glycerol and Acute Kidney Injury studies

Moon: The natural satellite of the planet Earth. It includes the lunar cycles or phases, the lunar month, lunar landscapes, geography, and soil.

Acute Kidney Injury: Abrupt reduction in kidney function. Acute kidney injury encompasses the entire spectrum of the syndrome including acute kidney failure; ACUTE KIDNEY TUBULAR NECROSIS; and other less severe conditions.

Research Excerpts

Excerpt	Relevance	Reference
"Here in this study, we investigated the therapeutic efficacy of Rg1 and Rg3 in alleviating glycerol-induced acute kidney injury, also known as rhabdomyolysis-induced acute kidney injury (RAKI)."	8.31	Therapeutic propensity of ginsenosides Rg1 and Rg3 in rhabdomyolysis-induced acute kidney injury and renohepatic crosstalk in rats. ( Chang, SN; Kang, SC; Park, JG, 2023)
"5 ml/kg saline (Group A) or of the same volume 50% glycerol was used to induce rhabdomyolysis and subsequent AKI (Group B)."	8.12	Pifithrin-α ameliorates glycerol induced rhabdomyolysis and acute kidney injury by reducing p53 activation. ( Jiejun, W; Lisha, Z; Niansong, W; Qin, X; Yuqiang, C, 2022)
" This study aimed to evaluate the renoprotective effect of LF (30, 100, and 300 mg/kg orally) against glycerol (GLY)-induced rhabdomyolysis (RM) in rats."	8.12	Dose-dependent renoprotective impact of Lactoferrin against glycerol-induced rhabdomyolysis and acute kidney injury. ( Helal, MG; Madkour, AH; Said, E; Salem, HA, 2022)
"The current study investigated the effects of treatment with 300 mg/kg valproic acid on rhabdomyolysis and acute kidney injury induced by intramuscular injection of hypertonic glycerol in rats."	8.02	Valproate attenuates hypertonic glycerol-induced rhabdomyolysis and acute kidney injury. ( Abd-Eldayem, AM; Abdelzaher, LA; Badary, DM; Hareedy, MS; Mohammed Alnasser, S, 2021)
"5-aminolevulinic acid markedly reduced renal dysfunction and tubular damage in mice with rhabdomyolysis-induced AKI."	7.91	5-Aminolevulinic acid exerts renoprotective effect via Nrf2 activation in murine rhabdomyolysis-induced acute kidney injury. ( Itano, S; Kashihara, N; Kidokoro, K; Nagasu, H; Sasaki, T; Satoh, M; Sogawa, Y; Uchida, A, 2019)
"The protective activity of N-(2-hydroxyphenyl)acetamide (NA-2) and NA-2-coated gold nanoparticles (NA-2-AuNPs) in glycerol-treated model of acute kidney injury (AKI) in mice was investigated."	7.91	N-(2-hydroxyphenyl)acetamide and its gold nanoparticle conjugation prevent glycerol-induced acute kidney injury by attenuating inflammation and oxidative injury in mice. ( Ateeq, M; Hussain, SS; Kabir, N; Shah, MR; Siddiqui, RA; Simjee, SU, 2019)
"Glycerol injection in rats can lead to rhabdomyolysis, with the release of the intracellular muscle content to the extracellular compartment and acute kidney injury (AKI)."	7.91	Protective effect of calcitriol on rhabdomyolysis-induced acute kidney injury in rats. ( Coimbra, TM; Costa, RS; de Almeida, LF; Francescato, HDC; Reis, NG; Silva, CGAD, 2019)
" In this study, we investigated the effectiveness and mechanisms of action of anisodamine in promoting recovery from glycerol-induced acute kidney injury (AKI)."	7.91	Protective effect of anisodamine in rats with glycerol-induced acute kidney injury. ( An, LP; An, R; Du, XF; Li, YF; Sun, JH; Wang, W; Wu, GL; Xu, BY; Yu, K; Zhang, GH, 2019)
"Glycerol injection increased the kidney relative weight as well as rhabdomyolysis (RM)- and AKI-related index levels, including the levels of creatine kinase, lactate dehydrogenase, creatinine, urea, and Kim-1 expression."	7.91	Oleuropein suppresses oxidative, inflammatory, and apoptotic responses following glycerol-induced acute kidney injury in rats. ( Abdel Moneim, AE; Al-Brakati, AY; Guo, L; Jiang, N; Kassab, RB; Ni, Z; Othman, MS; Yin, M, 2019)
"In this study, the protective effect of valsartan against glycerol-induced acute kidney injury (AKI) in male albino rats was investigated."	7.88	Valsartan prevents glycerol-induced acute kidney injury in male albino rats by downregulating TLR4 and NF-κB expression. ( Luan, Q; Qiu, S; Sun, X, 2018)
"The model consisted of heat stress exposure (1 h, 37°C) plus rhabdomyolysis (R) induced by repetitive IM injections of glycerol (7."	7.88	Kidney Injury from Recurrent Heat Stress and Rhabdomyolysis: Protective Role of Allopurinol and Sodium Bicarbonate. ( Blas-Marron, MG; García-Arroyo, FE; Glaser, J; Gonzaga, G; Johnson, RJ; Madero, M; Muñoz-Jimenez, I; Osorio-Alonso, H; Roncal-Jiménez, CA; Sánchez-Lozada, LG; Silverio, O; Tapia, E; Weiss, I, 2018)
"The aim of this study was to investigate the protective role and underlying mechanisms of curcumin on glycerol-induced acute kidney injury (AKI) in rats."	7.85	Effect of curcumin on glycerol-induced acute kidney injury in rats. ( Bao, D; Chen, Q; Dai, Y; Fu, H; Hao, Q; Hou, D; Pan, X; Wu, J; Yin, Y; Zheng, Y, 2017)
"We investigated the renal protective effect of low-molecular-weight sulfated polysaccharide (LMWSP) fractions extracted from Laminaria japonica on glycerol-induced acute kidney injury (AKI) in rats."	7.85	Renoprotective effect of low-molecular-weight sulfated polysaccharide from the seaweed Laminaria japonica on glycerol-induced acute kidney injury in rats. ( Li, X; Wang, J; Zhang, H; Zhang, Q, 2017)
"Pretreatment by HRS ameliorated renal dysfunction in glycerol-induced rhabdomyolysis by inhibiting oxidative stress and the inflammatory response."	7.80	Pretreatment with hydrogen-rich saline reduces the damage caused by glycerol-induced rhabdomyolysis and acute kidney injury in rats. ( Gao, X; Gu, H; Sun, X; Yang, M; Zhao, B; Zhao, X, 2014)
"This study was conducted to elucidate the role of renal macrophages in the development of acute kidney injury (AKI) in a glycerol (Gly)-induced rhabdomyolysis mouse model."	7.80	Macrophage depletion ameliorates glycerol-induced acute kidney injury in mice. ( Chang, SH; Cho, HS; Jeon, DH; Jung, MH; Kim, JH; Lee, DW; Park, DJ, 2014)
" In this study, we evaluated the role of p53 activation in glycerol-induced acute kidney injury (Gly-AKI)."	7.77	p53-Mediated oxidative stress and tubular injury in rats with glycerol-induced acute kidney injury. ( Bouçada Inácio Peixoto, E; Butori Lopes de Faria, J; Homsi, E; Janino, P; Machado de Brito, S; Mota da Silva, S, 2011)
" We tested the effect of silymarin administration before glycerol-induced acute kidney injury (Gly-AKI) in rats."	7.76	Silymarin exacerbates p53-mediated tubular apoptosis in glycerol-induced acute kidney injury in rats. ( de Brito, SM; Homsi, E; Janino, P, 2010)
"Neoadjuvant treatment with gemcitabine, cisplatin, and nab-paclitaxel is feasible and safe prior to resection of intrahepatic cholangiocarcinoma and does not adversely impact perioperative outcomes."	