Future technologies in pigs & poultry nutrition

The economic room for technologically and nutritionally more advanced diets will increase in the future. The processing of animal feed currently has a number of beneficial effects including the improvements in feed efficiency and to find the right balance between animal health and efficiency. In the feed mill diagrams, a large diversity of equipment and systems can be found. This diversity is already present for each different unit operations: in the case of particle size reduction, there is a large choice in special equipment and the way the different steps are set up into a grinding system. For agglomeration e.g. these may vary from having large flexibility in more basic production of different feed forms, up to applying sophisticated equipment (expanders, compactors) to improve nutrient digestibility and pellet quality to strive towards high quality feeds. Farms are becoming larger and in certain countries farmer are using on-farm processing of feed ingredients in addition to purchased concentrates. There is a small but growing trend in organic farming to include the use of other ingredients for animal diets such as grass for sows, fermented ingredients, etc. and some are of the opinion that a new business model will emerge in agriculture where the objective has to be a balance between economy, ecology and society, called 'sustainable precision husbandry'

Strategies to prevent and reduce mycotoxins for compound feed manufacturing

Mycotoxins are the secondary metabolites of fungi, especially moulds. They have over 300 types and can be easily produced ubiquitously by moulds. Many mycotoxins have been found to be toxic to most farmed animals through the diets. With the globalization of feed ingredient trade and the rapid climate changes, occurrence of mycotoxins become increasingly difficult to be predicted. Thus, the unnoticeable mycotoxin hazards can directly impact the animal production systems. Preventing or minimizing mycotoxins in feed ingredients has become an important topic from the aspect of feed manufacturing industry. The aim of this literature review is to summarize the effective strategies for feed manufacturers to minimize the mycotoxin hazards. Prevention methods, including pre-harvest field management and post-harvest storage management, are still the most effective strategies, since mycotoxins are hardly to be eliminated once they are present in the ingredients. Moreover, mycotoxin reducing effects of several feed manufacturing technologies are also reviewed. In this review, the mycotoxin reducing methods are mainly categorized into 4 methodologies: physical methods, thermal methods, chemical methods, and mycotoxin controlling feed additives. The first three methodologies mainly focus on how to reduce mycotoxins in feed ingredients during processes, while the last one on how to compensate the adverse impacts of mycotoxin contaminated diets in animal bodies. The results showed that most of the methods reviewed show evident mycotoxin reducing effects, but of different consistencies. On the other hand, many practical factors that can affect the feasibility of each method in practical manufacturing are also discussed in this review. In conclusion, mycotoxin prevention management and the processing stage of cleaning and sorting are still the most efficient strategies to control mycotoxin hazards in current feed manufacturing

Strategies to prevent and reduce mycotoxins for compound feed manufacturing

Mycotoxins are the secondary metabolites of fungi, especially moulds. They have over 300 types and can be easily produced ubiquitously by moulds. Many mycotoxins have been found to be toxic to most farmed animals through the diets. With the globalization of feed ingredient trade and the rapid climate changes, occurrence of mycotoxins become increasingly difficult to be predicted. Thus, the unnoticeable mycotoxin hazards can directly impact the animal production systems. Preventing or minimizing mycotoxins in feed ingredients has become an important topic from the aspect of feed manufacturing industry. The aim of this literature review is to summarize the effective strategies for feed manufacturers to minimize the mycotoxin hazards. Prevention methods, including pre-harvest field management and post-harvest storage management, are still the most effective strategies, since mycotoxins are hardly to be eliminated once they are present in the ingredients. Moreover, mycotoxin reducing effects of several feed manufacturing technologies are also reviewed. In this review, the mycotoxin reducing methods are mainly categorized into 4 methodologies: physical methods, thermal methods, chemical methods, and mycotoxin controlling feed additives. The first three methodologies mainly focus on how to reduce mycotoxins in feed ingredients during processes, while the last one on how to compensate the adverse impacts of mycotoxin contaminated diets in animal bodies. The results showed that most of the methods reviewed show evident mycotoxin reducing effects, but of different consistencies. On the other hand, many practical factors that can affect the feasibility of each method in practical manufacturing are also discussed in this review. In conclusion, mycotoxin prevention management and the processing stage of cleaning and sorting are still the most efficient strategies to control mycotoxin hazards in current feed manufacturing

