glycerol has been researched along with Rhabdomyolysis in 74 studies
Moon: The natural satellite of the planet Earth. It includes the lunar cycles or phases, the lunar month, lunar landscapes, geography, and soil.
Rhabdomyolysis: Necrosis or disintegration of skeletal muscle often followed by myoglobinuria.
Excerpt | Relevance | Reference |
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"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) |
"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) |
"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 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) |
"Rhabdomyolysis-induced AKI was induced by an intramuscular injection of glycerol (5 mL/kg body weight) into mice." | 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 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) |
"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) |
"0 microg kg(-1) min(-1)) or saline on renal blood flow and function in 10 anaesthetized Labrador dogs in whom rhabdomyolysis and myoglobinuric acute renal failure had been induced by administration of glycerol 50% (10mL kg(-1)) intramuscularly." | 7.72 | Effects of fenoldopam on renal blood flow and its function in a canine model of rhabdomyolysis. ( Corcoran, T; Markos, F; Murray, C; Parfrey, N; Shorten, GD; Snow, HM, 2003) |
"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) |
"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) |
"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) |
"Rhabdomyolysis-induced AKI was induced by an intramuscular injection of glycerol (5 mL/kg body weight) into mice." | 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) |
"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) |
"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) |
" 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, 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) |
"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) |
"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) |
"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) |
"We investigated the changes in the forms of plasma iron and participation of aldehydes in the development of oxidative stress under glycerol-induced rhabdomyolysis in rats." | 3.79 | [The role of aldehydes in development of oxidative stress under rhabdomyolysis in rats]. ( Kapustianenko, LH; Shandrenko, SH; Tokarchuk, KO, 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) |
" Herein, we show for the first time the successful therapeutic application of hAFSC in a mouse model with glycerol-induced rhabdomyolysis and ATN." | 3.76 | Protective effect of human amniotic fluid stem cells in an immunodeficient mouse model of acute tubular necrosis. ( Atala, A; Carraro, G; Da Sacco, S; De Filippo, RE; Giuliani, S; Lemley, KV; Perin, L; Rosol, M; Sedrakyan, S; Shiri, L; Warburton, D; Wu, S, 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) |
"0 microg kg(-1) min(-1)) or saline on renal blood flow and function in 10 anaesthetized Labrador dogs in whom rhabdomyolysis and myoglobinuric acute renal failure had been induced by administration of glycerol 50% (10mL kg(-1)) intramuscularly." | 3.72 | Effects of fenoldopam on renal blood flow and its function in a canine model of rhabdomyolysis. ( Corcoran, T; Markos, F; Murray, C; Parfrey, N; Shorten, GD; Snow, HM, 2003) |
"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) |
"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) |
"Rhabdomyolysis was monitored using creatine kinase (CK) level." | 1.46 | Protective Effects of ( Du, Y; Ge, F; Yu, H; Zhang, Y; Zhou, Y, 2017) |
