Your search keyword '"Acute respiratory distress syndrome model"' showing total 3 results

1. Impact of time intervals on drug efficacy and phenotypic outcomes in acute respiratory distress syndrome in mice

Author

Sarah Paris-Robidas, Isabelle Bolduc, Vanessa Lapointe, Julia Galimi, Philippe Lemieux, Carole-Ann Huppé, and Frédéric Couture

Subjects

Acute respiratory distress syndrome model, Acute lung injury, Myeloperoxidase, Dexamethasone, Murine model, Plethysmography, Medicine, Science

Abstract

Abstract Acute respiratory distress syndrome is a severe lung condition resulting from various causes, with life-threatening consequences that necessitate intensive care. The phenomenon can be modeled in preclinical models, notably through the use of lipopolysaccharide (LPS) instillation in mice. The phenotype induced closely recapitulates the human syndrome, including pulmonary edema, leukocyte infiltration, acute inflammation, impaired pulmonary function, and histological damage. However, the experimental designs using LPS instillations are extremely diverse in the literature. This highly complicates the interpretation of the induced phenotype chronology for future study design and hinders the proper identification of the optimal time frame to assess different readouts. Therefore, the definition of the treatment window in relation to the beginning of the disease onset also presents a significant challenge to address questions or test compound efficacy. In this context, the temporality of the different readouts usually measured in the model was evaluated in both normal and neutrophil-depleted male C57bl/6 mice using LPS-induction to assess the best window for proper readout evaluation with an optimal dynamic response range. Ventilation parameters were evaluated by whole-body plethysmography and neutrophil recruitment were evaluated in bronchoalveolar lavage fluids and in lung tissues directly. Imaging evaluation of myeloperoxidase along with activity in lung lysates and fluids were compared, along with inflammatory cytokines and lung extravasation by enzyme-linked immunoassays. Moreover, dexamethasone, the gold standard positive control in this model, was also administered at different times before and after phenotype induction to assess how kinetics affected each parameter. Overall, our data demonstrate that each readout evaluated in this study has a singular kinetic and highlights the key importance of the timing between ARDS phenotype and treatment administration and/or analysis. These findings also strongly suggest that analyzes, both in-life and post-mortem should be conducted at multiple time points to properly capture the dynamic phenotype of the LPS-ARDS model and response to treatment.

Published

2024

2. Impact of time intervals on drug efficacy and phenotypic outcomes in acute respiratory distress syndrome in mice

Author

Paris-Robidas, Sarah, Bolduc, Isabelle, Lapointe, Vanessa, Galimi, Julia, Lemieux, Philippe, Huppé, Carole-Ann, and Couture, Frédéric

Published

2024

3. Escherichia coli lipopolysaccharide induces alveolar epithelial cell stiffening.

Author

Oliveira, Vinícius Rosa, Uriarte, Juan José, Falcones, Bryan, Zin, Walter Araujo, Navajas, Daniel, Farré, Ramon, and Almendros, Isaac

Subjects

*LIPOPOLYSACCHARIDES, *EPITHELIAL cells, *BIOMECHANICS, *STRESS fibers (Cytology), *YOUNG'S modulus

Abstract

Abstract Introduction Application of lipopolysaccharide (LPS) is a widely employed model to mimic acute respiratory distress syndrome (ARDS). Available data regarding LPS-induced biomechanical changes on pulmonary epithelial cells are limited only to P. aeruginosa LPS. Considering that LPS from different bacteria could promote a specific mechanical response in epithelial cells, we aim to assess the effect of E. coli LPS, widely employed as a model of ARDS, in the biomechanics of alveolar epithelial cells. Methods Young's modulus (E) of alveolar epithelial cells (A549) was measured by atomic force microscopy every 5 min throughout 60 min of experiment after treatment with LPS from E. coli (100 μg/mL). The percentage of cells presenting actin stress fibers (F-actin staining) was also evaluated. Control cells were treated with culture medium and the values obtained were compared with LPS-treated cells for each time-point. Results Application of LPS induced significant increase in E after 20 min (77%) till 60 min (104%) in comparison to controls. Increase in lung epithelial cell stiffness induced by LPS was associated with a higher number of cells presenting cytoskeletal remodeling. Conclusions The observed effects of E. coli LPS on alveolar epithelial cells suggest that this widely-used LPS is able to promote a quick formation of actin stress fibers and stiffening cells, thereby facilitating the disruption of the pulmonary epithelial barrier. [ABSTRACT FROM AUTHOR]

Published

2019