Objective: To explore the feasibility of the full automatic animal experimental cabin to establish the animal models in normobaric/hypobarie hypoxic and high carbon dioxide environment. Methods: 60 SPF-class male SD...Objective: To explore the feasibility of the full automatic animal experimental cabin to establish the animal models in normobaric/hypobarie hypoxic and high carbon dioxide environment. Methods: 60 SPF-class male SD rats were divided into two groups, 20 for normobaric, hypoxie conditions and the other 40 for hypobarie, hypoxic conditions. For each group, we examined the pulmonary arterial pressure and carotid arterial pressure indicators of rats by using the physiological muhi-detector measurement, and observed the pulmonary vascular changes in the structure. Results: The normobaric/hypobarie hypoxic with high carbon dioxide environment can promote the formation of pulmonary hypertension and accelerate changes in pulmonary vascular remodeling, and promote the right ventricular hypertrophy. Conclusion: Clinical applications showed that the animal experimental cabin has observed and controlled accurately. The result was safe, reliable and reproducible. The cabin can successfully establish the pulmonary hypertension model in normobaric/hypobaric hypoxie with high carbon dioxide enviromnent, and in order to study the physiological mechanism of a variety of circulation and respiratory diseases caused by lack of oxygen, which provided an experimental technology platform tor clinical research.展开更多
文摘Objective: To explore the feasibility of the full automatic animal experimental cabin to establish the animal models in normobaric/hypobarie hypoxic and high carbon dioxide environment. Methods: 60 SPF-class male SD rats were divided into two groups, 20 for normobaric, hypoxie conditions and the other 40 for hypobarie, hypoxic conditions. For each group, we examined the pulmonary arterial pressure and carotid arterial pressure indicators of rats by using the physiological muhi-detector measurement, and observed the pulmonary vascular changes in the structure. Results: The normobaric/hypobarie hypoxic with high carbon dioxide environment can promote the formation of pulmonary hypertension and accelerate changes in pulmonary vascular remodeling, and promote the right ventricular hypertrophy. Conclusion: Clinical applications showed that the animal experimental cabin has observed and controlled accurately. The result was safe, reliable and reproducible. The cabin can successfully establish the pulmonary hypertension model in normobaric/hypobaric hypoxie with high carbon dioxide enviromnent, and in order to study the physiological mechanism of a variety of circulation and respiratory diseases caused by lack of oxygen, which provided an experimental technology platform tor clinical research.