6.79	( Abbey, L; Abdelghany, TM; Abdellatif, MH; Abdelmohsen, UR; Abduljaleel Alzawar, NS; Abid, MF; Abu Kasim, AFB; Abu Saad, H; Adolpho, LF; Agostini, F; Agrizii, AP; Ahmed, S; Akce, M; Åkesson, D; Al-Awaadh, AM; Al-Mutar, DMK; Al-Odayni, AB; Al-Rajhi, AMH; Alaaeldin, R; Alam, M; Alam, MM; Alanazi, MA; Alattar, H; Alawlaqi, MM; Aldebis, HK; Algehainy, NA; Almeida, AA; Aloisi, F; Alrahlah, A; Alsenani, F; Alshabib, A; Altemani, FH; Althagafi, A; Amari, A; Andronesi, AG; Antonyuk, M; Arantes, TD; Araújo, R; Arrotti, S; Asakura, T; Asib, N; Atlaskin, AA; Aung, MS; Axiaq, A; Azekawa, S; Bacon, S; Bagalagel, A; Balbinot, GS; Barnet, LS; Baroyi, SAHM; Barreto, F; Barth, Y; Barysheva, AV; Bassa, E; Basu, R; Basu, S; Bates, C; Bautista, LS; Beitl, K; Beloti, MM; Benatti, G; Benavent-Celma, C; Bentaher, A; Bergsland, N; Bernardino, AF; Bernhardt, A; Bhandari, RK; Bhaskaran, K; Bhate, K; Bhattacharjee, A; Bian, X; Bien, EM; Birch, M; Bishara, K; Biswas, JP; Bleha, R; Bocale, R; Bona, S; Boriani, G; Bouyssi, A; Bradley, D; Bravo-Sánchez, MG; Bressan, GC; Brik, A; Brizuela, A; Brockbank, KGM; Buchner, F; Bunc, M; Buscombe, JR; Butler, AJ; Buzaleh, AM; Buzin, MI; Cabrera-Capetillo, CA; Calvo, AM; Camerota, A; Campagna, G; Campisi, M; Cano, K; Cao, HST; Cardellini, S; Carvalho, AP; Carvalho, BCR; Castillo-Baltazar, OS; Cataldo, P; Chai, P; Chakraborty, S; Chalo, DM; Chan, MY; Chander, S; Changbunjong, T; Chappuis, CJF; Chee, RCH; Chen, C; Chen, CJ; Chen, E; Chen, M; Chen, X; Chen, Y; Cheng, HT; Cheng, MC; Cheow, HK; Chi, Y; Chirikova, NK; Chiu, SH; Cho, G; Cho, HR; Cho, S; Cho, SJ; Choe, A; Choe, YH; Chun, BS; Chun, Z; Cinque, A; Ciopec, M; Cladas, Y; Cleary, SP; Clermont, O; Cléroux, M; Cockburn, J; Collares, FM; Colombini-Ishikiriama, BL; Conn, BN; Cortina, JL; Cox, DRA; Crini, G; Croker, R; Cursaru, DL; Curtis, HJ; da Silva, KJG; Dalla Costa, T; Davy, S; de Araújo, BV; de Cassia Ribeiro Gonçalves, R; de Gaetano, F; de Gregorio, C; de Oliveira, MG; De Vera, MAT; de Vos, M; de-la-Fuente, I; Dell'Oca, I; Delles, M; Déméautis, T; Dempster, M; Deng, YH; Denisenko, Y; Descombes, C; Desideri, G; Devarbhavi, H; Devouassoux, G; Di Bella, G; Di Marco, F; Diao, Y; Dias, BB; Dilgin, Y; Dimopoulou, I; Dionísio, TJ; Dobrovic, A; Dokin, ES; Dolby, T; Dong, X; Dong, Y; Dou, SX; Douglas, IJ; Dousset, S; Du, Z; Duan, M; Duan, SB; Duke-Williams, O; Duteanu, N; Dutertre, S; Dutta, S; Dwyer, MG; Ebenbauer, J; Eggo, RM; El-Mordy, FMA; Elbhnsawi, NA; Elrehany, MA; Elshewemi, SS; Elwakil, BH; Emadzadeh, D; Eraso, E; Ermolenko, E; Erten, K; Ettorre, E; Evans, D; Evans, SJ; Faheem, M; Fallanza, M; Faramarzi, M; Faria, FAC; Faro, DC; Fatma, YS; Fazil, S; Feng, Y; Ferguson, J; Fernandes, MH; Fernández-Domínguez, M; Ferrari, LAL; Ferraz, EP; Ferreira, LC; Ferri, C; Fikry, M; Floris, M; Forbes, H; Fotouh, B; Franke, K; Freitas, AC; Freitas, GP; Frieboes, HB; Fu, B; Fu, Y; Fukina, DG; Fukuda, DH; Fukunaga, K; Fulham, GJ; Furlan, L; Furtado Mesa, M; Furtunescu, FL; Gabbieri, D; Ganash, M; Gebers, JC; Gehman, V; Ghaedi, A; Ghazali, NSM; Ghebrekristos, Y; Gil, J; Gilbert, NM; Gimenes, R; Giordano, L; Glehen, O; Godeau, C; Goh, SK; Goldacre, B; Gomes, AM; Gomes, MPO; Gomes, PS; Gomes, RMODS; Gómez-Coma, L; Grenho, L; Gu, Q; Gu, T; Gu, YC; Guiducci, V; Guillemin, JP; Guo, W; Guo, YW; Gur, E; Guridi, A; Guzmán-López, A; Gvozdenko, T; H Elmaidomy, A; Hagar, M; Haider, S; Han, JM; Hanratty, J; Hans, R; Haque, N; Harharah, HN; Harharah, RH; Harper, S; Hasegawa, N; Hassanin, AH; Hastuti, YP; Hatem, AE; He, R; He, Y; Heinemann, C; Heinmaa, I; Heinzl, F; Helfer, VE; Hester, F; Hickman, G; Hill, MA; Hill, WG; Hintze, V; Ho, JSY; Ho, LY; Hoang, T; Holzer, I; Houbraken, J; Hsu, CN; Hu, J; Hu, X; Hu, Y; Hua, T; Huang, Z; Hulme, WJ; Hunter, A; Ianăşi, C; Ibañez, R; Iezzi, R; Iliuță, L; Im, YM; Imran, M; Inglesby, P; 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"Rhabdomyolysis is characterized by muscle damage and leads to acute kidney injury (AKI)."	5.91	Administration of a single dose of lithium ameliorates rhabdomyolysis-associated acute kidney injury in rats. ( Bernardo, DRD; Canale, D; de Bragança, AC; Nascimento, MM; Seguro, AC; Shimizu, MHM; Volpini, RA, 2023)
"Glycerol was used to induce RM-associated AKI in rats."	5.91	Protective effect of thymol on glycerol-induced acute kidney injury. ( Cheng, F; Liu, X; Qi, G; Wang, Q; Wang, R; Yang, X; Zhou, H, 2023)
"Rhabdomyolysis was induced by a single intramuscular injection of glycerol 50% (10mg/kg) in the thigh caudal muscle."	5.91	Protective effect of citronellol in rhabdomyolysis-induced acute kidney injury in mice. ( Kathem, SH; Mahmood, YS, 2023)
"Daidzein is a dietary isoflavone that has various biological activities."	5.91	Modulation of inflammatory, oxidative, and apoptotic stresses mediates the renoprotective effect of daidzein against glycerol-induced acute kidney injury in rats. ( Abdel Moneim, AE; Al-Amer, OM; Al-Ghamdy, AO; Albarakati, AJA; Albrakati, A; Alharthi, F; Alsharif, KF; Althagafi, HA; Elhefny, MA; Elhenawy, AA; Elmahallawy, EK; Habotta, OA; Hassan, KE; Hawsawi, YM; Kassab, RB; Lokman, MS; Moustafa, AA; Oyouni, AAA, 2023)
"Epigallocatechin gallate (EGCG) was administered for 3 consecutive days to evaluate its protective effects."	5.72	Rhabdomyolysis-induced acute kidney injury and concomitant apoptosis induction via ROS-mediated ER stress is efficaciously counteracted by epigallocatechin gallate. ( Chang, SN; Dey, DK; Haroon, M; Kang, SC, 2022)
"In thalidomide treated mice, blood urea nitrogen (BUN) (59."	5.62	Thalidomide reduces glycerol-induced acute kidney injury by inhibition of NF-κB, NLRP3 inflammasome, COX-2 and inflammatory cytokines. ( Amirshahrokhi, K, 2021)
"Glycerol treatment evoked significant increases in rhabdomyolysis-related markers (creatine kinase and LDH)."	5.62	Using Green Biosynthesized Lycopene-Coated Selenium Nanoparticles to Rescue Renal Damage in Glycerol-Induced Acute Kidney Injury in Rats. ( Abdel Moneim, AE; Al-Amer, O; Al-Brakati, A; Alsharif, KF; Alzahrani, KJ; Bauomy, AA; Habotta, OA; Kabrah, S; Kassab, RB; Lokman, MS; Oyouni, AA, 2021)
"Glycerol treatment caused significant renal histological abnormalities and functional impairment (increased urea and creatinine)."	5.51	Diacerein protects against glycerol-induced acute kidney injury: Modulating oxidative stress, inflammation, apoptosis and necroptosis. ( Abd-Ellatif, RN; Atef, MM; Hafez, YM; Hegab, II; Sadek, MT, 2019)
"Glycerol treatment produced significant renal structural abnormalities and functional impairment (increased urea and creatinine)."	5.46	Protective effect of quinacrine against glycerol-induced acute kidney injury in rats. ( Al Asmari, AK; Al Sadoon, KT; Obaid, AA; Tariq, M; Yesunayagam, D, 2017)
"Suramin treatment decreased interleukin-1β (IL-1β) mRNA, transforming growth factor-β(1) (TGF-β(1)), phospho-p65 of nuclear factor-κB (NF-κB), and cleaved caspase-3 at 48 h compared with glycerol alone."	5.38	Recovery from glycerol-induced acute kidney injury is accelerated by suramin. ( Korrapati, MC; Schnellmann, RG; Shaner, BE, 2012)
"Glycerol treatment resulted in a marked decrease in tissue and urine nitric oxide levels, renal oxidative stress and significantly deranged the renal functions along with deterioration of renal morphology."	5.33	Molsidomine, a nitric oxide donor and L-arginine protects against rhabdomyolysis-induced myoglobinuric acute renal failure. ( Chander, V; Chopra, K, 2005)
"Diethylene glycol (DEG) was found in patients' bottles in a median concentration of 14."	5.30	Epidemic of pediatric deaths from acute renal failure caused by diethylene glycol poisoning. Acute Renal Failure Investigation Team. ( Barr, DB; Barr, JR; Denerville, K; Espindola, J; Hecdivert, C; Hospedales, CJ; Lewis, MJ; Louis, M; Needham, LL; O'Brien, KL; Philen, RM; Placide, MF; Schwartz, B; Selanikio, JD; St Victor, S, 1998)
"Here in this study, we investigated the therapeutic efficacy of Rg1 and Rg3 in alleviating glycerol-induced acute kidney injury, also known as rhabdomyolysis-induced acute kidney injury (RAKI)."	4.31	Therapeutic propensity of ginsenosides Rg1 and Rg3 in rhabdomyolysis-induced acute kidney injury and renohepatic crosstalk in rats. ( Chang, SN; Kang, SC; Park, JG, 2023)
"5 ml/kg saline (Group A) or of the same volume 50% glycerol was used to induce rhabdomyolysis and subsequent AKI (Group B)."	4.12	Pifithrin-α ameliorates glycerol induced rhabdomyolysis and acute kidney injury by reducing p53 activation. ( Jiejun, W; Lisha, Z; Niansong, W; Qin, X; Yuqiang, C, 2022)
" This study aimed to evaluate the renoprotective effect of LF (30, 100, and 300 mg/kg orally) against glycerol (GLY)-induced rhabdomyolysis (RM) in rats."	4.12	Dose-dependent renoprotective impact of Lactoferrin against glycerol-induced rhabdomyolysis and acute kidney injury. ( Helal, MG; Madkour, AH; Said, E; Salem, HA, 2022)
"EGFR promotes autophagy to mediate rhabdomyolysis-induced AKI via STAT3/Atg7 axis, and gefitinib is a potential therapeutic option for AKI."	4.12	EGFR mediated the renal cell apoptosis in rhabdomyolysis-induced model via upregulation of autophagy. ( Deng, Y; Sun, T; Wu, D; Zhang, D, 2022)
