Muscle growth and flesh quality of farmed Atlantic halibut (Hippoglossus hippoglossus) in relation to season of harvest

Hagen, Ørjan

January 2008

In the present study, muscle growth and flesh quality have been investigated from both commercially farmed Atlantic halibut (Hippoglossus hippoglossus) (Aga marine AS, Norway)and halibut obtained from small-scale trials at Mørkvedbukta Research Station (Bodø University College, Norway). Morphometric techniques have been utilized to investigate fast muscle growth in halibut ranging from circa 2 g to 100 kg, and it was established that fast muscle fibre recruitment ceases when the fish attain approximately 81 and 177 cm, in the case of males and females, respectively. Different muscle fibre types were distinguished using histochemical (myosin ATPase and succinic dehydrogenase) and immunohistochemical (S-58, an antibody against slow muscle myosin) staining techniques. Females recruit twice as many fast muscle fibres compared to males, which allows them to reach a larger final size. Furthermore, the seasonal growth patterns during a one year production cycle in commercial farmed halibut revealed a winter depression in growth leading to loss of biomass, which was attributed to the maturation of males. Commercial farmed fish of equal size (~1.5 kg) showed sexual dimorphism of fast muscle fibre number, caused by a significantly higher rate of fast muscle fibre recruitment in females. During the winter season fast muscle fibres shrunk significantly, especially in male fish, as a consequence of loss of appetite, low water temperatures and sexual maturation. None of the female fish matured during the trial. Flesh quality of halibut deteriorated during winter and spring, since it had a softer appearance and significantly lower myotomal protein content, particularly in males. Cathepsin activity was measured using spectroscopy and showed a strong negative correlation to protein content, displaying a seasonal variation. The proteolytic depletion of fast muscle proteins affected the water holding capacity of the muscle (determined by centrifugation), which showed concomitant changes with the increase in cathepsin activity and drop in protein content. Despite the soft appearance, the firmness (shear force) of the flesh increased during the winter. The hydroxylysyl pyridinoline cross-link content of the collagen matrix, determined by HPLC, showed a strong correlation to the fillet texture. The increased firmness during the winter, a period of little (female) or negative growth (males), was probably due to an increased cross-linking of the collagen compartment. Partial sequences of IGF-I and IGF-II were cloned from fast muscle of Atlantic halibut, and their relative gene expression levels were determined along with those of cathepsin B, cathepsin D and IGF-IRa in male halibut using qPCR during a fasting and refeeding trial. Transcript levels of cathepsin B and to some extent cathepsin D were significantly higher during fasting than refeeding, suggesting an increased enzyme production during periods of food deprivation. A temporary increase in IGF-I transcripts was observed after 7 days refeeding suggesting that this growth factor is involved in muscle growth control. Both IGF- IRa and IGF-II were down-regulated during refeeding.

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Crack propagation mechanisms in human cortical bone on different paired anatomical locations : biomechanical, tomographic and biochemical approaches / Mécanismes de propagation de fissure dans l'os cortical humain sur différentes sites appariés : approches biomécanique, tomographique et biochimique

Gauthier, Rémy

25 September 2017

Il est estimé qu'une fracture se produit toutes les trois secondes autour du monde, accompagné par un risque élevé d'invalidité ou même de mortalité. La connaissance des mécanismes de fractures dans une configuration de chargement représentatif d'une chute semble être d'un intérêt majeur pour le développement de méthodes dédiées à la prédiction du risque de fracture. La ténacité est un paramètre approprié lorsqu'on s'intéresse à ces mécanismes de fracture, elle détermine l'énergie nécessaire pour propager une fissure à travers l'architecture du tissu. L'objectif de cette étude est d'évaluer la ténacité de l'os cortical humain, considérant à la fois des conditions chargement quasi-statique et représentatif d'une chute sur sites anatomiques appariés. L'acquisition d'images en micro-tomographie ainsi qu'une mesure des cross-links ont été réalisées afin d'évaluer leur influence sur les mécanismes fracture du tissu. Les résultats ont montré que dans des conditions quasi-statiques, les différents sites anatomiques présentent des propriétés mécaniques différentes : le radius résiste mieux à une propagation de fissure. Dans des conditions de chute, il n'y a plus de différences entre ces sites, mais la ténacité décroit de façon significative par rapport au chargement standard. L'os cortical résiste mieux à une propagation de fissure dans des conditions quasi-statiques. Les analyses structurales et biochimiques ont montré des différences entre les sites anatomiques qui expliquent les différences mécaniques. Les caractéristiques architecturales du tissu sont déterminantes vis-à-vis des mécanismes de fracture dans des conditions quasi-statiques. Mais leur rôle lors d'une chute est moins évident. Ces résultats impliquent que la microstructure de l'os cortical n'est pas un déterminant majeur vis-à-vis du risque de fracture. De futures études doivent être réalisées afin de déterminer les paramètres décisifs dans des conditions représentatives d'une chute / A fracture is estimated every three seconds in the world, leading to an increased risk of impairment or even mortality. The biomechanical knowledge of bone fracture mechanisms in a fall configuration of loading is of great interests for the development of clinical method for the prediction of the risk of fracture. Toughness seems to be a good candidate to investigate this fracture process as it corresponds to the energy needed to propagate a crack through cortical bone complex microstructure. The aim of this study was thus to evaluate human cortical bone toughness parameter under both quasi-static and fall-like loading conditions paired anatomical locations. Micro-computed tomography images using synchrotron radiation and collagen cross-links maturation measurements were performed to investigate the influence of the tissue architecture on crack propagation. Results found showed that under quasi-static condition, the different anatomical locations present different mechanical behavior. Radius significantly better resist crack propagation than the other studied location. Considering a fall-like loading condition, no more difference is observed between the locations but a significant decreased is measured compare to the first configuration. Human cortical bone has a better capacity to resist crack propagation under a standard quasi-static loading condition. By investigating the tissue morphometric and biochemical parameters, we observed different organization from a location to another that explains the mechanical differences. The architectural features appear to be determinant for crack propagation mechanisms under quasi-static condition, but they play a lesser role under fall-like condition. These results imply that the tissue microstructure is not a determinant when dealing with the prediction of the risk of fracture. Further work has to be done to reach out which parameters are more determinants under a specific fall-like loading condition

Ténacité de l’os cortical humain

Chute

Sites anatomiques appariés

Architecture tridimensionnelle

Cross-links

Human cortical bone toughness

Fall-like condition

Paired anatomical locations

Three-dimensional architecture

Collagen cross-links

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