Unilateral Bleomycin-induced Interstitial Pneumonitis Mouse Model With Both a Healthy and a Diseased Lung.

IF 1.8 4区医学 Q3 MEDICINE, RESEARCH & EXPERIMENTAL

In vivo Pub Date : 2025-01-01 DOI:10.21873/invivo.13823

Hiroshi Kodama, Haruyuki Takaki, Yutaka Hirata, Eisuke Ueshima, Yasushi Kimura, Reona Wada, Keigo Osuga, Koichiro Yamakado

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引用次数: 0

Abstract

Background/aim: A standard mouse model of pulmonary fibrosis has been created by intratracheal or intraperitoneal administration of bleomycin. However, a difficulty presented by this traditional method is its high mortality rate of more than 50% after bleomycin administration. In this study, we aimed to establish a unilateral lung disease model and to assess its feasibility and usefulness.

Materials and methods: After 6-week-old C57BL/6 mice were anesthetized, a 1.7Fr microcatheter was advanced into the trachea using an otoscope. Then, 1.0 mg/kg of bleomycin was injected into bilateral lung at the trachea (n=13) or unilateral lung (n=14) after advancing the microcatheter to the left main bronchus under fluoroscopy. Body weight change and survival of bilateral and unilateral lung disease group mice at day 28 were compared using Mann-Whitney and log-rank tests. Lungs were extracted and evaluated using Masson trichrome staining.

Results: Body weights decreased 75.7%±14.0% in the bilateral lung disease group, but were greater, 94.1%±11.4%, in the unilateral lung disease group (p=0.03). Overall survival rates at day 28 were 30.8% and 85.7% in the bilateral and unilateral lung disease groups, respectively. Survival was significantly better in the unilateral lung disease model (p=0.01). Histological evaluation confirmed collagen deposition only in the bleomycin injected lung in the unilateral lung disease model.

Conclusion: Establishing both a healthy and a diseased lung in the same individual model was feasible, achieving lessened body weight loss and more favorable survival. This technique allows for a more efficacious research design, where both the efficacy and adverse effects of a pharmaceutical agent can be evaluated in a single animal.

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单侧博莱霉素诱导的间质性肺炎小鼠健康肺和病变肺模型。

背景/目的：通过气管内或腹腔内给药博来霉素建立了肺纤维化标准小鼠模型。然而，这种传统方法存在一个困难，即博莱霉素给药后死亡率高达50%以上。在本研究中，我们旨在建立一个单侧肺部疾病模型，并评估其可行性和实用性。材料与方法：6周龄C57BL/6小鼠麻醉后，经耳镜将1.7Fr微导管置入气管内。然后在透视下将微导管推进至左主支气管，经气管或单侧肺分别注射1.0 mg/kg博来霉素。采用Mann-Whitney检验和log-rank检验比较双侧和单侧肺部疾病组小鼠第28天的体重变化和存活率。取肺，用马松三色染色评价。结果：双侧肺疾病组体重下降75.7%±14.0%，单侧肺疾病组体重下降94.1%±11.4% （p=0.03）。双侧和单侧肺部疾病组28天的总生存率分别为30.8%和85.7%。单侧肺疾病模型生存率明显提高（p=0.01）。组织学评价证实胶原沉积仅在单侧肺部疾病模型中注射博来霉素的肺中。结论：在同一个体模型中建立健康肺和病变肺是可行的，可以减轻体重损失，提高生存率。这项技术允许更有效的研究设计，其中药物制剂的功效和副作用都可以在单个动物中进行评估。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

In vivo 医学-医学：研究与实验

CiteScore

4.20

自引率

4.30%

发文量

330

审稿时长

3-8 weeks

期刊介绍： IN VIVO is an international peer-reviewed journal designed to bring together original high quality works and reviews on experimental and clinical biomedical research within the frames of physiology, pathology and disease management. The topics of IN VIVO include: 1. Experimental development and application of new diagnostic and therapeutic procedures; 2. Pharmacological and toxicological evaluation of new drugs, drug combinations and drug delivery systems; 3. Clinical trials; 4. Development and characterization of models of biomedical research; 5. Cancer diagnosis and treatment; 6. Immunotherapy and vaccines; 7. Radiotherapy, Imaging; 8. Tissue engineering, Regenerative medicine; 9. Carcinogenesis.