The SLC2A9 gene was first cloned and identified in 2000, encoding the glucose transporter GLUT9, which is highly expressed in the liver and kidneys (Phay et al., 2000). In 2007, a GWAS first identified a single-nucleotide polymorphism (SNP) within SLC2A9 as strongly associated with serum uric acid levels: individuals carrying the rare rs6855911 allele exhibited significantly lower serum uric acid levels than those with the common allele (Li et al., 2007). Subsequent studies confirmed that SLC2A9 variants explain 1.7%–5.3% of serum uric acid variation in the Croatian population (Vitart et al., 2008). Further studies showed that common allele nearly doubles the risk of hyperuricemia (Wallace et al., 2008). Large-scale cohort studies in Framingham and Rotterdam further demonstrated that rs16890979 is significantly associated with serum uric acid across diverse ethnic populations (Dehghan et al., 2008). Subsequent studies in European, African American (Charles et al., 2011), Mexican American (Voruganti et al., 2013), Korean (Sull et al., 2013); American Indians (Voruganti et al., 2014), and Hispanic cohorts (Voruganti et al., 2015) consistently validated SLC2A9 as the strongest genetic locus influencing serum uric acid, with multiple intronic and missense SNPs reaching genome-wide significance. Collectively, these findings indicate that SLC2A9 is a stable genetic determinant of serum uric acid across racial populations.

Beyond genetic associations, functional studies have elucidated the biological mechanisms by which SLC2A9 regulates uric acid homeostasis: alternative splicing generates two GLUT9 isoforms—GLUT9a (540 amino acids), localized to the basolateral membrane of proximal tubules, and GLUT9b (511 amino acids), localized to the apical membrane of collecting ducts. GLUT9a mediates trans-epithelial uric acid reabsorption, while the function of GLUT9b remains incompletely defined (Mandal and Mount, 2015). In African clawed frog oocytes, GLUT9 acts as a high-capacity, low-affinity uric acid transporter whose activity is inhibited by benzbromarone (Vitart et al., 2008). GLUT9 overexpression enhances uric acid reabsorption, directly promoting hyperuricemia development; Additionally, GLUT9-mediated fructose/glucose transport promotes hepatic uric acid production by activating the pentose phosphate pathway. In renal tubules, GLUT9 also regulates lactate concentration, thereby modulating URAT1-mediated uric acid exchange; however, this mechanism exacerbates hyperuricemia during purine loading or renal ischemia (Li et al., 2007).

In summary, SLC2A9/GLUT9 maintains uric acid homeostasis through three mechanisms: GLUT9a-mediated direct reabsorption, metabolic stimulation of hepatic uric acid synthesis, and microenvironmental regulation of URAT1 activity via lactate. Variants or abnormal expression of SLC2A9 significantly alter serum uric acid levels, playing a pivotal role in the pathogenesis of hyperuricemia.

The ABCG2 gene was first identified in 1998 in the multidrug-resistant breast cancer cell line MCF-7/AdrVp. It encodes the ATP-binding cassette transporter BCRP, which mediates ATP-dependent efflux of multiple substrates, thereby contributing to multidrug resistance (Doyle et al., 1998). A 2008 GWAS highlighted that the missense variant rs2231142 (p.Q141K) in ABCG2 is strongly associated with serum uric acid levels and gout risk (Dehghan et al., 2008). Subsequent functional studies confirmed that this variant reduces BCRP-mediated uric acid efflux, thereby elevating serum uric acid concentrations (Woodward et al., 2009). Large-scale population studies consistently validated the association between rs2231142 and hyperuricemia across diverse ethnicities. Significant associations were observed in European, African, Mexican, and Native American populations (Zhang et al., 2013), and East Asian populations (Yang et al., 2018; Yamagishi et al., 2010). Notably, in East Asians, rs2231142 ranks among the strongest genetic risk loci for hyperuricemia, with particularly high prevalence in China’s southeastern coastal regions. Additionally, rs2054576 and rs2725220 have also been confirmed as associated with hyperuricemia in a Korean cohort (Son et al., 2017; Sull et al., 2014). Collectively, these findings establish ABCG2 as a core genetic determinant of hyperuricemia across populations.

