FN Archimer Export Format PT J TI Investigation of marine bivalve morphology by in vivo MR imaging: first anatomical results of a promising technique BT AF POUVREAU, Stephane RAMBEAU, Marc COCHARD, Jean-Claude ROBERT, Rene AS 1:1;2:2;3:1;4:1; FF 1:PDG-DOP-DCB-PFOM-PI;2:;3:PDG-DOP-DCOP-AQUAPOL;4:PDG-DOP-DCB-PFOM-PI; C1 IFREMER, Dept Marine Anim Ecophysiol & Physiol, Argenton Expt Lab, F-29840 Argenton En Landunvez, France. South Hosp, Dept Radiol & Biomed Imaging, F-35203 Rennes 2, France. C2 IFREMER, FRANCE SOUTH HOSP, FRANCE SI ARGENTON TAHITI SE PDG-DOP-DCB-PFOM-PI PDG-DOP-DCOP-AQUAPOL IN WOS Ifremer jusqu'en 2018 copubli-france IF 2.081 TC 25 UR https://archimer.ifremer.fr/doc/2006/publication-1819.pdf LA English DT Article DE ;In vivo physiology;Aquaculture;Anatomy;MRI;Pacific oyster AB Classically, investigation of the internal morphology and composition of molluscs and especially bivalves relies on destructive method (biometry, biochemistry and histology). These techniques have given essential information, but in contrast are time consuming and lead to the irreversible loss of the animal while they don't allow integration of the various levels of molecular-to-organism functioning. The aim of this study is to analyze for the first time the potential of NMR (nuclear magnetic resonance) imaging (MRI) to depict, with sufficient resolution and satisfactory contrast, the anatomy of a bivalve model, the Pacific oyster, Crassostrea gigas, without opening it. MRI experiments were carried out at 19 °C in several non-anaesthetized adult Pacific oysters, analyzed individually in a standard General Electric Signa 1.5T (whole body) instrument with actively shielded gradient coils (23 mT/m). To enhance signal detection, the oyster was centered in the middle of a 12-cm diameter Helmholtz-like radio-frequency coil (medical wrist coil). After several trials, the best MRI acquisition sequence retained was a T1-weighted procedure (spoiled gradient echo sequence) through two orthogonal directions (transversal and sagittal sections). According to direction, MR parameters were as follows: TR = 200¿400 ms, TE = 4¿5 ms, FOV = 120 × 90 mm, matrix = 512 × 256 units, 6 signal averages per echo, spatial resolution = 230 μm, total scan time = 3¿6 min. The MR images obtained have satisfactory contrast-to-noise levels, and depict with a sufficient resolution all the main organs in the soft tissues of the oyster. Comparison with histology-based anatomical information shows that the MR images faithfully represent some detailed anatomical structures of Pacific oysters. Potential applications in shellfish aquaculture are reported, and perspectives are given which constitute starting point from furthers studies PY 2006 PD SEP SO Aquaculture SN 0044-8486 PU Elsevier VL 259 IS 1-4 UT 000240559500044 BP 415 EP 423 DI 10.1016/j.aquaculture.2006.05.018 ID 1819 ER EF