CN111374074A - Nutrition method for regulating and controlling healthy development of liver of micropterus salmoides - Google Patents

Abstract

The invention discloses a nutriology method for regulating and controlling the liver health development of micropterus salmoides juvenile fish, which divides the micropterus salmoides juvenile fish period into an initial stage and a later stage for growth and development, and respectively carries out accurate regulation and control; the method specifically comprises the following steps: for young fish in the early stage, the feed is: 50-55% of protein, 9-11% of fat, and 0.5-0.9% of bile acid and 0.1-0.5% of taurine; for young fish in later stage, the feed is: the feed additive comprises 47-52% of protein, 13-15% of fat, 0.1-0.6% of bile acid and 0.5-1.0% of taurine by mass ratio. The invention has the beneficial effects that: the micropterus salmoides fed by the feed have red and glossy liver, and the survival rate, the weight gain rate and the feed efficiency are obviously improved; and the cost is in a controllable range, and the economy is high.

Description

Nutrition method for regulating and controlling healthy development of liver of micropterus salmoides

Technical Field

The invention relates to the technical field of aquaculture, in particular to a nutriology method for regulating and controlling the healthy development of the liver of micropterus salmoides.

Background

The famous largemouth black perch of the California perch school is a rare carnivorous fish with fresh meat quality, strong disease resistance, rapid growth and wide temperature adaptability. At present, the breeding of the micropterus salmoides is mainly based on feeding of ice fresh trash fish, the use of artificial compound feed is not popularized yet, the most important reason is that the key mechanism of growth of the micropterus salmoides is liver metabolism, the liver is a main organ of metabolism of the micropterus salmoides and is the only place capable of biologically synthesizing bile acid in vivo, the bile acid is synthesized in liver cells, combined with glycine or taurine, secreted into capillary bile ducts to form bile and then stored in gall bladder, and the bile acid can maintain the steady state of cholesterol and can also be used as a signal molecule to play a role in regulating glycolipid metabolism and energy steady state.

The liver of the fish is divided into two types of 'glycogen contained in liver cells is main' and 'fat contained in liver cells is main', but the problem is that the micropterus salmoides is an innate 'fatty liver patient' and an innate 'diabetic patient', so the development of the compound feed for the micropterus salmoides is very difficult, particularly, the juvenile stage of the micropterus salmoides is a main stage of liver development, and the liver and gall diseases such as liver swelling and fat excessive accumulation of the micropterus salmoides are easily caused by feed grease and sugar, so that the scale culture of the micropterus salmoides is greatly restricted.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a nutritional method for stage accurate regulation and control of liver health development of micropterus salmoides, so that diseases such as hepatomegaly and excessive fat accumulation in the micropterus salmoides are avoided, and the production performance of micropterus salmoides is further improved.

The gist of the present invention is: dividing the growth period of micropterus salmoides into an initial stage and a later stage, and respectively carrying out accurate regulation and control; dividing the micropterus salmoides into an initial growth development stage and a later growth development stage according to weight parameters, feeding low-fat and low-sugar feed in a targeted manner at the early growth stage of the micropterus salmoides, and adding bile acid and taurine into the feed; feeding high-fat low-sugar feed in the later growth stage of micropterus salmoides, and supplementing bile acid and taurine in the feed; in the feed processing process, the multi-layer post-spraying process can avoid the swelling inactivation of vitamins and the dissolution loss of the vitamins in water, effectively improve the utilization rate of the phagostimulant, improve the palatability and improve the feed intake.

In order to realize the aim, the invention provides a nutriology method for regulating and controlling the healthy development of the liver of the micropterus salmoides juvenile fish, which divides the micropterus salmoides juvenile fish period into an initial growth development stage and a later growth development stage, and respectively carries out accurate regulation and control; the method specifically comprises the following steps:

for juvenile fish in the early stage of growth and development, the feed is fed as follows: the feed contains 50-55% of protein and 9-11% of fat, and is added with 0.5-0.9% of bile acid and 0.1-0.5% of taurine;

for juvenile fish in the later stage of growth and development, the feed is as follows: the protein content of the feed is 47-52%, the fat content is 13-15%, and bile acid accounting for 0.1-0.6% of the mass ratio of the feed and taurine accounting for 0.5-1.0% of the mass ratio of the feed are added.

