Page last updated: 2024-10-18

glycerol and Rhabdomyolysis

glycerol has been researched along with Rhabdomyolysis in 74 studies

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Rhabdomyolysis: Necrosis or disintegration of skeletal muscle often followed by myoglobinuria.

Research Excerpts

ExcerptRelevanceReference
"5 ml/kg saline (Group A) or of the same volume 50% glycerol was used to induce rhabdomyolysis and subsequent AKI (Group B)."8.12Pifithrin-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."8.12Dose-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."8.02Valproate 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)."7.91Protective 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."7.91N-(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."7.91Oleuropein 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."7.915-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."7.88Kidney 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."7.80Pretreatment 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."7.80Macrophage 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."7.72Effects 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)."5.91Administration 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."5.91Protective 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."5.91Protective 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."5.91Modulation 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."5.72Rhabdomyolysis-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."5.33Molsidomine, 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)."4.12Pifithrin-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."4.12Dose-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."4.12EGFR 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."4.12Blocking 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."4.02Valproate 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."3.915-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."3.91N-(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)."3.91Protective 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."3.91Oleuropein 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."3.88Kidney 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)."3.88miR-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."3.85Inhibition 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."3.85Dynamic 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)."3.83Reversal 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."3.81Differences 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."3.80Pretreatment 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."3.80Inhibition 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."3.80Macrophage 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."3.78Plasma 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."3.76Protective 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."3.74Evidence 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."3.73Renal 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."3.72Effects 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."3.69Induction 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."3.69Synergistic 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)."1.91Administration 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."1.91Protective 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."1.91Protective 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."1.91Modulation 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."1.72Rhabdomyolysis-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."1.46Protective 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."1.38Preventive 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."1.38Recombinant 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."1.36Progressive 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."1.33Biochemical 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."1.33Molsidomine, 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."1.30Enteral 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%."1.30A 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."1.27Protection against acute renal failure by prior acute renal failure: differences between myohemoglobinuric and ischemic models. ( Hollenberg, NK; Wilkes, BM, 1987)

Research

Studies (74)

TimeframeStudies, this research(%)All Research%
pre-19902 (2.70)18.7374
1990's6 (8.11)18.2507
2000's14 (18.92)29.6817
2010's34 (45.95)24.3611
2020's18 (24.32)2.80

