ABSTRACT
Mechanical ventilation (MV) with large tidal volumes can increase lung alveolar permeability and initiate inflammatory responses,resulting in ventilator-induced lung injury (VILI).The mechanisms of the injurious effects of MV and the genetic susceptibility remain unclear.VILI-related genes such as cysteine-rich angiogenic inducer 61 (Cyr61)have been demonstrated to play a detrimental role in the aggressive ventilation strategies.In the present study,we investigated the involvement of Cyr61 in the VIM and the underlying mechanism.A549 cells were exposed to cyclic stretch of varying durations and then the mRNA and protein levels of Cyr61 were measured by real-time PCR and Western blotting,respectively.Additionally,after exposure ofA549 cells to cyclic stretch for 5 min to 1 h,the expression levels of nuclear factor kappaB (NF-κB) and IL-8 were detected by ELISA and Western blotting.Thereafter,Cyr61 expression was depressed in A549 cells with the siRNA pGenesill.1-Cyr61-3 before the cyclic stretch,and IL-8 secretion and the activation of NF-κB pathways were probed by ELISA and Western blotting,respectively.Moreover,a NF-κB inhibitor (PDTC) and an activator (TNF) were used before mechanical stretch.Realtime PCR and ELISA were performed to detect the mRNA and protein of IL-8,respectively.The results showed that the mechanical cyclic stretch led to increased Cyr61 expression at mRNA and protein levels in A549 cells.Additionally,cyclic stretch also mobilized NF-κB from the cytoplasm to the nucleus and increased IL-8 secretion in A549 cells.The inhibition of Cyr61 blocked the NF-κB activation and IL-8 secretion in response to cyclic stretch.Inhibition of NF-κB attenuated the mRNA and protein expression of IL-8 in A549 cells transfected with Cyr61 siRNA.It was suggested that Cyr61/NF-κB signaling pathway mediates the upregulation of IL-8 in response to cyclic stretch in A594 cells.These findings support the hypothesis that Cyr61 plays a critical role in acute lung inflammation triggered by mechanical strain.
ABSTRACT
Mechanical ventilation (MV) with large tidal volumes can increase lung alveolar permeability and initiate inflammatory responses,resulting in ventilator-induced lung injury (VILI).The mechanisms of the injurious effects of MV and the genetic susceptibility remain unclear.VILI-related genes such as cysteine-rich angiogenic inducer 61 (Cyr61)have been demonstrated to play a detrimental role in the aggressive ventilation strategies.In the present study,we investigated the involvement of Cyr61 in the VIM and the underlying mechanism.A549 cells were exposed to cyclic stretch of varying durations and then the mRNA and protein levels of Cyr61 were measured by real-time PCR and Western blotting,respectively.Additionally,after exposure ofA549 cells to cyclic stretch for 5 min to 1 h,the expression levels of nuclear factor kappaB (NF-κB) and IL-8 were detected by ELISA and Western blotting.Thereafter,Cyr61 expression was depressed in A549 cells with the siRNA pGenesill.1-Cyr61-3 before the cyclic stretch,and IL-8 secretion and the activation of NF-κB pathways were probed by ELISA and Western blotting,respectively.Moreover,a NF-κB inhibitor (PDTC) and an activator (TNF) were used before mechanical stretch.Realtime PCR and ELISA were performed to detect the mRNA and protein of IL-8,respectively.The results showed that the mechanical cyclic stretch led to increased Cyr61 expression at mRNA and protein levels in A549 cells.Additionally,cyclic stretch also mobilized NF-κB from the cytoplasm to the nucleus and increased IL-8 secretion in A549 cells.The inhibition of Cyr61 blocked the NF-κB activation and IL-8 secretion in response to cyclic stretch.Inhibition of NF-κB attenuated the mRNA and protein expression of IL-8 in A549 cells transfected with Cyr61 siRNA.It was suggested that Cyr61/NF-κB signaling pathway mediates the upregulation of IL-8 in response to cyclic stretch in A594 cells.These findings support the hypothesis that Cyr61 plays a critical role in acute lung inflammation triggered by mechanical strain.
ABSTRACT
Há tempo sabe-se que o omento humano pode promover atividade angiogênica em estruturas adjacentes nas quais ele é aplicado. Na medicina veterinária, são poucas as pesquisas com retalho pediculado de omento maior como indutor angiogênico e imunogênico, porém suas propriedades de adesão e drenagem são bem conhecidas. Os objetivos deste estudo foram criar um retalho pediculado de omento maior, mensurar seu comprimento durante as etapas de criação e avaliar a possibilidade de alcance para ossos longos (fêmur, tíbia, úmero, rádio e ulna) através de túnel subcutâneo, visando a utilizá-lo futuramente como indutor angiogênico em focos de fratura, para aceleração da osteogênese e controle de infecções ósseas. Foram utilizados 30 cadáveres frescos de cães de todas as raças, com exceção dos condrodistróficos. Os resultados foram conclusivos e confirmaram a possibilidade de alcance do retalho de omento para ossos longos de cadáveres de cães em que todos os retalhos alcançaram a metáfise distal dos ossos avaliados. A média de comprimento do omento, em camada dupla, dos 30 animais avaliados foi de 30,87cm; da camada simples foi de 54,37cm e do retalho em L foi de 92,7cm. Com a extensão máxima do omento, foi possível alcançar as metáfises distais de todos os ossos propostos, com comprimento médio excedente de 29,87cm para fêmur, 20,73cm para tíbia/fíbula, 25,13cm para úmero e 16,27cm para rádio/ulna. As variáveis peso e retalho em L avaliadas estatisticamente de cada indivíduo apresentaram correlação positiva moderada. Concluiu-se que, em cadáveres de cães, é possível levar o retalho pediculado de omento maior através de túnel subcutâneo para metáfise distal de ossos longos e que, quanto maior o peso do animal, maior o comprimento do retalho em L.
It's known for long time hat the human omento can promote angiogenic activity in adjacent structures in which it is applied. In veterinary medicine, there is little research with greater omentum flap as angiogenic and immunogenic inductor, however, their adhesion properties and drainage are well known. This study wondered whether if the greater omentum can be used as angiogenic inductor in bone fractures, and therefore increase osteogenenic rates and decreasing bone infection. Initially it was designed an experimental study which aimed to obtain a greater omentum pedicle flap and conduct it so long as possible through a subcutaneous defect in order to reach long bones (femur, tibia, humerus, radius/ulna). For the experiment it was used 30 dogs cadavers of all breeds, except condrosdistrophics breeds. The results were conclusive and confirmed the possibility of reaching the omentum flap for long bones. All the animals had reached the distal half of the evaluated bones. Results were satisfactorily accomplished and in 100 percent of the cases the flap reached the distal half of the evaluated bones. The averages of the different flap length were: 30.87cm when double layer was used; 54.37cm in simple layer; and 92.7cm when the flap was built in L. The maximum length of the omentum has secured the possibility of reaching the distal metaphases of all the bones studied. The average length exceeded 29.87cm to femur, 20.73cm to tibia/fibula, 25.13cm to humerus, and 16.27cm to radius/ulna. The flap length variety statistically evaluated showed moderate positive correlation on the presented individuals. It was concluded that the omentum pedicle flap can be taken through the subcutaneous defect until the distal metaphase of the long bones of dogs cadavers without tension. Animals with high corporal weight have the biggest L flap length.