25 research outputs found

    Estimating front-wave velocity of infectious diseases: a simple, efficient method applied to bluetongue

    Get PDF
    Understanding the spatial dynamics of an infectious disease is critical when attempting to predict where and how fast the disease will spread. We illustrate an approach using a trend-surface analysis (TSA) model combined with a spatial error simultaneous autoregressive model (SARerr model) to estimate the speed of diffusion of bluetongue (BT), an infectious disease of ruminants caused by bluetongue virus (BTV) and transmitted by Culicoides. In a first step to gain further insight into the spatial transmission characteristics of BTV serotype 8, we used 2007-2008 clinical case reports in France and TSA modelling to identify the major directions and speed of disease diffusion. We accounted for spatial autocorrelation by combining TSA with a SARerr model, which led to a trend SARerr model. Overall, BT spread from north-eastern to south-western France. The average trend SARerr-estimated velocity across the country was 5.6 km/day. However, velocities differed between areas and time periods, varying between 2.1 and 9.3 km/day. For more than 83% of the contaminated municipalities, the trend SARerr-estimated velocity was less than 7 km/day. Our study was a first step in describing the diffusion process for BT in France. To our knowledge, it is the first to show that BT spread in France was primarily local and consistent with the active flight of Culicoides and local movements of farm animals. Models such as the trend SARerr models are powerful tools to provide information on direction and speed of disease diffusion when the only data available are date and location of cases

    Rôles des cardiofibroblastes dans la protection des cardiomyocytes au cours de l'ischémie-reperfusion

    No full text
    Roles of cardiac fibroblasts (CF) in the regulation of myocardial structure and function have been emphasized in the last decade. Their implications in pathophysiological aspects of chronic heart diseases such as myocardial remodelling and fibrosis is now well established. However their contribution to the acute phase of ischemia reperfusion injury still remains elusive. We hypothesized that CF may contribute to cardiomyocytes (CM) protection against ischemia reperfusion (l/R) injuries. This study was designed to investigate this protection and identify some of its mechanisms. Experiments were performed both on isolated neonatal rat CF and CM in vitro and in vivo mice model of myocardial infarction. We demonstrated that the presence of CF increases CM viability in co-cultures and that CF protect CM against l/R injuries in a paracrine manner. lt was confirmed by a similar effect of hypoxic CF secretome alone on CM viability. These findings were corroborated by in vivo experiments in which an infarct size reduction was observed in CF secretome treated mice. Furthermore, experiments with Tissue lnhibitor of Metalloproteinases-1 (TlMP-1), abundantly detected in CF secretome, was able to both decrease CM cell death and infarct size. Experiments with pharmacological inhibitors provided more evidence that this paracrine protection is partly mediated by Pl3K/Akt and ERK signalling pathways. Our data demonstrated for the first time that CF participate in cardioprotection during the acute phase of ischemia reperfusion, via a paracrine pathway, involving TlMP-1. Besides this first work, other collaborative studies have been performed, to investigate a major target in cardioprotection research : the mitochondrial permeability transition pore and its regulation by chain respiratory complex l and Ca2+ transfers and finally its implication in multiple organ failure in cardiac arrestLes cardiofibroblastes (CF) possèdent des rôles clés dans la régulation de la structure et du fonctionnement myocardique. Leurs implications physiopathologiques, notamment dans le remodelage et la fibrose, ont été largement décrites dans les maladies cardiovasculaires chroniques. Cependant, leurs rôles au cours de la phase aigüe d'ischémie-reperfusion (l/R) restent encore à élucider. Nous avons donc émis l'hypothèse que les CF pouvaient participer à la protection des cardiomyocytes (CM) face aux lésions d'l/R. Le but de ce travail a donc consisté en l'exploration et l'identification des mécanismes de cette protection. Un modèle cellulaire de CM et CF de rats nouveau-nés in vitro et un modèle d'l/R in vivo chez la souris ont été utilisés. Nos résultats montrent que la présence des CF, en co-culture avec les CM, augmente de façon paracrine leur viabilité, face aux lésions d'l/R. Cette action paracrine a été confirmée par l'utilisation du sécrétome de CF hypoxiques capable, à lui seul, d'augmenter la viabilité des CM. Ces résultats ont été corroborés par des expériences d'l/R in vivo, dans lesquelles les souris traitées avec le sécrétome de CF présentent une diminution de la taille d'infarctus. De plus, nous avons montré que TlMP-1, un facteur fortement détecté dans le sécrétome de CF, est capable de diminuer à la fois la mortalité cellulaire in vitro des CM et la taille de l'infarctus in vivo. L'utilisation d'inhibiteurs pharmacologiques nous a permis de mettre en évidence que cette protection paracrine était médiée en partie par l'activation des voies de signalisation Pl3K/Akt et ERK1/2. En conclusion cette étude démontre pour la première fois que les CF participent, de façon paracrine, à la protection des CM au cours la phase aigüe d'ischémie reperfusion. TlMP-1 semble être un des facteurs clé de cette cardioprotection par les CF. En parallèle de ce travail, plusieurs études collaboratives ont été réalisées, sur une cible majeure d'investigation dans la cardioprotection : le pore de transition de perméabilité mitochondriale et notamment sa régulation par le complexe l de la chaîne respiratoire et les échanges calciques, ainsi que son implication dans la défaillance multi-organe face à l'arrêt cardiaqu