Authors

AuthorsStudies
Yuqiang, C1
Lisha, Z1
Jiejun, W1
Qin, X1
Niansong, W1
Madkour, AH1
Helal, MG1
Said, E1
Salem, HA1
Mard, SA1
Hoseinynejad, K1
Nejaddehbashi, F1
Chang, SN1
Haroon, M1
Dey, DK1
Kang, SC1
Sun, T1
Wu, D3
Deng, Y1
Zhang, D1
Semenovich, DS1
Plotnikov, EY1
Lukiyenko, EP1
Astrowski, AA1
Kanunnikova, NP1
Muratsu, J1
Sanada, F1
Koibuchi, N1
Shibata, K1
Katsuragi, N1
Ikebe, S1
Tsunetoshi, Y1
Rakugi, H1
Morishita, R1
Taniyama, Y1
Al-Kharashi, L1
Attia, H1
Alsaffi, A1
Almasri, T1
Arafa, M1
Hasan, I1
Alajami, H1
Ali, R1
Badr, A1
Shimizu, MHM2
Volpini, RA3
de Bragança, AC1
Nascimento, MM1
Bernardo, DRD1
Seguro, AC3
Canale, D2
Eltahir, HM1
Elbadawy, HM1
Alalawi, A1
Aldhafiri, AJ1
Ibrahim, SRM1
Mohamed, GA1
Shalkami, AS1
Almikhlafi, MA1
Albadrani, M1
Alahmadi, Y1
Abouzied, MM1
Nazmy, MH1
Afolabi, JM1
Kanthakumar, P1
Williams, JD1
Kumar, R1
Soni, H1
Adebiyi, A1
Wang, Q1
Qi, G1
Zhou, H1
Cheng, F1
Yang, X2
Liu, X1
Wang, R1
Mahmood, YS1
Kathem, SH1
Kassab, RB2
Elhenawy, AA1
Hawsawi, YM1
Al-Amer, OM1
Oyouni, AAA1
Habotta, OA1
Althagafi, HA1
Alharthi, F1
Lokman, MS1
Alsharif, KF1
Albrakati, A1
Al-Ghamdy, AO1
Elmahallawy, EK1
Elhefny, MA1
Hassan, KE1
Albarakati, AJA1
Abdel Moneim, AE3
Moustafa, AA1
Hebert, JF1
Eiwaz, MB1
Nickerson, MN1
Munhall, AC1
Pai, AA1
Groat, T1
Andeen, NK1
Hutchens, MP1
da Silva, BHCS1
Ariga, SK1
Barbeiro, HV1
Barbeiro, DF1
Pinheiro da Silva, F1
Hareedy, MS1
Abdelzaher, LA1
Badary, DM1
Mohammed Alnasser, S1
Abd-Eldayem, AM1
Yamaoka, M1
Shimizu, H1
Takahashi, T1
Omori, E1
Morimatsu, H1
Tsai, JP1
Lee, CJ2
Subeq, YM2
Lee, RP2
Hsu, BG2
Uchida, A1
Kidokoro, K1
Sogawa, Y1
Itano, S1
Nagasu, H1
Satoh, M1
Sasaki, T1
Kashihara, N1
Zhang, Y1
Du, Y1
Yu, H1
Zhou, Y1
Ge, F1
Huang, X1
Zhao, W1
Zhang, L2
Wang, L1
Chen, Y1
Wang, J1
Zhang, C1
Wu, G1
Siddiqui, RA1
Simjee, SU1
Kabir, N1
Ateeq, M1
Shah, MR1
Hussain, SS1
Mathia, S1
Rudigier, LJ1
Kasim, M1
Kirschner, KM1
Persson, PB1
Eckardt, KU2
Rosenberger, C2
Fähling, M1
Gattai, PP1
Maquigussa, E1
da Silva Novaes, A1
da Silva Ribeiro, R1
Varela, VA1
Ormanji, MS1
Boim, MA1
Sánchez-Lozada, LG1
García-Arroyo, FE1
Gonzaga, G1
Silverio, O1
Blas-Marron, MG1
Muñoz-Jimenez, I1
Tapia, E1
Osorio-Alonso, H1
Madero, M1
Roncal-Jiménez, CA1
Weiss, I1
Glaser, J1
Johnson, RJ1
Reis, NG1
Francescato, HDC1
de Almeida, LF1
Silva, CGAD1
Costa, RS1
Coimbra, TM1
AlBasher, G1
Alfarraj, S1
Alarifi, S1
Alkhtani, S1
Almeer, R1
Alsultan, N1
Alharthi, M1
Alotibi, N1
Al-Dbass, A1
Yin, M1
Jiang, N1
Guo, L1
Ni, Z1
Al-Brakati, AY1
Othman, MS1
Tang, W1
Chen, Z1
Wu, W1
Qiu, H1
Bo, H1
Fu, P1
Tokarchuk, KO1
