Stem cells protect the bronchial stump in rat, increasing Sox6, Col2a1, and Agc1 expression.

BACKGROUND: Post-pneumonectomy bronchopleural fistulas (BPFs) are associated with high morbidity and mortality. Currently, since the management of BPFs is difficult to assess, the best therapeutic approach is prevention. Our objective was to evaluate the effects of adipose-derived stem cells (ASCs) on the healing of the bronchial stump in an experimental animal model. METHODS: Left pneumonectomy was performed in 37 Sprague-Dawley rats. Animals were randomly assigned to a control group (n = 13), an ASC group (n = 12), and an ASC plus Tissucol(®) group (ASCT) (n = 12). The ASCs and ASCTs were locally administered at the bronchial stump after surgical pneumonectomy. Animals were killed at 10 and 20 days. We analyzed histological changes and changes in the expression of relevant genes involved in wound repair in the bronchial stump. RESULTS: Two control animals, one animal from the ASC group, and one from the ASCT group died from early BPF. All the remaining animals had an adequate postoperative outcome. ASCs and ASCTs significantly decreased the necrosis and ulcerations of the bronchial stump at 10 and 20 days. ASCs significantly decreased mRNA expression of Igf1 at 10 days and Igf1, Tgfb1, Vegfa, and Col2a1 at 20 days, whereas there was increased expression of Agc1 and Col2a1 at 10 days and Sox6 at 20 days. CONCLUSIONS: Our findings indicate that local ASCs protected the bronchial stump after pneumonectomy and induced local changes in gene expression related to their protective action. These results could lead to a potential new therapeutic modality for the prevention of BPF.

Autologous platelet-poor plasma decreases the bronchial stump necrosis in rat.

BACKGROUND: Necrosis of the bronchial stump is a very important trigger for bronchopleural fistula. The administration of local autologous platelet-poor plasma (PPP) could protect the bronchial stump. MATERIALS AND METHODS: Left pneumonectomy was performed in 25 Sprague-Dawley rats. Animals were randomly assigned to a control group (n=13) and PPP group (n=12). PPP was locally administered on the bronchial stump after pneumonectomy. We analyzed histologic changes in the bronchial stump and messenger RNA expression changes of genes involved in wound repair at 10 and 20 d. RESULTS: Local PPP treatment produced a mass of fibrous tissue surrounding the bronchial stump and significantly decreased the presence of necrosis at 20 d. PPP increased the expression of insulin like growth factor 1 at 10 d although it did not reach statistical significance. CONCLUSIONS: Our findings indicate that local PPP treatment of the bronchial stump after pneumonectomy decreased necrosis and could have a protective effect on the bronchial stump.

Searching for novel molecular targets of chronic rejection in an orthotopic experimental lung transplantation model.

BACKGROUND: Chronic rejection (CR) is the main reason for the limited survival rates among lung transplant (LT) recipients. There remains no effective treatment for CR. The aim of this study was to identify new molecular mechanisms involved in CR by using DNA microarray analysis. METHODS: We performed 10 left LTs using the microsurgical cuff technique in inbred Sprague-Dawley rats. Lung isograft samples were obtained 3 months after surgery. We analyzed histologic, apoptotic and gene expression changes by DNA microarray and quantitative PCR analysis. RESULTS: Histologic analyses confirmed signs of CR in all lungs and positive labeling for apoptotic and anti-apoptotic markers. A total of 702 genes were regulated in the CR lungs: 317 genes were upregulated and 385 were downregulated. Significant changes for about 30 biologic processes, including regulation of the cytoskeleton, and 15 signaling pathways, such as adherens junctions, were observed. We found significantly increased mRNA expression of the Cldn5, Epas1, Tgfb1, Vegf, Selp1, Hsp27 and Igf1 genes. CONCLUSIONS: This is the first experimental study performed in an orthotopic model of LT using DNA microarray analysis. The individual genes, biologic process and pathways identified may represent novel targets that could be manipulated and contribute to the development of treatments capable of providing protection from CR.