyl moiety and the resulting molecules have anticonvulsant activity in the 6 Hz model while exhibiting less toxicity (ataxia) than the parent 2,6-dialkylphenols."	3.77	The anticonvulsant effects of propofol and a propofol analog, 2,6-diisopropyl-4-(1-hydroxy-2,2,2-trifluoroethyl)phenol, in a 6 Hz partial seizure model. ( Baker, MT, 2011)
" We investigated the effect of propofol on HIF-1α expression and acute lung injury in LPS-treated mice."	3.77	Propofol inhibits lipopolysaccharide-induced lung epithelial cell injury by reducing hypoxia-inducible factor-1alpha expression. ( Cho, W; Chu, CC; Hsing, CH; Lin, MC; So, EC; Wang, JJ; Yeh, CH, 2011)
"To explore the effects of propofol on the outcomes of rats with sepsis."	3.77	Effects of propofol on the outcomes of rats with sepsis. ( Bao, HG; Li, S, 2011)
"Sixty Sprague-Dawley rats were randomly divided into 5 groups (n = 12 rats per group): control group, depression group, propofol group, ECT group, and propofol + ECT group."	3.76	Effects of electroconvulsive therapy and propofol on spatial memory and glutamatergic system in hippocampus of depressed rats. ( Cao, J; Dong, J; Li, P; Li, Y; Min, S; Wei, K, 2010)
" Research has shown that propofol, which is an intravenous anesthetic agent, exhibits neuroprotective effects against cerebral ischemia-reperfusion injury, although the neuroprotective mechanism is still unclear."	3.76	The effects of propofol on hippocampal caspase-3 and Bcl-2 expression following forebrain ischemia-reperfusion in rats. ( Han, B; Li, J; Ma, X; Qi, S, 2010)
" Hypoxemia episodes were induced by apnea alone or by apnea combined with a reduction in LV and C(RS)."	3.75	Targeted minute ventilation and tidal volume in an animal model of acute changes in lung mechanics and episodes of hypoxemia. ( Bancalari, E; Claure, N; D'Ugard, C; Hehre, D; Peng, J; Suguihara, C, 2009)
"To observe the influence of propofol on corticosteroid, and cytokines in rats after hemorrhagic shock and resuscitation, as well as its protective effects on vital organs."	3.75	[The influences of propofol on corticosteroid and immunity of rats after hemorrhagic shock and resuscitation]. ( Cao, SH; Ji, X, 2009)
" Two animal models of TLE--amygdala kindling and pilocarpine-induced status epilepticus (Pilo-SE)--were tested."	3.75	Pilocarpine model of temporal lobe epilepsy shows enhanced response to general anesthetics. ( Leung, LS; Long, JJ; Luo, T; McMurran, TJ; Shen, B; Stewart, L, 2009)
"To investigate the effect of propofol intra-aortic and intravenous infusion on the concentration of propofol for an ischemia-reperfusion spinal cord injury in rabbits."	3.74	[Comparison of propofol concentration in the spinal cord between intra-aortic and intravenous infusion]. ( Liao, Z; Lin, Y; Zhang, J; Zhang, L, 2008)
" Although its mechanism of smooth muscle relaxation is unknown, propofol has been associated with less bronchoconstriction during anaesthetic induction."	3.74	Investigation of the relaxant effects of propofol on ovalbumin-induced asthma in guinea pigs. ( Bagcivan, I; Cevit, O; Gursoy, S; Kaya, T; Mimaroglu, C; Yildirim, MK; Yildirim, S, 2007)
"We previously found that propofol attenuated the mortality rate and inflammatory responses during endotoxemia in rats; however, whether propofol retains its antiinflammatory effects during hypothermia has not been determined."	3.74	The antiinflammatory effects of propofol in endotoxemic rats during moderate and mild hypothermia. ( Kanakura, H; Taniguchi, T, 2007)
"We have previously demonstrated, in the isolated rat heart, that propofol attenuates hydrogen peroxide-induced damage and ischaemia-reperfusion injury, and that the beneficial effect of propofol is correlated with reduction of the lipid peroxidation."	3.74	Propofol attenuates ischaemia-reperfusion injury in the rat heart in vivo. ( Kobayashi, I; Kokita, N; Namiki, A, 2008)
"To study the therapeutic effect and its mechanisms of propofol on gastric mucosal injury after hemorrhagic shock with reperfusion in rabbits."	3.74	[Effect of propofol on gastric mucosal injury after hemorrhagic shock and reperfusion in rabbits]. ( Li, HY; Lü, YX; Wang, LL; Zhang, LF, 2008)
"We conclude that the severity of remote lung injury was not different between sevoflurane and propofol anaesthesia in this porcine model of severe lower-body ischaemia and reperfusion injury."	3.74	Lung injury following thoracic aortic occlusion: comparison of sevoflurane and propofol anaesthesia. ( Annecke, T; Bittmann, I; Conzen, PF; Hilberath, JM; Kahr, S; Kemming, GI; Krombach, F; Kubitz, JC; Langer, K; Rehm, M, 2008)
"To explore whether propofol plays a protective role in kidney injury during acute respiratory distress syndrome (ARDS) by affecting the expression of Gq/11 protein."	3.73	[Influence of propofol on Gq/11 protein in kidney during acute respiratory distress syndrome]. ( Abasi, K; Jialili, A; Li, XJ; Zhang, L, 2006)