Kapustianenko, LH1
Shandrenko, SH1
Gu, H1
Yang, M1
Zhao, X1
Zhao, B1
Sun, X1
Gao, X1
Wang, Z1
Shah, SV1
Liu, H1
Baliga, R1
Zeleniuk, VH1
Zamors'kyĭ, II1
Horoshko, OM1
Haglind, CB1
Nordenström, A1
Ask, S1
von Döbeln, U1
Gustafsson, J1
Stenlid, MH1
Belliere, J1
Casemayou, A1
Ducasse, L1
Zakaroff-Girard, A1
Martins, F1
Iacovoni, JS1
Guilbeau-Frugier, C1
Buffin-Meyer, B1
Pipy, B1
Chauveau, D1
Schanstra, JP1
Bascands, JL1
Kim, JH1
Lee, DW1
Jung, MH1
Cho, HS1
Jeon, DH1
Chang, SH1
Park, DJ1
Nishida, K1
Watanabe, H1
Ogaki, S1
Kodama, A1
Tanaka, R1
Imafuku, T1
Ishima, Y1
Chuang, VT1
Toyoda, M1
Kondoh, M1
Wu, Q1
Fukagawa, M1
Otagiri, M1
Maruyama, T1
Singbartl, K1
Miller, L1
Ruiz-Velasco, V1
Kellum, JA1
Geng, X2
Wang, Y1
Hong, Q2
Yang, J1
Zheng, W2
Zhang, G1
Cai, G2
Chen, X2
Gois, PHF1
Ferreira, D1
Veras, MM1
Andrade-Oliveira, V1
Câmara, NOS1
Lv, X1
Yu, Z1
Xie, C1
Dai, X1
Li, Q1
Miao, D1
Jin, J1
Shi, Y1
Xu, L1
Tang, J1
Fang, L1
Ma, S1
Ma, X1
Nie, J1
Pi, X1
Qiu, A1
Zhuang, S1
Liu, N1
Wang, W1
Li, O1
Ustundag, S1
Yalcin, O1
Sen, S1
Cukur, Z1
Ciftci, S1
Demirkan, B1
Zager, RA6
Johnson, AC5
Fylymonenko, VP1
Nikitchenko, IV1
Kaliman, PA2
Perin, L1
Sedrakyan, S1
Giuliani, S1
Da Sacco, S1
Carraro, G1
Shiri, L1
Lemley, KV1
Rosol, M1
Wu, S1
Atala, A1
Warburton, D1
De Filippo, RE1
Maeda, E1
Mori, Y1
Amano, E1
Akamatsu, T1
Okada, T1
Ware, LB1
Yang, FL1
Chiu, YH1
Ayvaz, S1
Aksu, B1
Kanter, M1
Uzun, H1
Erboga, M1
Colak, A1
Basaran, UN1
Pul, M1
Becker, K1
Helmy, MM1
El-Gowelli, HM1
Murray, C1
Markos, F1
Snow, HM1
Corcoran, T1
Parfrey, N1
Shorten, GD1
Hanson, SY2
Barannik, T1
Strel'chenko, E1
Inshina, N1
Sokol, O1
Chander, V1
Chopra, K1
Aydogdu, N1
Erbas, H1
Atmaca, G1
Erten, O1
Kaymak, K1
Rodrigo, R1
Trujillo, S1
Bosco, C1
Murakami, S1
Yasuda, T1
Kushikata, T1
Hashimoto, H1
Hirota, K1
Goldfarb, M1
Shina, A1
Bachmann, S1
Frei, U1
Schrader, T1
Rosen, S1
Heyman, SN1
Nath, KA1
Dvergsten, J1
Correa-Rotter, R1
Hostetter, TH1
Manivel, JC1
Rosenberg, ME1
Salahudeen, AK1
Wang, C1
Bigler, SA1
Dai, Z1
Tachikawa, H1
Zurovsky, Y1
Eligal, Z1
Grossman, S1
Bergman, M1
Gafter, U1
Roberts, PR1
Black, KW1
Zaloga, GP1
Lochhead, KM1
Kharasch, ED1
Moore, KP1
Holt, SG1
Patel, RP1
Svistunenko, DA1
Zackert, W1
Goodier, D1
Reeder, BJ1
Clozel, M1
Anand, R1
Cooper, CE1
Morrow, JD1
Wilson, MT1
Darley-Usmar, V1
Roberts, LJ1
Stefanovic, V1
Savic, V1
Vlahovic, P1
Cvetkovic, T1
Najman, S1
Mitic-Zlatkovic, M1
Kertai, E1
Hollósi, G1
Kovács, J1
Varga, V1
Vanuxem, P1
Vanuxem, D1
Raharison, L1
Aubert, M1
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Wilkes, BM1
Hollenberg, NK1

