OpenAlex is a bibliographic catalogue of scientific papers, authors and institutions accessible in open access mode, named after the Library of Alexandria. It's citation coverage is excellent and I hope you will find utility in this listing of citing articles!
If you click the article title, you'll navigate to the article, as listed in CrossRef. If you click the Open Access links, you'll navigate to the "best Open Access location". Clicking the citation count will open this listing for that article. Lastly at the bottom of the page, you'll find basic pagination options.
Requested Article:
Urate Handling in the Human Body
David Hyndman, Sha Liu, Jeffrey N. Miner
Current Rheumatology Reports (2016) Vol. 18, Iss. 6
Open Access | Times Cited: 138
David Hyndman, Sha Liu, Jeffrey N. Miner
Current Rheumatology Reports (2016) Vol. 18, Iss. 6
Open Access | Times Cited: 138
Showing 1-25 of 138 citing articles:
Physiology of Hyperuricemia and Urate-Lowering Treatments
Caroline Benn, Vivek Dua, Rachel Gurrell, et al.
Frontiers in Medicine (2018) Vol. 5
Open Access | Times Cited: 273
Caroline Benn, Vivek Dua, Rachel Gurrell, et al.
Frontiers in Medicine (2018) Vol. 5
Open Access | Times Cited: 273
Catalpol ameliorates fructose-induced renal inflammation by inhibiting TLR4/MyD88 signaling and uric acid reabsorption
Yan Chen, Qingpu Liu, Xinyu Meng, et al.
European Journal of Pharmacology (2024) Vol. 967, pp. 176356-176356
Closed Access | Times Cited: 28
Yan Chen, Qingpu Liu, Xinyu Meng, et al.
European Journal of Pharmacology (2024) Vol. 967, pp. 176356-176356
Closed Access | Times Cited: 28
Kidney function decline mediates the adverse effects of per- and poly-fluoroalkyl substances (PFAS) on uric acid levels and hyperuricemia risk
Zhiping Niu, Zhizhou Duan, Weixiang He, et al.
Journal of Hazardous Materials (2024) Vol. 471, pp. 134312-134312
Closed Access | Times Cited: 28
Zhiping Niu, Zhizhou Duan, Weixiang He, et al.
Journal of Hazardous Materials (2024) Vol. 471, pp. 134312-134312
Closed Access | Times Cited: 28
Mechanisms of urate transport and uricosuric drugs inhibition in human URAT1
Wenjun Guo, Miao Wei, Yunfeng Li, et al.
Nature Communications (2025) Vol. 16, Iss. 1
Open Access | Times Cited: 3
Wenjun Guo, Miao Wei, Yunfeng Li, et al.
Nature Communications (2025) Vol. 16, Iss. 1
Open Access | Times Cited: 3
The ABCG2 Q141K hyperuricemia and gout associated variant illuminates the physiology of human urate excretion
Kazi Mirajul Hoque, Eryn E. Dixon, Raychel M. Lewis, et al.
Nature Communications (2020) Vol. 11, Iss. 1
Open Access | Times Cited: 114
Kazi Mirajul Hoque, Eryn E. Dixon, Raychel M. Lewis, et al.
Nature Communications (2020) Vol. 11, Iss. 1
Open Access | Times Cited: 114
The biology of urate
Robert T. Keenan
Seminars in Arthritis and Rheumatism (2020) Vol. 50, Iss. 3, pp. S2-S10
Open Access | Times Cited: 114
Robert T. Keenan
Seminars in Arthritis and Rheumatism (2020) Vol. 50, Iss. 3, pp. S2-S10
Open Access | Times Cited: 114
Gout, Hyperuricemia, and Crystal‐Associated Disease Network Consensus Statement Regarding Labels and Definitions for Disease Elements in Gout
David Bursill, William J. Taylor, Robert Terkeltaub, et al.
Arthritis Care & Research (2018) Vol. 71, Iss. 3, pp. 427-434
Open Access | Times Cited: 90
David Bursill, William J. Taylor, Robert Terkeltaub, et al.