"Although TIVA is less prone than isoflurane anaesthesia to primary cardiovascular depression leading to asphyxia, TIVA is associated with reduced effectiveness of CPR in which resuscitation because of asphyxic haemodynamic depression occurs."	3.72	Comparison of isoflurane and propofol-fentanyl anaesthesia in a swine model of asphyxia. ( Kazama, T; Kurita, T; Morita, K; Sato, S, 2003)
"Propofol in this model was more arrhythmogenic than thiopental, as manifested by a longer duration of induced arrhythmias, particularly AFI."	3.72	Comparative effects of thiopental and propofol on atrial vulnerability: electrophysiological study in a porcine model including acute alcoholic intoxication. ( Almendral, J; Anadón, MJ; González, P; Navia, J; Zaballos, M, 2004)
"Intrathecal administration of propofol had analgesic effects on inflammation-induced acute and facilitated pain but not on thermally-induced acute pain."	3.72	Intrathecal propofol has analgesic effects on inflammation-induced pain in rats. ( Hanaoka, K; Matsukawa, T; Nishiyama, T, 2004)
"To compare the effects of pentobarbital and propofol on the outcome of focal cerebral ischemia model, and to evaluate the availability of propofol in setting the focal cerebral ischemia."	3.72	[Comparison of pentobarbital and propofol on the outcome of focal cerebral ischemia model in rats]. ( Kang, QY; Li, J; Liu, Y; Zhang, PB; Zhao, JJ, 2004)
"We investigated the effects of selective and non-selective endothelin (ET) antagonists on warm ischemia-reperfusion injury of the early phase in the murine liver under propofol anesthesia."	3.70	[Effects of endothelin antagonists on isolated perfused murine livers in the early phase of warm ischemia-reperfusion injury under propofol anesthesia]. ( Karasawa, F; Sato, T; Tanaka, K, 1999)
"It has been suggested that propofol has the protective effect on cerebral ischemia-reperfusion injury."	3.70	Effectiveness of propofol pretreatment on the extent of deranged cerebral mitochondrial oxidative enzyme system after incomplete forebrain ischemia/reperfusion in rats. ( Chung, C; Lee, Y; Oh, YS, 2000)
" Propofol was used for surgical anesthesia because recovery in normal animals from an intravenous infusion was found to be nearly complete within 2 h of cessation and absolutely complete by 4 h."	3.68	Early assessment of neurologic deficits in the fluid percussion model of brain injury. ( Einhaus, SL; Hilton, DL; Meric, AL; Park, MR; Robertson, JT; Schweitzer, JB; White, RP, 1993)
"We have examined the anticonvulsant properties of propofol in high doses in two experimental models of status epilepticus: generalized pentylenetetrazol (PTZ)-induced seizures and partial, cortically applied penicillin G-induced seizures."	3.68	Propofol anticonvulsant activity in experimental epileptic status. ( Caria, MA; De Riu, PL; Mameli, O; Melis, F; Mulas, M; Petruzzi, V; Testa, C, 1992)
"Propofol has yet not arrived on the local black markets."	2.47	[Assessment of the addictive risk of propofol]. ( Bonnet, U, 2011)
"Propofol functions as a tumor-inhibitor drug by regulating microRNAs (miRNAs)."	1.91	Propofol decreases cisplatin resistance of non-small cell lung cancer by inducing GPX4-mediated ferroptosis through the miR-744-5p/miR-615-3p axis. ( Han, B; Liang, L; Liu, Y; Zhang, Q, 2023)
"Propofol is an anesthetic agent with neuroprotective property."	1.72	Propofol via Antioxidant Property Attenuated Hypoxia-Mediated Mitochondrial Dynamic Imbalance and Malfunction in Primary Rat Hippocampal Neurons. ( Chen, J; Cui, W; Han, J; Tao, W, 2022)
"Propofol is a known intravenous hypnotic drug used for induction and maintenance of sedation and general anesthesia."	1.62	Propofol Suppresses Microglia Inflammation by Targeting TGM2/NF- ( Hou, Y; Qi, S; Xiao, X; Yu, W, 2021)
"Propofol acts as an intravenous anesthetic cure which is widely used as a therapy for the craniocerebral injury that comprised surgical anesthesia as well as the sedation done in the intensive care units."	1.62	Propofol Alleviates Neuropathic Pain Induced by Chronic Contractile Injury by Regulating the Spinal glun2b-p38mapkepac1 Pathway. ( Li, W; Qin, C; Yan, J; Yang, Y; You, L; Zhao, Q, 2021)
"Propofol- or vehicle-treated tumor cells are also injected to the mice."	1.62	Anesthetic Propofol Promotes Tumor Metastasis in Lungs via GABA ( Cheng, C; Lanuti, M; Liu, Q; Liu, R; Shen, Y; Sheng, Z; Wang, P; Xie, Z; Zheng, H, 2021)
"Propofol is an intravenous anesthetic that is commonly used during intravascular embolectomy following acute ischemic stroke."	1.56	Propofol Attenuates α-Synuclein Aggregation and Neuronal Damage in a Mouse Model of Ischemic Stroke. ( Cui, V; Tian, D; Wang, H; Wang, Y; Wei, C; Wu, A; Yue, Y; Zhu, Y, 2020)
"Propofol treatment improved VILI, alleviated pulmonary inflammation induced by mechanical ventilation."	1.56	Propofol alleviates ventilator-induced lung injury through regulating the Nrf2/NLRP3 signaling pathway. ( Chen, G; Li, W; Ruan, H; Wang, J; Wang, Z; Xia, B; Zhang, M, 2020)