"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) |
"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) |
"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) |
"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) |
"Rhabdomyolysis was induced by intramuscular glycerol injection (50% v/v, 10 ml/kg), and the control group was injected with saline vehicle." | 1.33 | Biochemical and ultrastructural lung damage induced by rhabdomyolysis in the rat. ( Bosco, C; Rodrigo, R; Trujillo, S, 2006) |
"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) |
"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) |
"Administration of alkali, a treatment for rhabdomyolysis, improved renal function and significantly reduced the urinary excretion of F2-isoprostanes by approximately 80%." | 1.30 | A causative role for redox cycling of myoglobin and its inhibition by alkalinization in the pathogenesis and treatment of rhabdomyolysis-induced renal failure. ( Anand, R; Clozel, M; Cooper, CE; Darley-Usmar, V; Goodier, D; Holt, SG; Moore, KP; Morrow, JD; Patel, RP; Reeder, BJ; Roberts, LJ; Svistunenko, DA; Wilson, MT; Zackert, W, 1998) |
"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) |
Timeframe | Studies, this research(%) | All Research% |
---|---|---|
pre-1990 | 2 (2.70) | 18.7374 |
1990's | 6 (8.11) | 18.2507 |
2000's | 14 (18.92) | 29.6817 |
2010's | 34 (45.95) | 24.3611 |
2020's | 18 (24.32) | 2.80 |
Authors | Studies |
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Yuqiang, C | 1 |
Lisha, Z | 1 |
Jiejun, W | 1 |
Qin, X | 1 |
Niansong, W | 1 |
Madkour, AH | 1 |
Helal, MG | 1 |
Said, E | 1 |
Salem, HA | 1 |
Mard, SA | 1 |
Hoseinynejad, K | 1 |
Nejaddehbashi, F | 1 |
Chang, SN | 1 |
Haroon, M | 1 |
Dey, DK | 1 |
Kang, SC | 1 |
Sun, T | 1 |
Wu, D | 3 |
Deng, Y | 1 |
Zhang, D | 1 |
Semenovich, DS | 1 |
Plotnikov, EY | 1 |
Lukiyenko, EP | 1 |
Astrowski, AA | 1 |
Kanunnikova, NP | 1 |
Muratsu, J | 1 |
Sanada, F | 1 |
Koibuchi, N | 1 |
Shibata, K | 1 |
Katsuragi, N | 1 |
Ikebe, S | 1 |
Tsunetoshi, Y | 1 |
Rakugi, H | 1 |
Morishita, R | 1 |
Taniyama, Y | 1 |
Al-Kharashi, L | 1 |
Attia, H | 1 |
Alsaffi, A | 1 |
Almasri, T | 1 |
Arafa, M | 1 |
Hasan, I | 1 |
Alajami, H | 1 |
Ali, R | 1 |
Badr, A | 1 |
Shimizu, MHM | 2 |
Volpini, RA | 3 |
de Bragança, AC | 1 |
Nascimento, MM | 1 |
Bernardo, DRD | 1 |
Seguro, AC | 3 |
Canale, D | 2 |
Eltahir, HM | 1 |
Elbadawy, HM | 1 |
Alalawi, A | 1 |
Aldhafiri, AJ | 1 |
Ibrahim, SRM | 1 |
Mohamed, GA | 1 |
Shalkami, AS | 1 |
Almikhlafi, MA | 1 |
Albadrani, M | 1 |
Alahmadi, Y | 1 |
Abouzied, MM | 1 |
Nazmy, MH | 1 |
Afolabi, JM | 1 |
Kanthakumar, P | 1 |
Williams, JD | 1 |
Kumar, R | 1 |
Soni, H | 1 |
Adebiyi, A | 1 |
Wang, Q | 1 |
Qi, G | 1 |
Zhou, H | 1 |
Cheng, F | 1 |
Yang, X | 2 |
Liu, X | 1 |
Wang, R | 1 |
Mahmood, YS | 1 |
Kathem, SH | 1 |
Kassab, RB | 2 |
Elhenawy, AA | 1 |
Hawsawi, YM | 1 |
Al-Amer, OM | 1 |
Oyouni, AAA | 1 |
Habotta, OA | 1 |
Althagafi, HA | 1 |
Alharthi, F | 1 |
Lokman, MS | 1 |
Alsharif, KF | 1 |
Albrakati, A | 1 |
Al-Ghamdy, AO | 1 |
Elmahallawy, EK | 1 |
Elhefny, MA | 1 |
Hassan, KE | 1 |
Albarakati, AJA | 1 |
Abdel Moneim, AE | 3 |
Moustafa, AA | 1 |
Hebert, JF | 1 |
Eiwaz, MB | 1 |
Nickerson, MN | 1 |
Munhall, AC | 1 |
Pai, AA | 1 |
Groat, T | 1 |
Andeen, NK | 1 |
Hutchens, MP | 1 |
da Silva, BHCS | 1 |
Ariga, SK | 1 |
Barbeiro, HV | 1 |
Barbeiro, DF | 1 |
Pinheiro da Silva, F | 1 |
Hareedy, MS | 1 |
Abdelzaher, LA | 1 |
Badary, DM | 1 |
Mohammed Alnasser, S | 1 |
Abd-Eldayem, AM | 1 |
