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Impact of ultrafiltration and nanofiltration of an industrial fish protein hydrolysate on its bioactive properties
Authors:Laurent Picot  Rozenn Ravallec  Martine Fouchereau‐Péron  Laurent Vandanjon  Pascal Jaouen  Maryse Chaplain‐Derouiniot  Fabienne Guérard  Aurélie Chabeaud  Yves LeGal  Oscar Martinez Alvarez  Jean‐Pascal Bergé  Jean‐Marie Piot  Irineu Batista  Carla Pires  Gudjon Thorkelsson  Charles Delannoy  Greta Jakobsen  Inez Johansson  Patrick Bourseau
Affiliation:1. UMR CNRS 6250 LIENSs, Université de La Rochelle, La Rochelle, France;2. ProBioGEM, UPRES EA‐1026, IUT A‐Polytech'Lille, USTL, Lille, France;3. UMR BOREA (Biologie des Organismes et Ecosystèmes Aquatiques), MNHN/CNRS 7208/IRD 207/UPMC, Station de Biologie Marine, Concarneau, France;4. UMR CNRS 6144 GEPEA, Université de Nantes, Saint‐Nazaire, France;5. LIMATB, Université de Bretagne Sud, Lorient, France;6. ANTiOX, Université de Bretagne Occidentale, Quimper, France;7. CSIC, Consejo Superior de Investigaciones Científicas, Instituto del Frío, Madrid, Spain;8. IFREMER, STAM, Nantes, France;9. Ipimar, Lisbon, Portugal;10. Matis ohf, Reykjavik, Iceland;11. University of Iceland, Reykjavik, Iceland;12. Copalis, Boulogne sur Mer, France;13. Marinova, H?jmark, Denmark
Abstract:BACKGROUND: Numerous studies have demonstrated that in vitro controlled enzymatic hydrolysis of fish and shellfish proteins leads to bioactive peptides. Ultrafiltration (UF) and/or nanofiltration (NF) can be used to refine hydrolysates and also to fractionate them in order to obtain a peptide population enriched in selected sizes. This study was designed to highlight the impact of controlled UF and NF on the stability of biological activities of an industrial fish protein hydrolysate (FPH) and to understand whether fractionation could improve its content in bioactive peptides. RESULTS: The starting fish protein hydrolysate exhibited a balanced amino acid composition, a reproducible molecular weight (MW) profile, and a low sodium chloride content, allowing the study of its biological activity. Successive fractionation on UF and NF membranes allowed concentration of peptides of selected sizes, without, however, carrying out sharp separations, some MW classes being found in several fractions. Peptides containing Pro, Hyp, Asp and Glu were concentrated in the UF and NF retentates compared to the unfractionated hydrolysate and UF permeate, respectively. Gastrin/cholecystokinin‐like peptides were present in the starting FPH, UF and NF fractions, but fractionation did not increase their concentration. In contrast, quantification of calcitonin gene‐related peptide (CGRP)‐like peptides demonstrated an increase in CGRP‐like activities in the UF permeate, relative to the starting FPH. The starting hydrolysate also showed a potent antioxidant and radical scavenging activity, and a moderate angiotensin‐converting enzyme (ACE)‐1 inhibitory activity, which were not increased by UF and NF fractionation. CONCLUSION: Fractionation of an FPH using membrane separation, with a molecular weight cut‐off adapted to the peptide composition, may provide an effective means to concentrate CGRP‐like peptides and peptides enriched in selected amino acids. The peptide size distribution observed after UF and NF fractionation demonstrates that it is misleading to characterize the fractions obtained by membrane filtration according to the MW cut‐off of the membrane only, as is currently done in the literature. Copyright © 2010 Society of Chemical Industry
Keywords:fish protein hydrolysate  ultrafiltration  nanofiltration  membrane separation  fractionation process  bioactive peptide
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