ethylene glycol has been researched along with Hyperoxaluria in 51 studies
Ethylene Glycol: A colorless, odorless, viscous dihydroxy alcohol. It has a sweet taste, but is poisonous if ingested. Ethylene glycol is the most important glycol commercially available and is manufactured on a large scale in the United States. It is used as an antifreeze and coolant, in hydraulic fluids, and in the manufacture of low-freezing dynamites and resins.
ethanediol : Any diol that is ethane or substituted ethane carrying two hydroxy groups.
ethylene glycol : A 1,2-glycol compound produced via reaction of ethylene oxide with water.
Hyperoxaluria: Excretion of an excessive amount of OXALATES in the urine.
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" Most of the studies used ethylene glycol (EG) to induce hyperoxaluria and nephrolithiasis in rats." | 9.12 | Antiurolithic effects of medicinal plants: results of in vivo studies in rat models of calcium oxalate nephrolithiasis-a systematic review. ( Bashir, S; Khan, A; Khan, SR, 2021) |
"75 percent ethylene glycol (v/v) in their drinking water for six weeks to induce hyperoxaluria." | 8.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"Hyperoxaluria caused by ethylene glycol may be prevented by a combination of Ulva lactuca aqueous extract, ulvan polysaccharides, and atorvastatin." | 8.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
" Weight loss, serum creatinine, serum urea, serum uric acid, serum oxalate, kidney oxalate, kidney lipid peroxidation, and kidney DNA fragmentation and kidney histopathological studies were done." | 8.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"Weight loss, rise of serum creatinine, serum urea, serum uric acid, serum oxalate, kidney oxalate, kidney lipid peroxidation, and kidney DNA fragmentation were all shown to be prevented by the addition of atorvastatin, polysaccharides, or aqueous extract, respectively." | 8.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
" Ulvan infusions (100 mg/kg body weight), ulvan polysaccharides (100 mg/kg body weight), and atorvastatin (two milligrams/kg body weight) to treat hyperoxaluric rats for four weeks (every other day) were used." | 8.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
" The rats were randomized into three groups: Group 1 consisted of the controls (n = 8), Group 2 of hyperoxaluria (1% ethylene glycol (EG), n = 8), and Group 3 of the treatment (1% EG + 10 mg/kg of RES, n = 8) group." | 7.85 | Protective impact of resveratrol in experimental rat model of hyperoxaluria. ( Aydın Candan, I; Calapoğlu, M; Ergün, O; Oksay, T; Onaran, İ; Özorak, A; Yunusoğlu, S, 2017) |
"In the present study, resveratrol was seen to prevent hyperoxaluria." | 7.85 | Protective impact of resveratrol in experimental rat model of hyperoxaluria. ( Aydın Candan, I; Calapoğlu, M; Ergün, O; Oksay, T; Onaran, İ; Özorak, A; Yunusoğlu, S, 2017) |
"To investigate whether the sex-dependent expression of hepatic and renal oxalate transporter sat-1 (Slc26a1) changes in a rat model of ethylene glycol (EG)-induced hyperoxaluria." | 7.81 | In female rats, ethylene glycol treatment elevates protein expression of hepatic and renal oxalate transporter sat-1 (Slc26a1) without inducing hyperoxaluria. ( Breljak, D; Brzica, H; Burckhardt, BC; Burckhardt, G; Henjakovic, M; Jurasović, J; Karaica, D; Ljubojević, M; Lovrić, M; Micek, V; Peraica, M; Rašić, D; Sabolić, I; Schnedler, N; Sekovanić, A; Vrhovac, I; Wegner, W, 2015) |
"Oral administration of ethylene glycol resulted in hyperoxaluria and increased renal excretion of calcium and phosphate." | 7.78 | Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats. ( Gadge, NB; Jalalpure, SS, 2012) |
" In groups 1A, 1B and 1C hyperoxaluria was induced with ethylene glycol for 2 weeks." | 7.76 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"Increased systemic and local tissue asymmetrical dimethylarginine may help explain the pathogenetic mechanisms of hyperoxaluria induced disorders such as nephrolithiasis and atherosclerosis." | 7.76 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
" (HARC) against ethylene glycol induced urolithiasis and its possible underlying mechanisms using male Wistar albino rats." | 7.76 | Protective effect of the hydro-alcoholic extract of Rubia cordifolia roots against ethylene glycol induced urolithiasis in rats. ( Chandrasekhar, SB; Dighe, SB; Divakar, G; Divakar, K; Pawar, AT, 2010) |
"Indicate that the HARC can protect against ethylene glycol induced urolithiasis as it reduced and prevented the growth of urinary stones." | 7.76 | Protective effect of the hydro-alcoholic extract of Rubia cordifolia roots against ethylene glycol induced urolithiasis in rats. ( Chandrasekhar, SB; Dighe, SB; Divakar, G; Divakar, K; Pawar, AT, 2010) |
"The present study was undertaken to explore the efficiency of the pentacyclic triterpene lupeol (1) and its ester derivative, lupeol linoleate (2), in experimental hyperoxaluria." | 7.74 | Antiurolithic effect of lupeol and lupeol linoleate in experimental hyperoxaluria. ( Sudhahar, V; Varalakshmi, P; Veena, CK, 2008) |
"Ethylene glycol (EG) consumption is commonly employed as an experimental regimen to induce hyperoxaluria in animal models of calcium oxalate nephrolithiasis." | 7.73 | Ethylene glycol induces hyperoxaluria without metabolic acidosis in rats. ( Freel, RW; Green, ML; Hatch, M, 2005) |
" Ethylene glycol feeding resulted in hyperoxaluria as well as increased renal excretion of calcium and phosphate." | 7.73 | Effect of Moringa oleifera Lam. root-wood on ethylene glycol induced urolithiasis in rats. ( Alagawadi, KR; Gadge, NB; Karadi, RV; Savadi, RV, 2006) |
"Hyperoxaluria was produced in rats by ethylene glycol in drinking water." | 7.69 | Lipid peroxidation in ethylene glycol induced hyperoxaluria and calcium oxalate nephrolithiasis. ( Hackett, RL; Khan, SR; Thamilselvan, S, 1997) |