"Propofol was effective, exhibiting high efficacy and potency for terminating seizure activity quickly in pediatric and adult animals, suggesting it may be an effective anticonvulsant for NA-induced seizures in pediatric populations."	1.56	Evaluation of fosphenytoin, levetiracetam, and propofol as treatments for nerve agent-induced seizures in pediatric and adult rats. ( Ardinger, CE; Berger, KE; Dunn, EN; Haines, KM; Jackson Piercy, CE; Lee-Stubbs, RB; Matson, LM; McCarren, HS; McDonough, JH; Miller-Smith, SM; Whitten, KA, 2020)
"Autism is a challenging neurodevelopmental disorder."	1.51	Dexmedetomidine and propofol sedation requirements in an autistic rat model. ( Elgendy, H; Elmorsy, SA; Rashed, LA; Soliman, GF, 2019)
"Propofol was added intraperitoneally to the mice from 7th day of insulin/saline treatment, and general anesthesia was induced and maintained for 2 hours/day for 5 consecutive days."	1.51	Intranasal Insulin Prevents Anesthesia-induced Cognitive Impairments in Aged Mice. ( Huang, F; Ke, D; Li, X; Liang, Z; Liu, R; Run, X; Wang, JZ; Wang, Q; Wang, X; Wei, Z; Zeng, K; Zhang, B, 2019)
"Mechanical allodynia induced by plantar incision peaked at 1 hr and lasted for 3 days after incision."	1.51	Propofol attenuates postoperative hyperalgesia via regulating spinal GluN2B-p38MAPK/EPAC1 pathway in an animal model of postoperative pain. ( Cheung, CW; Gu, P; Li, Q; Qiu, Q; Sun, L; Wang, XM; Wong, SS, 2019)
"Propofol treatment alleviated intestinal and lung morphological changes which were observed in II/R group，Moreover, wet/dry weight ratio, the MDA level, MPO activity and expression of caspase-3 were significantly decreased whereas the SOD activity and p-Akt expression were significantly increased."	1.51	The role of PI3K/Akt signal pathway in the protective effects of propofol on intestinal and lung injury induced by intestinal ischemia/reperfusion1. ( Cui, S; Ding, H; He, X; Jing, G; Li, Q; Xia, Z, 2019)
" Intralipid (10%, 10 mL/kg) for vehicle control and different dosage of propofol for three treatment groups (50, 100 and 200 mg/kg) were administered intraperitoneally."	1.48	PKA-CREB-BDNF signaling pathway mediates propofol-induced long-term learning and memory impairment in hippocampus of rats. ( Chen, J; Jiang, Y; Li, L; Pan, S; Qin, Y; Wei, Y; Xie, Y; Zhong, Y, 2018)
"Propofol was injected for anesthesia (n = 22)."	1.48	The recovery from transient cognitive dysfunction induced by propofol was associated with enhanced autophagic flux in normal healthy adult mice. ( Baik, HJ; Cho, S; Han, JI; Jung, YJ; Lee, GY; Lee, KE; Suh, EC, 2018)
"Pre-treatment with propofol significantly increased the CoBF and DPOAE amplitudes, decreased 8-iso-PGF2α and the loss of OHCs."	1.46	Protective effect of propofol on noise-induced hearing loss. ( Duan, N; Jing, GX; Wang, Q; Wen, J; Xiao, Y, 2017)
"Propofol treatment could elicit a robust neuroprotective response, resulting in significant neurological function improvement for TBI rats, which was independent with intralipid."	1.43	Propofol administration improves neurological function associated with inhibition of pro-inflammatory cytokines in adult rats after traumatic brain injury. ( Chen, MR; Liu, F; Liu, J; Wang, TH; Wang, TY; Zou, Y; Zuo, YX, 2016)
" The propofol self-administration model was established by a fixed ratio 1 (FR1) schedule of reinforced dosing over successive 14days in rats."	1.43	Glucocorticoid receptor mediated the propofol self-administration by dopamine D1 receptor in nucleus accumbens. ( Chen, Z; Dong, Z; Ge, RS; Lian, Q; Liang, Y; Lin, W; Wang, B; Wang, S; Wu, B; Zhang, G, 2016)
"Propofol (30 mg/kg) was intraperiotoneally administered to 7‑day‑old Sprague Dawley rats (n=75) three times each day at 90 min intervals for seven consecutive days with or without Dex (75 µg/kg) treatment 20 min prior to propofol injection."	1.43	Dexmedetomidine attenuates repeated propofol exposure-induced hippocampal apoptosis, PI3K/Akt/Gsk-3β signaling disruption, and juvenile cognitive deficits in neonatal rats. ( Guo, X; Han, B; Mao, M; Wang, J; Wang, Y; Wu, C; Xu, F, 2016)
"When propofol was applied for 4-8 h after kainate washout, strong neuroprotection was observed in all spinal areas, including attenuation of motoneuron loss."	1.43	Neuroprotective effect of propofol against excitotoxic injury to locomotor networks of the rat spinal cord in vitro. ( Flores Gutiérrez, J; Kaur, J; Nistri, A, 2016)
"Propofol is an intravenous sedative-hypnotic agent that is commonly used to induce and maintain general anaesthesia."	1.43	Effects of Propofol on Oxidative Stress Parameters in Selected Parts of the Brain in a Rat Model of Parkinson Disease. ( Birkner, E; Chwalińska, E; Hudziec, E; Nowak, P; Prudel, B; Romuk, E; Skowron, M; Szczurek, W, 2016)
"Pretreatment with propofol significantly ameliorated renal pathology and abrogated the increase of the Cr and BUN concentrations, O2•‑ and ·OH activities, and MDA levels induced by OLAT."	1.42	Propofol pretreatment attenuates remote kidney injury induced by orthotopic liver autotransplantation, which is correlated with the activation of Nrf2 in rats. ( Chi, X; Ge, M; Hei, Z; Luo, C; Luo, G; Yao, W; Yuan, D; Zhou, S, 2015)