Yamaoka, M | 1 |
Shimizu, H | 1 |
Takahashi, T | 1 |
Omori, E | 1 |
Morimatsu, H | 1 |
Tsai, JP | 1 |
Lee, CJ | 2 |
Subeq, YM | 2 |
Lee, RP | 2 |
Hsu, BG | 2 |
Uchida, A | 1 |
Kidokoro, K | 1 |
Sogawa, Y | 1 |
Itano, S | 1 |
Nagasu, H | 1 |
Satoh, M | 1 |
Sasaki, T | 1 |
Kashihara, N | 1 |
Zhang, Y | 1 |
Du, Y | 1 |
Yu, H | 1 |
Zhou, Y | 1 |
Ge, F | 1 |
Huang, X | 1 |
Zhao, W | 1 |
Zhang, L | 2 |
Wang, L | 1 |
Chen, Y | 1 |
Wang, J | 1 |
Zhang, C | 1 |
Wu, G | 1 |
Siddiqui, RA | 1 |
Simjee, SU | 1 |
Kabir, N | 1 |
Ateeq, M | 1 |
Shah, MR | 1 |
Hussain, SS | 1 |
Mathia, S | 1 |
Rudigier, LJ | 1 |
Kasim, M | 1 |
Kirschner, KM | 1 |
Persson, PB | 1 |
Eckardt, KU | 2 |
Rosenberger, C | 2 |
Fähling, M | 1 |
Gattai, PP | 1 |
Maquigussa, E | 1 |
da Silva Novaes, A | 1 |
da Silva Ribeiro, R | 1 |
Varela, VA | 1 |
Ormanji, MS | 1 |
Boim, MA | 1 |
Sánchez-Lozada, LG | 1 |
García-Arroyo, FE | 1 |
Gonzaga, G | 1 |
Silverio, O | 1 |
Blas-Marron, MG | 1 |
Muñoz-Jimenez, I | 1 |
Tapia, E | 1 |
Osorio-Alonso, H | 1 |
Madero, M | 1 |
Roncal-Jiménez, CA | 1 |
Weiss, I | 1 |
Glaser, J | 1 |
Johnson, RJ | 1 |
Reis, NG | 1 |
Francescato, HDC | 1 |
de Almeida, LF | 1 |
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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 | |||
[information is prepared from clinicaltrials.gov, extracted Sep-2024] |
1 trial available for glycerol and Rhabdomyolysis
Article | Year |
---|---|
Maximal exercise and muscle energy metabolism after recovery from exercise hyperthermia syndrome.
Topics: Adult; Blood Pressure; Body Temperature; Central Nervous System Diseases; Convalescence; Creatine Ki | 2001 |
73 other studies available for glycerol and Rhabdomyolysis
Article | Year |
---|---|
Pifithrin-α ameliorates glycerol induced rhabdomyolysis and acute kidney injury by reducing p53 activation.
Topics: Acute Kidney Injury; Animals; Benzothiazoles; Glycerol; Mice; Mice, Inbred C57BL; Rhabdomyolysis; To | 2022 |
Dose-dependent renoprotective impact of Lactoferrin against glycerol-induced rhabdomyolysis and acute kidney injury.
Topics: Acute Kidney Injury; Animals; Cell Cycle Proteins; Glycerol; Kidney; Lactoferrin; Male; NLR Family, | 2022 |
Gallic Acid Improves Therapeutic Effects of Mesenchymal Stem Cells Derived from Adipose Tissue in Acute Renal Injury Following Rhabdomyolysis Induced by Glycerol.
Topics: Acute Kidney Injury; Adipose Tissue; Animals; Antioxidants; Gallic Acid; Glycerol; Kidney; Mesenchym | 2022 |
Rhabdomyolysis-induced acute kidney injury and concomitant apoptosis induction via ROS-mediated ER stress is efficaciously counteracted by epigallocatechin gallate.
Topics: Acute Kidney Injury; Animals; Apoptosis; Catechin; Endoplasmic Reticulum Stress; Glycerol; HEK293 Ce | 2022 |
EGFR mediated the renal cell apoptosis in rhabdomyolysis-induced model via upregulation of autophagy.
Topics: Acute Kidney Injury; Animals; Apoptosis; Autophagy; ErbB Receptors; Gefitinib; Glycerol; Kidney; Mic | 2022 |
Protective Effect of D-Panthenol in Rhabdomyolysis-Induced Acute Kidney Injury.
Topics: Acute Kidney Injury; Animals; Antioxidants; Catalase; Coenzyme A; Creatine Kinase; Creatinine; Gluta | 2022 |
Blocking Periostin Prevented Development of Inflammation in Rhabdomyolysis-Induced Acute Kidney Injury Mice Model.
Topics: Acute Kidney Injury; Animals; Cell Adhesion Molecules; Disease Models, Animal; Glycerol; Inflammatio | 2022 |
Pentoxifylline and thiamine ameliorate rhabdomyolysis-induced acute kidney injury in rats via suppressing TLR4/NF-κB and NLRP-3/caspase-1/gasdermin mediated-pyroptosis.
