Boshuizen Berit, De Maré Lorie, Oosterlinck Maarten, Van Immerseel Filip, Eeckhaut Venessa, De Meeus Constance, Devisscher Lindsey, Vidal Moreno de Vega Carmen, Willems Maarten, De Oliveira Jean Eduardo, Hosotani Guilherme, Gansemans Yannick, Meese Tim, Van Nieuwerburgh Filip, Deforce Dieter, Vanderperren Katrien, Verdegaal Elisabeth-Lidwien, Delesalle Cathérine
Department of Translational Physiology, Infectiology and Public Health, Research Group of Comparative Physiology, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium.
Equine Hospital Wolvega, Oldeholtpade, Netherlands.
Front Physiol. 2025 Apr 10;16:1565005. doi: 10.3389/fphys.2025.1565005. eCollection 2025.
Aleurone, derived from the bran layer of grains like wheat and barley, has demonstrated positive effects on energy metabolism in pigs, mice, and untrained horses, influencing glucose-insulin dynamics and gut microbiome composition. Training itself enhances insulin sensitivity in horses, similar to the improvements in performance capacity observed in human athletes. This study aimed to investigate whether aleurone supplementation provides additional benefits to training by modulating insulin metabolism and gut microbiota in Standardbred mares.
Sixteen Standardbred mares (aged 3-5 years) participated in a cross-over study with two 8-week training periods separated by 8 weeks of detraining. Each horse received either 200 g/day aleurone supplementation or a control diet. Insulin metabolism was evaluated using oral (OGTT) and intravenous (FSIGTT) glucose tolerance tests, measuring parameters such as Maximum, AUC, Maximum, AUC, Time to peak (OGTT), Acute Insulin Response to Glucose (AIRg), glucose effectiveness (Sg), and disposition index (DI) (FSIGTT). Fecal samples underwent metagenomic analysis to assess alpha and beta diversity and microbial composition.
Training alone: Training significantly improved OGTT parameters by decreasing Maximum ( = 0.005) and AUC ( = 0.001), while increasing Time to peak ( = 0.03), indicating enhanced insulin sensitivity. FSIGTT results also showed a decrease in logAIRg ( = 0.044). Training with Aleurone: Aleurone supplementation further reduced FSIGTT AIRg ( = 0.030), logAIRg ( = 0.021) while increasing glucose effectiveness (Sg; = 0.031). These findings suggest aleurone improves insulin sensitivity, glucose disposal, and fasting glucose regulation beyond training. Microbiome analysis revealed training decreased , associated with dysbiosis, while aleurone reduced inflammation-associated . Beta diversity metrics showed no significant changes.
Aleurone supplementation enhances training-induced improvements in glucose metabolism and fecal microbiota composition, which could offer potential benefits for equine athletes by optimizing metabolic flexibility. It also supports improvements in glucose and insulin dynamics, particularly by further enhancing insulin sensitivity and glucose-mediated disposal. Future studies should investigate the mechanisms of aleurone at the muscle and gut level and explore its potential applications for metabolic disorders such as Equine Metabolic Syndrome.
糊粉层源自小麦和大麦等谷物的麸皮层,已证明对猪、小鼠和未经训练的马匹的能量代谢具有积极影响,可影响葡萄糖 - 胰岛素动态变化及肠道微生物群组成。训练本身可增强马匹的胰岛素敏感性,类似于人类运动员运动能力的提升。本研究旨在调查补充糊粉层是否能通过调节标准赛马母马的胰岛素代谢和肠道微生物群为训练带来额外益处。
16匹3至5岁的标准赛马母马参与了一项交叉研究,包括两个为期8周的训练期,中间间隔8周的停训期。每匹马每天要么补充200克糊粉层,要么采用对照饮食。使用口服(OGTT)和静脉(FSIGTT)葡萄糖耐量试验评估胰岛素代谢,测量诸如最大值、AUC、最大值、AUC、达到峰值的时间(OGTT)、对葡萄糖的急性胰岛素反应(AIRg)、葡萄糖效能(Sg)和处置指数(DI)(FSIGTT)等参数。对粪便样本进行宏基因组分析,以评估α和β多样性及微生物组成。
单独训练:训练通过降低最大值( = 0.005)和AUC( = 0.001),同时增加达到峰值的时间( = 0.03),显著改善了OGTT参数,表明胰岛素敏感性增强。FSIGTT结果还显示logAIRg降低( = 0.044)。糊粉层与训练结合:补充糊粉层进一步降低了FSIGTT的AIRg( = 0.030)、logAIRg( = 0.021),同时提高了葡萄糖效能(Sg; = 0.031)。这些发现表明,糊粉层在训练之外还能改善胰岛素敏感性、葡萄糖处置和空腹血糖调节。微生物组分析显示,训练降低了 ,与生态失调相关,而糊粉层减少了与炎症相关的 。β多样性指标无显著变化。
补充糊粉层可增强训练对葡萄糖代谢和粪便微生物群组成的改善作用,通过优化代谢灵活性为赛马运动员带来潜在益处。它还支持改善葡萄糖和胰岛素动态变化,特别是通过进一步增强胰岛素敏感性和葡萄糖介导的处置。未来的研究应在肌肉和肠道水平研究糊粉层的作用机制,并探索其在诸如马代谢综合征等代谢紊乱中的潜在应用。
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