" Clinical data imply a correlation between cumulative propofol dosage and diaphragm dysfunction, whereas laboratory investigations have revealed that propofol has some antioxidant properties."	1.40	Sedation using propofol induces similar diaphragm dysfunction and atrophy during spontaneous breathing and mechanical ventilation in rats. ( Bergs, I; Bleilevens, C; Bruells, CS; Cielen, N; Gayan-Ramirez, G; Maes, K; Rossaint, R; Thomas, D; Weis, J, 2014)
"Propofol was administrated to the WT and AD Tg mice once a week for 8 or 12 weeks, respectively."	1.40	Chronic treatment with anesthetic propofol improves cognitive function and attenuates caspase activation in both aged and Alzheimer's disease transgenic mice. ( Dong, Y; Shao, H; Xia, W; Xie, Z; Yu, B; Zhang, Y, 2014)
"Propofol is a short-acting, intravenous general anesthetic that is widely used in clinical practice for short procedures; however, it causes depressed cognitive function for several hours thereafter."	1.40	(R)-alpha-methylhistamine suppresses inhibitory neurotransmission in hippocampal CA1 pyramidal neurons counteracting propofol-induced amnesia in rats. ( Cheng, LZ; Li, WW; Raya, AD; Shi, XY; Tian, ML; Wang, Y; Zhang, H; Zou, Z, 2014)
"A medically induced coma is an anesthetic state of profound brain inactivation created to treat status epilepticus and to provide cerebral protection after traumatic brain injuries."	1.39	Real-time closed-loop control in a rodent model of medically induced coma using burst suppression. ( Brown, EN; Chemali, JJ; Ching, S; Kenny, JD; Liberman, MY; Purdon, PL; Solt, K; Westover, MB, 2013)
"Propofol treatment reduced infarct volume and improved the neurological functions."	1.39	Propofol protects against focal cerebral ischemia via inhibition of microglia-mediated proinflammatory cytokines in a rat model of experimental stroke. ( Liu, F; Tan, Y; Tang, X; Wu, X; Yang, Z; Zhou, R, 2013)
"Propofol is an intravenous anesthetic widely used for sedation and general anesthesia."	1.37	Possible role of propofol's cyclooxygenase-inhibiting property in alleviating dopaminergic neuronal loss in the substantia nigra in an MPTP-induced murine model of Parkinson's disease. ( Inada, T; Kubo, K; Shingu, K, 2011)
"Propofol is a drug used in anesthesia that has unique antioxidant qualities that may be beneficial."	1.36	Apoptosis: understanding programmed cell death for the CRNA. ( Bennetts, PS; Pierce, JD, 2010)
"Pretreatment with propofol significantly decreased writhing responses induced by visceral pain, suppressed the visceral pain-induced aspartate and glutamate release, and reversed the decreased release of γ-amino butyric acid in the cerebrospinal fluid."	1.36	Effects of anesthetic propofol on release of amino acids from the spinal cord during visceral pain. ( Fang, L; Liu, Y; Mu, X; Wang, Y; Wu, A; Wu, J; Yue, Y; Zhang, Y, 2010)
"Propofol has inhibited the hepatic NF-kappaB activation and the pro-inflammatory cytokine response during polymicrobial sepsis in rats."	1.35	Effects of propofol on pro-inflammatory cytokines and nuclear factor kappaB during polymicrobial sepsis in rats. ( Li, JG; Liang, H; Song, XM; Wang, CY; Wang, YL; Zhang, ZZ; Zhou, Q, 2009)
"Remifentanil has been implicated as causing intraoperative bradyarrhythmias, but little information is available regarding its cardiac electrophysiological effects."	1.35	Cardiac electrophysiological effects of remifentanil: study in a closed-chest porcine model. ( Almendral, J; Anadón, MJ; Atienza, F; Jimeno, C; Navia, J; Patiño, D; Valdes, E; Zaballos, M, 2009)
"Rats underwent 2 h of middle cerebral artery occlusion (MCAO) followed by 22 h of reperfusion were randomly divided into nine groups (n=15 each): sham-operated group, MCAO group, propofol 10, 20 and 35 mg x kg(-1) x h(-1) group (propofol 10, 20, 35 mg x kg(-1) x h(-1) infused at the onset of reperfusion for 30 min), wortmannin group (wortmannin 0."	1.35	The role of phosphoinositide-3-kinase/Akt pathway in propofol-induced postconditioning against focal cerebral ischemia-reperfusion injury in rats. ( Wang, GL; Wang, HY; Wang, Y; Yu, YH, 2009)
"Propofol has been demonstrated to ameliorate cerebral ischemic injury and attenuate changes in multiple links of molecular reaction included in the paths to apoptosis."	1.35	Effect of propofol on pathologic time-course and apoptosis after cerebral ischemia-reperfusion injury. ( Chen, L; Jiang, H; Xue, Z, 2008)
"Treatment with propofol abrogated or reversed the oleic acid-induced changes."	1.35	Protective effects of propofol on acute lung injury induced by oleic acid in conscious rats. ( Chen, HI; Hsieh, NK; Kao, SJ; Su, CF, 2008)
"ICAM-1 plays an important role in lung injury after intestinal I/R."	1.33	[Propofol reduces intercellular adhesion molecular-1 expression in lung injury following intestinal ischemia/reperfusion in rats]. ( Hu, XM; Lu, Y; Yao, SL, 2005)