Wherein, the division mode of two stages of juvenile fish is:

the early stage of the growth and development of the juvenile fish specifically comprises the following steps: the weight of the juvenile fish is less than or equal to 70 g;

the later stage of the growth and development of the juvenile fish specifically comprises the following steps: the weight of the juvenile fish is 70-200 g.

Preferably, the first and second electrodes are formed of a metal,

for juvenile fish in the early stage of growth and development, the feed is fed as follows: the feed contains 52% of protein and 10% of fat, and is added with 0.8% of bile acid and 0.2% of taurine in mass ratio of the feed;

for juvenile fish in the later stage of growth and development, the feed is as follows: the protein content of the feed is 50%, the fat content is 14%, and bile acid accounting for 0.3% of the mass ratio of the feed and taurine accounting for 0.7% of the mass ratio of the feed are added.

The juvenile fish feed for the early growth and development stage is prepared from the following raw materials in parts by weight:

380 portions of fish meal, 160 portions of rice protein powder, 40-80 portions of casein, 240 portions of bean pulp, 40-80 portions of strong flour, 30-50 portions of fish oil, 10-25 portions of soybean lecithin, 15-25 portions of mineral premix, 15-25 portions of vitamin premix, 7-15 portions of phagostimulant, 5-9 portions of bile acid and 1-5 portions of taurine;

preferably, the juvenile fish feed for the early growth and development stage is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 8 parts of bile acid and 2 parts of taurine.

The juvenile fish feed for the later stage of growth and development is prepared from the following raw materials in parts by weight:

420 parts of 370-grade fish meal, 150 parts of 120-grade rice protein powder, 50-70 parts of casein, 220 parts of 160-grade soybean meal, 55-70 parts of strong flour, 60-80 parts of fish oil, 25-35 parts of soybean lecithin, 15-25 parts of mineral premix, 15-25 parts of vitamin premix, 8-12 parts of phagostimulant, 1-6 parts of bile acid and 5-10 parts of taurine;

preferably, the juvenile fish feed for the later stage of growth and development is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 3 parts of bile acid and 7 parts of taurine.

The preparation method of the feed in the two stages comprises the following steps:

(1) the material preparation step: weighing other raw materials except the vitamin premix, the fish oil and the phagostimulant according to the weight parts, and putting the raw materials into a mixer to be uniformly mixed for 30-60 s;

(2) a granulation step: putting the uniformly mixed material obtained in the step (1) into a granulator for granulation, and pre-cooling by adjusting the air intake to reduce the temperature of a puffing cavity to below 65 ℃;

(3) post-spraying: spraying vitamin premix, adjusting the limit vacuum value to 15mbar, controlling the temperature to be 34 ℃, and avoiding the expansion and inactivation of the vitamin; spraying fish oil, adjusting the limit vacuum value to be 18mbar, controlling the temperature to be 46 ℃, spraying oil for 4 minutes, and standing for 15 minutes after spraying; and finally spraying a phagostimulant, adjusting the limit vacuum value to be 12mbar, and controlling the temperature to be 26 ℃.

