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Substancje bioaktywne występujące w owadach jako potencjalne stymulatory wzrostu w żywieniu drobiu cz.I
Black Soldier Fly Meal as a Gastrointestinal Tract Microbiota Remodelling Factor: A New Natural and Sustainable Source of Prebiotic Substances for Fish?
The microbiota of the gastrointestinal tract (GIT) plays a crucial role in the development, lifespan, physiology, barrier functions and immunity against pathogens in fish. One of the significant causes of fish mortality in production systems, which also generates huge financial losses, is pathogenic dieseases. Consequently, effectively managing disruptions in the microbiota could play a crucial role in mitigating economic losses across the sector. It was investigated the effect of an alternative raw material increasing inclusion—full‐fat Hermetia illucens larvae meal on the composition of the gastrointestinal microbiome of Atlantic salmon. Thus, five experimental feeds were prepared: a control diet (CON) without the addition of black soldier fly full‐fat meal (BSFM) and with 30% fish meal (FM); BSFM5, with 5% addition of full‐fat BSFM and 27.1% FM; BSFM10, with 10% full‐fat BSFM and 24.3% FM; BSFM15, with 15% addition of full‐fat BSFM and 21.3% FM; and BSFM20, with 20% addition of full‐fat BSFM and 18.6% FM. After 60 days of growth experiment on Atlantic salmon presmolts, the contents of two sections of the GIT, proximal and distal, were gently sampled and subjected to next‐generation sequencing (NGS) to analyse the microbial populations. No significant differences were observed in the microbial compositions of the groups, irrespective of the intestinal section analysed. In the proximal and distal intestine, the CON group exhibited the highest number of distinct phyla. Increasing the inclusion of BSFM in the diet led to a reduction in the abundance of specific phyla. Similar results were noted at genus level. The BSFM5 and BSFM10 groups showed increase number in Enterococcus, while the Lactobacillus population were maintained at a high level. Due to abovementioned changes as well as the increased share of Bacilli populations, it may be concluded that up to 20% BSFM shares may have positive microbiota‐modulating effects. Thus, BSFM may be considered not only as a nutrient source but a functional feed material in fish diets also, due to its prebiotic effects observed in the study.
Cecal microbiota of broilers responds similarly to black soldier fly larvae fat and conventional dietary fat sources
This study aimed to compare the effects of black soldier fly ( Hermetia illucens ) larvae (BSFL) fat with those of dietary fats commonly used in broiler chicken nutrition on gut pH and cecal microbiome. A total of 800 one-day-old male Ross 308 chicks were randomly assigned to eight dietary groups, with each group consisting of 10 replicate pens of 10 birds each fed for 35 days. The study design was as follows: the basal diet was enriched with various dietary fats as the sole source of fat, including BSFL fat (as the reference group), soybean oil (SO), rapeseed oil (RO), palm oil (PO), palm kernel fatty acid distillate (PKFD), poultry fat (PF), pig lard (PL), and beef tallow (BT). At the end of the experiment (35 days), the digesta from the crop, gizzard, jejunum, and ceca were sampled for further analyses, including pH determination and next-generation sequencing (NGS). Compared with PKFD, PF, and BT, BSFL significantly reduced the crop pH (P = 0.005). Additionally, BSFL increased the gizzard pH (P = 0.006) relative to PKFD. No differences in alpha diversity were detected among the diets; however, beta diversity differed significantly between the BSFL and PKFD groups (P = 0.034). BSFL fat was associated with a significant reduction in the abundances of Proteobacteria (P = 0.011), Enterobacteriaceae (P = 0.009), and Escherichia-Shigella (P = 0.009) compared with PKFD fat. LEfSe analysis revealed the following microbial markers responsive to BSFL treatment: total bacteria (P < 0.001), Rikenellaceae (P = 0.025), Peptococcaceae [uncultured genus] (P = 0.003), Rhodospirillales (P = 0.048), Alistipes (P = 0.025), the Eubacterium coprostanoligenes group (P = 0.018), the Clostridia vadin BB60 group (P = 0.032), and Alistipes sp. (P = 0.023). These findings suggest that BSFL positively affects the pH in the upper part of a bird’s gut compared with selected animal fats. Furthermore, BSFL enriched beneficial bacteria while inhibiting opportunistic pathogens in the cecal environment of broiler chickens.
Bacillus licheniformis and phytase combination in broiler chicken diets: Effects on growth performance, digestibility coefficients, gut microbiome activities, and bone quality
Substancje bioaktywne występujące w owadach jako potencjalne stymulatory wzrostu w żywieniu drobiu cz. II
Black Soldier Fly Larva Fat in Broiler Chicken Diets Affects Breast Meat Quality
This study aimed to evaluate the dose-dependent effect of black soldier fly (BFL) larvae fat inclusion in broiler chicken diets on breast meat quality. Four hundred 1-day-old male birds (Ross 308) were assigned to the following four treatments (10 replicates with 10 birds each): HI0, a basal diet without dietary fat inclusion, and HI03, HI06, and HI09, basal diets enriched with 30 g/kg, 60 g/kg, and 90 g/kg of BSF larvae fat, respectively. Principal component analysis showed noticeable differentiation between the selected plant, animal, and insect-origin dietary fats. The BSF fat exhibits a strong relationship with saturated fatty acids (SFAs), resulting in a high concentration of C12:0 and C14:0. The fatty acid (FA) profile in breast muscle obtained from broilers fed diets with increasing insect fat inclusion showed a significant linear effect in terms of C12:0, C15:0, C18:2, C18:3n6, and total FAs. The proportion of dietary insect fat had a quadratic effect on meat color. The water-holding capacity indices have stayed consistent with the meat color changes. Throughout the experiment, favorable growth performance results were noticed in HI06. The present study confirmed that BSF larvae fat negatively affects the n3 level in meat. However, the physicochemical indices related to consumer acceptance were not altered to negatively limit their final decision, even when a relatively high inclusion of insect fat was used.
Insect fat influences broiler performance, meat quality, and the cecal microbiota similarly to plant oils rather than animal fats
Abstract We evaluated the addition of Hermetia illucens larvae (BSFL) fat to broiler diets compared to that of soybean oil (SO), rapeseed oil (RO), palm oil (PO), palm kernel fatty acid distillate (PKFD), poultry fat (PF), pig lard (PL), and beef tallow (BT) on performance, meat quality, and cecal microbiota abundance. BSFL addition reduced the feed conversion ratio compared to PO, PF, and BT addition and improved nutrient digestibility at 14 days and 28 days of age. BSFL addition enhanced broiler immune responses compared with SO, PO, and PL by increasing IgA levels; compared to PO by increasing IgG levels; and compared to PL by increasing IgY and IL-6 levels. Moreover, broiler free triiodothyronine levels increased when BSFL was added. Reduced drip loss after 7 days was observed in the RO, PO, PF, PL, and BT groups, while the salt-induced water uptake in the PL group was greater than that in the BSFL group. Compared with the SO group, BSFL addition increased C18:3 and overall n-3 FAs in breast meat. BSFL fat in broiler diets leads to outcomes that are more similar to those of plant oils than to those of animal fats, particularly regarding nutrient digestiblity and immune response.