"In vivo, we performed an intramuscular injection of 50% glycerol (5 mg/kg body weight) to make rhabdomyolysis-induced AKI."	4.12	Blocking Periostin Prevented Development of Inflammation in Rhabdomyolysis-Induced Acute Kidney Injury Mice Model. ( Ikebe, S; Katsuragi, N; Koibuchi, N; Morishita, R; Muratsu, J; Rakugi, H; Sanada, F; Shibata, K; Taniyama, Y; Tsunetoshi, Y, 2022)
"The current study investigated the effects of treatment with 300 mg/kg valproic acid on rhabdomyolysis and acute kidney injury induced by intramuscular injection of hypertonic glycerol in rats."	4.02	Valproate attenuates hypertonic glycerol-induced rhabdomyolysis and acute kidney injury. ( Abd-Eldayem, AM; Abdelzaher, LA; Badary, DM; Hareedy, MS; Mohammed Alnasser, S, 2021)
" Considering the clinical diagnosis of glycerol-induced hemolysis and acute kidney injury, intravenous hydration and haptoglobin administration were started, which successfully treated the dark red urine and renal dysfunction."	3.96	Acute Kidney Injury with Hemolysis after Glycerin Enema-induced Rectal Injury in a Patient with Type 2 Diabetes. ( Furuya, F; Harima, N; Hayashida, R; Ichijo, M; Kitamura, K; Nakamura, S; Tsuchiya, K, 2020)
"5-aminolevulinic acid markedly reduced renal dysfunction and tubular damage in mice with rhabdomyolysis-induced AKI."	3.91	5-Aminolevulinic acid exerts renoprotective effect via Nrf2 activation in murine rhabdomyolysis-induced acute kidney injury. ( Itano, S; Kashihara, N; Kidokoro, K; Nagasu, H; Sasaki, T; Satoh, M; Sogawa, Y; Uchida, A, 2019)
"The protective activity of N-(2-hydroxyphenyl)acetamide (NA-2) and NA-2-coated gold nanoparticles (NA-2-AuNPs) in glycerol-treated model of acute kidney injury (AKI) in mice was investigated."	3.91	N-(2-hydroxyphenyl)acetamide and its gold nanoparticle conjugation prevent glycerol-induced acute kidney injury by attenuating inflammation and oxidative injury in mice. ( Ateeq, M; Hussain, SS; Kabir, N; Shah, MR; Siddiqui, RA; Simjee, SU, 2019)
"Glycerol injection in rats can lead to rhabdomyolysis, with the release of the intracellular muscle content to the extracellular compartment and acute kidney injury (AKI)."	3.91	Protective effect of calcitriol on rhabdomyolysis-induced acute kidney injury in rats. ( Coimbra, TM; Costa, RS; de Almeida, LF; Francescato, HDC; Reis, NG; Silva, CGAD, 2019)
" In this study, we investigated the effectiveness and mechanisms of action of anisodamine in promoting recovery from glycerol-induced acute kidney injury (AKI)."	3.91	Protective effect of anisodamine in rats with glycerol-induced acute kidney injury. ( An, LP; An, R; Du, XF; Li, YF; Sun, JH; Wang, W; Wu, GL; Xu, BY; Yu, K; Zhang, GH, 2019)
"Glycerol injection increased the kidney relative weight as well as rhabdomyolysis (RM)- and AKI-related index levels, including the levels of creatine kinase, lactate dehydrogenase, creatinine, urea, and Kim-1 expression."	3.91	Oleuropein suppresses oxidative, inflammatory, and apoptotic responses following glycerol-induced acute kidney injury in rats. ( Abdel Moneim, AE; Al-Brakati, AY; Guo, L; Jiang, N; Kassab, RB; Ni, Z; Othman, MS; Yin, M, 2019)
"We found that the levels of creatinine, urea, nitric oxide, alanine transaminase, aspartate aminotransferase, creatine kinase in serum samples, malondialdehyde, nitric oxide, inducible nitric oxide synthase, and endothelial nitric oxide synthase concentrations in renal tissue were increased in the myoglobinuric acute kidney injury group compared with the control group (p<0."	3.88	The Effects of Baicalin on Myoglobinuric Acute Renal Failure in Rats. ( Aydoğdu, N; Süt, N; Taştekin, E; Yalçınkaya Yavuz, Ö, 2018)
" The role of miR-26a in the kidney repair process was evaluated in Wistar rats submitted to an acute kidney injury model of rhabdomyolysis induced by glycerol (6 mL/kg)."	3.88	miR-26a modulates HGF and STAT3 effects on the kidney repair process in a glycerol-induced AKI model in rats. ( Boim, MA; da Silva Novaes, A; da Silva Ribeiro, R; Gattai, PP; Maquigussa, E; Ormanji, MS; Varela, VA, 2018)
"In this study, the protective effect of valsartan against glycerol-induced acute kidney injury (AKI) in male albino rats was investigated."	3.88	Valsartan prevents glycerol-induced acute kidney injury in male albino rats by downregulating TLR4 and NF-κB expression. ( Luan, Q; Qiu, S; Sun, X, 2018)
"The model consisted of heat stress exposure (1 h, 37°C) plus rhabdomyolysis (R) induced by repetitive IM injections of glycerol (7."	3.88	Kidney Injury from Recurrent Heat Stress and Rhabdomyolysis: Protective Role of Allopurinol and Sodium Bicarbonate. ( Blas-Marron, MG; García-Arroyo, FE; Glaser, J; Gonzaga, G; Johnson, RJ; Madero, M; Muñoz-Jimenez, I; Osorio-Alonso, H; Roncal-Jiménez, CA; Sánchez-Lozada, LG; Silverio, O; Tapia, E; Weiss, I, 2018)
"Free heme, a pro-oxidant released from myoglobin, is thought to contribute to the pathogenesis of rhabdomyolysis-associated acute kidney injury (RM-AKI), because renal overexpression of heme oxygenase-1 (HO-1), the rate-limiting enzyme in heme catabolism, confers protection against RM-AKI."	3.85	Dynamic changes in Bach1 expression in the kidney of rhabdomyolysis-associated acute kidney injury. ( Morimatsu, H; Omori, E; Shimizu, H; Takahashi, T; Yamaoka, M, 2017)
"The aim of this study was to investigate the protective role and underlying mechanisms of curcumin on glycerol-induced acute kidney injury (AKI) in rats."	3.85	Effect of curcumin on glycerol-induced acute kidney injury in rats. ( Bao, D; Chen, Q; Dai, Y; Fu, H; Hao, Q; Hou, D; Pan, X; Wu, J; Yin, Y; Zheng, Y, 2017)
"We investigated the renal protective effect of low-molecular-weight sulfated polysaccharide (LMWSP) fractions extracted from Laminaria japonica on glycerol-induced acute kidney injury (AKI) in rats."	3.85	Renoprotective effect of low-molecular-weight sulfated polysaccharide from the seaweed Laminaria japonica on glycerol-induced acute kidney injury in rats. ( Li, X; Wang, J; Zhang, H; Zhang, Q, 2017)
" In this study, we examined the effect of tubastatin A (TA), a highly selective inhibitor of HDAC6, on AKI in a murine model of glycerol (GL) injection-induced rhabdomyolysis."	3.85	Inhibition of HDAC6 protects against rhabdomyolysis-induced acute kidney injury. ( Fang, L; Liu, N; Ma, S; Ma, X; Nie, J; Pi, X; Qiu, A; Shi, Y; Tang, J; Xu, L; Zhuang, S, 2017)
"Murine acute kidney injury was induced by intraperitoneal injections of folic acid (nephrotoxic acute kidney injury) or by IM injections of glycerol (rhabdomyolysis-induced acute kidney injury)."	3.83	Reversal of Acute Kidney Injury-Induced Neutrophil Dysfunction: A Critical Role for Resistin. ( Kellum, JA; Miller, L; Ruiz-Velasco, V; Singbartl, K, 2016)
"In this study, we used glycerol-induced renal injury as a model of rhabdomyolysis-induced AKI."	3.81	Differences in gene expression profiles and signaling pathways in rhabdomyolysis-induced acute kidney injury. ( Cai, G; Chen, X; Geng, X; Hong, Q; Wang, Y; Wu, D; Yang, J; Zhang, G; Zheng, W, 2015)
"Pretreatment by HRS ameliorated renal dysfunction in glycerol-induced rhabdomyolysis by inhibiting oxidative stress and the inflammatory response."	3.80	Pretreatment with hydrogen-rich saline reduces the damage caused by glycerol-induced rhabdomyolysis and acute kidney injury in rats. ( Gao, X; Gu, H; Sun, X; Yang, M; Zhao, B; Zhao, X, 2014)
" In glycerol-induced myoglobinuric acute kidney injury, we found an increase in the nuclear factor erythroid 2-related factor 2 (Nrf2) nuclear protein, a key redox-sensitive transcription factor, and Nrf2-regulated genes and proteins including upregulation of heme oxygenase-1."	3.80	Inhibition of cytochrome P450 2E1 and activation of transcription factor Nrf2 are renoprotective in myoglobinuric acute kidney injury. ( Baliga, R; Liu, H; Shah, SV; Wang, Z, 2014)