Functionally, BCRP serves as a high-capacity uric acid efflux transporter expressed in the apical membranes of renal proximal tubules, intestinal epithelial cells, and hepatocytes. Under physiological conditions, it promotes ATP-dependent uric acid secretion into urine, bile, and the intestinal lumen to maintain uric acid homeostasis. Loss-of-function variants significantly reduce transport activity; for example, the p.Q141K variant decreases uric acid excretion by approximately 53% (Mandal and Mount, 2015). Impaired BCRP function in the kidney reduces tubular uric acid excretion, while decreased BCRP activity in the intestine and liver diminishes extra-renal uric acid clearance and increases renal uric acid load, collectively promoting the development of hyperuricemia.

In summary, ABCG2/BCRP is a key efflux transporter regulating systemic uric acid levels. Genetic variants such as p.Q141K significantly impair its function, constituting a major risk factor for hyperuricemia pathogenesis.

In 2002, research identified URAT1, encoded by the SLC22A12 gene, as the primary renal uric acid transporter (Enomoto et al., 2002b). URAT1 localizes to the apical membranes of renal proximal tubule cells, and mediates uric acid reabsorption via anion exchange. Its activity depends on the chloride gradient but is independent of sodium cotransport, membrane potential, and pH (Mandal and Mount, 2015). URAT1 exchanges uric acid with organic anions such as lactate and nicotinate, while pyrazino-1,2,3-tricarboxylic acid significantly enhances uric acid uptake. This physiological function also makes URAT1 an important pharmacological target. Uricosuric agents like febuxostat reduce serum uric acid levels by inhibiting URAT1, thereby decreasing reabsorption and promoting excretion. Conversely, loss-of-function mutations in SLC22A12 (e.g., p.W258X, p.T217M) cause idiopathic renal hypouricemia (Mandal and Mount, 2015).

GWAS further confirmed SLC22A12’s contribution to uric acid regulation: a large cross-ethnic GWAS (N = 457,690) identified 183 loci explaining 17% of serum uric acid heritability, with core variants in SLC2A9, ABCG2, and SLC22A12 collectively contributing approximately 5% (Tin et al., 2019). In individuals of African ancestry, genome-wide significant variants in SLC2A9 (rs7683856, rs6838021) and SLC22A12 (rs147647315) collectively explained 4.3% of serum uric acid variation. These findings establish SLC22A12 as a key uric acid transporter and an important contributor to hyperuricemia susceptibility across populations.

The PDZK1 gene encodes a scaffold protein containing a PDZ domain that regulates the activity of multiple uric acid transporters. As a binding chaperone for URAT1, PDZK1 enhances URAT1-mediated uric acid uptake (Anzai et al., 2004). It also influences ABCG2 function by regulating its expression, activity, subcellular localization, and specific signaling pathways (Chen et al., 2018). PDZK1 interacts with uric acid transporters such as URAT1, OAT4, and NPT1 to form bidirectional transport system, achieving functional coupling between different transporters (Wright et al., 2010). By organizing and regulating these transporter networks, PDZK1 plays a crucial role in uric acid homeostasis. Loss of PDZK1activity disrupts the function of multiple transporters, indirectly impairing uric acid clearance and promoting the development of hyperuricemia (Higashino et al., 2016).

The GCKR gene encodes the glucose kinase regulator protein, which modulates glucose metabolism by interacting with glucose kinase and inhibiting its activity. In 2009, a study first reported that the rs780094 polymorphism in GCKR was associated with serum uric acid levels (P = 1.46 × 10⁻⁹), with a more pronounced effect in males (Kolz et al., 2009). Subsequently, research confirmed this association in an Asian cohort, linking rs780093 and rs780094 to hyperuricemia (Wang et al., 2012). Follow-up studies identified gender-specific effects: rs1260326 and rs780094 showed stronger associations in girls than in boys (Ho et al., 2022).

Given the close relationship between glucose and purine metabolism, GCKR can indirectly influence purine metabolism and uric acid production by regulating glucose metabolism. GCKR variants are also associated with lipid metabolism, which in turn affects renal uric acid excretion. For example, the rs1260326 variant alters GCKR expression, disrupting glucose metabolism and elevating uric acid levels. Furthermore, GCKR gene variants may affect uric acid transporters such as ABCG2 and SLC2A9, thereby simultaneously influencing uric acid production and excretion (Tanikawa et al., 2019; Mandal and Mount, 2015).