"Ethylene glycol is a toxic alcohol which may induce significant toxicity when ingested accidentally or intentionally." | 6.72 | The three biological gaps and hyperoxaluria in ethylene glycol poisoning: case presentation and review. ( Ahmad, Y; Chiche, JD; Kissling, S; Liaudet, L; Ltaief, Z; Torrent, C, 2021) |
"Hyperoxaluria caused by ethylene glycol may be prevented by a combination of Ulva lactuca aqueous extract, ulvan polysaccharides, and atorvastatin." | 5.91 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"We found that EG not only resulted hyperoxaluria and kidney stone formation, but also promoted the intestinal inflammation, elevated intestinal permeability, and gut microbiota disorders." | 5.62 | Probiotic Lactiplantibacillus plantarum N-1 could prevent ethylene glycol-induced kidney stones by regulating gut microbiota and enhancing intestinal barrier function. ( Cui, Y; Jin, X; Li, H; Liu, Y; Sun, Q; Tian, L; Wang, K; Wei, Z; Yu, Y, 2021) |
"Hyperoxaluria is characterized by an increased excretion of urinary oxalate which is caused by inherited disorders or high oxalate intake leading to renal stone ailment." | 5.51 | Amelioration of hyperoxaluria-induced kidney dysfunction by chemical chaperone 4-phenylbutyric acid. ( Bhardwaj, R; Kaur, T; Randhawa, R, 2019) |
"In the hyperoxaluria group, urinary oxalate levels were higher than the control group; yet, lower in the treatment group compared to hyperoxaluria group (p < 0." | 5.46 | Protective impact of resveratrol in experimental rat model of hyperoxaluria. ( Aydın Candan, I; Calapoğlu, M; Ergün, O; Oksay, T; Onaran, İ; Özorak, A; Yunusoğlu, S, 2017) |
"Treatment of ethylene glycol intoxication is based on specific inhibitors of alcohol dehydrogenase and hemodialysis in the most severe forms, and should be started promptly." | 5.39 | [Secondary hyperoxaluria and nephrocalcinosis due to ethylene glycol poisoning]. ( Harambat, J; Llanas, B; Missonnier, S; Monet, C; Rebouissoux, L; Richard, E, 2013) |
"Calcium oxalate lithiasis was induced in rats by oral administration of 0." | 5.38 | Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats. ( Gadge, NB; Jalalpure, SS, 2012) |
"Drawbacks of presently available treatments for urolithiasis necessitate finding the treatment of hyperoxaluria specifically aimed at reduction in oxalate excretion." | 5.38 | Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats. ( Gadge, NB; Jalalpure, SS, 2012) |
"There is some evidence that hyperoxaluria may effect vascular endothelium and many studies link renal stones to atherosclerosis." | 5.36 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"In groups 1A, 1B and 1C hyperoxaluria was induced with ethylene glycol for 2 weeks." | 5.36 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"Hyperoxaluria induced a significantly dense staining pattern in renal tissue asymmetrical dimethylarginine vs controls (p = 0." | 5.36 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"Hyperoxaluria was induced in male Wistar rats with 0." | 5.35 | Antiurolithic effect of lupeol and lupeol linoleate in experimental hyperoxaluria. ( Sudhahar, V; Varalakshmi, P; Veena, CK, 2008) |
"Frank metabolic acidosis was observed in the MA rats: decreased arterial pH and plasma HCO3(-) concentration with lower urinary pH and citrate excretion with elevated excretion of ammonium, phosphate and, hence, titratable acid." | 5.33 | Ethylene glycol induces hyperoxaluria without metabolic acidosis in rats. ( Freel, RW; Green, ML; Hatch, M, 2005) |
"Mild hyperoxaluria was induced in male Wistar rats using ethylene glycol (EG; 0." | 5.33 | Mild tubular damage induces calcium oxalate crystalluria in a model of subtle hyperoxaluria: Evidence that a second hit is necessary for renal lithogenesis. ( D'Angelo, A; Del Prete, D; Della Barbera, M; Gambaro, G; Trevisan, A; Valente, ML; Zanetti, E, 2006) |
"Hyperoxaluria was produced in rats by ethylene glycol in drinking water." | 5.30 | Lipid peroxidation in ethylene glycol induced hyperoxaluria and calcium oxalate nephrolithiasis. ( Hackett, RL; Khan, SR; Thamilselvan, S, 1997) |
" Most of the studies used ethylene glycol (EG) to induce hyperoxaluria and nephrolithiasis in rats." | 5.12 | Antiurolithic effects of medicinal plants: results of in vivo studies in rat models of calcium oxalate nephrolithiasis-a systematic review. ( Bashir, S; Khan, A; Khan, SR, 2021) |
"Formation of calcium oxalate (CaOx) kidney stones was investigated using three approaches." | 4.80 | Nephrolithiasis: a consequence of renal epithelial cell exposure to oxalate and calcium oxalate crystals. ( Khan, SR; Thamilselvan, S, 2000) |
"75 percent ethylene glycol (v/v) in their drinking water for six weeks to induce hyperoxaluria." | 4.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"Hyperoxaluria caused by ethylene glycol may be prevented by a combination of Ulva lactuca aqueous extract, ulvan polysaccharides, and atorvastatin." | 4.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
" Weight loss, serum creatinine, serum urea, serum uric acid, serum oxalate, kidney oxalate, kidney lipid peroxidation, and kidney DNA fragmentation and kidney histopathological studies were done." | 4.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"Weight loss, rise of serum creatinine, serum urea, serum uric acid, serum oxalate, kidney oxalate, kidney lipid peroxidation, and kidney DNA fragmentation were all shown to be prevented by the addition of atorvastatin, polysaccharides, or aqueous extract, respectively." | 4.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
" Ulvan infusions (100 mg/kg body weight), ulvan polysaccharides (100 mg/kg body weight), and atorvastatin (two milligrams/kg body weight) to treat hyperoxaluric rats for four weeks (every other day) were used." | 4.31 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"Experimental induction of hyperoxaluria by ethylene glycol (EG) administration is disapproved as it causes metabolic acidosis while the oral administration of chemically synthesized potassium oxalate (KOx) diet does not mimic our natural system." | 3.88 | Oral administration of oxalate-enriched spinach extract as an improved methodology for the induction of dietary hyperoxaluric nephrocalcinosis in experimental rats. ( Albert, A; Ganesan, D; Govindan Sadasivam, S; Mariaraj Sivakumar, S; Paul, E; Ponnusamy, S; Prabhakaran, R; Tiwari, V, 2018) |