"Rats treated with isoflurane had the best cognitive recovery (p < 0."	1.33	Comparison of seven anesthetic agents on outcome after experimental traumatic brain injury in adult, male rats. ( Alexander, H; Clark, RS; Dixon, CE; Jenkins, L; Kochanek, PM; Statler, KD; Vagni, V, 2006)
"Naloxone did not cause changes in ejection fraction or mean pulmonary artery pressure in hypoxic and hypercarbic conditions."	1.33	Cardiovascular changes after naloxone administration in propofol-sedated piglets during opioid overdose. ( Aittomäki, JV; Boyd, JJ; Kyttä, JV; Randell, TT; Rosenberg, PH; Seppälä, TA, 2006)
"Hepatic encephalopathy is a neurologic syndrome secondary to liver failure that causes cognitive and motor abnormalities."	1.33	Functional abnormalities of the motor tract in the rat after portocaval anastomosis and after carbon tetrachloride induction of cirrhosis. ( Bartolí, R; Chatauret, N; Córdoba, J; Odena, G; Oria, M; Planas, R; Raguer, N, 2006)
"propofol was not significantly different between ethanol-treated and control rats."	1.32	Chronic ethanol consumption does not affect action of propofol on rat hippocampal acetylcholine release in vivo. ( Andoh, T; Inagawa, G; Kikuchi, T; Koyama, Y; Nishihama, M; Sato, K; Shioda, M; Yamada, Y, 2004)
" Etoposide phosphate in combination with any other agent was observed to be highly neurotoxic if both agents were administered after BBBD."	1.31	Unexpected neurotoxicity of etoposide phosphate administered in combination with other chemotherapeutic agents after blood-brain barrier modification to enhance delivery, using propofol for general anesthesia, in a rat model. ( Fortin, D; McCormick, CI; Neuwelt, EA; Nixon, R; Remsen, LG, 2000)
"Status epilepticus is commonly refractory to first-line therapy, and thus better treatments are needed."	1.31	Propofol in subanesthetic doses terminates status epilepticus in a rodent model. ( Holtkamp, M; Tong, X; Walker, MC, 2001)
"In the other 15 cats, cytotoxic brain edema (CBE) was created by an acute reduction in blood osmolality."	1.30	The effects of intravenous anesthetics on intracranial pressure and cerebral perfusion pressure in two feline models of brain edema. ( Nimkoff, L; Quinn, C; Sagy, M; Silver, P, 1997)
"Propofol is a cardiac depressant with minimal diastolic effects in the adult myocardium."	1.30	Left ventricular systolic and diastolic function is unaltered during propofol infusion in newborn swine. ( Graham, MR; Mutch, WA; Thiessen, DB, 1998)
"Pentobarbital pretreatment failed to suppress FLI."	1.30	Pre- versus postinjury effects of intravenous GABAergic anesthetics on formalin-induced Fos immunoreactivity in the rat spinal cord. ( Coderre, TJ; Gilron, I; Quirion, R, 1999)
"Propofol did not produce direct effects on the electrophysiological or electrocardiographical variables at any infusion rates."	1.30	Propofol does not affect the canine cardiac conduction system under autonomic blockade. ( Akazawa, S; Ikeno, S; Inoue, S; Ishii, R; Nakaigawa, Y; Satoh, M; Shimizu, R, 1999)
" However, the dose-response relationship, reproducibility and effect of anesthetic agents on induction are not well understood."	1.30	Induction of atrial fibrillation and flutter in dogs using methacholine. ( Ross, DL; Thomas, SP, 1999)
" Morphine, pethidine and fentanyl, which showed a biphasic dose-response relationship with respect to seizure modulation, abolished the anticonvulsant activity of propofol to exhibit their own intrinsic activity in proconvulsant doses."	1.29	Interactions between opioid drugs and propofol in laboratory models of seizures. ( Ahmad, I; Pleuvry, BJ, 1995)
"Forebrain ischemia was produced by bilaterally occluding the common carotid arteries for 10 minutes; then the blood supply to the brain was restored."	1.29	Effect of 2,6-diisopropylphenol on the delayed hippocampal cell loss following transient forebrain ischemia in the gerbil. ( Arcadi, FA; Costa, G; De Luca, R; Rapisarda, A; Trimarchi, GR, 1996)
"Anaesthetic techniques for malignant hyperthermia susceptible (MHS) patients should include drugs which do not trigger MH and provide stress free conditions."	1.28	Effect of propofol on the malignant hyperthermia susceptible pig model. ( Adnet, P; Becq, MC; Krivosic-Horber, R; Reyfort, H, 1989)

Timeframe	Studies, this research(%)	All Research%
pre-1990	1 (0.46)	18.7374
1990's	16 (7.34)	18.2507
2000's	51 (23.39)	29.6817
2010's	113 (51.83)	24.3611
2020's	37 (16.97)	2.80

Trial	Phase	Enrollment	Study Type	Start Date	Status
Intranasal Insulin Improves Postoperative Neurocognitive Disorders in Elderly Patients: a Multicenter, Randomized, Double-blind, Placebo-controlled Study[NCT05613491]		438 participants (Anticipated)	Interventional	2022-11-07	Recruiting
AnaConDa-therapy in COVID-19 Patients[NCT05586126]		42 participants (Actual)	Observational	2020-10-01	Terminated (stopped due to Concerns about possible association between drug and increased ICU mortality)