The HNF4A gene (rs6031598) is primarily expressed in the liver and was first associated with serum uric acid levels (P = 2.90 × 10⁻⁸) via GWAS in 2019 (Nakatochi et al., 2019). HNF4A directly influences glucose metabolism by regulating liver function, indirectly affecting purine metabolism, and ultimately impacting uric acid production. Subsequently, it was confirmed that the p.Thr139Ile variant in HNF4A enhances transcriptional activity at the ABCG2 promoter, increasing its expression and promoting uric acid excretion (Tin et al., 2019). Recent evidence further indicates that HNF4A regulates the expression of multiple uric acid transporter genes, including SLC2A9, PDZK1, and MAF, participating in multi-pathway regulation of uric acid homeostasis. eQTL analysis and functional validation confirmed that the transcription factor encoded by HNF4A is expressed in the renal proximal tubule and regulates the expression of the uric acid transporter gene (Leask et al., 2020). These findings establish HNF4A as a key transcription factor in uric acid metabolism, regulating uric acid production and excretion.

Phellodendron bark, the dried bark of P. amurense, is a frequently used treatment for hyperuricemia and a key component in Ermiao San–related formulas. Research indicates that P. amurense inhibits hepatic XOD activity, reduces serum and hepatic uric acid levels, modulates inflammatory pathways such as PI3K/Akt, TNF, and NF-κB, decreases inflammatory mediators like IL-6, and lowers serum Cr and BUN levels, thereby improving renal pathological damage (Xu et al., 2022).

Polygonum capitatum, also known as Shimangcao, is a Polygonaceae herb widely used in Guangxi for urinary system disorders. Research indicates that P. capitatum inhibits XOD activity, reducing uric acid production; it downregulates renal URAT1 and GLUT9 expression, promoting uric acid excretion and thereby improving hyperuricemia. Concurrently, it reduces inflammatory factors such as IL-6, IL-1β, and TNF-α, alleviating joint inflammation and improving gout symptoms (Zhang C. et al., 2021).

Clerodendranthus spicatus (Lamiaceae), also known as Kidney Tea or Cat’s Whisker Herb, is used medicinally for its stems and leaves. It has a long history of use in treating gout and urinary system disorders. Research indicates that cat’s whisker herb reduces serum and hepatic XOD and PRPS activity, inhibiting uric acid production; downregulates renal URAT1 and GLUT9 expression to decrease reabsorption; upregulates OAT1 and ABCG2 to promote uric acid excretion; simultaneously lowers serum Cr and BUN levels; improves renal tubular and interstitial damage; and alleviates renal inflammation by inhibiting inflammatory pathways (Wang et al., 2024). Furthermore, cat’s whisker corrects disturbances in fatty acid, glycerophospholipid, bile acid, and purine metabolism. It increases beneficial bacteria such as Roseburia and Enterorhabdus while reducing harmful bacteria like Ileibacterium and UBA1819, thereby improving gut ecology and maintaining uric acid metabolic homeostasis (Chen et al., 2023; Zhu et al., 2023).

Plantago seed is the dried mature seed of Plantago asiatica L. and Plantago depressa Willd. (Plantaginaceae). They have a long history of use in hyperuricemia and chronic kidney disease. Studies indicate that Plantago asiatica seeds can inhibit serum XOD activity, reducing uric acid production; downregulate renal URAT1 and GLUT9 expression, decreasing uric acid reabsorption; activate the PPAR signaling pathway to improve lipid metabolism; and lower levels of inflammatory factors (Liu T. et al., 2024).

Mulberry bark is the dried root bark of Morus alba L. (Moraceae), known for its diuretic and edema-reducing effects. Its urate-lowering and renal protective mechanisms include: inhibiting hepatic XOD activity to reduce uric acid production; downregulating renal URAT1 and GLUT9 expression while upregulating ABCG2 to decrease reabsorption and promote excretion; and simultaneously suppressing renal inflammatory responses. Research has also isolated the Diels–Alder compound alkanol A, which has been identified as a mixed-type XOD inhibitor with high development potential (Wang Y. A. et al., 2025).

The aerial parts of the Asteraceae plant Cichorium glandulosum Boiss. and Huet and Cichorium intybus, commonly used as traditional medicine by the Uyghur ethnic group. Research indicates that C. intybus enhances ABCG2 expression by regulating the lncRNA H19/miR-21-3p axis, thereby reducing renal uric acid deposition, improving renal function, and alleviating inflammation. Among its components, 11β,13-dihydrocichoriin may be the key active ingredient (An et al., 2025). Furthermore, C. intybus modulates gut microbiota to elevate butyrate levels, activates the PPARγ-ABCG2 pathway to promote intestinal ABCG2 expression and enhance uric acid excretion, and upregulates the tight junction protein Claudin-1 to repair the intestinal barrier, thereby maintaining uric acid metabolic homeostasis (Yang Y. et al., 2025).