" The rats were randomized into three groups: Group 1 consisted of the controls (n = 8), Group 2 of hyperoxaluria (1% ethylene glycol (EG), n = 8), and Group 3 of the treatment (1% EG + 10 mg/kg of RES, n = 8) group." | 3.85 | Protective impact of resveratrol in experimental rat model of hyperoxaluria. ( Aydın Candan, I; Calapoğlu, M; Ergün, O; Oksay, T; Onaran, İ; Özorak, A; Yunusoğlu, S, 2017) |
"In the present study, resveratrol was seen to prevent hyperoxaluria." | 3.85 | Protective impact of resveratrol in experimental rat model of hyperoxaluria. ( Aydın Candan, I; Calapoğlu, M; Ergün, O; Oksay, T; Onaran, İ; Özorak, A; Yunusoğlu, S, 2017) |
"Hyperoxaluria was induced in male SD rats by administering ethylene glycol." | 3.83 | Involvement of renin-angiotensin-aldosterone system in calcium oxalate crystal induced activation of NADPH oxidase and renal cell injury. ( Khan, SR; Peck, AB; Shimizu, N; Sunil, J; Tsuji, H; Uemura, H; Wang, W; Yoshimura, K, 2016) |
"To investigate whether the sex-dependent expression of hepatic and renal oxalate transporter sat-1 (Slc26a1) changes in a rat model of ethylene glycol (EG)-induced hyperoxaluria." | 3.81 | In female rats, ethylene glycol treatment elevates protein expression of hepatic and renal oxalate transporter sat-1 (Slc26a1) without inducing hyperoxaluria. ( Breljak, D; Brzica, H; Burckhardt, BC; Burckhardt, G; Henjakovic, M; Jurasović, J; Karaica, D; Ljubojević, M; Lovrić, M; Micek, V; Peraica, M; Rašić, D; Sabolić, I; Schnedler, N; Sekovanić, A; Vrhovac, I; Wegner, W, 2015) |
"Oral administration of ethylene glycol resulted in hyperoxaluria and increased renal excretion of calcium and phosphate." | 3.78 | Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats. ( Gadge, NB; Jalalpure, SS, 2012) |
"75% v/v ethylene glycol in drinking water to induce chronic hyperoxaluria and simultaneously BDE was given to nephrolithiasic treated rats at the dose of 100 and 200 mg/kg b." | 3.77 | Aqueous extract of Boerhaavia diffusa root ameliorates ethylene glycol-induced hyperoxaluric oxidative stress and renal injury in rat kidney. ( Mazumder, PM; Pareta, SK; Patra, KC; Sasmal, D, 2011) |
" In groups 1A, 1B and 1C hyperoxaluria was induced with ethylene glycol for 2 weeks." | 3.76 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"Increased systemic and local tissue asymmetrical dimethylarginine may help explain the pathogenetic mechanisms of hyperoxaluria induced disorders such as nephrolithiasis and atherosclerosis." | 3.76 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
" (HARC) against ethylene glycol induced urolithiasis and its possible underlying mechanisms using male Wistar albino rats." | 3.76 | Protective effect of the hydro-alcoholic extract of Rubia cordifolia roots against ethylene glycol induced urolithiasis in rats. ( Chandrasekhar, SB; Dighe, SB; Divakar, G; Divakar, K; Pawar, AT, 2010) |
"Indicate that the HARC can protect against ethylene glycol induced urolithiasis as it reduced and prevented the growth of urinary stones." | 3.76 | Protective effect of the hydro-alcoholic extract of Rubia cordifolia roots against ethylene glycol induced urolithiasis in rats. ( Chandrasekhar, SB; Dighe, SB; Divakar, G; Divakar, K; Pawar, AT, 2010) |
"The present study was undertaken to explore the efficiency of the pentacyclic triterpene lupeol (1) and its ester derivative, lupeol linoleate (2), in experimental hyperoxaluria." | 3.74 | Antiurolithic effect of lupeol and lupeol linoleate in experimental hyperoxaluria. ( Sudhahar, V; Varalakshmi, P; Veena, CK, 2008) |
"Ethylene glycol (EG) consumption is commonly employed as an experimental regimen to induce hyperoxaluria in animal models of calcium oxalate nephrolithiasis." | 3.73 | Ethylene glycol induces hyperoxaluria without metabolic acidosis in rats. ( Freel, RW; Green, ML; Hatch, M, 2005) |
"l-Arg could act as a potent antilithic agent, by increasing the level of citrate in the hyperoxaluria-induced rats and decreasing calcium oxalate binding to the THP." | 3.73 | Oral L-arginine supplementation ameliorates urinary risk factors and kinetic modulation of Tamm-Horsfall glycoprotein in experimental hyperoxaluric rats. ( Kalaiselvi, P; Pragasam, V; Srinivasan, S; Sumitra, K; Varalakshmi, P, 2005) |
" Ethylene glycol feeding resulted in hyperoxaluria as well as increased renal excretion of calcium and phosphate." | 3.73 | Effect of Moringa oleifera Lam. root-wood on ethylene glycol induced urolithiasis in rats. ( Alagawadi, KR; Gadge, NB; Karadi, RV; Savadi, RV, 2006) |
"Osteopontin expression in the kidneys was significantly increased after hyperoxaluria and it increased further after the deposition of calcium oxalate crystals in the kidneys." | 3.71 | Expression of osteopontin in rat kidneys: induction during ethylene glycol induced calcium oxalate nephrolithiasis. ( Cornelius, JG; Glenton, PA; Johnson, JM; Khan, SR; Peck, AB, 2002) |
"To correlate serum glycolic acid levels with clinical severity and outcome in ethylene glycol poisoning and to determine if glycolic acid levels are predictive of renal failure and the need for hemodialysis." | 3.71 | Ethylene glycol toxicity: the role of serum glycolic acid in hemodialysis. ( Bush, BA; Dunnington, JE; Pappas, AA; Porter, WH; Rutter, PW, 2001) |
" Hyperoxaluria was induced by feeding ethylene glycol (EG) in drinking water." | 3.70 | Role of glutathione on renal mitochondrial status in hyperoxaluria. ( Muthukumar, A; Selvam, R, 1998) |
"Hyperoxaluria was produced in male Wistar rats by adding ethylene glycol to their drinking water." | 3.70 | Possible biphasic changes of free radicals in ethylene glycol-induced nephrolithiasis in rats. ( Chen, CF; Chen, J; Chien, CT; Huang, HS, 2000) |
