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Chronic obstructive pulmonary disease ( COPD ) major chronic disease threatening public health with complex pathological mechanisms. The change of the cell microenvironment of the lung is an important part of the pathophysiology of COPD. Cell culture technology is an important method to investigate the pathological mechanism of COPD and evaluate the pharmacological effect of medicine. Here we introduce the composition of the cell microenvironment of the lung, the change of the cell microenvironment in the pathological process of COPD, and summarize the application of in vitro model mimics cell microenvironment of COPD in the study of mechanism. In addition, we aim to put forward the ideas of the in vitro model establishment of cell microenvironment of COPD.
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Aim To explore the air-liquid interface(ALI)culture conditions of Calu-3 cells and their tolerance to exposure to clean air in the exposure system. Methods Calu-3 cells were cultured in three stages:flask expansion,liquid-liquid culture until full Transwell membrane covered,and ALI culture,and the cell barrier status was determined by cell trans-epithelium electrical resistant(TEER)measurement and expression of tight junction protein ZO-1; Calu-3 cells were exposed to clean air using the air-liquid interface exposure system for 1,2,3,4,5,6 hours,and cells cultured in incubators were used as controls to detect changes in Calu-3 cell activity and TEER after exposure,and to determine the single maximum exposure time of Calu-3 cells in the in vitro exposure system based on ALI culture. Results Calu-3 cells were cultured in liquid-liquid culture for 8±1 days to grow full Transwell membranes and barrier formation,and then were transferred to ALI culture. The barrier was intact and in a stable state for 1 to 18 days of ALI culture,and could be used for exposure experiments. The activity of Calu-3 cells decreased significantly after 6 hours of clean air exposure(P<0.01),and TEER decreased significantly after 4,5,and 6 hours of clean air exposure(P<0.05,P<0.01,P<0.01). Conclusions Calu-3 cells cultured for 1 to 18 days in ALI can be used for air-liquid interface exposure experiments; the combined changes in cell activity and TEER suggest that the maximum single exposure time for Calu-3 cells exposed to clean air in the exposure system is 3 hours.
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BACKGROUND: The information on nasal transport and the metabolism of peptides have been obtained from pharmacokinetic investigations in experimental animals. However, there are no transport and metabolic studies of human nasal epithelial cells. In this study, the permeability characteristics and the metabolic properties of in vitro human nasal cell monolayers were investigated. Material and METHODS: Normal human inferior nasal conchal tissue samples were obtained from patients undergoing endoscopic nasal cavitary surgery. The specimens were cultured in a transwell using an air-liquid interface (ALI) culture, and the transepithelial electrical resistance (TEER) value of the blank filter and confluent cell monolayers were measured. To determine the % leakage of mannitol, 4µmol 14C-labelled mannitol was added and the % leakage was measured every 10 minute for 1 hour. RESULT: Human nasal epithelial cells in the primary culture grew to a confluent monolayer within 7 days and expressed microvilli. The tight junction between the cells was confirmed by transmission electron microscopy. The TEER value of the blank filter, fifth day and seventh day reached 108.5 ohm.cm2, 141 ohm.cm2 and 177.5 ohm.cm2, respectively. Transcellular % leakage of the 14C-mannitol at 10, 20, 30, 40, 50 and 60 minutes was 35.67±5.43, 34.42±5.60, 32.75±5.71, 31.76±4.22, 30.96±3.49 and 29.60±3.68 %, respectively. CONCLUSION: The human nasal epithelial monolayer using ALI using techniques is suitable for a transcellular permeability study. The data suggests that human nasal epithelial cells in as ALI culture technique shows some promise for a nasal transport and metabolism study.