A hardwood-derived carbohydrate composition is disclosed. The hardwood-derived carbohydrate composition comprises monomeric sugars in an amount of 50-80 weight-% based on the total dry matter content of the carbohydrate composition, wherein the monomeric sugars include monomeric glucose and monomeric xylose, the amount of monomeric xylose in the carbohydrate composition being 40-60 weight-% based on the total dry matter content of the carbohydrate composition, and the weight ratio of monomeric glucose to monomeric xylose being 0.067-0.2. Disclosed is also a method for producing a wood-derived carbohydrate composition.

Embodiments of a system and method for formulating an adjusted diet and/or a dietary supplement for a ruminant are disclosed. The adjusted diet and/or dietary supplement are formulated to mitigate an amino acid deficiency of the ruminant’s unaltered diet and provide the ruminant with an amino-acid balanced diet. Embodiments of a system and method of administering the adjusted diet and/or dietary supplement are also disclosed. In some embodiments, a computer system or other computing device can be used to implement part or all of the formulation methods and/or the diet administration methods.

An in-feed life cycle interruption agent (LCIA) including a granulated core comprising LCIA material and a coating on the core. Related methods and products are also disclosed. Examples of LCIA include, but are not limited to Naturally occurring insect toxins (NOIT such as saponin and Insect Growth Regulators (IFR) such as Cyromazine.

A method for enhancing the enzymatic efficiency of an enzyme added to poultry feed for a living subject, comprises adding a cellulose-degrading enzyme to a mobile enzyme sequestration platform (MESP) so as to form an enzyme-MESP complex; adding the enzyme-MESP complex to poultry feed for a living subject; the enzyme efficiency of the cellulose-degrading enzyme of the enzyme-MESP complex after being exposed to a first adverse environment for a first period of time is at least 50% higher than the enzyme efficacy of the cellulose-degrading enzyme independent of the MESP being exposed to the first adverse environment for the first period of time.

A method for enhancing the enzymatic efficiency of an enzyme added to poultry feed for a living subject, comprises adding a cellulose-degrading enzyme to a mobile enzyme sequestration platform (MESP) so as to form an enzyme-MESP complex; adding the enzyme-MESP complex to poultry feed for a living subject; the enzyme efficiency of the cellulose-degrading enzyme of the enzyme-MESP complex after being exposed to a first adverse environment for a first period of time is at least 50% higher than the enzyme efficacy of the cellulose-degrading enzyme independent of the MESP being exposed to the first adverse environment for the first period of time.

Disclosed is a method for preparing an attapulgite-based pH-responsive antibacterial material, including: directly spraying a natural aldehyde-based antibacterial agent onto an attapulgite powder under stirring, and constantly stirring the attapulgite powder for 20-30 min; grinding the attapulgite powder in a ball mill for 30-60 min to obtain a ground attapulgite powder; placing the ground attapulgite powder in a stirred tank, and spraying a chitosan-citric acid aqueous solution onto the ground attapulgite powder; after spraying, constantly stirring the ground attapulgite powder for 30-120 min; and finally drying the ground attapulgite powder to obtain a dried attapulgite powder, sieving the dried attapulgite powder to obtain a sieved attapulgite powder, and packaging the sieved attapulgite powder to obtain the antibacterial material.

Disclosed is a method for preparing an attapulgite-based pH-responsive antibacterial material, including: directly spraying a natural aldehyde-based antibacterial agent onto an attapulgite powder under stirring, and constantly stirring the attapulgite powder for 20-30 min; grinding the attapulgite powder in a ball mill for 30-60 min to obtain a ground attapulgite powder; placing the ground attapulgite powder in a stirred tank, and spraying a chitosan-citric acid aqueous solution onto the ground attapulgite powder; after spraying, constantly stirring the ground attapulgite powder for 30-120 min; and finally drying the ground attapulgite powder to obtain a dried attapulgite powder, sieving the dried attapulgite powder to obtain a sieved attapulgite powder, and packaging the sieved attapulgite powder to obtain the antibacterial material.

A nutritional supplement is disclosed. The nutritional supplement may be included in a fish diet. The nutritional supplement may include a carrier oil; 22-30 wt. % Omega 3; and 8-20 wt. % Omega 7. In some embodiments, the carrier oil may be a vegetable oil. In some embodiments, the Omega 3 includes EPA and DHA fatty acids. In some embodiments, the Omega 3 includes is a mixture of EPA and DHA having ratios in the range of 1:10 to 10:1 wt. %.

Disclosed are bolus compositions for ruminants comprising potassium phosphate dibasic and water configured to rapidly dissolve in the rumen for use in the prevention or treatment of hypokalemia and hypophosphatemia. These conditions occur in ruminants at around the time of calving or during periods when ruminants do not eat (anorexia). The bolus compositions may comprise a coating that is compatible with a ruminant digestive tract. Additionally, the bolus compositions may comprise a wick which may be used during the manufacturing process to facilitate the bulk handling and transfer of the bolus compositions.

The present invention relates to a Bifidobacterium longum probiotic for use to improve fermentability of a plant fibre during gastro-intestinal tract passage in a subject, wherein said plant fibre has an insoluble fraction of between 40 to 80% (w/w).