Topics: Acute Kidney Injury; Animals; Antioxidants; Caspase 1; Creatinine; Gasdermins; Glycerol; Male; NF-ka | 2023 |
Administration of a single dose of lithium ameliorates rhabdomyolysis-associated acute kidney injury in rats.
Topics: Acute Kidney Injury; Animals; Apoptosis; Glycerol; Glycogen Synthase Kinase 3 beta; Inflammation; In | 2023 |
Alpha-Mangostin ameliorates acute kidney injury via modifying levels of circulating TNF-α and IL-6 in glycerol-induced rhabdomyolysis animal model.
Topics: Acute Kidney Injury; Animals; Anti-Inflammatory Agents; Antioxidants; Creatinine; Glycerol; Interleu | 2023 |
Post-injury Inhibition of Endothelin-1 Dependent Renal Vasoregulation Mitigates Rhabdomyolysis-Induced Acute Kidney Injury.
Topics: Acute Kidney Injury; Animals; Endothelin-1; Glycerol; Kidney; Myoglobin; Rats; Rats, Wistar; Rhabdom | 2023 |
Protective effect of thymol on glycerol-induced acute kidney injury.
Topics: Acute Kidney Injury; Animals; Glycerol; Kidney; Oxidative Stress; Phosphatidylinositol 3-Kinases; Pr | 2023 |
Protective effect of citronellol in rhabdomyolysis-induced acute kidney injury in mice.
Topics: Acute Kidney Injury; Animals; Apoptosis; bcl-2-Associated X Protein; Caspase 3; Glycerol; Kidney; Mi | 2023 |
Modulation of inflammatory, oxidative, and apoptotic stresses mediates the renoprotective effect of daidzein against glycerol-induced acute kidney injury in rats.
Topics: Acute Kidney Injury; Animals; Antioxidants; Glycerol; Isoflavones; Kidney; Male; Oxidative Stress; R | 2023 |
Legal Performance-enhancing Drugs Alter Course and Treatment of Rhabdomyolysis-induced Acute Kidney Injury.
Topics: Acute Kidney Injury; Animals; Caffeine; Cilastatin; Glycerol; Humans; Ibuprofen; Mice; Performance-E | 2023 |
Cathelicidin protects mice from Rhabdomyolysis-induced Acute Kidney Injury.
Topics: Acute Kidney Injury; Animals; Antimicrobial Cationic Peptides; Cathelicidins; Disease Models, Animal | 2021 |
Valproate attenuates hypertonic glycerol-induced rhabdomyolysis and acute kidney injury.
Topics: Acute Kidney Injury; Animals; Glycerol; Humans; Kidney; Male; Rats; Rhabdomyolysis; Valproic Acid | 2021 |
Dynamic changes in Bach1 expression in the kidney of rhabdomyolysis-associated acute kidney injury.
Topics: 5-Aminolevulinate Synthetase; Acute Kidney Injury; Animals; Basic-Leucine Zipper Transcription Facto | 2017 |
Acute Alcohol Intoxication Exacerbates Rhabdomyolysis-Induced Acute Renal Failure in Rats.
Topics: Acute Kidney Injury; Alcoholic Intoxication; Alcoholism; Alkyl and Aryl Transferases; Animals; Blood | 2017 |
5-Aminolevulinic acid exerts renoprotective effect via Nrf2 activation in murine rhabdomyolysis-induced acute kidney injury.
Topics: Acute Kidney Injury; Aminolevulinic Acid; Animals; Antioxidants; Apoptosis; Cells, Cultured; Cytokin | 2019 |
Protective Effects of
Topics: Acute Kidney Injury; Animals; Antioxidants; Complex Mixtures; Cordyceps; Creatinine; Disease Models, | 2017 |
The role of complement activation in rhabdomyolysis-induced acute kidney injury.
Topics: Acute Kidney Injury; Animals; Complement Activation; Disease Models, Animal; Glycerol; In Situ Nick- | 2018 |
N-(2-hydroxyphenyl)acetamide and its gold nanoparticle conjugation prevent glycerol-induced acute kidney injury by attenuating inflammation and oxidative injury in mice.
Topics: Acetanilides; Acute Kidney Injury; Animals; Apoptosis; Cryoprotective Agents; Disease Models, Animal | 2019 |
A dual role of miR-22 in rhabdomyolysis-induced acute kidney injury.
