SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3129477328> ?p ?o ?g. }

Showing items 1 to 100 of ±175 with 100 items per page.

W3129477328 endingPage "736550" @default.
W3129477328 startingPage "736550" @default.
W3129477328 abstract "In the last decades, processed animal proteins, such as poultry by-product meal (PBM) and insect meals have received great attention as sustainable and nutritious aquafeed ingredients. The aim of the present study was to evaluate growth performances, liver and gut histology, macromolecular composition and inflammatory response in rainbow trout ( Oncorhynchus mykiss ) fed diets deprived of fish meal, where graded levels of vegetable protein-rich ingredients, were replaced by defatted Hermetia illucens pupae meal (HM) or PBM, singly or in combination. To this end eight grossly iso‐proteic (45% DM), isolipidic (26% DM) and isoenergetic (23.5 MJ/kg DM) were offered each to triplicated groups of juveniles' fish in a 91 days feeding trial. A diet rich in vegetable protein derivatives high in soybean meal ( CV ) was prepared to have a 10:90 and 20:80 fish to vegetable protein and lipid ratios respectively. By contrast, a fish-based diet ( CF ) was formulated with opposite fish to vegetable protein and lipid ratios. Six more diets, were obtained by replacing graded levels of protein (10, 30 and 60%) of diet CV , by protein from a defatted Hermetia illucens pupae meal and/or poultry by-product meal, singly or combined, while maintaining the same vegetable to fish lipid ratio as in the CV diet. Relative to diets CV and CF , a medium to high substitution (30 and 60%) of dietary vegetable protein-rich ingredients, with HM and/or PBM resulted in improved growth performance as well as in a minor incidence of distal intestine morphological alterations. The diet including both the test animal proteins led to nearly the best overall response in terms of growth and gut/liver health. Both HM and PBM when included at moderate or high levels in the diet, resulted in a downregulation of the expression of inflammatory-related genes relative to diet CV . This effect was greater with HM than that observed with PBM and goes beyond the parallel reduction of vegetable protein and SBM levels in the same diets, suggesting a beneficial role of insect meal that warrant further investigation. The results obtained so far, provide support to a reliable use of alternative/underexploited protein and lipid sources [(HM) or (PBM)] in developing a new generation of sustainable and healthy trout diets that meet the circular economy principles. • Insects and poultry by-product meal are suitable aquafeed ingredients. • A combination of poultry by-product and H. illucens resulted in better fish welfare. • H. illucens meal elicited an anti-inflammatory response in distal intestine. • FTIR resulted as a reliable technique to investigate fish metabolic responses." @default.
W3129477328 created "2021-03-01" @default.
W3129477328 creator A5000129537 @default.
W3129477328 creator A5006668167 @default.
W3129477328 creator A5027743916 @default.
W3129477328 creator A5029153489 @default.
W3129477328 creator A5035271366 @default.
W3129477328 creator A5040249095 @default.
W3129477328 creator A5052021490 @default.
W3129477328 creator A5067038902 @default.
W3129477328 creator A5077270152 @default.
W3129477328 creator A5089568772 @default.
W3129477328 date "2021-05-01" @default.
W3129477328 modified "2023-10-03" @default.
W3129477328 title "Physiological response of rainbow trout (Oncorhynchus mykiss) to graded levels of Hermetia illucens or poultry by-product meals as single or combined substitute ingredients to dietary plant proteins" @default.
W3129477328 cites W1477475959 @default.
W3129477328 cites W1849660911 @default.
W3129477328 cites W1963566148 @default.
W3129477328 cites W1964186648 @default.
W3129477328 cites W1964726674 @default.
W3129477328 cites W1987228708 @default.
W3129477328 cites W1989947627 @default.
W3129477328 cites W2004012959 @default.
W3129477328 cites W2004735447 @default.
W3129477328 cites W2005686803 @default.
W3129477328 cites W2009263714 @default.
W3129477328 cites W2012769636 @default.
W3129477328 cites W2020153062 @default.
W3129477328 cites W2030602350 @default.
W3129477328 cites W2034455241 @default.
W3129477328 cites W2053332821 @default.
W3129477328 cites W2057945718 @default.
W3129477328 cites W2058810252 @default.
W3129477328 cites W2061028824 @default.
W3129477328 cites W2064162334 @default.
W3129477328 cites W2067315688 @default.
W3129477328 cites W2067825096 @default.
W3129477328 cites W2068778903 @default.
W3129477328 cites W2072760626 @default.
W3129477328 cites W2074056187 @default.
W3129477328 cites W2078212812 @default.
W3129477328 cites W2080939000 @default.
W3129477328 cites W2092556731 @default.
W3129477328 cites W2093785962 @default.
W3129477328 cites W2093789216 @default.
W3129477328 cites W2105289341 @default.
W3129477328 cites W2105816476 @default.
W3129477328 cites W2135800182 @default.
W3129477328 cites W2138444889 @default.
W3129477328 cites W2142164571 @default.
W3129477328 cites W2142795239 @default.
W3129477328 cites W2145061092 @default.
W3129477328 cites W2153846295 @default.
W3129477328 cites W2154044303 @default.
W3129477328 cites W2167232355 @default.
W3129477328 cites W2168526937 @default.
W3129477328 cites W2189179437 @default.
W3129477328 cites W2212345261 @default.
W3129477328 cites W2325229224 @default.
W3129477328 cites W2329345240 @default.
W3129477328 cites W2396627190 @default.
W3129477328 cites W2437349461 @default.
W3129477328 cites W2733843495 @default.
W3129477328 cites W2745659110 @default.
W3129477328 cites W2752303672 @default.
W3129477328 cites W2757580003 @default.
W3129477328 cites W2781761573 @default.
W3129477328 cites W2789833268 @default.
W3129477328 cites W2790360633 @default.
W3129477328 cites W2795087523 @default.
W3129477328 cites W2795293280 @default.
W3129477328 cites W2808997074 @default.
W3129477328 cites W2809179845 @default.
W3129477328 cites W2817023537 @default.
W3129477328 cites W2883731715 @default.
W3129477328 cites W2891022024 @default.
W3129477328 cites W2907323199 @default.
W3129477328 cites W2912794268 @default.
W3129477328 cites W2934592069 @default.
W3129477328 cites W2940149314 @default.
W3129477328 cites W2946063886 @default.
W3129477328 cites W2954297376 @default.
W3129477328 cites W2972638968 @default.
W3129477328 cites W2981936341 @default.
W3129477328 cites W2982480042 @default.
W3129477328 cites W2988779057 @default.
W3129477328 cites W2995549096 @default.
W3129477328 cites W3004360253 @default.
W3129477328 cites W3024046263 @default.
W3129477328 cites W3039043483 @default.
W3129477328 cites W3042109439 @default.
W3129477328 cites W3043546913 @default.
W3129477328 cites W3046232939 @default.
W3129477328 cites W3047507965 @default.
W3129477328 cites W4241854952 @default.
W3129477328 doi "https://doi.org/10.1016/j.aquaculture.2021.736550" @default.
W3129477328 hasPublicationYear "2021" @default.
W3129477328 type Work @default.