注射醋酸铅的小鼠由于参与骨吸收的程度较低,因此是向人类推断钙化反应的动物模型。

IF 3.3 3区 医学 Q2 ENDOCRINOLOGY & METABOLISM
Calcified Tissue International Pub Date : 2024-09-01 Epub Date: 2024-07-01 DOI:10.1007/s00223-024-01245-w
Shota Morikane, Koichi Ishida, Naoki Ashizawa, Tetsuya Taniguchi, Masaya Matsubayashi, Naoki Kurita, Seiichi Kobashi, Takashi Iwanaga
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引用次数: 0

摘要

血管钙化会影响肾衰竭患者的预后。由于双膦酸盐对磷酸钙聚集和骨吸收均有抑制作用,因此被视为抗钙化的候选药物。然而,在著名的啮齿类动物模型中,钙化依赖于伴随着过度骨转换的骨吸收,因此很难准确估计药物的抗钙化潜力。因此,需要用骨吸收率低的模型来推断药物对人体的抗钙化作用。我们研究了三种双膦酸盐(依替膦酸盐、阿仑膦酸盐和 FYB-931)对体内骨吸收的抑制作用,以及通过体外钙蛋白颗粒形成估算的磷酸钙聚集作用。然后,使用两种诱导异位钙化的模型对它们的作用进行了检验:向小鼠皮下注射醋酸铅的部位和移植供体大鼠的主动脉。双膦酸盐对骨吸收和磷酸钙聚集的抑制作用分别为阿仑膦酸盐 > FYB-931 > 依替膦酸盐和 FYB-931 > 阿仑膦酸盐 = 依替膦酸盐。在醋酸铅诱导的模型中,FYB-931抑制钙化的作用最强,其次是阿仑膦酸盐和依替膦酸盐。在主动脉移植模型中,只有高剂量的 FYB-931 能抑制钙化。在这两种模型中,均未观察到钙化与骨吸收标记物抗酒石酸磷酸酶(TRACP)之间的相关性。醋酸铅诱导模型的结果表明,抑制磷酸钙聚集的效力有助于抑制钙化。这两种钙化模型,尤其是醋酸铅诱导的模型,可能是将钙化反应外推至人体的理想选择,因为其机制是磷酸钙聚集而不是骨吸收。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Lead Acetate-Injected Mice is an Animal Model for Extrapolation of Calcifying Response to Humans Due to Low Involvement of Bone Resorption.

Lead Acetate-Injected Mice is an Animal Model for Extrapolation of Calcifying Response to Humans Due to Low Involvement of Bone Resorption.

Vascular calcification affects the prognosis of patients with renal failure. Bisphosphonates are regarded as candidate anti-calcifying drugs because of their inhibitory effects on both calcium-phosphate aggregation and bone resorption. However, calcification in well-known rodent models is dependent upon bone resorption accompanied by excessive bone turnover, making it difficult to estimate accurately the anti-calcifying potential of drugs. Therefore, models with low bone resorption are required to extrapolate anti-calcifying effects to humans. Three bisphosphonates (etidronate, alendronate, and FYB-931) were characterised for their inhibitory effects on bone resorption in vivo and calcium-phosphate aggregation estimated by calciprotein particle formation in vitro. Then, their effects were examined using two models inducing ectopic calcification: the site where lead acetate was subcutaneously injected into mice and the transplanted, aorta obtained from a donor rat. The inhibitory effects of bisphosphonates on bone resorption and calcium-phosphate aggregation were alendronate > FYB-931 > etidronate and FYB-931 > alendronate = etidronate, respectively. In the lead acetate-induced model, calcification was most potently suppressed by FYB-931, followed by alendronate and etidronate. In the aorta-transplanted model, only FYB-931 suppressed calcification at a high dose. In both the models, no correlation was observed between calcification and bone resorption marker, tartrate-resistant acid phosphatase (TRACP). Results from the lead acetate-induced model showed that inhibitory potency against calcium-phosphate aggregation contributed to calcification inhibition. The two calcification models, especially the lead acetate-induced model, may be ideal for the extrapolation of calcifying response to humans because of calcium-phosphate aggregation rather than bone resorption as its mechanism.

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来源期刊
Calcified Tissue International
Calcified Tissue International 医学-内分泌学与代谢
CiteScore
8.00
自引率
2.40%
发文量
112
审稿时长
4-8 weeks
期刊介绍: Calcified Tissue International and Musculoskeletal Research publishes original research and reviews concerning the structure and function of bone, and other musculoskeletal tissues in living organisms and clinical studies of musculoskeletal disease. It includes studies of cell biology, molecular biology, intracellular signalling, and physiology, as well as research into the hormones, cytokines and other mediators that influence the musculoskeletal system. The journal also publishes clinical studies of relevance to bone disease, mineral metabolism, muscle function, and musculoskeletal interactions.
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