Topics: Acute Kidney Injury; Animals; Gene Expression Regulation; Glycerol; Kidney Tubules, Distal; Male; Mi | 2018 |
miR-26a modulates HGF and STAT3 effects on the kidney repair process in a glycerol-induced AKI model in rats.
Topics: Acute Kidney Injury; Animals; Cell Line; Creatinine; Disease Models, Animal; Gene Expression Regulat | 2018 |
Kidney Injury from Recurrent Heat Stress and Rhabdomyolysis: Protective Role of Allopurinol and Sodium Bicarbonate.
Topics: Acute Kidney Injury; Allopurinol; Animals; Disease Models, Animal; Disease Progression; Glycerol; He | 2018 |
Protective effect of calcitriol on rhabdomyolysis-induced acute kidney injury in rats.
Topics: Acute Kidney Injury; Animals; Apoptosis; Calcitriol; Calcium; Creatine Kinase; Glomerular Filtration | 2019 |
Nephroprotective Role of Selenium Nanoparticles Against Glycerol-Induced Acute Kidney Injury in Rats.
Topics: Acute Kidney Injury; Animals; Glycerol; Kidney; Nanoparticles; Oxidative Stress; Rats; Rhabdomyolysi | 2020 |
Oleuropein suppresses oxidative, inflammatory, and apoptotic responses following glycerol-induced acute kidney injury in rats.
Topics: Acute Kidney Injury; Animals; Antioxidants; Apoptosis; Cell Adhesion Molecules; Creatine Kinase; Cre | 2019 |
Renal protective effects of early continuous venovenous hemofiltration in rhabdomyolysis: improved renal mitochondrial dysfunction and inhibited apoptosis.
Topics: Acute Kidney Injury; Animals; Apoptosis; Dogs; Female; Glycerol; Hemofiltration; Interleukin-6; Kidn | 2013 |
[The role of aldehydes in development of oxidative stress under rhabdomyolysis in rats].
Topics: Aldehydes; Animals; Blood Proteins; Cyclohexanones; Glycerol; Injections, Intramuscular; Injections, | 2013 |
Pretreatment with hydrogen-rich saline reduces the damage caused by glycerol-induced rhabdomyolysis and acute kidney injury in rats.
Topics: Acute Kidney Injury; Animals; Anti-Inflammatory Agents; Antioxidants; Creatine Kinase; Disease Model | 2014 |
Inhibition of cytochrome P450 2E1 and activation of transcription factor Nrf2 are renoprotective in myoglobinuric acute kidney injury.
Topics: Acute Kidney Injury; Animals; Chlormethiazole; Cytochrome P-450 CYP2E1; Cytochrome P-450 CYP2E1 Inhi | 2014 |
[Renoprotective efficacy of different doses of statins in experimental acute renal failure].
Topics: Acute Kidney Injury; Administration, Topical; Animals; Atorvastatin; Creatine Kinase; Diuresis; Glom | 2014 |
Increased and early lipolysis in children with long-chain 3-hydroxyacyl-CoA dehydrogenase (LCHAD) deficiency during fast.
Topics: 3-Hydroxyacyl CoA Dehydrogenases; Age Factors; Biomarkers; Blood Glucose; Calorimetry, Indirect; Car | 2015 |
Specific macrophage subtypes influence the progression of rhabdomyolysis-induced kidney injury.
Topics: Acute Kidney Injury; Animals; Cells, Cultured; Clodronic Acid; Disease Models, Animal; Disease Progr | 2015 |
Macrophage depletion ameliorates glycerol-induced acute kidney injury in mice.
Topics: Acute Kidney Injury; Administration, Intravenous; Animals; Apoptosis; Clodronic Acid; Cytokines; Dis | 2014 |
Renoprotective effect of long acting thioredoxin by modulating oxidative stress and macrophage migration inhibitory factor against rhabdomyolysis-associated acute kidney injury.
Topics: Acute Kidney Injury; Animals; Apoptosis; Cell Survival; Cytokines; Disease Models, Animal; Glycerol; | 2015 |
Reversal of Acute Kidney Injury-Induced Neutrophil Dysfunction: A Critical Role for Resistin.
Topics: Acute Kidney Injury; Animals; Buffers; Cell Culture Techniques; Cell Movement; Cells, Cultured; Dise | 2016 |
Differences in gene expression profiles and signaling pathways in rhabdomyolysis-induced acute kidney injury.