"Hyperoxaluria was produced in rats by ethylene glycol in drinking water." | 3.69 | Lipid peroxidation in ethylene glycol induced hyperoxaluria and calcium oxalate nephrolithiasis. ( Hackett, RL; Khan, SR; Thamilselvan, S, 1997) |
"Ethylene glycol is a toxic alcohol which may induce significant toxicity when ingested accidentally or intentionally." | 2.72 | The three biological gaps and hyperoxaluria in ethylene glycol poisoning: case presentation and review. ( Ahmad, Y; Chiche, JD; Kissling, S; Liaudet, L; Ltaief, Z; Torrent, C, 2021) |
"Sustained hyperoxaluria in association with CaOx crystals induced apoptosis as well as necrosis." | 2.41 | Nephrolithiasis: a consequence of renal epithelial cell exposure to oxalate and calcium oxalate crystals. ( Khan, SR; Thamilselvan, S, 2000) |
"Hyperoxaluria caused by ethylene glycol may be prevented by a combination of Ulva lactuca aqueous extract, ulvan polysaccharides, and atorvastatin." | 1.91 | The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria. ( Abdel-Gabbar, M; Abdelaziz, MA; Abdelzaher, MH; Ahmed, OM; Geddawy, AI; Ibrahim, SR; Moawd, SA; Mohammad, MR; Mohideen, AP, 2023) |
"We found that EG not only resulted hyperoxaluria and kidney stone formation, but also promoted the intestinal inflammation, elevated intestinal permeability, and gut microbiota disorders." | 1.62 | Probiotic Lactiplantibacillus plantarum N-1 could prevent ethylene glycol-induced kidney stones by regulating gut microbiota and enhancing intestinal barrier function. ( Cui, Y; Jin, X; Li, H; Liu, Y; Sun, Q; Tian, L; Wang, K; Wei, Z; Yu, Y, 2021) |
"Hyperoxaluria is well known to cause renal injury and end-stage kidney disease." | 1.56 | Alteration of the gut microbiota by vinegar is associated with amelioration of hyperoxaluria-induced kidney injury. ( Duan, X; He, Z; Lan, Y; Li, S; Liu, Y; Lu, S; Luo, L; Mai, X; Wu, C; Xiao, C; Yang, Z; Zeng, G; Zhang, X; Zhong, W; Zhu, W, 2020) |
"Hyperoxaluria is characterized by an increased excretion of urinary oxalate which is caused by inherited disorders or high oxalate intake leading to renal stone ailment." | 1.51 | Amelioration of hyperoxaluria-induced kidney dysfunction by chemical chaperone 4-phenylbutyric acid. ( Bhardwaj, R; Kaur, T; Randhawa, R, 2019) |
"Induction of hyperoxaluria in rats with MS causes severe morphological alterations with a significant impairment of renal function." | 1.48 | Metabolic syndrome contributes to renal injury mediated by hyperoxaluria in a murine model of nephrolithiasis. ( Carballido, J; Castillón, I; Corbacho, C; Coronado, MJ; Jorge, E; Prieto, D; Ramil, E; Sáenz-Medina, J; Sánchez, A; Santos, M; Soblechero, P; Virumbrales, E, 2018) |
"Experimental induction of hyperoxaluria by ethylene glycol (EG) administration is disapproved as it causes metabolic acidosis while the oral administration of chemically synthesized potassium oxalate (KOx) diet does not mimic our natural system." | 1.48 | Oral administration of oxalate-enriched spinach extract as an improved methodology for the induction of dietary hyperoxaluric nephrocalcinosis in experimental rats. ( Albert, A; Ganesan, D; Govindan Sadasivam, S; Mariaraj Sivakumar, S; Paul, E; Ponnusamy, S; Prabhakaran, R; Tiwari, V, 2018) |
"Hyperoxaluria induces crystalluria, interstitial fibrosis, and progressive renal failure." | 1.46 | Calcium oxalate crystals and oxalate induce an epithelial-to-mesenchymal transition in the proximal tubular epithelial cells: Contribution to oxalate kidney injury. ( Borges, FT; Convento, MB; Cruz, E; da Glória, MA; Pessoa, EA; Schor, N, 2017) |
"Hyperoxaluria was induced by adding hydroxyproline and ethylene glycol to the mice's drinking water for up to 60 days." | 1.46 | Calcium oxalate crystals and oxalate induce an epithelial-to-mesenchymal transition in the proximal tubular epithelial cells: Contribution to oxalate kidney injury. ( Borges, FT; Convento, MB; Cruz, E; da Glória, MA; Pessoa, EA; Schor, N, 2017) |
"In the hyperoxaluria group, urinary oxalate levels were higher than the control group; yet, lower in the treatment group compared to hyperoxaluria group (p < 0." | 1.46 | Protective impact of resveratrol in experimental rat model of hyperoxaluria. ( Aydın Candan, I; Calapoğlu, M; Ergün, O; Oksay, T; Onaran, İ; Özorak, A; Yunusoğlu, S, 2017) |
"Treatment with spironolactone reversed the effect of hyperoxaluria." | 1.43 | Involvement of renin-angiotensin-aldosterone system in calcium oxalate crystal induced activation of NADPH oxidase and renal cell injury. ( Khan, SR; Peck, AB; Shimizu, N; Sunil, J; Tsuji, H; Uemura, H; Wang, W; Yoshimura, K, 2016) |
"Hyperoxaluria was induced in male SD rats by administering ethylene glycol." | 1.43 | Involvement of renin-angiotensin-aldosterone system in calcium oxalate crystal induced activation of NADPH oxidase and renal cell injury. ( Khan, SR; Peck, AB; Shimizu, N; Sunil, J; Tsuji, H; Uemura, H; Wang, W; Yoshimura, K, 2016) |
"Results indicate that hyperoxaluria-induced production of ROS, injury and inflammation are in part associated with the activation of Nox through renin-angiotensin-aldosterone pathway." | 1.43 | Involvement of renin-angiotensin-aldosterone system in calcium oxalate crystal induced activation of NADPH oxidase and renal cell injury. ( Khan, SR; Peck, AB; Shimizu, N; Sunil, J; Tsuji, H; Uemura, H; Wang, W; Yoshimura, K, 2016) |
" In summary, pAA is a potent anti-urolithic agent in rats and we can propose that 10 mg/kg body weight is the effective dosage of pAA and this concentration can be used for further studies." | 1.43 | Polyacrylic acid attenuates ethylene glycol induced hyperoxaluric damage and prevents crystal aggregation in vitro and in vivo. ( Ganesh, RN; Sridharan, B; Viswanathan, P, 2016) |
"Bergenin treatment significantly (P<0." | 1.43 | Bergenin attenuates renal injury by reversing mitochondrial dysfunction in ethylene glycol induced hyperoxaluric rat model. ( Aggarwal, D; Gautam, D; Sharma, M; Singla, SK, 2016) |
