High fructose feeding has been suggested to involve in several features of metabolic syndrome including hyperuricemia (HP). We designed and implemented a study to determine the effect size of fructose intake and the relative risk of HP based on the type of fructose feeding (diet or solution), duration of treatment (2–6, 7–10, and > 10 weeks), and animal race. The required information was accepted from international databases, including PubMed/MEDLINE, Science Direct, Scopus, and etc., from 2009 until 2019 on the basis of predetermined eligibility criteria. The data selection and extraction and quality assessment were performed independently by two researchers. Results were pooled as random effects weighting and reported as standardized mean differences with 95% confidence intervals. Thirty-five studies including 244 rats with fructose consumption were included in the final analysis. The heterogeneity rate of parameters was high (I2 = 81.3%, p < 0.001) and estimated based on; 1) type of fructose feeding (diet; I2 = 79.3%, solution 10%; I2 = 83.4%, solution 20%; I2 = 81.3%), 2) duration of treatment (2–6 weeks; I2 = 86.8%, 7–10 weeks; I2 = 76.3%, and > 10 weeks; I2 = 82.8%), 3) the animal race (Wistar; I2 = 78.6%, Sprague-Dawley; I2 = 83.9%). Overall, the pooled estimate for the all parameters was significant (p < 0.001). The results of this study indicated that a significant relationship between HP and fructose intake regardless of the treatment duration, animal race, fructose concentration and route of consumption.

Citations

Citations to this article as recorded by  

• Fructose-induced hyperuricaemia – protection factor or oxidative stress promoter?
  Amelia Tero-Vescan, Ruxandra Ștefănescu, Tudor-Ionuț Istrate, Amalia Pușcaș
  Natural Product Research.2025; 39(4): 948.     CrossRef
• Rosmarinic acid attenuates hyperuricemia via restoring hyperuricemia-induced renal and intestinal dysfunctions
  Liyang Jia, Boyu Sun, Anzheng Nie, Yamin Shi, Zheng Zhou, Chunsheng Zhu
  Phytomedicine.2025; 145: 157084.     CrossRef
• Facteurs de risque alimentaires et médicamenteux de goutte
  G. Chalès, G. Coiffier, F. Robin
  EMC - Appareil locomoteur.2025; 39(4): 1.     CrossRef
• A Comprehensive Review on Targeting Hyperuricemia with Edible Bioactive Polysaccharides: Advances in Structure, Xanthine Oxidase inhibition, Uric acid-Lowering Strategies, Mechanisms, and Current Applications
  Zain Ullah, Zihao Yan, Min Zhang, Peng Liu, Panpan Yue, Ting Zhao, Liuqing Yang, Guangying Chen
  Food Reviews International.2025; : 1.     CrossRef
• Elevated uric acid level and metabolic syndrome in Non-Hispanic Black American adults
  Ike S. Okosun
  Journal of Diabetes & Metabolic Disorders.2024;[Epub]     CrossRef
• Dietary pattern and risk of hyperuricemia: an updated systematic review and meta-analysis of observational studies
  Zhao-Yan Wen, Yi-Fan Wei, Ye-Huan Sun, Wen-Ping Ji
  Frontiers in Nutrition.2024;[Epub]     CrossRef
• Effects of ∆-9 tetrahydrocannabinol on the small intestine altered by high fructose diet: A Histopathological study
  Basak Isildar, Alisa Bahar Beydogan, Ece Koyuturk, Zeynep Mine Coskun Yazici, Meral Koyuturk, Sema Bolkent
  Histochemistry and Cell Biology.2024; 162(5): 363.     CrossRef
• Probiotics, bioactive compounds and dietary patterns for the effective management of hyperuricemia: a review
  Lei Sun, Caixin Ni, Jianxin Zhao, Gang Wang, Wei Chen
  Critical Reviews in Food Science and Nutrition.2024; 64(7): 2016.     CrossRef
• Hyperuricemia and its related diseases: mechanisms and advances in therapy
  Lin Du, Yao Zong, Haorui Li, Qiyue Wang, Lei Xie, Bo Yang, Yidan Pang, Changqing Zhang, Zhigang Zhong, Junjie Gao
  Signal Transduction and Targeted Therapy.2024;[Epub]     CrossRef
• Omega-3 Effects on Ligature-Induced Periodontitis in Rats with Fructose-Induced Metabolic Syndrome
  Maysa O. A. Oliveira, Álvaro R. Leonço, Vinícius B. Pavani, Isadora R. Barbosa, Maria M. Campos
  Inflammation.2023; 46(1): 388.     CrossRef
• The chemistry, processing, and preclinical anti-hyperuricemia potential of tea: a comprehensive review
  Yu Chen, Liyong Luo, Shanshan Hu, Renyou Gan, Liang Zeng
  Critical Reviews in Food Science and Nutrition.2023; 63(24): 7065.     CrossRef
• Inclusive Overview of Sweeteners Trends: Nutritional Safety and Commercialization
  Saba Anwar, Qamar Abbas Syed, Faiza Munawar, Mehwish Arshad, Waheed Ahmad, Muhammad Adil Rehman, Muhammad Kamran Arshad
  ACS Food Science & Technology.2023; 3(2): 245.     CrossRef
• Dietary patterns and risk for hyperuricemia in the general population: Results from the TCLSIH cohort study
  Tingjing Zhang, Sabina Rayamajhi, Ge Meng, Qing Zhang, Li Liu, Hongmei Wu, Yeqing Gu, Yawen Wang, Shunming Zhang, Xuena Wang, Juanjuan Zhang, Huiping Li, Amrish Thapa, Shaomei Sun, Xing Wang, Ming Zhou, Qiyu Jia, Kun Song, Kaijun Niu
  Nutrition.2022; 93: 111501.     CrossRef
• Are the levels of uric acid associated with biometeorological conditions?
  Jerzy Romaszko, Ewa Dragańska, Iwona Cymes, Marek Drozdowski, Leszek Gromadziński, Katarzyna Glińska-Lewczuk
  Science of The Total Environment.2022; 819: 152020.     CrossRef
• Comparing the Effects of Febuxostat and Allopurinol in an Animal Model of Metabolic Syndrome
  Eman H. Nadwa, George N.B. Morcos, Nagwan M. Salama, Amani N. Shafik
  Pharmacology.2021; 106(9-10): 564.     CrossRef
• Fructose and metabolic diseases: too much to be good
  Ya-Nan Shi, Ya-Jin Liu, Zhifang Xie, Weiping J. Zhang
  Chinese Medical Journal.2021; 134(11): 1276.     CrossRef
• The Role of ABCG2 in the Pathogenesis of Primary Hyperuricemia and Gout—An Update
  Robert Eckenstaler, Ralf A. Benndorf
  International Journal of Molecular Sciences.2021; 22(13): 6678.     CrossRef
• Recent advances in fructose intake and risk of hyperuricemia
  Congwang Zhang, Lijun Li, Yipeng Zhang, Changchun Zeng
  Biomedicine & Pharmacotherapy.2020; 131: 110795.     CrossRef