The embodiments herein are directed to methods for incorporating high quality, sustainable carbon product into animal feed. In particular, the sustainable carbon product described herein for use in animal feed may be produced as byproducts of efficient, clean energy processes. Utilization of sustainable carbon product produced by such clean energy solutions can provide long-term benefits to the environment, while providing a high-quality feed supplement for treating microbial infections without increasing anti-microbial resistance.

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.

The group of inventions relates to feed supplements. The feed supplement for a feed product intended for broiler chickens includes, in the first variant, amorphous mesoporous silicon dioxide, solution of curcumin and rutin in polysorbate 80; in the second variant, amorphous mesoporous silicon dioxide, solution of curcumin in polysorbate 80, activated carbon; in the third variant, amorphous mesoporous silicon dioxide, solution of curcumin and rutin in polysorbate 80, activated carbon. The method for producing the feed supplement for a feed product intended for broiler chickens comprises loading amorphous silicon dioxide or amorphous silicon dioxide in a mixture with activated carbon into a disperser, stirring at from about 1000 rpm to about 2000 rpm for about 0.5 h while gradually adding micellated extract of curcumin in polysorbate 80 or micellated extract of curcumin and rutin in polysorbate 80, increasing the stirring speed to 7000 to 9000 rpm until a homogeneous product is generated. The group of inventions provides increased growth performance, improved quality of meat of broiler chickens. 4 independent claims, 7 subclaims, 8 tables.

The group of inventions relates to feed supplements. The feed supplement for a feed product intended for broiler chickens includes, in the first variant, amorphous mesoporous silicon dioxide, solution of curcumin and rutin in polysorbate 80; in the second variant, amorphous mesoporous silicon dioxide, solution of curcumin in polysorbate 80, activated carbon; in the third variant, amorphous mesoporous silicon dioxide, solution of curcumin and rutin in polysorbate 80, activated carbon. The method for producing the feed supplement for a feed product intended for broiler chickens comprises loading amorphous silicon dioxide or amorphous silicon dioxide in a mixture with activated carbon into a disperser, stirring at from about 1000 rpm to about 2000 rpm for about 0.5 h while gradually adding micellated extract of curcumin in polysorbate 80 or micellated extract of curcumin and rutin in polysorbate 80, increasing the stirring speed to 7000 to 9000 rpm until a homogeneous product is generated. The group of inventions provides increased growth performance, improved quality of meat of broiler chickens. 4 independent claims, 7 subclaims, 8 tables.

A functional feed additive which may promote metabolism in livestock without the use of separate antibiotics, antibacterial agents and growth hormones, thereby increasing autoimmune cells to maximize the autoimmunity of livestock against various diseases, and which makes it possible to obtain meat containing increased amounts of unsaturated fatty acids beneficial to the human body and which has an effect of significantly reducing the complex odor of livestock excrement by removing ammonia gas (NH.sub.3) generated from livestock excrement.

A functional feed additive which may promote metabolism in livestock without the use of separate antibiotics, antibacterial agents and growth hormones, thereby increasing autoimmune cells to maximize the autoimmunity of livestock against various diseases, and which makes it possible to obtain meat containing increased amounts of unsaturated fatty acids beneficial to the human body and which has an effect of significantly reducing the complex odor of livestock excrement by removing ammonia gas (NH.sub.3) generated from livestock excrement.

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.

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.