Clinical Trials (3)

Trial Overview

TrialPhaseEnrollmentStudy TypeStart DateStatus
Resistin as a Diagnostic and Prognostic Biomarker of Sepsis[NCT03146546]200 participants (Anticipated)Observational2020-08-06Enrolling 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)Interventional2016-12-27Completed
Plasma Cytochrome c as Biomarker of Traumatic Injury and Predictor of Outcome[NCT02440373]12 participants (Actual)Observational2014-03-31Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Trials

1 trial available for glycerol and Rhabdomyolysis

ArticleYear
Maximal exercise and muscle energy metabolism after recovery from exercise hyperthermia syndrome.
    Muscle & nerve, 2001, Volume: 24, Issue:8

    Topics: Adult; Blood Pressure; Body Temperature; Central Nervous System Diseases; Convalescence; Creatine Ki

2001

Other Studies

73 other studies available for glycerol and Rhabdomyolysis

ArticleYear
Pifithrin-α ameliorates glycerol induced rhabdomyolysis and acute kidney injury by reducing p53 activation.
    Renal failure, 2022, Volume: 44, Issue:1

    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.
    Life sciences, 2022, Aug-01, Volume: 302

    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.
    Inflammation, 2022, Volume: 45, Issue:6

    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.
    The Journal of nutritional biochemistry, 2022, Volume: 110

    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.
    Life sciences, 2022, Nov-15, Volume: 309

    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.
    International journal of molecular sciences, 2022, Oct-14, Volume: 23, Issue:20

    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.
    Cells, 2022, 10-27, Volume: 11, Issue:21

    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.
    Toxicology and applied pharmacology, 2023, 02-15, Volume: 461

    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.
    PloS one, 2023, Volume: 18, Issue:2

    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.
    Acta biochimica Polonica, 2023, Apr-17, Volume: 70, Issue:2

    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.
    Function (Oxford, England), 2023, Volume: 4, Issue:4

    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.
    Renal failure, 2023, Volume: 45, Issue:1

    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.
    Journal of medicine and life, 2023, Volume: 16, Issue:7

    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.
    Environmental science and pollution research international, 2023, Volume: 30, Issue:56

    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.
    Military medicine, 2023, 11-08, Volume: 188, Issue:Suppl 6

    Topics: Acute Kidney Injury; Animals; Caffeine; Cilastatin; Glycerol; Humans; Ibuprofen; Mice; Performance-E

2023
Cathelicidin protects mice from Rhabdomyolysis-induced Acute Kidney Injury.
    International journal of medical sciences, 2021, Volume: 18, Issue:4

    Topics: Acute Kidney Injury; Animals; Antimicrobial Cationic Peptides; Cathelicidins; Disease Models, Animal

2021
Valproate attenuates hypertonic glycerol-induced rhabdomyolysis and acute kidney injury.
    Nephrologie & therapeutique, 2021, Volume: 17, Issue:3

    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.
    PloS one, 2017, Volume: 12, Issue:7

    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.
    International journal of medical sciences, 2017, Volume: 14, Issue:7

    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.
    Nephrology (Carlton, Vic.), 2019, Volume: 24, Issue:1

    Topics: Acute Kidney Injury; Aminolevulinic Acid; Animals; Antioxidants; Apoptosis; Cells, Cultured; Cytokin

2019
Protective Effects of
    Journal of immunology research, 2017, Volume: 2017

    Topics: Acute Kidney Injury; Animals; Antioxidants; Complex Mixtures; Cordyceps; Creatinine; Disease Models,

2017
The role of complement activation in rhabdomyolysis-induced acute kidney injury.
    PloS one, 2018, Volume: 13, Issue:2

    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.
    Molecular and cellular biochemistry, 2019, Volume: 450, Issue:1-2

    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.
    Acta physiologica (Oxford, England), 2018, Volume: 224, Issue:3

    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.
    Journal of cellular biochemistry, 2018, Volume: 119, Issue:9

    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.
    American journal of nephrology, 2018, Volume: 48, Issue:5

    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.
    Scientific reports, 2019, 05-08, Volume: 9, Issue:1

    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.
    Biological trace element research, 2020, Volume: 194, Issue:2

    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.
    Life sciences, 2019, Sep-01, Volume: 232

    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.
    Artificial organs, 2013, Volume: 37, Issue:4

    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].
    Fiziolohichnyi zhurnal (Kiev, Ukraine : 1994), 2013, Volume: 59, Issue:1

    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.
    The Journal of surgical research, 2014, May-01, Volume: 188, Issue:1

    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.
    Kidney international, 2014, Volume: 86, Issue:2

    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].
    Fiziolohichnyi zhurnal (Kiev, Ukraine : 1994), 2014, Volume: 60, Issue:2

    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.
    Journal of inherited metabolic disease, 2015, Volume: 38, Issue:2

    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.
    Journal of the American Society of Nephrology : JASN, 2015, Volume: 26, Issue:6

    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.
    Nephron. Experimental nephrology, 2014, Volume: 128, Issue:1-2

    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.
    Scientific reports, 2015, Sep-28, Volume: 5

    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.
    Critical care medicine, 2016, Volume: 44, Issue:7

    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.
    International journal of clinical and experimental pathology, 2015, Volume: 8, Issue:11

    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.
    Free radical biology & medicine, 2016, Volume: 101