Topics: Acute Kidney Injury; Animals; Computational Biology; Databases, Genetic; Disease Models, Animal; Gen | 2015 |
Allopurinol attenuates rhabdomyolysis-associated acute kidney injury: Renal and muscular protection.
Topics: Acute Kidney Injury; Allopurinol; Animals; Apoptosis; Dinoprost; Epithelial Cells; Free Radical Scav | 2016 |
Bmi-1 plays a critical role in the protection from acute tubular necrosis by mobilizing renal stem/progenitor cells.
Topics: AC133 Antigen; Animals; CD24 Antigen; Cell Differentiation; Creatinine; Disease Progression; Glycero | 2017 |
Inhibition of HDAC6 protects against rhabdomyolysis-induced acute kidney injury.
Topics: Acetylation; Acute Kidney Injury; Animals; Apoptosis; Biomarkers; Blood Urea Nitrogen; Caspase 3; Cr | 2017 |
Biological Membrane-Packed Mesenchymal Stem Cells Treat Acute Kidney Disease by Ameliorating Mitochondrial-Related Apoptosis.
Topics: Acute Kidney Injury; Animals; Apoptosis; Cadherins; Cell Line; Cell Membrane; Cell Survival; Cell- a | 2017 |
Experimental myoglobinuric acute renal failure: the effect of vitamin C.
Topics: Acute Kidney Injury; Animals; Ascorbic Acid; Biopsy, Needle; Disease Models, Animal; Glycerol; Immun | 2008 |
Progressive histone alterations and proinflammatory gene activation: consequences of heme protein/iron-mediated proximal tubule injury.
Topics: Acute Kidney Injury; Animals; Blood Urea Nitrogen; Cell Survival; Cells, Cultured; Chemokine CCL2; D | 2010 |
[Effect of L-arginine on pro- and antioxidant status of the rat vessels and lungs in experimental rhabdomyolysis].
Topics: Animals; Antioxidants; Arginine; Blood Vessels; Catalase; Disease Models, Animal; Glycerol; Heme; He | 2009 |
Protective effect of human amniotic fluid stem cells in an immunodeficient mouse model of acute tubular necrosis.
Topics: Amniotic Fluid; Animals; Apoptosis; Blood Urea Nitrogen; Cell Proliferation; Creatinine; Cytokines; | 2010 |
[A case of the complications following glycerin enema which suggested malignant hyperthermia].
Topics: Aged; Arthroplasty, Replacement, Knee; Diagnosis, Differential; Enema; Glycerol; Hemolysis; Humans; | 2010 |
Renal cortical albumin gene induction and urinary albumin excretion in response to acute kidney injury.
Topics: Acute Kidney Injury; Adult; Aged; Albumins; Albuminuria; Animals; Biomarkers; Cells, Cultured; Endot | 2011 |
Recombinant human erythropoietin reduces rhabdomyolysis-induced acute renal failure in rats.
Topics: Acute Kidney Injury; Alanine Transaminase; Animals; Aspartate Aminotransferases; Blood Urea Nitrogen | 2012 |
Preventive effects of hyperbaric oxygen treatment on glycerol-induced myoglobinuric acute renal failure in rats.
Topics: Acute Kidney Injury; Animals; Catalase; Creatinine; Glutathione; Glycerol; Hyperbaric Oxygenation; K | 2012 |
Plasma and urinary heme oxygenase-1 in AKI.
Topics: Acute Kidney Injury; Animals; Biomarkers; Blotting, Western; Cells, Cultured; Cisplatin; Cohort Stud | 2012 |
Montelukast abrogates rhabdomyolysis-induced acute renal failure via rectifying detrimental changes in antioxidant profile and systemic cytokines and apoptotic factors production.
Topics: Acetates; alpha-Tocopherol; Animals; Anti-Asthmatic Agents; Antioxidants; Cyclopropanes; Cytokines; | 2012 |
Effects of fenoldopam on renal blood flow and its function in a canine model of rhabdomyolysis.
Topics: Animals; Antihypertensive Agents; Creatinine; Disease Models, Animal; Dogs; Female; Fenoldopam; Glyc | 2003 |
Proximal tubular cytochrome c efflux: determinant, and potential marker, of mitochondrial injury.
Topics: Acute Kidney Injury; Adenosine Diphosphate; Adenosine Triphosphate; Animals; Antimycin A; Biomarkers | 2004 |
Renal tubular triglyercide accumulation following endotoxic, toxic, and ischemic injury.