" Hence, we tested the following: i) Does acute kidney injury (AKI) up-regulate the normally renal silent AAT gene? ii) Does rapid urinary AAT excretion result? And iii) Can AAT's anti-protease/anti-neutrophil elastase (NE) activity protect injured proximal tubule cells? CD-1 mice were subjected to ischemic or nephrotoxic (glycerol, maleate, cisplatin) AKI."	3.80	Rapid renal alpha-1 antitrypsin gene induction in experimental and clinical acute kidney injury. ( Frostad, KB; Johnson, AC; Zager, RA, 2014)
"This study was conducted to elucidate the role of renal macrophages in the development of acute kidney injury (AKI) in a glycerol (Gly)-induced rhabdomyolysis mouse model."	3.80	Macrophage depletion ameliorates glycerol-induced acute kidney injury in mice. ( Chang, SH; Cho, HS; Jeon, DH; Jung, MH; Kim, JH; Lee, DW; Park, DJ, 2014)
"For the study of pharmacodynamics, recombinant human HGF was intravenously administered to rats with glycerol-induced acute kidney injury (AKI)."	3.80	Pharmacokinetics and pharmacodynamics following intravenous administration of recombinant human hepatocyte growth factor in rats with renal injury. ( Abe, T; Adachi, E; Adachi, K; Fukuta, K; Hirose-Sugiura, T; Ikebuchi, F; Kato, Y; Matsumoto, K; Yamashita, A, 2014)
" To investigate GF delivery in vivo, a hydrogel loaded with murine EGF or bFGF was injected subcapsularly into the left kidney of mice with experimental acute kidney injury caused by glycerol induced rhabdomyolysis."	3.79	Growth factor delivery from hydrogel particle aggregates to promote tubular regeneration after acute kidney injury. ( Bussolati, B; Camussi, G; Carvalhosa, R; Freudenberg, U; Hauser, PV; Tsurkan, MV; Werner, C; Zieris, A, 2013)
" We measured plasma and urinary levels of HO-1 by ELISA during the induction and/or maintenance phases of four mouse models of AKI: ischemia/reperfusion, glycerol-induced rhabdomyolysis, cisplatin nephrotoxicity, and bilateral ureteral obstruction."	3.78	Plasma and urinary heme oxygenase-1 in AKI. ( Becker, K; Johnson, AC; Zager, RA, 2012)
" In this study, we evaluated the role of p53 activation in glycerol-induced acute kidney injury (Gly-AKI)."	3.77	p53-Mediated oxidative stress and tubular injury in rats with glycerol-induced acute kidney injury. ( Bouçada Inácio Peixoto, E; Butori Lopes de Faria, J; Homsi, E; Janino, P; Machado de Brito, S; Mota da Silva, S, 2011)
" We tested the effect of silymarin administration before glycerol-induced acute kidney injury (Gly-AKI) in rats."	3.76	Silymarin exacerbates p53-mediated tubular apoptosis in glycerol-induced acute kidney injury in rats. ( de Brito, SM; Homsi, E; Janino, P, 2010)
"Rhabdomyolysis was induced in rats by IM glycerol (GLY) injection, which largely recapitulates the full clinical syndrome."	3.74	Evidence for sustained renal hypoxia and transient hypoxia adaptation in experimental rhabdomyolysis-induced acute kidney injury. ( Bachmann, S; Eckardt, KU; Frei, U; Goldfarb, M; Heyman, SN; Rosen, S; Rosenberger, C; Schrader, T; Shina, A, 2008)
"CD-1 mice were subjected to three diverse models of renal stress: (1) endotoxemia [Escherichia coli lipopolysaccharide (LPS), injection]; (2) ischemia/reperfusion (I/R); or (3) glycerol-induced rhabdomyolysis."	3.73	Renal tubular triglyercide accumulation following endotoxic, toxic, and ischemic injury. ( Hanson, SY; Johnson, AC; Zager, RA, 2005)
" Furthermore, whether subacute/insidious tubular injury [eg, cyclosporine A (CSA), tacrolimus toxicity], nontubular injury (eg, acute glomerulonephritis), or physiological stress (eg, mild dehydration) impact renal cholesterol homeostasis have not been addressed."	3.71	Renal cholesterol accumulation: a durable response after acute and subacute renal insults. ( Andoh, T; Bennett, WM; Zager, RA, 2001)
"Male CD-1 mice were subjected to glycerol-induced myohemoglobinuria (MH), systemic heat shock (HS), or E."	3.71	Renal cortical cholesterol accumulation is an integral component of the systemic stress response. ( Johnson, A; Zager, RA, 2001)
"We employed the glycerol model of acute renal failure (Gly-ARF), a model in which oxidant damage occurs in the kidney and other organs as a result of rhabdomyolysis and hemolysis."	3.69	Acquired resistance to acute oxidative stress. Possible role of heme oxygenase and ferritin. ( Alam, J; Croatt, AJ; Nath, KA; Vercellotti, GM; Vogt, BA, 1995)
" ARF was produced by ischemia or glycerol."	3.69	Effects of efonidipine hydrochloride (NZ-105), a new calcium antagonist, against acute renal failure in rats. ( Masuda, Y; Shudo, C; Sugita, H; Tanaka, S; Tomita, K, 1994)
"In glycerol-induced acute renal failure, a model of rhabdomyolysis, clusterin mRNA was markedly increased 24 hours after injection of glycerol (control 97 +/- 21 versus glycerol 3644 +/- 134 optical density units; p < 0."	3.69	Induction of clusterin in acute and chronic oxidative renal disease in the rat and its dissociation from cell injury. ( Correa-Rotter, R; Dvergsten, J; Hostetter, TH; Manivel, JC; Nath, KA; Rosenberg, ME, 1994)
" 21-AS was then administered to rats developing renal failure from glycerol-induced rhabdomyolysis."	3.69	Synergistic renal protection by combining alkaline-diuresis with lipid peroxidation inhibitors in rhabdomyolysis: possible interaction between oxidant and non-oxidant mechanisms. ( Bigler, SA; Dai, Z; Salahudeen, AK; Tachikawa, H; Wang, C, 1996)
"The beneficial effects of post-insult administration of pentoxifylline, a novel hemorheologic agent experimentally studied in various ischemic diseases, were evaluated in two models of acute renal failure (ARF): direct nephrotoxicity (mercuric chloride 4 mg/kg via femoral vein) and hemoglobinuria (glycerol 10 ml/kg i."	3.67	Effects of pentoxifylline in experimental acute renal failure. ( Brunner, LJ; Luke, DR; Vadiei, K, 1989)
"To clarify the diuretic response to furosemide in a diseased state, the urinary excretion of furosemide, water, and electrolytes was examined after a single intravenous injection of furosemide in control rats and rats with mild acute renal failure (ARF) induced by glycerol."	3.67	Increased diuretic response to furosemide in rats with glycerol-induced acute renal failure. ( Hayashi, Y; Hori, R; Huang, Y; Inui, K; Kamiya, A; Kikkoji, T, 1988)
"These studies examined the effects of the volume expansion and the enhanced activity of the renin-angiotensin system during pregnancy on the severity of glycerol-induced myoglobinuric acute renal failure (ARF) in the rat."	3.66	Glycerol-induced myohemoglobinuric acute renal failure in the pregnant rat. ( Bidani, A; Churchill, PC; Fleischmann, L; McDonald, FD, 1980)
"Serum and urine fibrin(ogen) degradation products (FDP), FDP clearances, and serum urea nitrogen (SUN) concentrations of rats challenged with glycerol-induced myohemoglobinuria were measured serially over a period of 4 days."	3.66	The pathogenetic significance of intravascular coagulation in experimental acute renal failure. ( Carvalho, AC; Carvalho, JS; Colman, RW; Landwehr, DM; Oken, DE; Page, LB; Vaillancourt, RA, 1978)
" Neither mode of immunization significantly affected the degree of azotemia or the marked reduction of inulin clearance expected in rats subjected to glycerol-induced myohemoglobinuria."	3.65	Active and passive immunization to angiotensin in experimental acute renal failure. ( Cotes, SC; Flamenbaum, W; Lever, AF; Oken, DE; Powell-Jackson, JD, 1975)
"Gentamicin has been shown in both in vitro and in vivo studies to enhance the generation of reactive oxygen metabolites."	2.40	Oxidant mechanisms in toxic acute renal failure. ( Baliga, R; Shah, SV; Ueda, N; Walker, PD, 1997)
"Gentamicin has been shown both in in vitro and in vivo studies to enhance the generation of reactive oxygen metabolites."	2.40	Oxidant mechanisms in toxic acute renal failure. ( Baliga, R; Shah, SV; Ueda, N; Walker, PD, 1999)