    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.
    Biochemical and biophysical research communications, 2017, Jan-22, Volume: 482, Issue:4

    Topics: AC133 Antigen; Animals; CD24 Antigen; Cell Differentiation; Creatinine; Disease Progression; Glycero

2017
Inhibition of HDAC6 protects against rhabdomyolysis-induced acute kidney injury.
    American journal of physiology. Renal physiology, 2017, 03-01, Volume: 312, Issue:3

    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.
    Scientific reports, 2017, 01-24, Volume: 7

    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.
    Renal failure, 2008, Volume: 30, Issue:7

    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.
    American journal of physiology. Renal physiology, 2010, Volume: 298, Issue:3

    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].
    Fiziolohichnyi zhurnal (Kiev, Ukraine : 1994), 2009, Volume: 55, Issue:5

    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.
    PloS one, 2010, Feb-24, Volume: 5, Issue:2

    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].
    Masui. The Japanese journal of anesthesiology, 2010, Volume: 59, Issue:7

    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.
    American journal of physiology. Renal physiology, 2011, Volume: 300, Issue:3

    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.
    Injury, 2012, Volume: 43, Issue:3

    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.
    Journal of molecular histology, 2012, Volume: 43, Issue:2

    Topics: Acute Kidney Injury; Animals; Catalase; Creatinine; Glutathione; Glycerol; Hyperbaric Oxygenation; K

2012
Plasma and urinary heme oxygenase-1 in AKI.
    Journal of the American Society of Nephrology : JASN, 2012, Volume: 23, Issue:6

    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.
    European journal of pharmacology, 2012, May-15, Volume: 683, Issue:1-3

    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.
    European journal of anaesthesiology, 2003, Volume: 20, Issue:9

    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.
    Kidney international, 2004, Volume: 65, Issue:6

    Topics: Acute Kidney Injury; Adenosine Diphosphate; Adenosine Triphosphate; Animals; Antimycin A; Biomarkers

2004
Renal tubular triglyercide accumulation following endotoxic, toxic, and ischemic injury.
    Kidney international, 2005, Volume: 67, Issue:1

    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.
    Cell biology international, 2005, Volume: 29, Issue:1

    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.
    Biochimica et biophysica acta, 2005, May-25, Volume: 1723, Issue:1-3

    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.
    Renal failure, 2006, Volume: 28, Issue:5

    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.
    Experimental biology and medicine (Maywood, N.J.), 2006, Volume: 231, Issue:8

    Topics: Animals; Bronchoalveolar Lavage Fluid; Carbon Dioxide; Catalase; F2-Isoprostanes; Glutathione; Gluta

2006
[Case of hemoglobinuria following glycerin enema].
    Masui. The Japanese journal of anesthesiology, 2007, Volume: 56, Issue:6

    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.
    Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association, 2008, Volume: 23, Issue:4

    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.
    Laboratory investigation; a journal of technical methods and pathology, 1994, Volume: 71, Issue:2

    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.
    Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association, 1996, Volume: 11, Issue:4

    Topics: Acute Kidney Injury; Animals; Antioxidants; Creatinine; Diuresis; Diuretics, Osmotic; Drug Combinati

1996
Glycerol-induced augmentation of sensitivity to endotoxin in rats.
    Toxicon : official journal of the International Society on Toxinology, 1994, Volume: 32, Issue:1

    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.
    American journal of respiratory and critical care medicine, 1997, Volume: 156, Issue:4 Pt 1

    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.
    Journal of the American Society of Nephrology : JASN, 1998, Volume: 9, Issue:2

    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.
    The Journal of biological chemistry, 1998, Nov-27, Volume: 273, Issue:48

    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.
    Renal failure, 2000, Volume: 22, Issue:3

    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.
    Acta physiologica Hungarica, 2000, Volume: 87, Issue:3

    Topics: Acute Kidney Injury; Animals; Biotransformation; Creatinine; Cytochrome P-450 Enzyme System; Cytochr

2000
Myoglobinuria exacerbates ischemic renal damage in the dog.
    Nephron, 1989, Volume: 53, Issue:3

    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.
    Nephron, 1987, Volume: 47, Issue:3

    Topics: Acute Kidney Injury; Animals; Blood Urea Nitrogen; Creatinine; Disease Models, Animal; Glycerol; Iod

1987