In order to better realize the aim of the invention, the invention provides a nutritional feed for regulating and controlling the healthy development of the liver of micropterus salmoides, which comprises the following specific steps:

for juvenile fish in the early growth and development stage, the feed has the protein content of 52 percent and the fat content of 10 percent, and contains 0.5 to 0.9 percent of bile acid and 0.1 to 0.5 percent of taurine in mass ratio of the feed;

for juvenile fish in the later stage of growth and development, the feed has the protein content of 50 percent and the fat content of 14 percent, and contains 0.1 to 0.6 percent of bile acid and 0.5 to 1.0 percent of taurine in mass ratio of the feed;

wherein, the early stage of the growth and development of the juvenile fish specifically comprises the following steps: the weight of the juvenile fish is less than or equal to 70 g; the later stage of the growth and development of the juvenile fish specifically comprises the following steps: the weight of the juvenile fish is 70-200 g.

Preferably, the first and second electrodes are formed of a metal,

for juvenile fish in the early growth and development stage, the feed has the protein content of 52 percent and the fat content of 10 percent, and contains 0.8 percent of bile acid and 0.2 percent of taurine in mass ratio of the feed;

for juvenile fish in the later stage of growth and development, the feed has the protein content of 50 percent and the fat content of 14 percent, and contains 0.3 percent of bile acid and 0.7 percent of taurine in mass ratio of the feed.

The specific formula of the feed comprises:

when the juvenile fish is in the early stage of growth and development, the feed is prepared from the following raw materials in parts by weight:

380 portions of fish meal, 160 portions of rice protein powder, 40-80 portions of casein, 240 portions of bean pulp, 40-80 portions of strong flour, 30-50 portions of fish oil, 10-25 portions of soybean lecithin, 15-25 portions of mineral premix, 15-25 portions of vitamin premix, 7-15 portions of phagostimulant, 5-9 portions of bile acid and 1-5 portions of taurine;

when the juvenile fish is in the later stage of production and development, the feed is prepared from the following raw materials in parts by weight:

420 parts of 370-grade fish meal, 150 parts of 120-grade rice protein powder, 50-70 parts of casein, 220 parts of 160-grade soybean meal, 55-70 parts of strong flour, 60-80 parts of fish oil, 25-35 parts of soybean lecithin, 15-25 parts of mineral premix, 15-25 parts of vitamin premix, 8-12 parts of phagostimulant, 1-6 parts of bile acid and 5-10 parts of taurine.

Preferably, the first and second electrodes are formed of a metal,

when the juvenile fish is in the early stage of growth and development, the feed is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 8 parts of bile acid and 2 parts of taurine;

when the juvenile fish is in the later stage of production and development, the feed is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 3 parts of bile acid and 7 parts of taurine.

It may also be preferred that:

when the juvenile fish is in the early stage of growth and development, the feed is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 9 parts of bile acid and 1 part of taurine; or 410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 6 parts of bile acid and 4 parts of taurine; or 410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 5 parts of bile acid and 5 parts of taurine;

when the juvenile fish is in the later stage of production and development, the feed is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 3 parts of bile acid and 7 parts of taurine; or 390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 2 parts of bile acid and 8 parts of taurine; or 390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 4 parts of bile acid and 6 parts of taurine; or 390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 5 parts of bile acid and 5 parts of taurine.

In order to better achieve the above object, the present application also provides a preparation method of the feed, which comprises the following steps:

(1) the material preparation step: weighing other raw materials except the vitamin premix, the fish oil and the phagostimulant according to the weight parts, and putting the raw materials into a mixer to be uniformly mixed for 30-60 s;

(2) a granulation step: putting the uniformly mixed material obtained in the step (1) into a granulator for granulation, and pre-cooling by adjusting the air intake to reduce the temperature of a puffing cavity to below 65 ℃;

(3) post-spraying:

spraying vitamin premix, adjusting the limit vacuum value to 15mbar, controlling the temperature to be 34 ℃, and avoiding the expansion and inactivation of the vitamin;

spraying fish oil, adjusting the limit vacuum value to be 18mbar, controlling the temperature to be 46 ℃, spraying oil for 4 minutes, and standing for 15 minutes after spraying;

and finally spraying a phagostimulant, adjusting the limit vacuum value to be 12mbar, and controlling the temperature to be 26 ℃.

