Etude sanitaire de la zone 17.48 de Fouras. Charente-Maritime

Suite à la demande d’exploitation de la zone de Fouras, n°17.48 par le Comité Régional de la Conchyliculture du Poitou-Charentes (CRCPC), la Direction Départementale des Territoires et de la Mer (DDTM) a demandé la réalisation d’une étude sanitaire en vue du classement de la zone de production de coquillages pour les bivalves fouisseurs (groupe 2). Cette étude réalisée par le Laboratoire Environnement Ressources des Pertuis Charentais (LER/PC) bénéficie d’un financement de la Direction Générale de l 'Alimentation (DGAL). Basée sur les paramètres microbiologiques (Escherichia coli) et chimiques (plomb, mercure, cadmium), l’étude sanitaire a pour objectifs d'estimer la qualité microbiologique et chimique de la zone en vue du classement sanitaire de la zone par l'administration conformément aux exigences du Règlement CE n° 854/2004 ; et de déterminer la stratégie d'échantillonnage à mettre en oeuvre dans le cadre de la surveillance sanitaire régulière de cette zone suite à son classement. L’étude des informations disponibles a permis l’identification de sources de contamination potentielle et la définition d’une stratégie d’échantillonnage. Deux points de suivis ont été positionnés dans les secteurs jugés sensibles aux sources de contamination et ont été échantillonnés du 29 juillet 2011 au 4 octobre 2012. Les concentrations maximales en cadmium, mercure et plomb sont inférieures aux critères chimiques réglementaires et sont compatibles avec un classement A, B ou C. Le suivi microbiologique réalisé indique une qualité B pour chacun des deux points de suivi. La qualité de la zone semble donc homogène, et est estimée B dans son ensemble. Le point « Les Ecussons » est le plus sensible aux contaminations microbiologiques, la surveillance régulière REMI de la zone du Fier d’Ars pour le groupe 2 sera donc basée sur ce point.

X-ray velocimetry within the ex vivo carotid artery

X-ray velocimetry offers a non-invasive method by which blood flow, blood velocity and wall shear stress can be measured in arteries prone to atherosclerosis. Analytical tools for measuring haemodynamics in artificial arteries have previously been developed and here the first quantification of haemodynamics using X-ray velocimetry in a living mammalian artery under physiologically relevant conditions is demonstrated. Whole blood seeded with a clinically used ultrasound contrast agent was pumped with a steady flow through live carotid arterial tissue from a rat, which was kept alive in a physiological salt solution. Pharmacological agents were then used to produce vascular relaxation. Velocity measurements were acquired with a spatial resolution of 14 µm × 14 µm and at a rate of 5000 acquisitions per second. Subtle velocity changes that occur are readily measurable, demonstrating the ability of X-ray velocimetry to sensitively and accurately measure haemodynamics ex vivo. Future applications and possible limitations of the technique are discussed, which allows for detailed living tissue investigations to be carried out for various disease models, including atherosclerosis and diabetic vasculopathy.

Functional imaging to understand biomechanics : a critical tool for the study of biology, pathology and the development of pharmacological solutions

We present four case studies of the literature discussing the effects of physical forces on biological function. While the field of biomechanics has existed for many decades, it may be considered by some a poor cousin to biochemistry and other traditional fields of medical research. In these case studies, including cardiovascular and respiratory systems, we demonstrate that, in fact, many systems historically believed to be controlled by biochemistry are dominated by biomechanics. We discuss both the previous paradigms that have advanced research in these fields and the changing paradigms that will define the progressions of these fields for decades to come. In the case of biomechanical effects of flowing blood on the endothelium, this has been well understood for decades. In the cases of platelet activation and liquid clearance from the lungs during birth, these discoveries are far more recent and perhaps not as universally accepted. While only a few specific examples are examined here, it is clear that not enough attention is paid to the possible mechanical links to biological function. The continued development of these research areas, with the inclusion of physical effects, will hopefully provide new insight into disease development, progression, diagnosis and effective therapies.