Efficiënter voeren en met voeding sturen op immuniteit

Met voeding valt veel te sturen, zoals de gezondheid van het dier, groeisnelheid, melkgift en melksamenstelling en de efficiëntie waarmee nutriënten worden benut of via mest en urine worden uitgescheiden. Binnen Feed4Foodure wordt gebouwd aan kennis en nieuwe voedingsmodellen om beter te begrijpen welke effecten voeding heeft op het dier

Storage temperature and time and its influence on feed quality of fungal treated wheat straw

Degradation of lignocellulose by selective white-rot fungi can significantly improve the nutritional value of high lignocellulose containing biomass by affecting the access of rumen microbes to structural carbohydrates. To determine if such treated biomass is stable in time to allow it to be conserved for subsequent feeding to ruminant animals, wheat straw (WS) pre-treated for 7 weeks with either Ceriporiopsis subvermispora or Lentinula edodes was stored anaerobically up to 10 weeks at different temperatures (24.7–52.4 °C). Substrates were subsequently analysed for changes in pH, titratable acidity, fibre composition, in vitro gas production (IVGP) and colour, as well as polar metabolites by GC–MS and ceriporic acids by LC–MS. The increased titratable acidity of fungal treated WS during storage indicated acidification of the straw. A significant decrease in hemicellulose and an increase in acid detergent lignin content was observed at 52.4 °C. No negative effect of the storage condition on the degradability of both fungal treated WS in rumen fluid was observed. A darker colour was observed for substrates incubated at higher temperatures, coinciding with a strong accumulation of several organic acids and sugars. A decrease in ceriporic acid A, B, C and G produced by C. subvermispora was observed when stored at 52.4 °C from week 2–10. The results show that, although the chemical composition changes, anaerobic storage of fungal treated WS at different temperatures does not affect its fermentation potential for ruminants

Modeling improvements in ileal digestible amino acids by a novel consensus bacterial 6-phytase variant in broilers

Data from 13 datasets from 4 trials on the effect of a novel consensus bacterial 6-phytase variant (PhyG) on the apparent ileal digestibility (AID) of amino acids (AA) in broilers were used to model AID AA responses. The datasets were obtained from 3 trial locations (New Zealand, Australia and United States) and collectively incorporated variations in diet composition (feedstuff composition, phytate-P (PP) level, limestone solubility), feed form (mash or pellet), bird genetics (strain), and age at sampling (11–35 d of age). In total, 384 observations were analyzed. First, the relationships between AID of AA (as coefficients) and increasing phytase dose level from 0 to 4,000 FTU/kg were evaluated across all datasets using exponential curve fitting. Second, the percentage unit change in AID of AA at each phytase dose level from baseline (basal diet [BD] without phytase) was calculated separately for each dataset and the data then modeled together using exponential curve fitting. The model-predicted mean coefficient of AID of total AA in basal diets was 0.76 (range 0.56 [Cys] to 0.83 [Glu]), which was increased by PhyG to 0.80 and 0.81 at 2,000 and 4,000 FTU/kg, respectively. Exponential increases in the percentage unit improvement in AID of 18 individual and of total AA with increasing phytase dose level were evident (P < 0.05). Improvements (vs. BD) at 2,000 FTU/kg and 4,000 FTU/kg, respectively, were greatest for Cys (+9.2 and +11.0% units), Met (after deduction of synthetic Met, +8.4 and +9.0% units), and Thr (after deduction of synthetic Thr, +6.2 and +7.3% units). The data demonstrated consistent improvements in the AID of AA by the phytase. The modeling results generated from data gathered from birds sampled at different ages and from different dietary settings with correction of synthetic AA for Lys, Met, Thr, and Trp, enabled a more accurate prediction of the digestible AA contribution from the diet by this novel phytase. This will allow diet-specific AA matrix recommendations to be made in commercial feed formulations