" After chronic administration of this antagonist during 6 weeks after the beginning of DOCA/salt treatment, the severity of hypertension was reduced."	2.37	The significance of vasopressin as a pressor agent. ( Hofbauer, KG; Mah, SC; Michel, JB; Stalder, R; Studer, W; Wood, JM, 1984)
"Oliguric acute renal failure in man is characterized by intense outer cortical vasoconstriction and a marked increase in preglomerular resistance."	2.37	Hemodynamic basis for human acute renal failure (vasomotor nephropathy). ( Oken, DE, 1984)
"Rhabdomyolysis is characterized by muscle damage and leads to acute kidney injury (AKI)."	1.91	Administration of a single dose of lithium ameliorates rhabdomyolysis-associated acute kidney injury in rats. ( Bernardo, DRD; Canale, D; de Bragança, AC; Nascimento, MM; Seguro, AC; Shimizu, MHM; Volpini, RA, 2023)
"Glycerol was used to induce RM-associated AKI in rats."	1.91	Protective effect of thymol on glycerol-induced acute kidney injury. ( Cheng, F; Liu, X; Qi, G; Wang, Q; Wang, R; Yang, X; Zhou, H, 2023)
"Rhabdomyolysis was induced by a single intramuscular injection of glycerol 50% (10mg/kg) in the thigh caudal muscle."	1.91	Protective effect of citronellol in rhabdomyolysis-induced acute kidney injury in mice. ( Kathem, SH; Mahmood, YS, 2023)
"Daidzein is a dietary isoflavone that has various biological activities."	1.91	Modulation of inflammatory, oxidative, and apoptotic stresses mediates the renoprotective effect of daidzein against glycerol-induced acute kidney injury in rats. ( Abdel Moneim, AE; Al-Amer, OM; Al-Ghamdy, AO; Albarakati, AJA; Albrakati, A; Alharthi, F; Alsharif, KF; Althagafi, HA; Elhefny, MA; Elhenawy, AA; Elmahallawy, EK; Habotta, OA; Hassan, KE; Hawsawi, YM; Kassab, RB; Lokman, MS; Moustafa, AA; Oyouni, AAA, 2023)
"Epigallocatechin gallate (EGCG) was administered for 3 consecutive days to evaluate its protective effects."	1.72	Rhabdomyolysis-induced acute kidney injury and concomitant apoptosis induction via ROS-mediated ER stress is efficaciously counteracted by epigallocatechin gallate. ( Chang, SN; Dey, DK; Haroon, M; Kang, SC, 2022)
"In thalidomide treated mice, blood urea nitrogen (BUN) (59."	1.62	Thalidomide reduces glycerol-induced acute kidney injury by inhibition of NF-κB, NLRP3 inflammasome, COX-2 and inflammatory cytokines. ( Amirshahrokhi, K, 2021)
"Glycerol treatment evoked significant increases in rhabdomyolysis-related markers (creatine kinase and LDH)."	1.62	Using Green Biosynthesized Lycopene-Coated Selenium Nanoparticles to Rescue Renal Damage in Glycerol-Induced Acute Kidney Injury in Rats. ( Abdel Moneim, AE; Al-Amer, O; Al-Brakati, A; Alsharif, KF; Alzahrani, KJ; Bauomy, AA; Habotta, OA; Kabrah, S; Kassab, RB; Lokman, MS; Oyouni, AA, 2021)
"Donepezil treatment protected rats from renal dysfunction in a dose-dependent manner and through the cholinergic anti-inflammatory pathway."	1.56	Donepezil protects glycerol-induced acute renal failure through the cholinergic anti-inflammatory and nitric oxide pathway in rats. ( Fu, X; Ren, H; Song, Z; Sun, G; Wang, J; Wang, P; Yue, Y, 2020)
"Glycerol treatment caused significant renal histological abnormalities and functional impairment (increased urea and creatinine)."	1.51	Diacerein protects against glycerol-induced acute kidney injury: Modulating oxidative stress, inflammation, apoptosis and necroptosis. ( Abd-Ellatif, RN; Atef, MM; Hafez, YM; Hegab, II; Sadek, MT, 2019)
"Rhabdomyolysis was monitored using creatine kinase (CK) level."	1.46	Protective Effects of ( Du, Y; Ge, F; Yu, H; Zhang, Y; Zhou, Y, 2017)
"Glycerol treatment produced significant renal structural abnormalities and functional impairment (increased urea and creatinine)."	1.46	Protective effect of quinacrine against glycerol-induced acute kidney injury in rats. ( Al Asmari, AK; Al Sadoon, KT; Obaid, AA; Tariq, M; Yesunayagam, D, 2017)
"In our assay, glycerol-induced acute renal failure in rats was employed to study the protective effects of ginsenoside."	1.40	Protective effect of ginsenoside against acute renal failure via reduction of renal oxidative stress and enhanced expression of ChAT in the proximal convoluted tubule and ERK1/2 in the paraventricular nuclei. ( Cui, YM; Fan, K; Jiang, CL; Lin, Y; Liu, HM; Ma, JM; Xu, Y; Zhang, HA; Zhao, N; Zhou, J, 2014)
"At the same time, in the animals with acute renal failure the level of creatine phosphokinase was increased by 141%."	1.40	[Renoprotective efficacy of different doses of statins in experimental acute renal failure]. ( Horoshko, OM; Zamors'kyĭ, II; Zeleniuk, VH, 2014)
" This study aimed to investigate the influence of ARI on ARG and methylarginines metabolism, and to establish the relationship between disturbances in the latter and reduced NO bioavailability in ARI."	1.39	The influence of acute renal injury on arginine and methylarginines metabolism. ( Gilinsky, MA; Sukhovershin, RA, 2013)
"Rhabdomyolysis is one of the causes of acute renal failure."	1.38	Recombinant human erythropoietin reduces rhabdomyolysis-induced acute renal failure in rats. ( Chiu, YH; Hsu, BG; Lee, CJ; Lee, RP; Subeq, YM; Yang, FL, 2012)
"Suramin treatment decreased interleukin-1β (IL-1β) mRNA, transforming growth factor-β(1) (TGF-β(1)), phospho-p65 of nuclear factor-κB (NF-κB), and cleaved caspase-3 at 48 h compared with glycerol alone."	1.38	Recovery from glycerol-induced acute kidney injury is accelerated by suramin. ( Korrapati, MC; Schnellmann, RG; Shaner, BE, 2012)
"Glycerol (8 ml/kg) was injected into the hind legs of each of the rats in ARF and ARF+HBO groups."	1.38	Preventive effects of hyperbaric oxygen treatment on glycerol-induced myoglobinuric acute renal failure in rats. ( Aksu, B; Ayvaz, S; Basaran, UN; Colak, A; Erboga, M; Kanter, M; Pul, M; Uzun, H, 2012)
"Acute renal failure was accompanied by enhanced daily excretion of asymmetric and symmetric dimethylarginine, increased plasma level of symmetric dimethylarginine, and decreased plasma level of arginine."	1.38	Endogenous regulators of NO bioavailability in rats with acute renal failure. ( Gilinsky, MA; Sukhovershin, RA, 2012)
" Both acute hepatic and renal failure resulted in significantly increased area under the curve (AUC), prolonged elimination half-life (t(1/2β)), and reduced total body clearance (Cl(tot)) compared with respective controls (P<0."	1.37	Effects of acute hepatic and renal failure on pharmacokinetics of flunixin meglumine in rats. ( Hwang, YH; Yun, HI, 2011)
"In our assay, glycerol-induced acute renal failure in rats was employed to study the protective effects of ginsenoside."	1.36	Protective effect of ginsenoside against acute renal failure and expression of tyrosine hydroxylase in the locus coeruleus. ( Jiang, CL; Ma, JM; Wang, M; Yao, QY; Zhang, HA; Zhou, J, 2010)
"Rhabdomyolysis (Fe)-induced acute renal failure (ARF) causes renal inflammation, and, with repetitive insults, progressive renal failure can result."	1.36	Progressive histone alterations and proinflammatory gene activation: consequences of heme protein/iron-mediated proximal tubule injury. ( Johnson, AC; Zager, RA, 2010)
"Many of the studies of acute renal injury have been conducted in young mice usually during their rapid growth phase; yet, the impact of age or growth stage on the degree of injury is unknown."	1.35	Growth and development alter susceptibility to acute renal injury. ( Bomsztyk, K; Johnson, AC; Kim, N; Lund, SR; Naito, M; Zager, RA, 2008)
"Ethanol hypotension was also attenuated after the centrally acting sympatholytic drug moxonidine (selective I(1)-site agonist, 100 microg."	1.35	Facilitation of central imidazoline I(1)-site/extracellular signal-regulated kinase/p38 mitogen-activated protein kinase signalling mediates the hypotensive effect of ethanol in rats with acute renal failure. ( El-Gowelli, HM; El-Mas, MM; Ghazal, AR; Harraz, OF; Mohy El-Din, MM, 2009)