"Bergenin was administrated at a dose of 10mg/kg body wt i." | 1.43 | Bergenin attenuates renal injury by reversing mitochondrial dysfunction in ethylene glycol induced hyperoxaluric rat model. ( Aggarwal, D; Gautam, D; Sharma, M; Singla, SK, 2016) |
"Hyperoxaluria serves an important role in the pathophysiological process of stone formation." | 1.43 | Analysis of altered microRNA expression profiles in the kidney tissues of ethylene glycol-induced hyperoxaluric rats. ( Ding, Y; Jiang, H; Liu, J; Liu, Z; Wang, S; Wang, T; Yang, J; Ye, Z, 2016) |
"Hyperoxaluria was induced successfully in rats." | 1.39 | Matrix Gla protein is involved in crystal formation in kidney of hyperoxaluric rats. ( Gao, B; Hirose, M; Kohri, K; Li, Y; Liu, T; Lu, X; Mao, X; Wu, Y; Xiao, C; Yasui, T; Yu, D; Zhu, Q, 2013) |
"Treatment of ethylene glycol intoxication is based on specific inhibitors of alcohol dehydrogenase and hemodialysis in the most severe forms, and should be started promptly." | 1.39 | [Secondary hyperoxaluria and nephrocalcinosis due to ethylene glycol poisoning]. ( Harambat, J; Llanas, B; Missonnier, S; Monet, C; Rebouissoux, L; Richard, E, 2013) |
"Calcium oxalate lithiasis was induced in rats by oral administration of 0." | 1.38 | Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats. ( Gadge, NB; Jalalpure, SS, 2012) |
"Drawbacks of presently available treatments for urolithiasis necessitate finding the treatment of hyperoxaluria specifically aimed at reduction in oxalate excretion." | 1.38 | Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats. ( Gadge, NB; Jalalpure, SS, 2012) |
"These effects of hyperoxaluria were reversed by concurrent PGG treatment along with decreased urinary oxalate levels and CaOx supersaturation." | 1.37 | 1,2,3,4,6-Penta-O-galloyl-beta-D-glucose reduces renal crystallization and oxidative stress in a hyperoxaluric rat model. ( Bae, H; Jeong, SJ; Kim, SH; Lee, EO; Lee, HJ; Lieske, JC, 2011) |
"There is some evidence that hyperoxaluria may effect vascular endothelium and many studies link renal stones to atherosclerosis." | 1.36 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"In groups 1A, 1B and 1C hyperoxaluria was induced with ethylene glycol for 2 weeks." | 1.36 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"Hyperoxaluria induced a significantly dense staining pattern in renal tissue asymmetrical dimethylarginine vs controls (p = 0." | 1.36 | Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders. ( Aydin, H; Comunoğlu, N; Koyuncu, HH; Mutlu, N; Sarica, K; Yencilek, F, 2010) |
"Hyperoxaluria is a major risk factor for recurrent urolithiasis and nephrocalcinosis." | 1.35 | Hyperoxaluria is reduced and nephrocalcinosis prevented with an oxalate-degrading enzyme in mice with hyperoxaluria. ( Grujic, D; Jung, CW; Langman, CB; Mandapati, S; Margolin, AL; McGrath, ME; Patel, RJ; Rashid, A; Salido, EC; Shenoy, BC, 2009) |
"Hyperoxaluria was induced in male Wistar rats with 0." | 1.35 | Antiurolithic effect of lupeol and lupeol linoleate in experimental hyperoxaluria. ( Sudhahar, V; Varalakshmi, P; Veena, CK, 2008) |
"This study explored whether vitamin E deficiency affects intrarenal oxidative stress and accelerates crystal deposition in hyperoxaluria." | 1.35 | Low-vitamin E diet exacerbates calcium oxalate crystal formation via enhanced oxidative stress in rat hyperoxaluric kidney. ( Chen, J; Huang, HS; Ma, MC, 2009) |
"Hyperoxaluria induced a decrease in the activities of TCA cycle enzymes and respiratory complex enzymes." | 1.35 | Mitochondrial dysfunction in an animal model of hyperoxaluria: a prophylactic approach with fucoidan. ( Josephine, A; Preetha, SP; Rajesh, NG; Varalakshmi, P; Veena, CK, 2008) |
"Hyperoxaluria was induced in two groups by the administration of 0." | 1.34 | Effect of sulphated polysaccharides on erythrocyte changes due to oxidative and nitrosative stress in experimental hyperoxaluria. ( Josephine, A; Preetha, SP; Varalakshmi, P; Veena, CK, 2007) |
"Hyperoxaluria was induced using 0." | 1.33 | Counteraction of oxalate induced nitrosative stress by supplementation of l-arginine, a potent antilithic agent. ( Kalaiselvi, P; Pragasam, V; Srinivasan, S; Sumitra, K; Varalakshmi, P, 2005) |
"Frank metabolic acidosis was observed in the MA rats: decreased arterial pH and plasma HCO3(-) concentration with lower urinary pH and citrate excretion with elevated excretion of ammonium, phosphate and, hence, titratable acid." | 1.33 | Ethylene glycol induces hyperoxaluria without metabolic acidosis in rats. ( Freel, RW; Green, ML; Hatch, M, 2005) |
"Hyperoxaluria was induced by 0." | 1.33 | Oral L-arginine supplementation ameliorates urinary risk factors and kinetic modulation of Tamm-Horsfall glycoprotein in experimental hyperoxaluric rats. ( Kalaiselvi, P; Pragasam, V; Srinivasan, S; Sumitra, K; Varalakshmi, P, 2005) |
"Mild hyperoxaluria was induced in male Wistar rats using ethylene glycol (EG; 0." | 1.33 | Mild tubular damage induces calcium oxalate crystalluria in a model of subtle hyperoxaluria: Evidence that a second hit is necessary for renal lithogenesis. ( D'Angelo, A; Del Prete, D; Della Barbera, M; Gambaro, G; Trevisan, A; Valente, ML; Zanetti, E, 2006) |
"Chronic hyperoxaluria was induced by adding 0." | 1.32 | Changes in renal hemodynamics and urodynamics in rats with chronic hyperoxaluria and after acute oxalate infusion: role of free radicals. ( Chen, CF; Chen, J; Huang, HS; Ma, MC, 2003) |
"Hyperoxaluria was induced in male Wistar rats by feeding 0." | 1.32 | Expression of nuclear pore complex oxalate binding protein p62 in experimental hyperoxaluria. ( Kalaiselvi, P; Sakthivel, R; Selvam, R; Sivakamasundari, P; Varalakshmi, P, 2004) |
"During hyperoxaluria osteopontin expression in the kidneys was increased but still mostly limited to cells of the thin limb and papillary surface epithelium." | 1.31 | Expression of osteopontin in rat kidneys: induction during ethylene glycol induced calcium oxalate nephrolithiasis. ( Cornelius, JG; Glenton, PA; Johnson, JM; Khan, SR; Peck, AB, 2002) |