Volatile Anesthetic Pharmacokinetics During Extracorporeal Membrane[NCT05680545]		10 participants (Anticipated)	Interventional	2024-07-01	Not yet recruiting
A Randomized Pilot Clinical Trial of the Effects in Oxygenation and Hypoxic Pulmonary Vasoconstriction of Sevoflurane in Patient's Whit ARDS Secondary to Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV2)[NCT04998253]	Early Phase 1	24 participants (Actual)	Interventional	2020-10-01	Completed
Sevoflurane Sedation: A Potentially Promising Immunomodulation in Patients With Septic Shock[NCT03643367]	Phase 2	153 participants (Anticipated)	Interventional	2025-01-31	Not yet recruiting
"Hemodynamic Stability During Induction of General Anesthesia With Propofol and Remifentanil: A Randomized, Controlled, Double-blind Study Comparing Medium and Low Remifentanil Doses."[NCT03861377]	Phase 4	99 participants (Actual)	Interventional	2020-06-09	Completed
Investigation of Changes in the Levels of Exhaled NO and Eosinophil Blood Count in Patients Undergoing Thyroidectomy by Two Different Methods of General Anesthesia Maintenance[NCT02065635]		60 participants (Actual)	Interventional	2014-05-31	Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Article	Year
Effects of propofol on ischemia-reperfusion and traumatic brain injury. Journal of critical care, 2020, Volume: 56 Topics: Anesthesia; Anesthetics; Animals; Apoptosis; Astrocytes; Brain; Brain Injuries, Traumatic; Disease M	2020
The Relationship Between Sedatives, Sedative Strategy, and Healthcare-Associated Infection: A Systematic Review. Infection control and hospital epidemiology, 2016, Volume: 37, Issue:10 Topics: Animals; Benzodiazepines; Clinical Trials as Topic; Critical Care; Cross Infection; Disease Models,	2016
[Assessment of the addictive risk of propofol]. Fortschritte der Neurologie-Psychiatrie, 2011, Volume: 79, Issue:8 Topics: Administration, Oral; Anesthetics, Intravenous; Animals; Disease Models, Animal; Electroconvulsive T	2011

propofol and Disease Models, Animal

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Other Studies

Authors	Studies
Mishra, RK	1
Baker, MT	2
Solinski, HJ	1
Dranchak, P	1
Oliphant, E	1
Gu, X	1
Earnest, TW	1
Braisted, J	1
Inglese, J	1
Hoon, MA	1
Abrams, RPM	1
Yasgar, A	1
Teramoto, T	1
Lee, MH	1
Dorjsuren, D	1
Eastman, RT	1
Malik, N	1
Zakharov, AV	1
Li, W	5
Bachani, M	1
Brimacombe, K	1
Steiner, JP	1
Hall, MD	1
Balasubramanian, A	1
Jadhav, A	1
Padmanabhan, R	1
Simeonov, A	1
Nath, A	1
Hou, Y	2
Xiao, X	1
Yu, W	1
Qi, S	2
Shen, M	1
Lian, N	1
Song, C	1
Qin, C	2
Yu, Y	2
Yan, J	1
Zhao, Q	1
You, L	1
Yang, Y	3
Sousa, GC	1
Fernandes, MV	1
Cruz, FF	1
Antunes, MA	1
da Silva, CM	1
Takyia, C	1
Battaglini, D	1
Samary, CS	2
Robba, C	1
Pelosi, P	2
Rocco, PRM	1
Silva, PL	2
Han, J	1
Tao, W	1
Cui, W	1
Chen, J	6
Azevedo, MR	1
de-Lima-Oliveira, M	1
Belon, AR	1
Brasil, S	1
Teixeira, MJ	1
Paiva, WS	1
Bor-Seng-Shu, E	1
Li, Y	6
Liu, Y	9
Zhang, J	6
Li, J	7
Shu, Y	1
Yan, R	1
Song, T	1
Wang, W	1
Tian, J	1
Ma, X	2
Ikeda, T	1
Amorim, E	1
Miyazaki, Y	1
Kato, R	1
Marutani, E	1
Silverman, MG	1
Malhotra, R	1
Solt, K	2
Ichinose, F	1
Fan, GB	3
Xu, GS	3
Zhao, AY	3
Jin, HJ	3
Sun, SQ	3
Qi, SH	3
Han, B	5
Zhang, Q	4
Liang, L	3
Huang, Y	2
Lu, H	1
Ren, X	1
Li, F	1
Bu, W	1
Liu, W	1
Dailey, WP	1
Saeki, H	1
Gabrielson, K	1
Abraham, R	1
Eckenhoff, R	1
Gao, WD	1
Wang, Y	10
Tian, D	1
Wei, C	1
Cui, V	1
Wang, H	4
Zhu, Y	1
Wu, A	2
Yue, Y	2
Fang, H	3
Zhang, FX	1
Li, HF	1
Yang, M	3
Liao, R	1
Wang, RR	1
Wang, QY	1
Zheng, PC	1
Zhang, JP	2
Zhang, HB	1
Tu, XK	1
Chen, Q	2
Shi, SS	1
Zhang, Z	1
Tian, L	1
Jiang, K	1
Yan, HJ	1
Qi, GQ	1
Ma, Y	2
Tan, S	1
Liu, H	2
Zhu, S	1
Hausburg, MA	1
Banton, KL	1
Roman, PE	1
Salgado, F	1
Baek, P	1
Waxman, MJ	1
Tanner, A	1
Yoder, J	1
Bar-Or, D	1
Li, R	1
Lin, J	2
Wu, S	1
Yao, W	5
Chen, C	1
Chen, H	3
Huang, F	2
Cai, J	1
Yuan, D	4
Hei, Z	5
Liu, Z	2
Zhang, F	3
Chang, Y	2
Ruan, H	1
Wang, J	2
Chen, G	1
Xia, B	1
Wang, Z	3
Zhang, M	1
Liu, X	1
Geng, J	1
Guo, H	1
Zhao, H	1
Ai, Y	1
Dunn, EN	1
Matson, LM	1
Haines, KM	1
Whitten, KA	1
Lee-Stubbs, RB	1
Berger, KE	1
McCarren, HS	1
Ardinger, CE	1
Jackson Piercy, CE	1
Miller-Smith, SM	1
McDonough, JH	1
Wu, MB	1
Ma, B	2
Zhang, TX	1
Zhao, K	1
Cui, SM	1
He, SC	1
Lotz, C	1
Stumpner, J	1
Smul, TM	1
Yang, L	1
Ton, H	1
Zhao, R	1
Geron, E	1
Li, M	1
Dong, Y	2
Zhang, Y	3
Yu, B	2
Yang, G	1
Xie, Z	3
Wu, CC	1
Hung, CJ	1
Wang, YY	1
Lin, SY	1
Chen, WY	1
Kuan, YH	1
Liao, SL	1
Yang, CP	1
Chen, CJ	1
Ellermann, C	1
Könemann, H	1
Wolfes, J	1
Rath, B	1
Wegner, FK	1
Willy, K	1
Dechering, DG	1
Reinke, F	1
Eckardt, L	1
Frommeyer, G	1
Zhang, HS	1
Liu, CD	1
Zheng, MC	1
Zhao, HT	1
Liu, XJ	1
Zhang, N	1
Liao, Z	2
Wu, P	1
Cai, G	1
Shibata, Y	1
Venincasa, MJ	1
Randlett, O	1
Sumathipala, SH	1
Bindernagel, R	1
Stark, MJ	1
Yan, Q	1
Sloan, SA	1
Buglo, E	2
Meng, QC	1
Engert, F	1
Züchner, S	2
Kelz, MB	1
Syed, S	1
Dallman, JE	2
Li, L	2
Shu, F	1
Wang, XQ	1
Wang, F	2
Cai, L	1
Zhao, X	2
Lv, HG	1
Li, X	4
Zhao, F	1
Hu, Y	2
Liu, Q	1
Sheng, Z	1
Cheng, C	1
Zheng, H	1
Lanuti, M	1
Liu, R	2
Wang, P	1
Shen, Y	1
Zhang, WJ	1
Jing, H	1
Wang, C	2
Zhao, L	1
Cheng, J	1
Qin, P	2
Lin, H	1