" These results suggested that the decreased CL/F of metoprolol in rats with glycerol-induced ARF is mainly a result of the increased initial absorption rate in the intestine followed by partial saturation of hepatic first-pass metabolism."	1.34	Pharmacokinetics and hepatic extraction of metoprolol in rats with glycerol-induced acute renal failure. ( Hashimoto, Y; Taguchi, M; Taira, S; Tanabe, H, 2007)
"The occurrence of acute renal failure (ARF) following rhabdomyolysis has been put at between 10 and 40% of cases, and accounts for between 3 and 15% of all cases of ARF."	1.33	Reversal of experimental myoglobinuric acute renal failure in rats by quercetin, a bioflavonoid. ( Chander, V; Chopra, K; Singh, D, 2005)
"Glycerol treatment resulted in a marked decrease in tissue and urine nitric oxide levels, renal oxidative stress and significantly deranged the renal functions along with deterioration of renal morphology."	1.33	Molsidomine, a nitric oxide donor and L-arginine protects against rhabdomyolysis-induced myoglobinuric acute renal failure. ( Chander, V; Chopra, K, 2005)
"Glycerol-induced acute renal failure is an experimental model for myoglobinuric nephropathy."	1.33	Effects of amifostine on glycerol-pretreated rabbit kidneys. ( Bali, M; Barun, S; Dileköz, E; Ercan, ZS; Erten, Y; Ertoy, D; Müftüoglu, S; Sarioglu, Y; Sucak, G; Tekeli, N, 2005)
"Rhabdomyolysis-induced myoglobinuric acute renal failure (ARF) accounts for about 10% to 40% of all cases of ARF."	1.33	Protective effect of resveratrol, a polyphenolic phytoalexin on glycerol-induced acute renal failure in rat kidney. ( Chander, V; Chopra, K, 2006)
"Glycerol treatment resulted in marked renal oxidative stress and deranged renal functions which significantly improved by trimetazidine and deferoxamine treatments."	1.32	Attenuation of glycerol-induced acute renal failure in rats by trimetazidine and deferoxamine. ( Chander, V; Chopra, K; Singh, D, 2003)
"Pretreatment by quercetin suppressed the arginase activity in the liver (p < 0."	1.32	Role of quercetin on hepatic urea production in acute renal failure. ( Cvetković, T; Nikolić, J; Sokolović, D, 2003)
"Rhabdomyolysis-induced acute renal failure was induced in mice by glycerol injection."	1.32	Acute tubular injury causes dysregulation of cellular cholesterol transport proteins. ( Hanson, SY; Johnson, AC; Shah, VO; Zager, RA, 2003)
"Glycerol treatment resulted in a marked renal oxidative stress and significantly deranged the renal functions."	1.32	Protective effect of naringin, a bioflavonoid on glycerol-induced acute renal failure in rat kidney. ( Chander, V; Chopra, K; Singh, D, 2004)
"The rats with acute renal failure showed arrested body weight gain and an increase of kidney weight, whereas oral administration of GABA attenuated the physiological changes induced by acute renal failure."	1.32	Protective effect of gamma-aminobutyric acid against glycerol-induced acute renal failure in rats. ( Kim, HY; Nakagawa, T; Sasaki, S; Yokozawa, T, 2004)
"Myoglobinuric acute renal failure has three pathogenic mechanisms: tubular obstruction, renal vasoconstriction, and oxidative stress."	1.32	Effect of N-acetylcysteine on antioxidant status in glycerol-induced acute renal failure in rats. ( Atienza, MP; Broseta Viana, L; Fernández-Fúnez, A; Polo-Romero, FJ; Sánchez Gascón, F, 2004)
"Rats with glycerol-induced acute renal failure (Gly-ARF) were treated with IL-6 200 microg/kg/day."	1.31	Interleukin-6 stimulates tubular regeneration in rats with glycerol-induced acute renal failure. ( Dias, EP; Homsi, E; Lopes de Faria, JB; Ribeiro-Alves, MA, 2002)
"Acute renal failure was induced in rats 24 hours after dehydration by an intramuscular injection of glycerol."	1.31	Stimulation of osteoclastic bone resorption in a model of glycerol-induced acute renal failure: evidence for a parathyroid hormone-independent mechanism. ( Dranitzki-Elhalel, M; Gal-Moscovici, A; Popovtzer, MM; Rubinger, D; Scherzer, P; Weiss, R, 2002)
"Glycerol treated rats exhibited collecting duct and medullary ascending limb dilation and casts, with focal tubular damage, confined mainly to the superficial cortex."	1.31	Nephroprotective effects of pentoxifylline in experimental myoglobinuric acute renal failure. ( Avramovic, V; Djordjevic, V; Mitic-Zlatkovic, M; Savic, V; Stefanovic, V; Vlahovic, P, 2002)
"The pathogenesis of acute renal failure may involve, among other causes, ischemia, vascular congestion, arachidonic acid pathways, and reactive oxygen metabolites."	1.31	Effect of vitamin E and pentoxifylline on glycerol-induced acute renal failure. ( Akpolat, I; Akpolat, T; Bedir, A; Coşar, AM; Kandemir, B; Oztürk, H; Sarikaya, S, 2000)
"Myoglobinuric acute renal failure remains one of the least understood clinical syndromes and the mediators involved remain obscure."	1.31	Role of glomerular nitric oxide in glycerol-induced acute renal failure. ( Eleno, N; López-Novoa, JM; Pérez Barriocanal, F; Valdivielso, JM, 2000)
"The HOCM, diatrizoate, was more toxic to rat kidneys than the LOCM iohexol; PLA2, LPO and calcium load played a role in producing renal function impairment induced by diatrizoate meglumine; amlodipine protected the renal tissue from nephrotoxicity induced by diatrizoate."	1.31	Nephrotoxicity of high- and low-osmolar contrast media. The protective role of amlodipine in a rat model. ( Duan, SB; Liu, FY; Liu, RH; Luo, JA; Peng, YM; Wu, HW; Yang, XL, 2000)
"The effect of glycerol-induced acute renal failure on P-glycoprotein expression and function was evaluated in rats."	1.31	Expression and function of P-glycoprotein in rats with glycerol-induced acute renal failure. ( Huang, ZH; Murakami, T; Nagai, J; Okochi, A; Takano, M; Yumoto, R, 2000)
"Administration of glycerol produces acute renal failure (ARF) accompanied by profound vasoconstriction."	1.31	Contribution of renal oxygenases to glycerol-induced acute renal failure in the rat. ( Newaz, MA; Oyekan, AO, 2002)
"Acute renal failure is a common cause of morbidity and mortality in critically ill patients and frequently results from vasoconstrictive ischemic injury to the kidney."	1.30	Enteral feeding improves outcome and protects against glycerol-induced acute renal failure in the rat. ( Black, KW; Roberts, PR; Zaloga, GP, 1997)
"Glycerol induced acute renal failure (ARF) is known to attenuate subsequent mercuric chloride nephrotoxicity."	1.30	Glycerol-induced acute renal failure attenuates subsequent HgCl2-associated nephrotoxicity: correlation of renal function and morphology. ( Backenroth, R; Popovtzer, MM; Schuger, L; Wald, H, 1998)
"Diethylene glycol (DEG) was found in patients' bottles in a median concentration of 14."	1.30	Epidemic of pediatric deaths from acute renal failure caused by diethylene glycol poisoning. Acute Renal Failure Investigation Team. ( Barr, DB; Barr, JR; Denerville, K; Espindola, J; Hecdivert, C; Hospedales, CJ; Lewis, MJ; Louis, M; Needham, LL; O'Brien, KL; Philen, RM; Placide, MF; Schwartz, B; Selanikio, JD; St Victor, S, 1998)
" The relative bioavailability of cyclosporin in ARF and control rats was 0."	1.30	Influence of glycerol-induced acute renal failure on the pharmacokinetics of cyclosporin in rats. ( Hoshino, N; Minouchi, T; Ohmae, T; Shibata, N; Yamaji, A, 1999)
"Acute renal failure was induced in rat with a hypertonic glycerol solution and endothelin-1 (ET-1) binding was measured in kidney membrane preparations."	1.29	Upregulation of renal endothelin receptors in glycerol-induced acute renal failure in the rat. ( Braquet, P; Chabrier, PE; Cornet, S; Guilmard, C; Pirotzky, E; Plas, P; Roubert, P, 1993)
"Acute renal failure was induced by i."	1.29	Role of nitric oxide in glycerol-induced acute renal failure in rats. ( Blum, M; Cabili, S; Iaina, A; Maree, A; Peer, G; Schwartz, D; Serban, I; Wollman, Y, 1994)
"Glycerol-injected rats were subdivided in three groups according to the urinary volume: oliguric, nonoliguric, and polyuric."	1.29	Angiotensin I converting enzyme in glycerol-induced acute renal failure in rats. ( Cruz, C; Hernández-Pando, R; Juárez, RM; Larriva-Sahd, J; Orozco, H; Pedraza-Chaverrí, J; Tapia, E, 1995)