"Calcium oxalate nephrolithiasis was induced by administering ethylene glycol." | 1.31 | Expression of osteopontin in rat kidneys: induction during ethylene glycol induced calcium oxalate nephrolithiasis. ( Cornelius, JG; Glenton, PA; Johnson, JM; Khan, SR; Peck, AB, 2002) |
"Hyperoxaluria was produced in male Wistar rats by adding ethylene glycol to their drinking water." | 1.31 | Possible biphasic changes of free radicals in ethylene glycol-induced nephrolithiasis in rats. ( Chen, CF; Chen, J; Chien, CT; Huang, HS, 2000) |
"Hematuria was more prevalent than oxaluria (86% and 41%, respectively), but neither was individually predictive of acute renal failure." | 1.31 | Ethylene glycol toxicity: the role of serum glycolic acid in hemodialysis. ( Bush, BA; Dunnington, JE; Pappas, AA; Porter, WH; Rutter, PW, 2001) |
"Hyperoxaluria was produced in rats by ethylene glycol in drinking water." | 1.30 | Lipid peroxidation in ethylene glycol induced hyperoxaluria and calcium oxalate nephrolithiasis. ( Hackett, RL; Khan, SR; Thamilselvan, S, 1997) |
"At autopsy, progressed chronic renal oxalosis could be confirmed." | 1.30 | [Fatal chronic oxalosis after sublethal ethylene glycol poisoning]. ( Brachwitz, C; Lange, H; Nizze, H; Schwabbauer, P, 1997) |
"Hyperoxaluria was induced by feeding ethylene glycol (EG) in drinking water." | 1.30 | Role of glutathione on renal mitochondrial status in hyperoxaluria. ( Muthukumar, A; Selvam, R, 1998) |
Timeframe | Studies, this research(%) | All Research% |
---|---|---|
pre-1990 | 0 (0.00) | 18.7374 |
1990's | 7 (13.73) | 18.2507 |
2000's | 19 (37.25) | 29.6817 |
2010's | 19 (37.25) | 24.3611 |
2020's | 6 (11.76) | 2.80 |
Authors | Studies |
---|---|
Wei, Z | 1 |
Cui, Y | 1 |
Tian, L | 1 |
Liu, Y | 3 |
Yu, Y | 1 |
Jin, X | 1 |
Li, H | 1 |
Wang, K | 1 |
Sun, Q | 1 |
Ahmad, Y | 1 |
Kissling, S | 1 |
Torrent, C | 1 |
Chiche, JD | 1 |
Liaudet, L | 1 |
Ltaief, Z | 1 |
He, Q | 1 |
Tang, Y | 1 |
Li, Y | 2 |
Wang, F | 1 |
Bao, J | 1 |
Gupta, S | 1 |
Abdelaziz, MA | 1 |
Ahmed, OM | 1 |
Abdel-Gabbar, M | 1 |
Mohammad, MR | 1 |
Ibrahim, SR | 1 |
Abdelzaher, MH | 1 |
Mohideen, AP | 1 |
Moawd, SA | 1 |
Geddawy, AI | 1 |
Zhu, W | 1 |
Duan, X | 1 |
Xiao, C | 2 |
Lan, Y | 1 |
Luo, L | 1 |
Wu, C | 1 |
Yang, Z | 1 |
Mai, X | 1 |
Lu, S | 1 |
Zhong, W | 1 |
Li, S | 1 |
He, Z | 1 |
Zhang, X | 1 |
Zeng, G | 1 |
Khan, A | 1 |
Bashir, S | 1 |
Khan, SR | 5 |
Convento, MB | 1 |
Pessoa, EA | 1 |
Cruz, E | 1 |
da Glória, MA | 1 |
Schor, N | 1 |
Borges, FT | 1 |
Sáenz-Medina, J | 1 |
Jorge, E | 1 |
Corbacho, C | 1 |
Santos, M | 1 |
Sánchez, A | 1 |
Soblechero, P | 1 |
Virumbrales, E | 1 |
Ramil, E | 1 |
Coronado, MJ | 1 |
Castillón, I | 1 |
Prieto, D | 1 |
Carballido, J | 1 |
Albert, A | 1 |
Tiwari, V | 1 |
Paul, E | 1 |
Ponnusamy, S | 1 |
Ganesan, D | 1 |
Prabhakaran, R | 1 |
Mariaraj Sivakumar, S | 1 |
Govindan Sadasivam, S | 1 |
Randhawa, R | 1 |
Bhardwaj, R | 1 |
Kaur, T | 1 |
Lu, X | 1 |
Gao, B | 1 |
Yasui, T | 1 |
Liu, T | 1 |
Mao, X | 1 |
Hirose, M | 1 |
Wu, Y | 1 |
Yu, D | 1 |
Zhu, Q | 1 |
Kohri, K | 1 |
Zhang, CY | 1 |
Kong, T | 1 |
Wu, WH | 1 |
Lan, MB | 1 |
Monet, C | 1 |
Richard, E | 1 |
Missonnier, S | 1 |
Rebouissoux, L | 1 |
Llanas, B | 1 |
Harambat, J | 1 |
Tsuji, H | 1 |
Wang, W | 1 |
Sunil, J | 1 |
Shimizu, N | 1 |
Yoshimura, K | 1 |
Uemura, H | 1 |
Peck, AB | 2 |
Breljak, D | 1 |
Brzica, H | 1 |
Vrhovac, I | 1 |
Micek, V | 1 |
Karaica, D | 1 |
Ljubojević, M | 1 |
Sekovanić, A | 1 |
Jurasović, J | 1 |
Rašić, D | 1 |
Peraica, M | 1 |
Lovrić, M | 1 |
Schnedler, N | 1 |
Henjakovic, M | 1 |
Wegner, W | 1 |
Burckhardt, G | 1 |
Burckhardt, BC | 1 |
Sabolić, I | 1 |
Sridharan, B | 1 |
Ganesh, RN | 1 |
Viswanathan, P | 1 |
Aggarwal, D | 1 |
Gautam, D | 1 |
Sharma, M | 1 |
Singla, SK | 1 |
Liu, Z | 1 |
Jiang, H | 1 |
Yang, J | 1 |
Wang, T | 1 |
Ding, Y | 1 |
Liu, J | 1 |
Wang, S | 1 |
Ye, Z | 1 |
Oksay, T | 1 |
Yunusoğlu, S | 1 |
Calapoğlu, M | 1 |
Aydın Candan, I | 1 |
Onaran, İ | 1 |
Ergün, O | 1 |
Özorak, A | 1 |
Stapenhorst, L | 1 |
Hesse, A | 1 |
Hoppe, B | 1 |
Grujic, D | 1 |
Salido, EC | 1 |
Shenoy, BC | 1 |
Langman, CB | 1 |
McGrath, ME | 1 |
Patel, RJ | 1 |
Rashid, A | 1 |
Mandapati, S | 1 |
Jung, CW | 1 |
Margolin, AL | 1 |
Sudhahar, V | 1 |
Veena, CK | 3 |
Varalakshmi, P | 6 |
Huang, HS | 3 |
Ma, MC | 2 |
Chen, J | 3 |
Aydin, H | 1 |
Yencilek, F | 1 |
Mutlu, N | 1 |
Comunoğlu, N | 1 |
Koyuncu, HH | 1 |
Sarica, K | 1 |
Divakar, K | 1 |
Pawar, AT | 1 |
Chandrasekhar, SB | 1 |
Dighe, SB | 1 |
Divakar, G | 1 |
Lee, HJ | 2 |
Jeong, SJ | 1 |
Lee, EO | 1 |
Bae, H | 1 |
Lieske, JC | 1 |
Kim, SH | 1 |
Pareta, SK | 1 |
Patra, KC | 1 |
Mazumder, PM | 1 |
Sasmal, D | 1 |
Amengual-Cladera, E | 1 |
Nadal-Casellas, A | 1 |
Gómez-Pérez, Y | 1 |
Gomila, I | 1 |
Prieto, RM | 1 |
Proenza, AM | 1 |
Lladó, I | 1 |
Gadge, NB | 2 |
Jalalpure, SS | 1 |
Johnson, JM | 1 |
Cornelius, JG | 1 |
Glenton, PA | 1 |
Chen, CF | 2 |
Sivakamasundari, P | 1 |
Sakthivel, R | 1 |
Kalaiselvi, P | 3 |
Selvam, R | 2 |
Pragasam, V | 2 |
Sumitra, K | 2 |
Srinivasan, S | 2 |
Yamaguchi, S | 1 |
Wiessner, JH | 1 |
Hasegawa, AT | 1 |
Hung, LY | 1 |
Mandel, GS | 1 |
Mandel, NS | 1 |
Green, ML | 1 |
Hatch, M | 1 |
Freel, RW | 1 |
Karadi, RV | 1 |
Alagawadi, KR | 1 |
Savadi, RV | 1 |
Gambaro, G | 1 |
Valente, ML | 1 |
Zanetti, E | 1 |
Della Barbera, M | 1 |
Del Prete, D | 1 |
D'Angelo, A | 1 |
Trevisan, A | 1 |
Gaines, L | 1 |
Waibel, KH | 1 |
Josephine, A | 2 |
Preetha, SP | 2 |
Rajesh, NG | 1 |
de Bruijn, WC | 3 |
Boevé, ER | 3 |
van Run, PR | 3 |
van Miert, PP | 3 |
Romijn, JC | 3 |
Verkoelen, CF | 3 |
Cao, LC | 3 |
Schröder, FH | 2 |
de Water, R | 2 |
van 't Noordende, JM | 1 |
Schrder, FH | 1 |
Thamilselvan, S | 2 |
Hackett, RL | 1 |
Nizze, H | 1 |
Schwabbauer, P | 1 |
Brachwitz, C | 1 |
Lange, H | 1 |
Muthukumar, A | 1 |
Chien, CT | 1 |
Porter, WH | 1 |
Rutter, PW | 1 |
Bush, BA | 1 |
Pappas, AA | 1 |
Dunnington, JE | 1 |
Bais, R | 1 |
Rofe, AM | 1 |
Conyers, RA | 1 |
3 reviews available for ethylene glycol and Hyperoxaluria
Article | Year |
---|---|
The three biological gaps and hyperoxaluria in ethylene glycol poisoning: case presentation and review.