The fruit or seeds with fleshy pedicels from the Rhamnaceae plant Hovenia acerba. Research indicates that H. acerba inhibits XOD activity to reduce uric acid production; upregulates ABCG2 and OAT1 expression to promote uric acid excretion; downregulates URAT1 and GLUT9 expression to inhibit uric acid reabsorption; and modulates hyperuricemia-related inflammatory genes such as ATF3 and CXCR4. It synergistically improves hyperuricemia through multiple pathways (Wang Y. et al., 2025).

Chishao refers to the dried root of Paeonia lactiflora Pall. (Paeoniaceae). Formula data mining indicates that peony-based botanical drugs are frequently used in treating hyperuricemia. Animal and cellular studies confirm that paeonia lactiflora significantly reduces serum uric acid levels: it inhibits XOD activity to decrease uric acid production; downregulates renal URAT1 and GLUT9 while upregulating OAT1 and ABCG2, thereby reducing uric acid reabsorption and promoting excretion. Concurrently, paeonia lactiflora exhibits a favorable safety profile and provides notable protective effects on hepatic and renal tissues (Du et al., 2024).

It refers to the whole botanical drug or the seeds of Thlaspi arvense, employed in Tibetan medicine for the prevention and treatment of hyperuricemia. Research indicates that T. arvense inhibits serum XOD activity, thereby reducing uric acid production. It also modulates multiple renal uric acid transport-related genes (SLC22A12, SLC2A9, SLC22A6, ABCG2, SLC22A8, SLC12A1, SLC16A7, SLC4A4), decreasing uric acid reabsorption while increasing secretion and excretion. Additionally, Tribulus terrestris alleviates oxidative stress and inflammatory responses induced by hyperuricemia. Network pharmacology combined with UPLC-Q-TOF-MS analysis indicates its core active components primarily consist of organic acids and flavonoids (Ke et al., 2024).

The herbal drug hand-shen is derived from the dried tuber of Gymnadenia conopsea. Its ethanol extract significantly improves hyperuricemic zebrafish models, with the 95% ethanol extract achieving 84.02% inhibition of XOD. Additionally, the extract markedly reduced reactive oxygen species (ROS) and malondialdehyde (MDA) levels while increasing superoxide dismutase (SOD) activity in hyperuricemic zebrafish, thereby alleviating oxidative stress. Metabolomics studies suggest that its urate-lowering effects may be associated with flavonoids, polyphenols, alkaloids, terpenoids, and phenylpropanoids (Chen T. et al. (2022)).

Huangqi is derived from the dried root of A. mongholicus, a representative qi-tonifying Chinese herbal medicine widely used in uric acid-lowering formulations. Research indicates that A. mongholicus modulates uric acid transporters by activating the PI3K/Akt signaling pathway, downregulating URAT1 and GLUT9 while upregulating ABCG2, thereby reducing uric acid reabsorption and promoting excretion. Concurrently, it inhibits hepatic XOD activity, decreasing uric acid production and improving hyperuricemia (Zhang M. et al., 2023). Another study indicates that A. mongholicus’s uric acid-lowering efficacy is closely linked to the microbiome-metabolite axis. On one hand, it directly modulates metabolic pathways (such as linoleic acid metabolism and glycerophospholipid metabolism). While also increasing the relative abundance of beneficial bacteria (Lactobacillaceae and Lactobacillus) and decreasing the relative abundance of pathogenic bacteria (Prevotellaceae, Rikenellaceae, and Bacteroidaceae). This indirectly modulates bile acid metabolism through the microbiota, thereby improving uric acid metabolism disorders (Deng et al., 2023).

Baqia refers to the rhizome of Smilax china. Previous studies have confirmed its effective uric acid-lowering properties in hyperuricemic mouse models. Recent studies in hyperuricemic chicken models revealed that S. china inhibits XOD activity to reduce uric acid production; upregulates BCRP and MRP4 expression in kidneys and ileum to enhance uric acid excretion; and decreases the expression of inflammatory factors (IL-6, TNF-α) to mitigate renal injury (Yan et al., 2024).