Topics: Acute Kidney Injury; Animals; Antimycin A; Cell Line; Cholesterol; Fatty Acids, Nonesterified; Glyce | 2005 |
Intracellular redistribution of heme in rat liver under oxidative stress: the role of heme synthesis.
Topics: 5-Aminolevulinate Synthetase; Animals; Cycloheximide; Enzyme Induction; Glutathione; Glycerol; Heme; | 2005 |
Molsidomine, a nitric oxide donor and L-arginine protects against rhabdomyolysis-induced myoglobinuric acute renal failure.
Topics: Acute Kidney Injury; Animals; Arginine; Glycerol; Kidney; Male; Molsidomine; Myoglobinuria; Nitric O | 2005 |
Melatonin reduces nitric oxide via increasing arginase in rhabdomyolysis-induced acute renal failure in rats.
Topics: Acute Kidney Injury; Animals; Arginase; Glycerol; Kidney; Male; Melatonin; Nitric Oxide; Nitric Oxid | 2006 |
Biochemical and ultrastructural lung damage induced by rhabdomyolysis in the rat.
Topics: Animals; Bronchoalveolar Lavage Fluid; Carbon Dioxide; Catalase; F2-Isoprostanes; Glutathione; Gluta | 2006 |
[Case of hemoglobinuria following glycerin enema].
Topics: Anesthesia, General; Diagnosis, Differential; Enema; Glycerol; Hemoglobinuria; Hemolysis; Humans; Lu | 2007 |
Evidence for sustained renal hypoxia and transient hypoxia adaptation in experimental rhabdomyolysis-induced acute kidney injury.
Topics: Acute Kidney Injury; Adaptation, Physiological; Animals; Disease Models, Animal; Disease Progression | 2008 |
Induction of clusterin in acute and chronic oxidative renal disease in the rat and its dissociation from cell injury.
Topics: Acute Disease; Acute Kidney Injury; Animals; Cells, Cultured; Chronic Disease; Clusterin; Glycerol; | 1994 |
Synergistic renal protection by combining alkaline-diuresis with lipid peroxidation inhibitors in rhabdomyolysis: possible interaction between oxidant and non-oxidant mechanisms.
Topics: Acute Kidney Injury; Animals; Antioxidants; Creatinine; Diuresis; Diuretics, Osmotic; Drug Combinati | 1996 |
Glycerol-induced augmentation of sensitivity to endotoxin in rats.
Topics: Animals; Creatine Kinase; Disease Models, Animal; Drug Synergism; Endotoxins; Free Radical Scavenger | 1994 |
Enteral feeding improves outcome and protects against glycerol-induced acute renal failure in the rat.
Topics: Acute Kidney Injury; Animals; Blood Urea Nitrogen; Creatinine; Disease Models, Animal; Enteral Nutri | 1997 |
Anesthetic effects on the glycerol model of rhabdomyolysis-induced acute renal failure in rats.
Topics: Acute Kidney Injury; Anesthetics, Inhalation; Animals; Creatine Kinase; Creatinine; Desflurane; Glyc | 1998 |
A causative role for redox cycling of myoglobin and its inhibition by alkalinization in the pathogenesis and treatment of rhabdomyolysis-induced renal failure.
Topics: Animals; Bicarbonates; Dinoprost; Disease Models, Animal; Electron Spin Resonance Spectroscopy; Glyc | 1998 |
Reversal of experimental myoglobinuric acute renal failure with bioflavonoids from seeds of grape.
Topics: Acute Kidney Injury; Analysis of Variance; Animals; Anthocyanins; Antioxidants; Disease Models, Anim | 2000 |
Effect of glycerol-induced acute renal failure and di-2-ethylhexyl phthalate on the enzymes involved in biotransformation of xenobiotixs.
Topics: Acute Kidney Injury; Animals; Biotransformation; Creatinine; Cytochrome P-450 Enzyme System; Cytochr | 2000 |
Myoglobinuria exacerbates ischemic renal damage in the dog.
Topics: Acute Kidney Injury; Animals; Creatinine; Dogs; Glycerol; Hematocrit; Injections, Intramuscular; Isc | 1989 |
Protection against acute renal failure by prior acute renal failure: differences between myohemoglobinuric and ischemic models.
Topics: Acute Kidney Injury; Animals; Blood Urea Nitrogen; Creatinine; Disease Models, Animal; Glycerol; Iod | 1987 |