Topics: Acidosis; Antidotes; Delayed Diagnosis; Ethylene Glycol; Female; Fomepizole; Humans; Hyperoxaluria; | 2021 |
Antiurolithic effects of medicinal plants: results of in vivo studies in rat models of calcium oxalate nephrolithiasis-a systematic review.
Topics: Animals; Anti-Inflammatory Agents; Antioxidants; Calcium Oxalate; Crystallization; Disease Models, A | 2021 |
Nephrolithiasis: a consequence of renal epithelial cell exposure to oxalate and calcium oxalate crystals.
Topics: Animals; Calcium Oxalate; Cell Aggregation; Cell Line; Crystallization; Dogs; Ethylene Glycol; Human | 2000 |
48 other studies available for ethylene glycol and Hyperoxaluria
Article | Year |
---|---|
Probiotic Lactiplantibacillus plantarum N-1 could prevent ethylene glycol-induced kidney stones by regulating gut microbiota and enhancing intestinal barrier function.
Topics: Animals; Colon; Ethylene Glycol; Fatty Acids, Volatile; Feces; Gastrointestinal Microbiome; Hyperoxa | 2021 |
A pilot dynamic analysis of formative factors of nephrolithiasis related to metabolic syndrome: evidence in a rat model.
Topics: Ammonium Chloride; Animals; Ethylene Glycol; Humans; Hyperoxaluria; Inflammation; Kidney Calculi; Ma | 2022 |
The preventive effects of Ulva lactuca aqueous extract, ulvan polysaccharides and atorvastatin on ethylene glycol-induced hyperoxaluria.
Topics: Animals; Antioxidants; Atorvastatin; Body Weight; Creatinine; Ethylene Glycol; Humans; Hyperoxaluria | 2023 |
Alteration of the gut microbiota by vinegar is associated with amelioration of hyperoxaluria-induced kidney injury.
Topics: Acetic Acid; Administration, Oral; Animals; Ethylene Glycol; Gastrointestinal Microbiome; Hyperoxalu | 2020 |
Calcium oxalate crystals and oxalate induce an epithelial-to-mesenchymal transition in the proximal tubular epithelial cells: Contribution to oxalate kidney injury.
Topics: Animals; Calcium Oxalate; Cell Movement; Epithelial-Mesenchymal Transition; Ethylene Glycol; Fibrosi | 2017 |
Metabolic syndrome contributes to renal injury mediated by hyperoxaluria in a murine model of nephrolithiasis.
Topics: Animals; Calcium Oxalate; Creatinine; Diet, Carbohydrate Loading; Disease Models, Animal; Ethylene G | 2018 |
Oral administration of oxalate-enriched spinach extract as an improved methodology for the induction of dietary hyperoxaluric nephrocalcinosis in experimental rats.
Topics: Administration, Oral; Animals; Biomarkers; Crystallization; Disease Models, Animal; Ethylene Glycol; | 2018 |
Amelioration of hyperoxaluria-induced kidney dysfunction by chemical chaperone 4-phenylbutyric acid.
Topics: Animals; Biomarkers; Calcium Oxalate; Disease Models, Animal; Drug Evaluation, Preclinical; Endoplas | 2019 |
Matrix Gla protein is involved in crystal formation in kidney of hyperoxaluric rats.
Topics: Animals; Calcium-Binding Proteins; Ethylene Glycol; Extracellular Matrix Proteins; Hyperoxaluria; Ki | 2013 |
The protection of polysaccharide from the Brown Seaweed Sargassum graminifolium against ethylene glycol-induced mitochondrial damage.
Topics: Adenosine Triphosphatases; Animals; Antioxidants; Dose-Response Relationship, Drug; Ethylene Glycol; | 2013 |
[Secondary hyperoxaluria and nephrocalcinosis due to ethylene glycol poisoning].
Topics: Accidents, Home; Acidosis; Calcium Oxalate; Child, Preschool; Citric Acid; Ethylene Glycol; Fluid Th | 2013 |
Involvement of renin-angiotensin-aldosterone system in calcium oxalate crystal induced activation of NADPH oxidase and renal cell injury.
Topics: 11-beta-Hydroxysteroid Dehydrogenase Type 2; Angiotensinogen; Animals; Calcium Oxalate; Cell Line; C | 2016 |
In female rats, ethylene glycol treatment elevates protein expression of hepatic and renal oxalate transporter sat-1 (Slc26a1) without inducing hyperoxaluria.
Topics: Alcohol Dehydrogenase; Animals; Anion Transport Proteins; Antiporters; Blotting, Western; Calcium Ox | 2015 |
Polyacrylic acid attenuates ethylene glycol induced hyperoxaluric damage and prevents crystal aggregation in vitro and in vivo.
Topics: Acrylic Resins; Animals; Calcium Oxalate; Ethylene Glycol; Female; Hyperoxaluria; Kidney; Liver; Mal | 2016 |
Bergenin attenuates renal injury by reversing mitochondrial dysfunction in ethylene glycol induced hyperoxaluric rat model.
Topics: Animals; Antioxidants; Benzopyrans; Biomarkers; Chemokine CCL2; Creatinine; Cytoprotection; Disease | 2016 |
Analysis of altered microRNA expression profiles in the kidney tissues of ethylene glycol-induced hyperoxaluric rats.
Topics: Animals; Cluster Analysis; Computational Biology; Ethylene Glycol; Gene Expression Profiling; Gene E | 2016 |
Protective impact of resveratrol in experimental rat model of hyperoxaluria.
Topics: Animals; Antioxidants; Biopsy, Needle; Disease Models, Animal; Ethylene Glycol; Hyperoxaluria; Immun | 2017 |
Hyperoxaluria after ethylene glycol poisoning.
Topics: Child; Drug Overdose; Ethanol; Ethylene Glycol; Female; Humans; Hyperoxaluria; Renal Dialysis; Suici | 2008 |
Hyperoxaluria is reduced and nephrocalcinosis prevented with an oxalate-degrading enzyme in mice with hyperoxaluria.
Topics: Administration, Oral; Amino Acid Transport Systems; Animals; Carboxy-Lyases; Chemistry, Pharmaceutic | 2009 |
Antiurolithic effect of lupeol and lupeol linoleate in experimental hyperoxaluria.
Topics: Administration, Oral; Animals; Disease Models, Animal; Ethylene Glycol; Hyperoxaluria; Kidney Calcul | 2008 |
Low-vitamin E diet exacerbates calcium oxalate crystal formation via enhanced oxidative stress in rat hyperoxaluric kidney.
Topics: Animals; Calcium Oxalate; Crystallization; Dietary Supplements; Disease Models, Animal; Ethylene Gly | 2009 |
Ethylene glycol induced hyperoxaluria increases plasma and renal tissue asymmetrical dimethylarginine in rats: a new pathogenetic link in hyperoxaluria induced disorders.
