# Tannic acid supplementation exerts biphasic effects on growth performance, immune function, and gut microbiota in Pekin duck

**Authors:** Xue-qian Jiang, Ze-cheng Zou, Ye-lin Zeng, Hao-tian Yuan, Xin Feng, Yong-sheng Wang

PMC · DOI: 10.1016/j.psj.2026.106754 · 2026-03-09

## TL;DR

Tannic acid at low doses improves duck growth, immunity, and gut health, but high doses cause negative effects.

## Contribution

This study reveals the biphasic effects of tannic acid on Pekin ducks and identifies optimal dosage ranges.

## Key findings

- Low-to-moderate tannic acid levels (0.1–0.35%) improved antioxidant capacity and immune function in ducks.
- High tannic acid (0.5%) reduced feed efficiency and caused gut microbiota dysbiosis.
- Tannic acid altered gut microbiota, reducing harmful bacteria and increasing beneficial taxa at low doses.

## Abstract

Tannins, which are polyphenols present in several plant species, have been shown to exert several beneficial effects in livestock at specific levels. However, the optimal dosage for growth promotion in waterfowl like Pekin ducks remains unclear. Therefore, this study aimed to investigate the effects of dietary tannic acid (TA) supplementation on the performance of Pekin ducks. A total of 420 male Pekin ducks were assigned to to five groups and fed a basal diet supplemented with 0, 0.1, 0.2, 0.35, or 0.5% TA (control, TAS0.1, TAS0.2, TAS0.35, and TAS0.5, respectively). Growth performance, serum biochemical, oxidative parameters, immune parameters, and cecal microbiota were analyzed. Low-to-moderate TA levels (0.1–0.35%) increased the pancreatic index (P < 0.05) and enhanced systemic antioxidant capacity, as evidenced by elevated activities of glutathione peroxidase, catalase, and total antioxidant capacity. Notably,0.1% TA supplementation increased serum immunoglobulin (IgA, IgG, IgM) and complement (C3, C4) levels compared to the control (P< 0.05). Conversely, dietary supplementation with 0.5% TA significantly compromised feed efficiency, increasing the feed conversion ratio by 14.6% during the initial 14-day period (P < 0.01). ​​​Importantly, TA intervention induced a dose-responsive restructuring of the cecal microbiota, characterized by a significant decrease in the relative abundance of Proteobacteria (P< 0.05), a marked reduction in the potentially pathogenic genus Desulfovibrio (from 6.24% to 0.17–2.14%, P< 0.01), and a selective enrichment of beneficial taxa, including Succinispira andRuminococcus. Functional predictions indicated enhanced xenobiotic metabolism in the low-dose groups but stress-related dysregulation in the TAS0.5 group. Collectively, these results demonstrate that TA exhibits dose-dependent biphasic effects. Optimal inclusion levels (0.1–0.35%) enhance antioxidant capacity, immune function, and gut microbial symbiosis, whereas excessive supplementation (0.5%) induces metabolic dysregulation and microbiota dysbiosis. Overall, this study established a theoretical framework for strategically optimizing TA supplementation in poultry production systems to reconcile productivity and health outcomes.

## Linked entities

- **Chemicals:** tannic acid (PubChem CID 16129778)

## Full-text entities

- **Genes:** ALB [NCBI Gene 101802920], Glutathione S-Transferase [NCBI Gene 101798048], CAT [NCBI Gene 101803207]
- **Diseases:** inflammatory (MESH:D007249), cholestasis (MESH:D002779), appetite suppression (MESH:D001068), hypertrophy (MESH:D006984), hyperphagia (MESH:D006963), hepatocellular injury (MESH:D056486), CP (MESH:D011488), metabolic dysregulation (MESH:D021081)
- **Chemicals:** butyrate (MESH:D002087), saline (MESH:D012965), nitrogen (MESH:D009584), nucleotide (MESH:D009711), Cu (MESH:D003300), phosphorus (MESH:D010758), vitamin B6 (MESH:D025101), water (MESH:D014867), short-chain fatty acids (MESH:D005232), polyphenols (MESH:D059808), carbohydrate (MESH:D002241), nicotinic acid (MESH:D009525), vitamin B12 (MESH:D014805), Choline chloride (MESH:D002794), d-pantothenic acid (MESH:D010205), amino acid (MESH:D000596), GSH (MESH:D005978), folic acid (MESH:D005492), lysine (MESH:D008239), indoles (MESH:D007211), vitamin B1 (MESH:D013831), vitamin E (MESH:D014810), lipid (MESH:D008055), essential amino acids (MESH:D000601), glycan (MESH:D011134), vitamin K3 (MESH:D024483), tryptophan (MESH:D014364), biotin (MESH:D001710), silver (MESH:D012834), Zn (MESH:D015032), SDS (MESH:D012967), Fe (MESH:D007501), TA (MESH:D013634), vitamin A (MESH:D014801), acid (MESH:D000143), polyketide (MESH:D061065), SYBR Green (MESH:C098022), methionine (MESH:D008715), threonine (MESH:D013912), MDA (MESH:D008315), terpenoid (MESH:D013729), CTAB (MESH:D000077286), CP (-), agarose (MESH:D012685), vitamin B2 (MESH:D012256), sulfate (MESH:D013431), Calcium (MESH:D002118), Mn (MESH:D008345), vitamin D3 (MESH:D002762), hydrogen sulfide (MESH:D006862), I (MESH:D007455)
- **Species:** Desulfovibrionales (order) [taxon 213115], Succinispira mobilis (species) [taxon 78120], Anas platyrhynchos (duck, species) [taxon 8839], Bifidobacterium (genus) [taxon 1678], Capra hircus (domestic goat, species) [taxon 9925], Desulfovibrio (genus) [taxon 872], Butyricicoccus (genus) [taxon 580596], Homo sapiens (human, species) [taxon 9606], Faecalibacterium (genus) [taxon 216851], Glycine max (soybean, species) [taxon 3847], Ruminococcus (genus) [taxon 1263], gut metagenome (species) [taxon 749906], Succinispira (genus) [taxon 78119]

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC13018930/full.md

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Source: https://tomesphere.com/paper/PMC13018930