Targeting Common Inflammatory Mediators in Experimental Severe Asthma and Acute Lung Injury.

Neutrophils, known to be mobilized and activated in high amounts through Il-17 stimulation, are a key factor for clinical manifestation and imbalance of redox systems favoring a dominant oxidative state in both severe asthma and acute lung injury (f). The aim of this study was to evaluate in mice, the effect of Secukinumab (SECU) in a model of ovalbumin-induced asthma exacerbated with LPS administration to induce ALI, compared to dexamethasone (DEXA), already known for its benefit in both asthma and ALI. Results on cytokine levels for specific Th1, Th2 and Th17 revealed an interplay of immune responses. For Th1 effector cytokines in BALF, DEXA treatment increased TNF-α levels, but TNF-α was not modified by SECU; DEXA and SECU significantly decreased IFN-γ and IL-6 levels. For typical Th2 cytokines, DEXA significantly increased Il-4, Il-5 and Il-13 levels, while SECU significantly inhibited Il-5 levels. Both SECU and DEXA significantly decreased Il-17 levels. Cytokine level changes in lung tissue homogenate were partly similar to BALF cytokines. Conclusion: in addition to DEXA, SECU possesses the ability to modulate inflammatory cytokine release and to decrease Th17 responses in ALI overlapped on exacerbated asthma in mice.

A novel device and system concept for therapeutic plasma exchange in rats.

INTRODUCTION: Therapeutic plasma exchange (TPE) has been developed more than 100 years ago in an animal model and adapted to humans 30 years later. Since then, the TPE research on animal models is lacking, mainly due to difficulties raised by the scaling of the plasmapheresis unit so that the animal's cardiovascular parameters are not considerably affected. METHODS: The system concept of a novel TPE device with continuous hemodynamic monitoring in small rodent models has been used. RESULTS: A continuum TPE unit for rats has been developed, able to produce up to 95% plasma exchange rate without any TPE-related hemodynamic impairment, monitored up to 35 days after the procedure. CONCLUSION: The TPE unit for rats was able to produce 95% plasma exchange rate in non-anesthetized animals, enabling a full translation of the human TPE into an animal model. The newly developed plasmapheresis unit enable a wide range of more accurate preclinical evaluation, with cardiac parameters monitoring, using small rodents in awaken state.