The aim of this study was to analyze the influence of organic fertilizer on the availability of natural food (plankton and benthos) and water quality. Two fertilization protocols were adopted using inorganic and organic fertilizers with shrimp (stocked treatment) and their controls (unstocked treatment). Experimental units consisted of 12 circular fiberglass tanks (500 l) with estuarine sediment, individual aeration and no water exchange. In stocked treatments were used 40 juveniles/m², and they were fed with 35% crude protein marine shrimp ration, three times a day. Under the organic fertilization protocol, the plankton showed higher abundance of Nitzschia and rotifers, the phytobenthos consisted mainly of Nitzschia, Amphiprora and Oscillatoria, the epibenthos was represented mainly by nematodes and rotifers, and the macro-invertebrates were mainly oligochaetes. In relation to inorganic fertilization, the plankton was represented mainly by Coscinodiscus and rotifers, the phytobenthos consisted mainly of Amphiprora and Oscillatoria, the epibenthos was represented mainly by nematodes and rotifers, and the macro-invertebrates were mainly oligochaetes. Dissolved oxygen was higher for organic fertilizer (6.16 ± 0.98 mg/l) than for inorganic (5.92 ± 1.19 mg/l) while the other water quality parameters did not present significant differences. Survival was similar in the two fertilization regimes (96.6%). Final body weight was 11.89 ± 1.73 g for the inorganic fertilizers and 12.28 ± 1.71 g for organic fertilizer. It is concluded that wheat bran showed good performance in the water quality without exchange, in the availability of natural food, and in the growth and survival of the shrimps in the microcosms.

Legumes, which include a great variety of seeds, are distinguished by their protein content. Legume seeds produce defensive compounds against fungi and insect predators, and these compounds can be extracted or isolated for antimicrobial use. Isolation and identification of legume proteins and peptides have been extensively studied as part of the search for antifungal compounds. Researchers have recently started to pay attention to the antimicrobial activities of legume proteins, lectins, and peptides; however, few overviews regarding their antifungal activity are available, particularly concerning food applications.This review summarizes the main legume proteins and peptides with antifungal activity and their principal antifungal mechanisms of action. Further, potential food applications of legume water extracts and legume crude protein extracts with antifungal activity are discussed.Most studies have focused on isolating and identifying proteins and peptides with antifungal activity. Antifungal mechanism of action has been established for legume defensins. In contrast, legume water extracts and legume crude protein extracts have been subjected to less investigation; however, these preparations have been explored for food applications, particularly in bread, with interesting results. Despite their antifungal activity, practical applications of legume proteins and peptides have yet to be found. This is due to their low yields, high costs, and poor safety regulatory status. Therefore, further research on legume water extracts is necessary before food applications can be broadly developed.

Twenty-four adult Beagles were utilised to evaluate the partial replacement of wheat bran with corn gluten feed without steep water on digestibility and characteristics of faeces. The treatments were 0 (no substitution), 30, 60 or 90 g/kg of corn gluten without steep water. There was no effect (p > .05) on the digestibility coefficients (g/kg) of dry matter (0.771), organic matter (0.806), crude protein (0.813), ether extract (0.798), crude fibre (0.393), neutral detergent fibre (0.425), acid detergent fibre (0.286) and crude energy (0.812), whilst there was effect (p < .05) on the digestible and metabolisable energy. There were effects (p < .05) for dry matter and pH of faeces but no effect (p > .05) was found on the remaining faecal characteristics: excretion for 100 g of food (56.77 g), excretion (129.6 g/day and 49.0 g dry matter/day), score (3.90), dry matter excretion for 100 g of food (22.86 g), buffering capacity (BC) at pH 5 (57.81), ammonia nitrogen (1.46 g/kg of faecal dry matter) and water balance (333.25 mL/day), in vivo and in situ gas production (p > .05). Corn gluten feed without steep water can be utilised to replace up to 90 g/kg of wheat bran without causing negative effect on the digestibility and characteristics of faeces.

The Pacific lamprey is an iconic native fish of great importance to the ecosystem and indigenous cultures in the U.S. Pacific Northwest. Pacific lamprey populations have declined in abundance from historic levels, and conservation aquaculture has been proposed as a technique to restore these populations. The present research focused on expanding the culture methods for larval lamprey. The larvae filter feed and cohabitate with juvenile salmonids in the wild, therefore the effluent water from rearing salmonids may be a viable source of water and food for culturing lamprey. This approach could be a sustainable method for raising lamprey at existing salmonid hatcheries. A nine week trial investigated the effects of rearing in effluent water from salmonid culture on the growth, survival, proximate composition, and fatty acid profile of larval lamprey. This trial also explored the potential of this rearing strategy to improve the water quality by removing nutrients from the effluent. The trial included three treatments testing the use of the effluent from steelhead trout (Oncorhynchus mykiss), a conventional lamprey diet (control diet), or both combined as a means for rearing lamprey. A fourth treatment where lamprey were excluded served as a water quality control to test the effect of lamprey presence on effluent quality. Lamprey survival was not affected by treatment. Lamprey reared solely on the effluent waste matched the survival and growth of fish fed the conventional diet. Lamprey fed the combination treatment grew faster than the conventional diet fed fish. Whole body lipid levels were elevated in lamprey from the combination treatment relative to the conventional diet fed lamprey. Crude protein in the whole bodies of effluent fed lamprey was low compared to fish from either of the treatments where the conventional diet was fed. Lamprey offered the effluent nutrients were high in saturated fats relative to the control fed fish, which reflected the lipid profile of this diet. However, lamprey from the combination treatment were lower in long chain polyunsaturated fatty acids relative to the control or the effluent treatment lamprey. There was no measureable improvement in water quality due to the presence of lamprey, though lamprey were able to sequester approximately 1.3% of the effluent dry matter as lamprey biomass. Overall, it appears the larval stage of lamprey can be effectively reared on salmonid effluent, and this method provides superior growth when used in combination with a conventional lamprey diet.

It is important to explore the use of alternative ingredients for soybean and fishmeal in aquaculture feeds because the demand and cost for those ingredients are expected to increase in the near future and long-term. Meanwhile, the food processing industry produces large quantities of wastes that often contain organic solids and nutrients (e.g. nitrogen waste and phosphorus) which can be converted in microbial protein (bioflocs) using suspended growth biological reactors. Bioflocs that were collected from such a reactor that treats confectionary food processing effluent water were dried and in shrimp feed as a replacement for soybean and fishmeal. A control diet (without bioflocs) was compared to three diets that replaced soybean (10, 20, and 30% biofloc inclusion) and two diets that replaced fishmeal (10 and 20% biofloc inclusion). The control and biofloc diets were formulated to be equivalent for levels of crude protein, total fat, crude fiber, calcium, magnesium, phosphorus, potassium, and sodium. Five juvenile shrimp were stocked per tank and each dietary treatment was tested using 8 replicates over a 35day feeding trial. Dietary treatments had some impact on shrimp performance. No differences (P>0.05) in shrimp performance were observed between the control and the diets that included bioflocs for survival (97.5 to 100%), growth (2.16 to 2.40g/wk), harvest biomass (687 to 732g/m2), or food conversion ratio (1.50 to 1.66). These results indicate the bioflocs harvested from a suspended growth biological reactor that treats food effluent water can successfully be used in shrimp diets.Alternative & sustainable protein source for shrimp culture.