Gouguye refers to the dried leaf of Ilex cornuta, possessing effects of dispelling wind-dampness and tonifying the liver and kidneys. Research indicates it exerts antihyperuricemic effects through multiple mechanisms: inhibiting hepatic XOD activity to reduce uric acid production; upregulating renal ABCG2, OAT1, and OAT3 while downregulating GLUT9 to decrease uric acid reabsorption and enhance excretion; and simultaneously suppressing NF-κB-mediated inflammatory responses to mitigate renal tubular epithelial cell apoptosis (Zhou et al., 2025).

This compound was isolated from Reynoutria japonica Houtt. (Polygonaceae). Studies indicate it reduces uric acid production via competitive inhibition of XOD (IC₅₀ = 14.35 μg/mL, Ki = 15.29 μg/mL); simultaneously downregulates inflammatory mediators such as TNF-α and IL-6 to mitigate renal injury; and aids uric acid reduction by regulating galactose and purine metabolic pathways (Hu et al., 2023).

Punicalagin (2,3-(S)-hexahydroxydiphenoyl-4,6-(S, S)-gallagyl-D-glucose) is the most abundant tannin in Punica granatum L. (Lythraceae). It promotes uric acid excretion by downregulating renal URAT1 and GLUT9 while upregulating ABCG2 and OAT1; simultaneously enhances intestinal excretion by upregulating intestinal ABCG2 and GLUT9; and regulates uric acid homeostasis through multiple pathways by inhibiting renal-intestinal inflammatory pathways, improving renal glucose metabolism disorders, and increasing beneficial bacterial abundance (Han et al., 2025).

SPFE is derived from the petals of Crocus sativus L. (Iridaceae). It inhibits hepatic XOD activity to reduce uric acid production, while upregulating renal/ileal ABCG2 and downregulating URAT1/GLUT9 to enhance uric acid excretion. It also modulates amino acid and lipid metabolic pathways, inhibits the NF-κB inflammatory pathway and oxidative stress, and improves renal pathological damage. Its core components include kaempferol and quercetin derivatives (Chen et al., 2025).

Quercetin is a natural flavonoid widely present in various Chinese herbal medicines. It downregulates renal GLUT9 to enhance uric acid excretion; inhibits inflammatory pathways and cytokine production; boosts antioxidant enzyme activity; and suppresses renal cell apoptosis and endoplasmic reticulum stress, thereby improving hyperuricemia and associated renal injury (Liu H. et al., 2025).

Glycitein is one of the major reported active components in Lycium barbarum L. (Solanaceae). It inhibits XOD activity and stabilizes XDH protein structure, thereby significantly reducing serum uric acid levels (Yang S. et al., 2025).

Linarin is a key flavonoid component in Chrysanthemum indicum L. (Asteraceae). It inhibits XOD and ADA activity to reduce uric acid production; downregulates URAT1, GLUT9, and OAT4 while upregulating ABCG2, OAT1, and OAT3 to enhance uric acid excretion. It also alleviates oxidative stress and improves hepatic, renal, and lipid metabolism (Qian et al., 2025; Jiao et al., 2024).

Puerarin is derived from Pueraria montana var. lobata (Willd.) Maesen and S.M.Almeida ex Sanjappa and Predeep (Fabaceae) and serves as its primary active component. It synergistically reduces uric acid through three mechanisms: inhibiting XOD and ADA activity to decrease uric acid production; upregulating renal and intestinal ABCG2 and renal OAT1 to enhance uric acid excretion; and strengthening intestinal tight junction protein expression, repairing the intestinal barrier, and enriching beneficial bacterial genera to improve gut microbiota (Li et al., 2025).

GLPP is an active extract component of Ganoderma lucidum (Curtis) P. Karst. (Polyporaceae). Research indicates that GLPP inhibits ADA activity, reducing the conversion of adenosine to hypoxanthine and thereby decreasing uric acid production. It also downregulates renal GLUT9 and upregulates OAT1, promoting uric acid excretion. Concurrently, it improves renal tissue ATP levels and alleviates tubular damage (Lin et al., 2022).