The invention has the beneficial effects that: the growth period of the micropterus salmoides is divided into two stages, aiming at the requirements of different growth and development stages of micropterus salmoides, the liver development condition is pertinently intervened by adding bile acid in a targeted manner by adjusting the glycolipid intake level in micropterus salmoides feed, the health of micropterus salmoides is regulated and controlled, the synergistic digestion and absorption efficiency of lipid substances such as soybean lecithin and the like in the feed formula is promoted, the feed conversion rate is improved, the animal growth is finally promoted, and the method has important significance for promoting the continuous development of micropterus salmoides breeding industry. Experiments show that the micropterus salmoides fed by the feed have red and glossy liver, and the survival rate, the weight gain rate and the feed efficiency are obviously improved; and the cost is in a controllable range, and the economy is high.

Drawings

FIG. 1 is a graph comparing the weight gain and feed factor of micropterus salmoides in each treatment group of comparative experiment I.

FIG. 2 is a graph comparing the effect of liver health in young micropterus salmoides in each treatment group of experiment one.

FIG. 3 is a graph comparing the total liver antioxidant capacity and malondialdehyde content of micropterus salmoides juvenile fish in the treatment group of comparative experiment I.

FIG. 4 is a graph comparing the weight gain and feed factor of micropterus salmoides in each treatment group of comparative experiment two.

FIG. 5 is a comparison of liver health status of micropterus salmoides in each treatment group of comparative experiment two.

FIG. 6 is a graph showing the comparison of the total liver antioxidant capacity and malondialdehyde content of micropterus salmoides in each treatment group of comparative experiment II.

Fig. 7 is a circuit diagram of the technique in comparative experiment three.

FIG. 8 is a graph showing the comparison of the liver weight gain and the feed factor of micropterus salmoides larvae of each treatment group in the third comparative experiment.

FIG. 9 is a comparison of the liver health status of micropterus salmoides in each treatment group of comparative experiment three.

FIG. 10 is a graph showing the comparison of the total liver antioxidant capacity and malondialdehyde content of micropterus salmoides in each treatment group of the third comparative experiment.

Detailed Description

In order to clearly illustrate the technical features of the present solution, the present solution is explained below by way of specific embodiments.

Example 1: feed 1 in early stage

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the early stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 8 parts of bile acid and 2 parts of taurine.

Example 2: feed 2 in early stage

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the early stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 9 parts of bile acid and 1 part of taurine.

Example 3: feed 3 in early stage

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the early stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 6 parts of bile acid and 4 parts of taurine.

Example 4: feed for early stage 4

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the early stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 5 parts of bile acid and 5 parts of taurine.

Example 5: feed 5 in early stage

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the early stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

380 parts of fish meal, 160 parts of rice protein powder, 40 parts of casein, 240 parts of soybean meal, 40 parts of high gluten flour, 30 parts of fish oil, 25 parts of soybean lecithin, 25 parts of mineral premix, 15 parts of vitamin premix, 7 parts of phagostimulant, 7 parts of bile acid and 3 parts of taurine.

Example 6: early stage feed 6

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the early stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

450 parts of fish meal, 100 parts of rice protein powder, 40 parts of casein, 180 parts of soybean meal, 80 parts of high gluten flour, 50 parts of fish oil, 10 parts of soybean lecithin, 15 parts of mineral premix, 25 parts of vitamin premix, 15 parts of phagostimulant, 8 parts of bile acid and 2 parts of taurine.

Example 7: feed for later stage 1

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the later stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts (7.0%) of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 3 parts of bile acid and 7 parts of taurine.

Example 8: late stage feed 2

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the later stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts (7.0%) of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 2 parts of bile acid and 8 parts of taurine.

Example 9: late stage feed 3

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the later stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts (7.0%) of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 4 parts of bile acid and 6 parts of taurine.

Example 10: late stage feed 4

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the later stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts (7.0%) of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 5 parts of bile acid and 5 parts of taurine.