    Role of cardiac fibroblasts in cardiomyocyte protection during ischemia reperfusion

    No full text
    Les cardiofibroblastes (CF) possèdent des rôles clés dans la régulation de la structure et du fonctionnement myocardique. Leurs implications physiopathologiques, notamment dans le remodelage et la fibrose, ont été largement décrites dans les maladies cardiovasculaires chroniques. Cependant, leurs rôles au cours de la phase aigüe d'ischémie-reperfusion (l/R) restent encore à élucider. Nous avons donc émis l'hypothèse que les CF pouvaient participer à la protection des cardiomyocytes (CM) face aux lésions d'l/R. Le but de ce travail a donc consisté en l'exploration et l'identification des mécanismes de cette protection. Un modèle cellulaire de CM et CF de rats nouveau-nés in vitro et un modèle d'l/R in vivo chez la souris ont été utilisés. Nos résultats montrent que la présence des CF, en co-culture avec les CM, augmente de façon paracrine leur viabilité, face aux lésions d'l/R. Cette action paracrine a été confirmée par l'utilisation du sécrétome de CF hypoxiques capable, à lui seul, d'augmenter la viabilité des CM. Ces résultats ont été corroborés par des expériences d'l/R in vivo, dans lesquelles les souris traitées avec le sécrétome de CF présentent une diminution de la taille d'infarctus. De plus, nous avons montré que TlMP-1, un facteur fortement détecté dans le sécrétome de CF, est capable de diminuer à la fois la mortalité cellulaire in vitro des CM et la taille de l'infarctus in vivo. L'utilisation d'inhibiteurs pharmacologiques nous a permis de mettre en évidence que cette protection paracrine était médiée en partie par l'activation des voies de signalisation Pl3K/Akt et ERK1/2. En conclusion cette étude démontre pour la première fois que les CF participent, de façon paracrine, à la protection des CM au cours la phase aigüe d'ischémie reperfusion. TlMP-1 semble être un des facteurs clé de cette cardioprotection par les CF. En parallèle de ce travail, plusieurs études collaboratives ont été réalisées, sur une cible majeure d'investigation dans la cardioprotection : le pore de transition de perméabilité mitochondriale et notamment sa régulation par le complexe l de la chaîne respiratoire et les échanges calciques, ainsi que son implication dans la défaillance multi-organe face à l'arrêt cardiaqueRoles of cardiac fibroblasts (CF) in the regulation of myocardial structure and function have been emphasized in the last decade. Their implications in pathophysiological aspects of chronic heart diseases such as myocardial remodelling and fibrosis is now well established. However their contribution to the acute phase of ischemia reperfusion injury still remains elusive. We hypothesized that CF may contribute to cardiomyocytes (CM) protection against ischemia reperfusion (l/R) injuries. This study was designed to investigate this protection and identify some of its mechanisms. Experiments were performed both on isolated neonatal rat CF and CM in vitro and in vivo mice model of myocardial infarction. We demonstrated that the presence of CF increases CM viability in co-cultures and that CF protect CM against l/R injuries in a paracrine manner. lt was confirmed by a similar effect of hypoxic CF secretome alone on CM viability. These findings were corroborated by in vivo experiments in which an infarct size reduction was observed in CF secretome treated mice. Furthermore, experiments with Tissue lnhibitor of Metalloproteinases-1 (TlMP-1), abundantly detected in CF secretome, was able to both decrease CM cell death and infarct size. Experiments with pharmacological inhibitors provided more evidence that this paracrine protection is partly mediated by Pl3K/Akt and ERK signalling pathways. Our data demonstrated for the first time that CF participate in cardioprotection during the acute phase of ischemia reperfusion, via a paracrine pathway, involving TlMP-1. Besides this first work, other collaborative studies have been performed, to investigate a major target in cardioprotection research : the mitochondrial permeability transition pore and its regulation by chain respiratory complex l and Ca2+ transfers and finally its implication in multiple organ failure in cardiac arres