Ye, C	1
Cheng, S	1
Cai, Y	1
Wang, L	3
Xiao, R	1
He, X	2
Gao, J	1
Xu, H	1
Fan, X	1
Du, G	1
Wang, S	3
Li, Z	1
Liu, J	2
Morena, M	1
Berardi, A	1
Peloso, A	1
Valeri, D	1
Palmery, M	1
Trezza, V	1
Schelling, G	1
Campolongo, P	1
Visvabharathy, L	1
Freitag, NE	1
Chen, B	2
Zhuo, Q	1
Bao, C	1
Lin, L	1
Mardini, F	1
Tang, JX	1
Li, JC	1
Arroliga, MJ	1
Eckenhoff, RG	1
Eckenhoff, MF	1
Behmenburg, F	1
van Caster, P	1
Bunte, S	1
Brandenburger, T	1
Heinen, A	1
Hollmann, MW	1
Huhn, R	1
Wu, L	1
Feng, Y	1
Zhao, W	2
Zuo, W	2
Zhong, L	1
Luo, F	1
Pearn, ML	1
Schilling, JM	1
Jian, M	1
Egawa, J	1
Wu, C	2
Mandyam, CD	1
Fannon-Pavlich, MJ	1
Nguyen, U	1
Bertoglio, J	1
Kodama, M	1
Mahata, SK	1
DerMardirossian, C	1
Lemkuil, BP	1
Han, R	1
Mobley, WC	1
Patel, HH	1
Patel, PM	1
Head, BP	1
Bedell, V	1
Marcato, D	1
Pylatiuk, C	1
Mikut, R	1
Stegmaier, J	1
Scudder, W	1
Wray, M	1
Strähle, U	1
Peravali, R	1
Zhou, J	1
Ma, L	1
Dong, T	1
Zhuang, Z	1
Zhong, Y	1
Qin, Y	1
Wei, Y	2
Pan, S	1
Jiang, Y	1
Xie, Y	1
Woodhouse, A	1
Fernandez-Martos, CM	1
Atkinson, RAK	1
Hanson, KA	1
Collins, JM	1
O'Mara, AR	1
Terblanche, N	1
Skinner, MW	1
Vickers, JC	1
King, AE	1
Pavković, Ž	1
Milanović, D	1
Ruždijić, S	1
Kanazir, S	1
Pešić, V	1
Elmorsy, SA	1
Soliman, GF	1
Rashed, LA	1
Elgendy, H	1
Yamada, T	1
Nagata, H	1
Kosugi, S	1
Suzuki, T	1
Morisaki, H	1
Kotake, Y	1
Ren, L	2
Hao, X	2
Min, S	8
Deng, J	1
Liu, D	3
Cho, S	1
Jung, YJ	1
Suh, EC	1
Baik, HJ	1
Han, JI	1
Lee, GY	1
Lee, KE	1
Glen, JB	1
Marquart, K	1
Herbert, J	1
Amend, N	1
Thiermann, H	1
Worek, F	1
Wille, T	1
Gazzaz, M	1
Saini, J	1
Pagliardini, S	1
Tsui, B	1
Jeffery, C	1
El-Hakim, H	1
Run, X	1
Wei, Z	1
Zeng, K	1
Liang, Z	1
Ke, D	1
Wang, Q	3
Wang, JZ	1
Zhang, B	1
Wang, X	4
Yu, H	1
Kang, F	1
Chen, Z	3
Meng, Y	1
Dai, M	1
Koutsogiannaki, S	1
Bernier, R	1
Tazawa, K	1
Yuki, K	1
Cheng, L	1
Lan, Y	1
Zheng, L	1
Wu, F	1
Wong, SS	1
Sun, L	1
Qiu, Q	1
Gu, P	1
Li, Q	2
Wang, XM	1
Cheung, CW	1
Cui, S	1
Jing, G	1
Ding, H	1
Xia, Z	4
Feng, Z	1
Wang, JW	1
Dong, WW	1
Xu, ZF	1
Wei, Q	1
Zhao, J	1
Zhou, X	2
Yu, L	1
Song, F	1
Lv, X	1
Meng, J	1
Zhang, WY	1
Zhang, QL	1
Xu, MJ	1
Chen, X	1
Xiao, ZY	1
Hou, DN	1
Li, DB	1
Zhang, XP	1
Yamamoto, N	1
Arima, H	1
Sugiura, T	1
Hirate, H	1
Taniura, H	1
Suzuki, K	1
Sobue, K	1
Yoo, YC	1
Yoo, KJ	1
Lim, BJ	1
Jun, JH	1
Shim, JK	1
Kwak, YL	1
Ren, J	1
Lenal, F	1
Ding, X	1
Greer, JJ	1
Ferrando, C	1
Aguilar, G	1
Piqueras, L	1
Soro, M	1
Moreno, J	1
Belda, FJ	1
Brekke, HK	1
Hammersborg, SM	1
Lundemoen, S	1
Mongstad, A	1
Kvalheim, VL	1
Haugen, O	1
Husby, P	1
Ching, S	1
Liberman, MY	1
Chemali, JJ	1
Westover, MB	1
Kenny, JD	1
Purdon, PL	1
Brown, EN	1
Takagaki, M	1
Feuerstein, D	1
Kumagai, T	1
Gramer, M	1
Yoshimine, T	1
Graf, R	1
Lv, F	2
Shen, YW	1
Peng, LH	1
Li, P	5
Luo, J	6
Wei, K	5
Zhou, R	1
Yang, Z	1
Tang, X	1
Tan, Y	1
Wu, X	1
Liu, F	2
Bruells, CS	1
Maes, K	1
Rossaint, R	2
Thomas, D	1
Cielen, N	1
Bergs, I	1
Bleilevens, C	1
Weis, J	2
Gayan-Ramirez, G	1
Shao, H	1
Xia, W	1
Luo, G	4
Zhu, G	2
Chi, X	4
Zhang, A	1
Quiroga, C	1
Chaparro, RE	1
Karlnoski, R	1
Erasso, D	1
Gordon, M	1
Morgan, D	1
Bosco, G	1
Rubini, A	1
Parmagnani, A	1
Paoli, A	1
Mangar, D	1
Camporesi, EM	1
Li, WW	1
Cheng, LZ	1
Zou, Z	1
Tian, ML	1
Zhang, H	1
Raya, AD	1
Shi, XY	1
Zhu, X	1
Xie, F	1
Yang, H	1
Hu, Q	1
Luo, H	1
Liu, L	2
Cavalcanti, V	1
Santos, CL	1
Araújo, MN	1
Heil, LB	1
Morales, MM	1
Fernandes, FC	1
Villela, N	1
Rocco, PR	1
Luo, C	2
Li, H	1
Irwin, MG	1
Umezawa, N	1
Arisaka, H	1
Sakuraba, S	1
Sugita, T	1
Matsumoto, A	1
Kaku, Y	1
Yoshida, K	2
Kuwana, S	1
Yue, ZY	1
Dong, H	1
Wang, YF	1
Song, CY	1
Yang, WC	1
Qian, H	1
Lu, SJ	1
Chang, FF	1
Liu, S	2
Wang, G	2
Zhu, A	1
Ge, M	1
Zhou, S	2
Xiong, M	1
Nadavaluru, PR	1
Ye, JH	1
Eloy, JD	1
Bekker, A	1
Schläpfer, M	2
Piegeler, T	2
Dull, RO	1
Schwartz, DE	1
Mao, M	2
Bonini, MG	1
Z'Graggen, BR	1
Beck-Schimmer, B	2
Minshall, RD	1
Qin, M	1
Zeidler, Z	1
Moulton, K	1
Krych, L	1
Smith, CB	1
Waterford, SD	1
Rastegar, M	1
Goodwin, E	1
Lapchak, PA	1
Juan, V	1
Haji, F	1
Bombien, R	1
Khoynezhad, A	1
Lin, MC	2
Lin, CF	1
Li, CF	1
Sun, DP	1
Wang, LY	1
Hsing, CH	2
Pakkianathan, C	1
Benggon, M	1
Khatibi, NH	1
Marcantonio, S	1
Applegate, R	1
Tang, J	1
Zhang, L	3
Jin, J	1
Yao, J	1
Yue, Z	1
Yang, W	1
Fu, S	1
Hsiao, HT	1
Wu, H	1
Huang, PC	1
Tsai, YC	1
Liu, YC	1
Zhao, CH	1
Li, GH	1
Zhao, B	1
Wang, ZB	1
Yu, QJ	1
Liu, C	2
Chen, MR	1
Zou, Y	1
Wang, TY	1
Zuo, YX	1
Wang, TH	1
Xu, Z	1
Yu, J	1
Wu, J	4
Qi, F	1
Wu, B	1
Liang, Y	1
Dong, Z	1
Zhang, G	1
Lin, W	1
Wang, B	2
Ge, RS	1
Lian, Q	1
Hao, XC	1
Xu, F	1
Guo, X	1
Caroff, DA	1
Szumita, PM	1
Klompas, M	1
Kaur, J	1
Flores Gutiérrez, J	1
Nistri, A	1
Shi, R	1
Meng, C	1
Wang, T	1
Deng, X	1
Kellner, P	1
Müller, M	1
Eugster, P	1
Booy, C	1
Wen, J	1
Duan, N	1
Jing, GX	1
Xiao, Y	1
Romuk, E	1
Szczurek, W	1
Nowak, P	1
Skowron, M	1
Prudel, B	1
Hudziec, E	1
Chwalińska, E	1
Birkner, E	1
Oras, J	1
Redfors, B	1
Ali, A	1
Lundgren, J	1
Sihlbom, C	1
Thorsell, A	1
Seeman-Lodding, H	1
Omerovic, E	1
Ricksten, SE	1
Lin, Y	1
Kobayashi, K	1
Yoshino, F	1
Takahashi, SS	1
Todoki, K	1
Maehata, Y	1
Komatsu, T	1
Lee, MC	1