Example 11: late stage feed 5

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the later stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

370 parts of fish meal, 120 parts of rice protein powder, 50 parts of casein, 220 parts of soybean meal, 70 parts of high gluten flour, 60 parts of fish oil, 35 parts of soybean lecithin, 15 parts of mineral premix, 25 parts of vitamin premix, 8 parts of phagostimulant, 1 part of bile acid and 9 parts of taurine.

Example 12: late stage feed 6

The embodiment of the invention provides a feed for regulating and controlling the liver health of micropterus salmoides juvenile fish, in particular to a feed for micropterus salmoides juvenile fish in the later stage of growth and development, which specifically comprises the following steps: the feed is prepared from the following raw materials in parts by weight:

420 parts of fish meal, 150 parts of rice protein powder, 70 parts of casein, 160 parts of soybean meal, 55 parts of high gluten flour, 80 parts of fish oil, 25 parts of soybean lecithin, 25 parts of mineral premix, 15 parts of vitamin premix, 12 parts of phagostimulant, 6 parts of bile acid and 10 parts of taurine.

Example 13: preparation method

This example provides a method for preparing a feed, particularly suitable for the preparation of the feeds of examples 1-12, comprising the following steps:

(1) the material preparation step: weighing other raw materials except the vitamin premix, the fish oil and the phagostimulant according to the weight parts, and putting the raw materials into a mixer to be uniformly mixed for 30-60 s;

(2) a granulation step: putting the uniformly mixed material obtained in the step (1) into a granulator for granulation, and pre-cooling by adjusting the air intake to reduce the temperature of a puffing cavity to below 65 ℃;

(3) post-spraying: spraying vitamin premix, adjusting the limit vacuum value to 15mbar, controlling the temperature to be 34 ℃, and avoiding the expansion and inactivation of the vitamin; spraying fish oil, adjusting the limit vacuum value to be 18mbar, controlling the temperature to be 46 ℃, spraying oil for 4 minutes, and standing for 15 minutes after spraying; and finally spraying a phagostimulant, adjusting the limit vacuum value to be 12mbar, and controlling the temperature to be 26 ℃.

Comparison test one: initial stage feed test

1. Experimental design and experimental feed formulation

The basic feed (protein content is 52 percent and fat content is 10 percent) is prepared by taking fish meal, rice protein powder, casein and soybean meal as main protein sources and fish oil as a main fat source. Adding bile acid and taurine into the basic feed to prepare 5 kinds of equal-nitrogen and other-lipid feeds with different bile acid and taurine levels; the feed formulation is shown in table 1.

TABLE 1 feed formulation and coarse ingredients (% dry matter) of the Low fat Low sugar test feeds

2. Fish and culture management for experiment

The experiment adopts the current year micropterus salmoides, divides the micropterus salmoides with the average weight of 29.64g into 25 boxes according to 70 boxes (2 m × 2m × 1.5 m), the initial weight of each box is basically consistent, randomly divides 25 net cage fish into 5 treatments, each treatment is repeated for 5 times, and the initial weight difference between each treatment is not significant (P > 0.05). The formal test feeds the micropterus salmoides 3 times every day, the feeding time is 07:30, 14:00 and 19:00, the feeding amount is 2-4%, the feeding amount is properly adjusted according to the weather, the feeding amount is increased by 10% every other week, an oxygenation system is started at regular time to ensure that the dissolved oxygen is more than 4mg/L, the water temperature is measured at regular time every day, the dissolved oxygen, ammonia nitrogen and nitrite are measured at regular time every week, preventive medication is carried out according to the measurement condition, the water quality is adjusted, and the culture period is 56 days.