    Why did bluetongue spread the way it did? Environmental factors influencing the velocity of bluetongue virus serotype 8 epizootic wave in France.

    Get PDF
    International audienceUnderstanding where and how fast an infectious disease will spread during an epidemic is critical for its control. However, the task is a challenging one as numerous factors may interact and drive the spread of a disease, specifically when vector-borne diseases are involved. We advocate the use of simultaneous autoregressive models to identify environmental features that significantly impact the velocity of disease spread. We illustrate this approach by exploring several environmental factors influencing the velocity of bluetongue (BT) spread in France during the 2007-2008 epizootic wave to determine which ones were the most important drivers. We used velocities of BT spread estimated in 4,495 municipalities and tested sixteen covariates defining five thematic groups of related variables: elevation, meteorological-related variables, landscape-related variables, host availability, and vaccination. We found that ecological factors associated with vector abundance and activity (elevation and meteorological-related variables), as well as with host availability, were important drivers of the spread of the disease. Specifically, the disease spread more slowly in areas with high elevation and when heavy rainfall associated with extreme temperature events occurred one or two months prior to the first clinical case. Moreover, the density of dairy cattle was correlated negatively with the velocity of BT spread. These findings add substantially to our understanding of BT spread in a temperate climate. Finally, the approach presented in this paper can be used with other infectious diseases, and provides a powerful tool to identify environmental features driving the velocity of disease spread

    Cyclophilin D modulates the cardiac mitochondrial target of isoflurane, sevoflurane, and desflurane

    No full text
    Background: Volatile anesthetics are known to limit myocardial ischemia-reperfusion injuries. Mitochondria were shown to be major contributors to cardioprotection. Cyclophilin D (CypD) is one of the main regulators of mitochondria-induced cell death. We compared the effect of isoflurane, sevoflurane, and desflurane in the presence or absence of CypD, to clarify its role in the mechanism of cardioprotection induced by these anesthetics.Methods: Oxidative phosphorylation, mitochondrial membrane potential, and H2O2 production were measured in isolated mitochondria from wild-type (WT) or CypD knockout mice in basal conditions and after hypoxia-reoxygenation in the presence or absence of volatile anesthetics.Results: All volatile anesthetics inhibited mitochondrial state 3 of complex I, decreased membrane potential, and increased adenosine diphosphate consumption duration in both WT and CypD knockout mice. However, they differently modified H2O2 production after stimulation by succinate: CypD ablation reduced H2O2 production, isoflurane decreased H2O2 level in WT but not in CypD knockout mice, sevoflurane affected both lines whereas desflurane increased H2O2 production in CypD knockout and had no effect on WT mice.Conclusions: This study showed different effects of isoflurane, sevoflurane, and desflurane on mitochondrial functions and highlighted the implication of CypD in the regulation of adenosine diphosphate consumption and complex I-induced radical oxygen species production
    corecore