"Fulminant hepatitis and acute renal failure could induce extensive edema in the cerebral white matter."	1.29	Reversible white matter lesions in a patient with fulminant hepatitis and acute renal failure. ( Ikeda, M; Matsunaga, T; Takahashi, K; Tsukagoshi, H, 1994)
"The glycerol-induced increase in MR and HQR was not attenuated by any of the treatments used."	1.29	Regional haemodynamic effects of dopamine and its prodrugs L-dopa and gludopa in the rat and in the glycerol-treated rat as a model for acute renal failure. ( Drieman, JC; Smits, JF; Struijker Boudier, HA; Thijssen, HH; van Essen, H; van Kan, FJ, 1994)
"In glycerol-treated rats, the total ET receptor density in kidney cortex and medulla was increased to 294 and 1172 fmol/mg of protein, with ETA/ETB ratios of 52:48 and 31:69, respectively."	1.29	Endothelin receptor subtypes A and B are up-regulated in an experimental model of acute renal failure. ( Braquet, P; Chabrier, PE; Cornet, S; Gillard-Roubert, V; Guilmard, C; Pirotzky, E; Plas, P; Pourmarin, L; Roubert, P, 1994)
"It was found that the development of acute renal failure related not only to renal blood flow, but also to the hepatic blood flow."	1.29	[Systemic hemodynamics and renal blood flow in glycerol induced acute renal failure]. ( Ohyama, A, 1993)
"Glycerol-induced acute renal failure (ARF) inhibited the proliferation of both lipopolysaccharide (LPS)-induced B-lymphocytes and concanavalin A (Con A)-induced T-lymphocytes by 80% and 87%, respectively."	1.29	Effect of glycerol-induced acute renal failure on glutathione status and mitogen-induced proliferation of rat splenocytes. ( Yeung, JH, 1993)
"Glycerol-induced acute renal failure (ARF) in rats is a model of acute trauma in which intra-muscular injection of 50% glycerol causes rapid myoglobinuria, oliguria, and a rapid reduction in glomerular filtration rate."	1.29	Glycerol induced ARF in rats is mediated by tumor necrosis factor-alpha. ( Eliahou, HE; Frolkis, I; Gavendo, S; Knecht, A; Shulman, LM; Yuhas, Y, 1993)
"Rats treated with glycerol and HgCl2 showed rather severe acute renal failure, but the beta-ATP level at 55 min glycerol infusion was 87."	1.29	[Glycerol-loading test in experimental acute renal failure using 31P magnetic resonance spectroscopy of the kidney]. ( Fukuda, Y; Ishii, H; Ishikawa, I; Shikura, N, 1993)
"Rats treated with dopexamine had higher renal Na+ and K+ excretion than dopamine-treated rats."	1.29	Comparative effects of dopexamine and dopamine on glycerol-induced acute renal failure in rats. ( Eleno, N; Gömez-Garre, DN; López-Farré, A; López-Novoa, JM, 1996)
"Treatment of glycerol-injected rats with 0."	1.28	Further characterization of the protective effect of 8-cyclopentyl-1,3-dipropylxanthine on glycerol-induced acute renal failure in the rat. ( Bowmer, CJ; Collis, MG; Munsey, TS; Panjehshahin, MR; Yates, MS, 1992)
"Glycerol-injected rats treated with BSO showed significantly worse renal failure than did rats given glycerol alone, while administration of GSH resulted in significant amelioration of glycerol-induced acute renal failure [glycerol treatment alone, blood urea nitrogen (BUN) = 96 +/- 10 and creatinine = 2."	1.28	Role of glutathione in an animal model of myoglobinuric acute renal failure. ( Abul-Ezz, SR; Shah, SV; Walker, PD, 1991)
"Glycerol acute renal failure (ARF) was examined to see if it alters theophylline (Th) neurotoxicity in rats."	1.28	Theophylline neurotoxicity is unaffected by glycerol-induced renal failure. ( Ramzan, I, 1990)
"Fourteen days after the operation, acute renal failure was induced by injection of 50% glycerol solution to both groups."	1.28	Glycerol-induced acute renal failure in the rat: the protective effect of unilateral nephrectomy. ( Anteby, EY; Popovtzer, MM; Wald, H, 1990)
" The mean residence time and half-life were 20."	1.28	The pharmacokinetics of gamma-glutamyl-L-dopa in normal and anephric rats and rats with glycerol-induced acute renal failure. ( Barber, HE; Boateng, YA; Lee, MR; MacDonald, TM; Petrie, JC; Whiting, PH, 1990)
"6."	1.28	Platelet-activating factor mediates glycerol-induced acute renal failure in rats. ( Bernabeu, F; Braquet, P; Gómez-Garre, D; López-Farré, A; López-Novoa, JM; Perez-Rodrigo, P; Ramón y Cajal, S, 1990)
"At this time, not only acute renal failure but also hepatic disorder developed in the water-drinking and captopril-drinking rats as indicated by elevations of serum creatinine, urea nitrogen, alanine aminotransferase and other blood chemistry levels."	1.28	Cardiac output, renal blood flow and hepatic blood flow in rats with glycerol-induced acute renal failure. ( Abe, Y; Ito, T; Iwai, K; Kim, T; Kishimoto, T; Nakatani, T; Sakamoto, W, 1989)
" The pharmacokinetic changes seen at a dose of 1 mg/kg, after jugular vein administration, were significant decreases in uraemic rats in the rate of entry of ICG into the liver (k12) and in the rate of movement of dye from liver to plasma (k21)."	1.27	The plasma clearance of indocyanine green in rats with acute renal failure: effect of dose and route of administration. ( Bowmer, CJ; Emmerson, J; Yates, MS, 1983)
"Rats treated with glycerol and a hydroxyl radical scavenger, dimethylthiourea (DMTU), had significantly lower blood urea nitrogen (BUN) and creatinine."	1.27	Evidence suggesting a role for hydroxyl radical in glycerol-induced acute renal failure. ( Shah, SV; Walker, PD, 1988)
"Hydrochlorothiazide treatment compared with vehicle treatment did not ameliorate any index of renal function but resulted in significant elevations in plasma urea and creatinine levels."	1.27	Effect of 8-phenyltheophylline, enprofylline and hydrochlorothiazide on glycerol-induced acute renal failure in the rat. ( Bowmer, CJ; Collis, MG; Kellett, R; Yates, MS, 1987)
"According to the severity of acute renal failure three subgroups were formed: mild, moderate, and severe acute renal failure."	1.27	Toxic renal failure in the rat: beneficial effects of atrial natriuretic factor. ( Götz, R; Heidbreder, E; Heidland, A; Schafferhans, K; Schramm, D, 1986)
"2."	1.27	Prolonged inhibition of angiotensin II attenuates glycerol-induced acute renal failure. ( Abdulkader, RC; Marcondes, M; Paiva, AC; Yuki, MM, 1988)
"Glycerol injection was also associated with significant lipid peroxidation, measured as renal malondialdehyde content."	1.27	Hemoglobin- and myoglobin-induced acute renal failure in rats: role of iron in nephrotoxicity. ( Paller, MS, 1988)
"Glycerol-treated rats exhibited significantly increased urinary thromboxane B2(TXB)2, prostaglandin E2 (PGE2) and 6-ketoprostaglandin F1 alpha (6kPGF1 alpha) excretion and urine volume (UV)."	1.27	Is thromboxane a potent antinatriuretic factor and is it involved in the development of acute renal failure? ( Bariety, J; Dontas, A; Gkikas, EL; Gkikas, G; Hatziantoniou, C; Papanicolaou, N; Paris, M, 1987)
"Prior acute renal failure (ARF) induced by either glycerol (G) or mercury provides protection against rechallenge with the same agent or the other."	1.27	Protection against acute renal failure by prior acute renal failure: differences between myohemoglobinuric and ischemic models. ( Hollenberg, NK; Wilkes, BM, 1987)
"glycerol was significantly greater in rats dosed i."	1.27	Effect of the adenosine antagonist 8-phenyltheophylline on glycerol-induced acute renal failure in the rat. ( Bowmer, CJ; Collis, MG; Yates, MS, 1986)
"The blood viscosity values of rats with acute renal failure were significantly higher than those of controls at any shear rates."	1.26	Blood viscosity in experimental acute renal failure. ( Hsu, CH; Kurtz, TW; Slavicek, JM, 1982)
"3 Glycerol-induced acute renal failure produced a significant increase in the unbound fractions of o-methyl red, methyl orange, bromocresol green (BCG), 2-(4'-hydroxybenzeneazo) benzoic acid (HABA), phenytoin and salicylic acid."	1.26	Decreased binding of drugs and dyes to plasma proteins from rats with acute renal failure: effects of ureter ligation and intramuscular injection of glycerol. ( Bowmer, CJ; Lindup, WE, 1979)