Arthritis Care & Research (2018) Vol. 71, Iss. 3, pp. 427-434
Open Access | Times Cited: 90
The systems biology of uric acid transporters
Sanjay K. Nigám, Vibha Bhatnagar
Current Opinion in Nephrology & Hypertension (2018) Vol. 27, Iss. 4, pp. 305-313
Open Access | Times Cited: 84
Sanjay K. Nigám, Vibha Bhatnagar
Current Opinion in Nephrology & Hypertension (2018) Vol. 27, Iss. 4, pp. 305-313
Open Access | Times Cited: 84
Apigenin ameliorates hyperuricemic nephropathy by inhibiting URAT1 and GLUT9 and relieving renal fibrosis via the Wnt/β-catenin pathway
Yongmei Li, Zean Zhao, Jian Luo, et al.
Phytomedicine (2021) Vol. 87, pp. 153585-153585
Closed Access | Times Cited: 67
Yongmei Li, Zean Zhao, Jian Luo, et al.
Phytomedicine (2021) Vol. 87, pp. 153585-153585
Closed Access | Times Cited: 67
Function of Uric Acid Transporters and Their Inhibitors in Hyperuricaemia
Haolu Sun, Yi-wan Wu, He-ge Bian, et al.
Frontiers in Pharmacology (2021) Vol. 12
Open Access | Times Cited: 67
Haolu Sun, Yi-wan Wu, He-ge Bian, et al.
Frontiers in Pharmacology (2021) Vol. 12
Open Access | Times Cited: 67
Hydrogen Sulfide Produced by Gut Bacteria May Induce Parkinson’s Disease
Kari Murros
Cells (2022) Vol. 11, Iss. 6, pp. 978-978
Open Access | Times Cited: 63
Kari Murros
Cells (2022) Vol. 11, Iss. 6, pp. 978-978
Open Access | Times Cited: 63
Live and pasteurized Akkermansia muciniphila attenuate hyperuricemia in mice through modulating uric acid metabolism, inflammation, and gut microbiota
Lihua Zhang, Jiaxiu Liu, Tong Jin, et al.
Food & Function (2022) Vol. 13, Iss. 23, pp. 12412-12425
Closed Access | Times Cited: 42
Lihua Zhang, Jiaxiu Liu, Tong Jin, et al.
Food & Function (2022) Vol. 13, Iss. 23, pp. 12412-12425
Closed Access | Times Cited: 42
Emerging Urate-Lowering Drugs and Pharmacologic Treatment Strategies for Gout: A Narrative Review
Robert Terkeltaub
Drugs (2023) Vol. 83, Iss. 16, pp. 1501-1521
Closed Access | Times Cited: 35
Robert Terkeltaub
Drugs (2023) Vol. 83, Iss. 16, pp. 1501-1521
Closed Access | Times Cited: 35
A review on gout: Looking back and looking ahead
Haolin Tao, Yingshi Mo, Wenbin Liu, et al.
International Immunopharmacology (2023) Vol. 117, pp. 109977-109977
Closed Access | Times Cited: 30
Haolin Tao, Yingshi Mo, Wenbin Liu, et al.
International Immunopharmacology (2023) Vol. 117, pp. 109977-109977
Closed Access | Times Cited: 30
Amelioration effects of α-viniferin on hyperuricemia and hyperuricemia-induced kidney injury in mice
Xiaoli Guo, Yanyan Gao, Ya-Xin Yang, et al.
Phytomedicine (2023) Vol. 116, pp. 154868-154868
Open Access | Times Cited: 29
Xiaoli Guo, Yanyan Gao, Ya-Xin Yang, et al.
Phytomedicine (2023) Vol. 116, pp. 154868-154868
Open Access | Times Cited: 29
Hyperuricemia, the heart, and the kidneys – to treat or not to treat?
Tadej Petreski, Robert Ekart, Radovan Hojs, et al.
Renal Failure (2020) Vol. 42, Iss. 1, pp. 978-986
Open Access | Times Cited: 54
Tadej Petreski, Robert Ekart, Radovan Hojs, et al.
Renal Failure (2020) Vol. 42, Iss. 1, pp. 978-986
Open Access | Times Cited: 54
Hyperuricemia and Progression of Chronic Kidney Disease: A Review from Physiology and Pathogenesis to the Role of Urate-Lowering Therapy
Tao Han Lee, Jia‐Jin Chen, Chao‐Yi Wu, et al.