Jacob, S	1
Abraham, AE	1
McKelvey, G	1
Claure, N	1
Suguihara, C	1
Peng, J	1
Hehre, D	1
D'Ugard, C	1
Bancalari, E	1
Song, XM	1
Wang, YL	1
Li, JG	1
Wang, CY	1
Zhou, Q	1
Zhang, ZZ	1
Liang, H	1
Rossaint, J	1
Fries, M	1
Rex, S	1
Coburn, M	1
Kostopanagiotou, GG	1
Grypioti, AD	1
Matsota, P	1
Mykoniatis, MG	1
Demopoulos, CA	1
Papadopoulou-Daifoti, Z	1
Pandazi, A	1
Ji, X	1
Cao, SH	1
Zaballos, M	2
Jimeno, C	1
Almendral, J	2
Atienza, F	1
Patiño, D	1
Valdes, E	1
Navia, J	2
Anadón, MJ	2
Wang, HY	2
Wang, GL	2
Yu, YH	2
Chen, XY	1
Long, JJ	1
Shen, B	1
Luo, T	1
Stewart, L	1
McMurran, TJ	1
Leung, LS	1
Ergün, Y	1
Darendeli, S	1
Imrek, S	1
Kilinç, M	1
Oksüz, H	1
Menku, A	1
Ogden, M	1
Saraymen, R	1
Jin, YW	1
Wang, DY	1
Wang, ZG	1
Imoto, A	1
Yokoyama, T	1
Suwa, K	1
Yamasaki, F	1
Yatabe, T	1
Yokoyama, R	1
Yamashita, K	1
Selldén, E	1
Dong, J	2
Cao, J	1
Bennetts, PS	1
Pierce, JD	1
Jiang, X	1
Qu, Q	1
Ou, C	1
Mu, X	1
Fang, L	1
Yeh, CH	1
Cho, W	1
So, EC	1
Chu, CC	1
Wang, JJ	1
Kubo, K	1
Inada, T	1
Shingu, K	1
Bao, HG	1
Li, S	1
Wang, M	1
Agarwal, S	1
Mayevsky, A	1
Joshi, S	1
Prakash, A	1
Medhi, B	1
Patyar, S	1
Shivaramaiah, PD	1
Khanduja, S	1
Palhora, S	1
Saikia, B	1
Bonnet, U	1
Kurita, T	2
Uraoka, M	1
Morita, K	2
Suzuki, M	1
Morishima, Y	1
Sato, S	2
Kitamura, T	1
Sato, K	2
Kawamura, G	1
Yamada, Y	2
Ozkan, F	1
Senayli, Y	1
Ozyurt, H	1
Erkorkmaz, U	1
Bostan, B	1
Ye, L	1
Luo, CZ	1
McCluskey, SA	1
Pang, QY	1
Zhu, T	1
Harman, F	1
Hasturk, AE	1
Yaman, M	1
Arca, T	1
Kilinc, K	1
Sargon, MF	1
Kaptanoglu, E	1
Annecke, T	2
Rehm, M	2
Bruegger, D	1
Kubitz, JC	2
Kemming, GI	2
Stoeckelhuber, M	1
Stoekelhuber, M	1
Becker, BF	1
Conzen, PF	2
Yucel, A	1
Aydogan, MS	1
Parlakpinar, H	1
Erdogan, MA	1
Kurt, A	1
Ucar, M	1
Durmus, M	1
Liu, XB	1
Shi, J	1
Sun, B	1
Gong, Y	1
He, Y	1
Xu, G	1
Luo, A	1
Li, E	1
Yuksel, A	1
Erdur, B	1
Kortunay, S	1
Ergin, A	1
Seehase, M	1
Houthuizen, P	1
Jellema, RK	1
Collins, JJ	1
Bekers, O	1
Breuer, J	1
Kramer, BW	1
Ball, C	1
Westhorpe, R	1
Taniguchi, T	2
Kanakura, H	2
Takemoto, Y	1
Kidani, Y	1
Yamamoto, K	1
Kazama, T	1
Terao, H	1
González, P	1
Inagawa, G	1
Kikuchi, T	1
Nishihama, M	1
Shioda, M	1
Koyama, Y	1
Andoh, T	1
Awad, IT	1
Chan, V	1
Nishiyama, T	1
Matsukawa, T	1
Hanaoka, K	1
Hu, XM	1
Lu, Y	1
Yao, SL	1
Yagmurdur, H	1
Yagmurder, H	1
Akca, G	1
Aksoy, M	1
Arslan, M	1
Baltaci, B	1
Dikmen, B	1
Zhang, PB	1
Zhao, JJ	1
Kang, QY	1
Yumoto, M	1
Nishida, O	1
Nakamura, F	1
Katsuya, H	1
Statler, KD	1
Alexander, H	1
Vagni, V	1
Dixon, CE	1
Clark, RS	1
Jenkins, L	1
Kochanek, PM	1
Karwacki, Z	1
Kowiański, P	1
Dziewiatowski, J	1
Domaradzka-Pytel, B	1
Ludkiewicz, B	1
Wójcik, S	1
Narkiewicz, O	1
Moryś, J	1
Rodríguez-López, JM	1
Sánchez-Conde, P	1
Lozano, FS	1
Nicolás, JL	1
García-Criado, FJ	1
Cascajo, C	1
Muriel, C	1
Boyd, JJ	1
Kyttä, JV	1
Aittomäki, JV	1
Rosenberg, PH	1
Seppälä, TA	1
Randell, TT	1
Oria, M	1
Raguer, N	1
Chatauret, N	1
Bartolí, R	1
Odena, G	1
Planas, R	1
Córdoba, J	1
Jialili, A	1
Abasi, K	1
Li, XJ	1
Bauer, A	1
Baschnegger, H	1
Renz, V	1
Brandl, U	1
Brenner, P	1
Thein, E	1
Reichart, B	1
Schmoeckel, M	1
Christ, F	1
Bagcivan, I	1
Cevit, O	1
Yildirim, MK	1
Gursoy, S	1
Yildirim, S	1
Kaya, T	1
Mimaroglu, C	1
Kakehata, J	1
Togashi, H	1
Yamaguchi, T	1
Morimoto, Y	1
Yoshioka, M	1
Amer, J	1
Weiss, L	1
Reich, S	1
Shapira, MY	1
Slavin, S	1
Fibach, E	1
Kobayashi, I	1
Kokita, N	1
Namiki, A	1
Fredriksson, A	1
Pontén, E	1
Gordh, T	1
Eriksson, P	1
Oztürk, E	1
Demirbilek, S	1
Köroğlu, A	1
But, A	1
Begeç, ZO	1
Gülec, M	1
Akyol, O	1
Ersoy, MO	1
Chen, L	1
Xue, Z	1
Jiang, H	1
Lü, YX	1
Zhang, LF	1
Wang, LL	1
Li, HY	1
Li Volti, G	1
Galvano, F	1
Scacco, A	1
Vanella, L	1
Murabito, P	1
Gullo, A	1
Biondi, A	1
Gazzolo, D	1
Vadalà, S	1
Chen, HI	1
Hsieh, NK	1
Kao, SJ	1
Su, CF	1
Langer, K	1
Hilberath, JM	1
Kahr, S	1
Krombach, F	1
Bittmann, I	1
Vermeyen, KM	1
De Hert, SG	1
Adriaensen, HF	1
Ahmad, I	1
Pleuvry, BJ	1
Goto, T	1
Marota, JJ	1
Crosby, G	1
Hilton, DL	1
Einhaus, SL	1
Meric, AL	1
White, RP	1
Schweitzer, JB	1
Park, MR	1
Robertson, JT	1
Tidmarsh, MD	1
Gorchein, A	1
Arcadi, FA	1
Rapisarda, A	1
De Luca, R	1
Trimarchi, GR	1
Costa, G	1
Nimkoff, L	1
Quinn, C	1
Silver, P	1
Sagy, M	1
Graham, MR	1
Thiessen, DB	1
Mutch, WA	1
Kelbel, I	1
Koch, T	1
Weber, A	1
Schiefer, HG	1
van Ackern, K	1
Neuhof, H	1
Gilron, I	1
Quirion, R	1
Coderre, TJ	1
Ikeno, S	1
Akazawa, S	1
Shimizu, R	1
Nakaigawa, Y	1
Ishii, R	1
Inoue, S	1
Satoh, M	1
Thomas, SP	1
Ross, DL	1
Tanaka, K	2
Karasawa, F	1
Sato, T	1
Kodaka, M	1
Mori, T	1
Nomura, M	1
Kawazoe, T	1
Clark, SC	1
Sudarshan, CD	1
Khanna, R	1
Roughan, JV	1
Flecknell, PA	1
Dark, JH	1
Bray, RJ	1
Fortin, D	1
McCormick, CI	1
Remsen, LG	1
Nixon, R	1
Neuwelt, EA	1
Lee, Y	1
Chung, C	1
Oh, YS	1
Holtkamp, M	1
Tong, X	1
Walker, MC	1
Bhardwaj, A	1
Castro III, AF	1
Alkayed, NJ	1
Hurn, PD	1
Kirsch, JR	1
Kahveci, FS	1
Kahveci, N	1
Alkan, T	1
Goren, B	1
Korfali, E	1
Ozluk, K	1
De Riu, PL	1
Petruzzi, V	1
Testa, C	1
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Melis, F	1
Caria, MA	1
Mameli, O	1
Krivosic-Horber, R	1
Reyfort, H	1
Becq, MC	1
Adnet, P	1