Topics: Animals; Arginine; Ethylene Glycol; Hyperoxaluria; Rats; Rats, Sprague-Dawley; Tissue Distribution; | 2010 |
Protective effect of the hydro-alcoholic extract of Rubia cordifolia roots against ethylene glycol induced urolithiasis in rats.
Topics: Animals; Antioxidants; Calcium; Disease Models, Animal; Ethanol; Ethylene Glycol; Hyperoxaluria; Kid | 2010 |
1,2,3,4,6-Penta-O-galloyl-beta-D-glucose reduces renal crystallization and oxidative stress in a hyperoxaluric rat model.
Topics: Animals; Apoptosis; Crystallization; Ethylene Glycol; Hyaluronic Acid; Hydrolyzable Tannins; Hyperox | 2011 |
Aqueous extract of Boerhaavia diffusa root ameliorates ethylene glycol-induced hyperoxaluric oxidative stress and renal injury in rat kidney.
Topics: Acute Kidney Injury; Animals; Antioxidants; Biphenyl Compounds; Catalase; Chromatography, Thin Layer | 2011 |
Phytotherapy in a rat model of hyperoxaluria: the antioxidant effects of quercetin involve serum paraoxonase 1 activation.
Topics: Animals; Antioxidants; Apolipoprotein A-I; Aryldialkylphosphatase; Blotting, Western; Catechin; Chol | 2011 |
Curative treatment with extracts of Bombax ceiba fruit reduces risk of calcium oxalate urolithiasis in rats.
Topics: Animals; Bombax; Calcium; Calcium Oxalate; Disease Models, Animal; Ethylene Glycol; Female; Fruit; H | 2012 |
Expression of osteopontin in rat kidneys: induction during ethylene glycol induced calcium oxalate nephrolithiasis.
Topics: Animals; Blotting, Western; Calcium Oxalate; Electrophoresis, Polyacrylamide Gel; Ethylene Glycol; H | 2002 |
Changes in renal hemodynamics and urodynamics in rats with chronic hyperoxaluria and after acute oxalate infusion: role of free radicals.
Topics: Acute Disease; Animals; Chronic Disease; Ethylene Glycol; Free Radicals; Glomerular Filtration Rate; | 2003 |
Expression of nuclear pore complex oxalate binding protein p62 in experimental hyperoxaluria.
Topics: Animals; Antibodies, Monoclonal; Carbon Radioisotopes; Cell Extracts; Chromatography, Gel; Ethylene | 2004 |
Counteraction of oxalate induced nitrosative stress by supplementation of l-arginine, a potent antilithic agent.
Topics: Animals; Antioxidants; Arginine; Body Weight; Dietary Supplements; Disease Models, Animal; Ethylene | 2005 |
Study of a rat model for calcium oxalate crystal formation without severe renal damage in selected conditions.
Topics: Acetylglucosaminidase; Ammonium Chloride; Animals; Calcium Oxalate; Crystallization; Disease Models, | 2005 |
Ethylene glycol induces hyperoxaluria without metabolic acidosis in rats.
Topics: Acidosis; Animals; Carbon Dioxide; Disease Models, Animal; Electrolytes; Ethylene Glycol; Hyperoxalu | 2005 |
Oral L-arginine supplementation ameliorates urinary risk factors and kinetic modulation of Tamm-Horsfall glycoprotein in experimental hyperoxaluric rats.
Topics: Animals; Arginine; Biomarkers; Calcium Compounds; Calcium Oxalate; Citric Acid; Clinical Enzyme Test | 2005 |
Effect of Moringa oleifera Lam. root-wood on ethylene glycol induced urolithiasis in rats.
Topics: Animals; Ethylene Glycol; Female; Hyperoxaluria; Male; Moringa oleifera; Plant Roots; Rats; Rats, Wi | 2006 |
Mild tubular damage induces calcium oxalate crystalluria in a model of subtle hyperoxaluria: Evidence that a second hit is necessary for renal lithogenesis.
Topics: Animals; Calcium Oxalate; Crystallization; Disease Models, Animal; Ethylene Glycol; Hyperoxaluria; K | 2006 |
Calcium oxalate crystalluria.
Topics: Adult; Calcium Oxalate; Diagnosis, Differential; Ethanol; Ethylene Glycol; Humans; Hyperoxaluria; Ma | 2007 |
Mitochondrial dysfunction in an animal model of hyperoxaluria: a prophylactic approach with fucoidan.
Topics: Animals; Antioxidants; Citric Acid Cycle; Disease Models, Animal; Ethylene Glycol; Fucus; Glutathion | 2008 |
Effect of sulphated polysaccharides on erythrocyte changes due to oxidative and nitrosative stress in experimental hyperoxaluria.
Topics: Animals; Biomarkers; Carbon Radioisotopes; Disease Models, Animal; Erythrocytes; Ethylene Glycol; Fu | 2007 |
Etiology of experimental calcium oxalate monohydrate nephrolithiasis in rats.
Topics: Ammonium Chloride; Animals; Calcium Oxalate; Diet; Ethylene Glycol; Ethylene Glycols; Hyperoxaluria; | 1994 |
Etiology of calcium oxalate nephrolithiasis in rats. I. Can this be a model for human stone formation?
Topics: Ammonium Chloride; Animals; Calcium Oxalate; Crystallization; Disease Models, Animal; Ethylene Glyco | 1995 |
Etiology of calcium oxalate nephrolithiasis in rats. II. The role of the papilla in stone formation.
Topics: Ammonium Chloride; Animals; Calcium Oxalate; Crystallization; Disease Models, Animal; Electron Probe | 1995 |
Lipid peroxidation in ethylene glycol induced hyperoxaluria and calcium oxalate nephrolithiasis.
Topics: Animals; Calcium Oxalate; Ethylene Glycol; Ethylene Glycols; Hyperoxaluria; Kidney Calculi; Lipid Pe | 1997 |
[Fatal chronic oxalosis after sublethal ethylene glycol poisoning].
Topics: Adult; Biopsy, Needle; Ethylene Glycol; Fatal Outcome; Humans; Hyperoxaluria; Hypertension, Renal; K | 1997 |
Role of glutathione on renal mitochondrial status in hyperoxaluria.
Topics: Albinism; Animals; Buthionine Sulfoximine; Ethylene Glycol; Glutathione; Hyperoxaluria; Kidney; Kidn | 1998 |
Possible biphasic changes of free radicals in ethylene glycol-induced nephrolithiasis in rats.
Topics: Animals; Ethylene Glycol; Free Radicals; Hyperoxaluria; Kidney Calculi; Luminescent Measurements; Ma | 2000 |
Ethylene glycol toxicity: the role of serum glycolic acid in hemodialysis.
Topics: Bicarbonates; Biomarkers; Central Nervous System Diseases; Ethylene Glycol; Gas Chromatography-Mass | 2001 |
The inhibition of metabolic oxalate production by sulfhydryl compounds.
Topics: Aluminum; Animals; Carbon Dioxide; Cysteine; Ethylene Glycol; Ethylene Glycols; Hyperoxaluria; In Vi | 1991 |