"In the patients with non-oliguric acute renal failure there was a positive correlation between duration of renal failure and severity of tubular necrosis."	1.26	The morphology of "acute tubular necrosis" in man: analysis of 57 renal biopsies and a comparison with the glycerol model. ( Morel-Maroger, L; Solez, K; Sraer, JD, 1979)
"50% glycerol (10 ml/kg bw) was injected intramuscularly in other groups of rats to induce ARF."	1.26	Renal effects of mannitol in the early stage of glycerol-induced acute renal failure in the rat. ( Greven, J; Klein, H, 1979)
"Acute renal failure was induced by an intramuscular injection of 50% glycerol (10 ml."	1.26	Action of the competitive angiotensin II antagonist saralasin during the initial phase of glycerol-induced acute renal failure of the rat. ( Greven, J; Klein, H, 1977)
"Furosemide (20 mg/kg) was injected intraperitoneally daily and for the first time 24 h after injection of glycerol Mortality and azotemia of acute renal failure was not improved by this drug."	1.26	[Action of furosemide in experimental acute renal failure (author's transl)]. ( Greven, J; Kölling, B, 1978)
"2."	1.26	Renal vasoconstriction in glycerol-induced acute renal failure. Studies in the isolated perfused rat kidney. ( Bauereiss, K; Gross, F; Hofbauer, KG; Konrads, A, 1978)
"1."	1.26	Protective effect of prostaglandin [PGE2] and in glycerol-induced acute renal failure in rats. ( Clark, WF; Jones, EO; Lindsay, RM; Linton, AL; Turnbull, DI; Werb, R, 1978)
"Glycerol-induced acute renal failure (ARF) was studied in rats with two degrees of reduced renal mass (RRM)."	1.26	Partial protection against acute renal failure in rats with reduced renal mass. ( Casado, S; Hernando, L; Lopez-Novoa, JM; Perez-Garcia, R, 1978)
"5."	1.26	Effect of saralasin and serum in myohaemoglobinuric acute renal failure of rats. ( Bauereiss, K; Gross, F; Hofbauer, KG; Konrads, A, 1978)
"When the grafts were well established, acute renal failure was induced in the rabbit by glycerol injection."	1.26	The mechanism of glycerol-induced acute renal failure. ( Chusilp, S; Hobbs, JB; Kincaid-Smith, P; McIver, MA, 1976)
"Thus, in contrast to human acute renal failure, marked renal cortical ischemia is not an essential feature of these different forms of murine acute renal failure."	1.26	Normal renocortical blood flow in experimental acute renal failure. ( Carvalho, JS; Churchill, S; Gottlieb, MN; Oken, DE; Zarlengo, MD, 1977)
"The renal effects of furosemide in acute renal failure of the rat were studied using clearance and micropuncture techniques."	1.26	Renal effects of furosemide in glycerol induced acute renal failure of the rat. ( Greven, J; Klein, H, 1976)
"per 100 gm."	1.26	A scanning electron microscopic study of the glycerol model of acute renal failure. ( Dach, JL; Kurtzman, NA, 1976)
" Differences in diatrizoate concentration which existed between cortical and medullary zones in healthy kidneys at low dises were progressively eliminated as dosage increased, consistent with the osmatic fiutryiv rggrvy of diatrizoate."	1.26	Effect of dose on renal diatrizoate concentrations in experimental acute renal failure. ( Gaunt, A; McLachlan, MS; Robinson, PJ, 1976)
"1."	1.25	The renin-angiotensin system in acute renal failure of rats. ( Dietz, R; Gross, F; Oster, P; Rauh, W, 1975)
"The appearance of an acute renal insufficiency in the rabbit, after glycerol injection (10, 13 or 15 ml/kg of a 50% solution) is investigated."	1.25	Acute renal insufficiency in the rabbit by glycerol. ( Cisar, F; de Vega, F; del Valle, O; Gras, J; Navarro, J; Tuset, N, 1975)
"1."	1.25	The effect of indomethacin and prostaglandin (PGE2) on renal failure due to glycerol in saline-loaded rats. ( Bariety, J; Callard, P; Milliez, P; Papanicolaou, N, 1975)

Timeframe	Studies, this research(%)	All Research%
pre-1990	182 (43.96)	18.7374
1990's	69 (16.67)	18.2507
2000's	61 (14.73)	29.6817
2010's	69 (16.67)	24.3611
2020's	33 (7.97)	2.80

Trial	Phase	Enrollment	Study Type	Start Date	Status
Resistin as a Diagnostic and Prognostic Biomarker of Sepsis[NCT03146546]		200 participants (Anticipated)	Observational	2020-08-06	Enrolling by invitation
A Pilot Study of Short Duration Hyperbaric Oxygen Therapy to Improve HbA1c, Leukocyte, and Serum Creatinine in Patient With Diabetic Foot Ulcer Wagner 3-4[NCT03615755]		30 participants (Actual)	Interventional	2016-12-27	Completed
Plasma Cytochrome c as Biomarker of Traumatic Injury and Predictor of Outcome[NCT02440373]		12 participants (Actual)	Observational	2014-03-31	Completed
A Randomized Factorial Trial of N-Acetylcysteine and Continuous Veno-Venous Hemo(Dia)Filtration for Rhabdomyolysis[NCT00391911]	Phase 2	3 participants (Actual)	Interventional	2006-11-30	Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Article	Year
Zeitschrift fur Gesundheitswissenschaften = Journal of public health, 2023, Jun-08 Topics: Acetogenins; Acute Disease; Acute Kidney Injury; Administration, Intravenous; Aged; Albumins; Alcoho	2023
Physiological roles of AQP7 in the kidney: Lessons from AQP7 knockout mice. Biochimica et biophysica acta, 2006, Volume: 1758, Issue:8 Topics: Acute Kidney Injury; Animals; Aquaporin 1; Aquaporins; Biological Transport, Active; Cell Membrane P	2006
The significance of vasopressin as a pressor agent. Journal of cardiovascular pharmacology, 1984, Volume: 6 Suppl 2 Topics: Acute Kidney Injury; Animals; Arginine Vasopressin; Blood Pressure; Desoxycorticosterone; Glycerol;	1984
Hemodynamic basis for human acute renal failure (vasomotor nephropathy). The American journal of medicine, 1984, Volume: 76, Issue:4 Topics: Acute Kidney Injury; Adult; Animals; Female; Folic Acid; Glomerular Filtration Rate; Glycerol; Human	1984
Acute renal failure in the 1980s: the importance of septic shock and of endotoxaemia. Nephron, 1982, Volume: 30, Issue:3 Topics: Acute Kidney Injury; Animals; Anti-Bacterial Agents; Disease Models, Animal; Endotoxins; Glomerular	1982
Oxidant mechanisms in toxic acute renal failure. American journal of kidney diseases : the official journal of the National Kidney Foundation, 1997, Volume: 29, Issue:3 Topics: Acute Kidney Injury; Animals; Anti-Bacterial Agents; Cyclosporine; Free Radicals; Gentamicins; Glyce	1997
Oxidant mechanisms in toxic acute renal failure. Drug metabolism reviews, 1999, Volume: 31, Issue:4 Topics: Acute Kidney Injury; Animals; Anti-Bacterial Agents; Antineoplastic Agents; Cisplatin; Cryoprotectiv	1999
Acute renal failure. II. Experimental models of acute renal failure: imperfect but indispensable. American journal of physiology. Renal physiology, 2000, Volume: 278, Issue:1 Topics: Acute Kidney Injury; Animals; Cells, Cultured; Disease Models, Animal; Glycerol; Hemodynamics; Human	2000
[Acute renal failure]. Nihon rinsho. Japanese journal of clinical medicine, 2002, Volume: 60 Suppl 4 Topics: Acute Kidney Injury; Animals; Cytochrome P-450 Enzyme System; Gentamicins; Glycerol; Heme Oxygenase	2002
Acute renal failure (vasomotor nephropathy): micropuncture studies of the pathogenetic mechanisms. Annual review of medicine, 1975, Volume: 26 Topics: Absorption; Acute Kidney Injury; Animals; Coloring Agents; Globins; Glomerular Filtration Rate; Glyc	1975
Post traumatic acute renal failure. Advances in experimental medicine and biology, 1987, Volume: 212 Topics: Acute Kidney Injury; Crush Syndrome; Disease Models, Animal; Glycerol; Humans; Kidney Tubular Necros	1987
Modern concepts of the role of nephrotoxic agents in the pathogenesis of acute renal failure. Progress in biochemical pharmacology, 1972, Volume: 7 Topics: Acute Kidney Injury; Animals; Anuria; Chromates; Dehydration; Edema; Glomerular Filtration Rate; Gly	1972

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