@article{Hinzpeter_Shene_Masson_2006, title={Biotechnological alternatives for omega-3 polyunsaturated fatty acids production}, volume={57}, url={https://grasasyaceites.revistas.csic.es/index.php/grasasyaceites/article/view/57}, DOI={10.3989/gya.2006.v57.i3.57}, abstractNote={<font face="Helvetica" size="1"><p align="left">Fish oils are the main sources of omega-3 (<font face="Symbol" size="1">ω</font><font face="Helvetica" size="1">3) polyunsaturated acids (PUFA) such as eicosapentaenoic (C20:5</font><font face="Symbol" size="1">ω</font><font face="Helvetica" size="1">3) and docosahexaenoic (C22:6</font><font face="Symbol" size="1">ω</font><font face="Helvetica" size="1">3) acids. World demand for </font><font face="Symbol" size="1">ω</font><font face="Helvetica" size="1">3 PUFA shows an increasing trend mainly due to the growth of the aquaculture industry and also due to the increasing demand for specific PUFA used as food supplements. Bacteria, fungi, microalgae and thraustochytrids are biotechnological PUFA alternatives to fish oils. These sources are characterized by specific PUFA profiles whose productivity depends on strain and growth conditions. PUFA content in bacteria is low; microalgae synthesize mixtures of PUFA; fungi system productivity is low due to long  <font face="Helvetica" size="1">fermentation times. In heterotrofic cultures of thraustochytrids high concentrations of PUFA can be obtained. Moreover, many strains are able to synthesize a single </font><font face="Symbol" size="1">ω</font><font face="Helvetica" size="1">3 PUFA. The optimization of fermentation systems and the development of technology capable of large-scale production are needed in order to make these alternatives feasible.</font></font></p></font>}, number={3}, journal={Grasas y Aceites}, author={Hinzpeter, I. and Shene, C. and Masson, L.}, year={2006}, month={Sep.}, pages={336–342} }