Intestinal in vitro transport assay combined with physiologically based kinetic modeling as a tool to predict bile acid levels in vivo.

IF 4.5 2区 医学 Q2 MEDICINE, RESEARCH & EXPERIMENTAL
Altex-Alternatives To Animal Experimentation Pub Date : 2024-01-09 Epub Date: 2023-07-27 DOI:10.14573/altex.2302011
Véronique M P De Bruijn, Willem Te Kronnie, Ivonne M C M Rietjens, Hans Bouwmeester
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引用次数: 0

Abstract

Bile acid homeostasis is vital for numerous metabolic and immune functions in humans. The enterohepatic circulation of bile acids is extremely efficient, with ~95% of intestinal bile acids being reabsorbed. Disturbing intestinal bile acid uptake is expected to substantially affect intestinal and systemic bile acid levels. Here, we aimed to predict the effects of apical sodium-dependent bile acid transporter (ASBT)-inhibition on systemic plasma levels. For this, we combined in vitro Caco-2 cell transport assays with physiologically based (PBK) modeling. We used the selective ASBT-inhibitor odevixibat (ODE) as a model compound. Caco-2 cells grown on culture inserts were used to obtain transport kinetic parameters of glycocholic acid (GCA). The apparent Michaelis-Menten constant (Km,app), apparent maximal intestinal transport rate (Vmax,app), and ODE’s inhibitory constant (Ki) were determined for GCA. These kinetic parameters were incorporated into a PBK model and used to predict the ASBT inhibition effects on plasma bile acid levels. GCA is transported over Caco-2 cells in an active and sodium-dependent manner, indicating the presence of functional ASBT. ODE inhibited GCA transport dose-dependently. The PBK model predicted that oral doses of ODE reduced conjugated bile acid levels in plasma. Our simulations match in vivo data and provide a first proof-of-principle for the incorporation of active intestinal bile acid uptake in a bile acid PBK model. This approach could in future be of use to predict the effects of other ASBT-inhibitors on plasma and intestinal bile acid levels.

将肠道体外转运试验与基于生理学的动力学模型相结合,作为预测体内胆汁酸水平的工具。
胆汁酸平衡对人体的多种代谢和免疫功能至关重要。胆汁酸的肠肝循环效率极高,约 95% 的肠道胆汁酸被重吸收。如果肠道胆汁酸摄取受到干扰,预计将对肠道和全身胆汁酸水平产生重大影响。在此,我们旨在预测顶端钠依赖性胆汁酸转运体(ASBT)抑制对全身血浆水平的影响。为此,我们将体外 Caco-2 细胞转运试验与生理学建模(PBK)相结合。在这项原理验证研究中,我们使用了选择性 ASBT 抑制剂奥德维西巴特(ODE)作为模型化合物。在培养插片上生长的 Caco-2 细胞被用来获得甘氨胆酸(GCA)的转运动力学参数。测定了 GCA 的表观 Michaelis Menten 常数(Km,app)、表观最大肠道转运率(Vmax,app)和 ODE 的抑制常数(Ki)。这些动力学参数被纳入 PBK 模型,并用于预测 ASBT 对血浆胆汁酸水平的抑制作用。GCA 在 Caco-2 细胞上的转运具有活性且依赖钠,这表明存在功能性 ASBT。ODE 对 GCA 转运的抑制是剂量依赖性的。根据 PBK 模型预测,口服剂量的 ODE 会降低血浆中的共轭胆汁酸水平。我们的模拟结果与体内数据相吻合,首次证明了胆汁酸 PBK 模型中的肠道胆汁酸摄取活性。这种方法将来可用于预测其他 ASBT 抑制剂对血浆和肠道胆汁酸水平的影响。
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来源期刊
Altex-Alternatives To Animal Experimentation
Altex-Alternatives To Animal Experimentation MEDICINE, RESEARCH & EXPERIMENTAL-
CiteScore
7.70
自引率
8.90%
发文量
89
审稿时长
2 months
期刊介绍: ALTEX publishes original articles, short communications, reviews, as well as news and comments and meeting reports. Manuscripts submitted to ALTEX are evaluated by two expert reviewers. The evaluation takes into account the scientific merit of a manuscript and its contribution to animal welfare and the 3R principle.
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