Diagnostics (2021) Vol. 11, Iss. 9, pp. 1674-1674
Open Access | Times Cited: 42
Tao Han Lee, Jia‐Jin Chen, Chao‐Yi Wu, et al.
Diagnostics (2021) Vol. 11, Iss. 9, pp. 1674-1674
Open Access | Times Cited: 42
Preventive effect of Lactobacillus johnsonii YH1136 against uric acid accumulation and renal damages
Xingting Zhang, Junliang Jiang, Jinge Xin, et al.
Frontiers in Microbiology (2024) Vol. 15
Open Access | Times Cited: 7
Xingting Zhang, Junliang Jiang, Jinge Xin, et al.
Frontiers in Microbiology (2024) Vol. 15
Open Access | Times Cited: 7
Renal organic anion transporters in drug–drug interactions and diseases
Xiaokui Huo, Kexin Liu
European Journal of Pharmaceutical Sciences (2017) Vol. 112, pp. 8-19
Closed Access | Times Cited: 56
Xiaokui Huo, Kexin Liu
European Journal of Pharmaceutical Sciences (2017) Vol. 112, pp. 8-19
Closed Access | Times Cited: 56
Novel urate transporter 1 (URAT1) inhibitors: a review of recent patent literature (2016–2019)
Yue Dong, Tong Zhao, Wei Ai, et al.
Expert Opinion on Therapeutic Patents (2019) Vol. 29, Iss. 11, pp. 871-879
Closed Access | Times Cited: 51
Yue Dong, Tong Zhao, Wei Ai, et al.
Expert Opinion on Therapeutic Patents (2019) Vol. 29, Iss. 11, pp. 871-879
Closed Access | Times Cited: 51
What Is the Biological Function of Uric Acid? An Antioxidant for Neural Protection or a Biomarker for Cell Death
Dequan Liu, Yu Yun, Dechun Yang, et al.
Disease Markers (2019) Vol. 2019, pp. 1-9
Open Access | Times Cited: 46
Dequan Liu, Yu Yun, Dechun Yang, et al.
Disease Markers (2019) Vol. 2019, pp. 1-9
Open Access | Times Cited: 46
Perfluoroalkyl acids, hyperuricemia and gout in adults: Analyses of NHANES 2009–2014
Franco Scinicariello, Melanie C. Buser, Lina S. Balluz, et al.
Chemosphere (2020) Vol. 259, pp. 127446-127446
Open Access | Times Cited: 45
Franco Scinicariello, Melanie C. Buser, Lina S. Balluz, et al.
Chemosphere (2020) Vol. 259, pp. 127446-127446
Open Access | Times Cited: 45
A brief review of urate transporter 1 (URAT1) inhibitors for the treatment of hyperuricemia and gout: Current therapeutic options and potential applications
Danni Song, Xu Zhao, Fuqi Wang, et al.
European Journal of Pharmacology (2021) Vol. 907, pp. 174291-174291
Closed Access | Times Cited: 37
Danni Song, Xu Zhao, Fuqi Wang, et al.
European Journal of Pharmacology (2021) Vol. 907, pp. 174291-174291
Closed Access | Times Cited: 37
Identification of three distinct cell populations for urate excretion in human kidneys
Yoshihiko Sakaguchi, Pattama Wiriyasermkul, Masaya Matsubayashi, et al.
The Journal of Physiological Sciences (2024) Vol. 74, Iss. 1
Open Access | Times Cited: 5
Yoshihiko Sakaguchi, Pattama Wiriyasermkul, Masaya Matsubayashi, et al.
The Journal of Physiological Sciences (2024) Vol. 74, Iss. 1
Open Access | Times Cited: 5
Aqueous extract of Phellinus igniarius ameliorates hyperuricemia and renal injury in adenine/potassium oxonate-treated mice
Lei Wang, Yufeng Tao, Xuesong Wang, et al.
Biomedicine & Pharmacotherapy (2024) Vol. 177, pp. 116859-116859
Open Access | Times Cited: 5
Lei Wang, Yufeng Tao, Xuesong Wang, et al.
Biomedicine & Pharmacotherapy (2024) Vol. 177, pp. 116859-116859
Open Access | Times Cited: 5