Dioscin is derived from the rhizomes of Dioscorea nipponica Makino (Dioscoreaceae) and is one of their primary active components. Research indicates dioscin exerts multidimensional synergistic effects in reducing uric acid levels by: reversing abnormalities in the tricarboxylic acid cycle, amino acid, and purine metabolism; corrects lipid imbalances like phospholipids and triglycerides; restores expression of energy metabolism-related genes such as Stx1b; simultaneously mitigates renal injury, downregulates inflammation-associated metabolites, and improves inflammatory states, thereby breaking the vicious cycle of “hyperuricemia–renal injury” (Tan et al., 2021). Its key metabolite, diosgenin, alleviates renal lipid accumulation by upregulating EPHX2 and modulating lipid-metabolism genes, including ACOX1, CPT1α, and PPAR-γ. It simultaneously suppresses expression of renal inflammatory factors (IL-1β, IL-6, TNF-α) and promotes uric acid excretion (Dang et al., 2024).

WW-60%-1 is a saponin fraction isolated from the roots of Clematis chinensis Osbeck (Ranunculaceae), serving as the primary molecular basis for its urate-lowering effects. Research indicates WW-60%-1 modulates urate homeostasis through multi-target synergistic actions: it inhibits hepatic XOD activity to reduce uric acid production; downregulates URAT1 and GLUT9 while upregulating ABCG2, OAT1, and OAT3 to enhance uric acid excretion; suppresses NF-κB/PI3K-Akt pathways to reduce inflammation; alleviates oxidative stress and improves renal-intestinal histopathological damage. Concurrently, NFKB1 has been identified as a pivotal hub gene in its network, regulating multidimensional processes including inflammatory modulation and transport (Liu S. et al., 2025).

TGPF is derived from the floral parts of the herbaceous peony, Paeonia lactiflora Pall. (Paeoniaceae). Studies indicate that TGPF dose-dependently reduces serum uric acid and XOD levels in model rats; downregulates the inflammatory factors TNF-α and MCP-1, along with renal injury markers Cr and BUN; and improves weight loss and pathological damage in the kidney, thymus, and spleen. Its core mechanism involves regulating the renal uric acid transport system: downregulating reabsorption transporters URAT1 and GLUT9 while upregulating excretion transporter OAT1, thereby reducing uric acid reabsorption and promoting excretion (Kang et al., 2020).

Berberine is the primary alkaloid in P. amurense Rupr. (Rutaceae). Molecular docking studies indicate that berberine exhibits strong affinity for URAT1, downregulating renal URAT1 protein and mRNA expression to inhibit uric acid reabsorption; simultaneously inhibits NLRP3 inflammasome activation, reduces pro-inflammatory factor levels, decreases serum BUN and CRE levels, and improves renal injury (Li et al., 2021).

9-Hydroxy-8-oxypalmatine is an oxidative metabolite of palmatine, the primary alkaloid in P. amurense. Studies indicate that it inhibits serum and hepatic XOD and ADA activity, reducing uric acid production; downregulates renal URAT1 and GLUT9 while upregulating OAT1 to regulate uric acid transport; and simultaneously suppresses the NLRP3 inflammasome and downstream inflammatory factors, thereby significantly lowering serum uric acid levels (Wu et al., 2024).

Geniposide is the primary active component in the fruit of Gardenia jasminoides J. Ellis (Rubiaceae) and serves as the precursor for its derivatives (geniposide derivatives). Research indicates that geniposide derivatives inhibit XOD activity to reduce uric acid production; downregulate abnormally activated renal uric acid reabsorption pathways to decrease uric acid accumulation; and suppress inflammatory responses by modulating the TLR4/IκBα/NF-κB signaling axis, thereby improving renal tissue damage and promoting uric acid excretion (Chen J. et al. (2022)).

Polygonati rhizome polysaccharide is a key bioactive component of Polygonatum sibiricum Delar. ex Redouté (Asparagaceae). It inhibits XOD and ADA activity and gene expression, thereby reducing uric acid production. Concurrently, it downregulates renal URAT1 expression while upregulating OAT1 and OAT3 expression to enhance uric acid excretion. It also promotes mitochondrial biogenesis, alleviates ROS accumulation and apoptosis in HK-2 cells, thereby exerting renal protective effects (Zhang et al., 2024).

CSO is derived from C. lacryma-jobi L. var. ma-yuen (Poaceae), obtained through enzymatic hydrolysis and column chromatography purification. Its main component is glucose oligosaccharides with a degree of polymerization of 2–9 (96.5% content). CSO inhibits XOD to reduce uric acid production; downregulates URAT1 and GLUT9 while upregulating ABCG2 and OAT1 to enhance uric acid excretion; suppresses inflammatory responses; improves renal inflammation and lipid metabolism; and increases beneficial gut microbiota abundance. These actions synergistically improve uric acid homeostasis through multiple pathways (Wu et al., 2025).