3. Results of the experiment

The influence of each treatment group on the weight gain rate and the feed coefficient of micropterus salmoides at the early growth stage is shown in figure 1, and as can be seen from figure 1, the weight gain rate of the treatment group is the highest in the three groups, and the weight gain rate of the treatment group is the lowest in the treatment group without adding bile acid and taurine; the bait coefficient of the three groups is the lowest, while the bait coefficient of the group without the addition of bile acid and taurine is the highest.

The influence of each treatment group on the liver health condition of the juvenile micropterus salmoides at the early growth stage is shown in fig. 2, and as can be seen from fig. 2, the livers of three groups are ruddy, full and healthy, and the livers of five groups of micropterus salmoides are treated to have pathological changes of different degrees.

The influence of each treatment group on the total antioxidant capacity and the malondialdehyde content of the liver of the juvenile Micropterus salmoides at the early stage of growth is shown in figure 3, and as can be seen from figure 3, the total antioxidant capacity of the liver of the treated three groups is higher than that of the liver of other groups; three groups of liver were treated with lower malondialdehyde content than the other groups.

Comparative experiment two: late stage feed test

1. Experimental design and experimental feed formulation

The basic feed (protein content is 50 percent, and fat content is 14 percent) is prepared by taking fish meal, rice protein powder, casein and soybean meal as main protein sources and fish oil as a main fat source. Bile acid and taurine are added into basic feed to prepare 5 kinds of equal-nitrogen-level lipid feeds with different bile acid and taurine levels. The feed formulation is shown in table 2.

Table 2 feed formulation and coarse content (% dry matter) of the experimental diets high fat and low sugar

2. Fish and culture management for experiment

The experiment adopts the current year micropterus salmoides, divides the micropterus salmoides with the average weight of 65g into 25 boxes according to 70 boxes (2 m × 2m × 1.5.5 m), the initial weight of each box is basically consistent, randomly divides 25 net cage fish into 5 treatments, each treatment is repeated for 5 times, and the initial weight difference between each treatment is not significant (P > 0.05). The formal test feeds the micropterus salmoides 3 times every day, the feeding time is 07:30, 14:00 and 19:00, the feeding amount is 2-4%, the feeding amount is properly adjusted according to the weather, the feeding amount is increased by 10% every week, an oxygenation system is started at regular time to ensure that the dissolved oxygen is more than 4mg/L, the water temperature is measured at regular time every day, the dissolved oxygen, ammonia nitrogen and nitrite are measured at regular time every week, the medicine is prevented according to the measurement condition, the water quality is adjusted, and the culture period is 56 days.

3. Results of the experiment

The influence of each treatment group on the weight gain rate and the feed coefficient of the micropterus salmoides at the later growth stage is shown in fig. 4, and as can be seen from fig. 4, the weight gain rate of the treatment group is the highest in the three groups, and the weight gain rate of the treatment group without adding bile acid and taurine is the lowest; the bait coefficient of the three groups is the lowest, while the bait coefficient of the group without the addition of bile acid and taurine is the highest.

The influence of each treatment group on the liver health condition of the micropterus salmoides at the later growth stage is shown in fig. 5, and as can be seen from fig. 5, the livers of three groups are ruddy, full and healthy, and the livers of five groups of micropterus salmoides are treated to have different degrees of pathological changes.

The influence of each treatment group on the total oxidation resistance of the liver and the malondialdehyde content of the micropterus salmoides at the later growth stage is shown in fig. 6, and as can be seen from fig. 6, the total oxidation resistance of the liver of the treated three groups is higher than that of the other groups; three groups of liver were treated with lower malondialdehyde content than the other groups.

And (3) comparison test III: juvenile fish full-stage feed test

1. Experimental design and experimental feed formulation

The technical circuit of the test is shown in fig. 7, and specifically includes:

and comparison one: feeding the iced fresh trash fish in the whole process without difference;

comparison two: feeding a certain commercial feed indiscriminately in the whole process;

comparison three: feeding commercial feed in the early stage and feeding iced fresh trash fish in the later stage;

control four: feeding iced fresh trash fish in the early stage and feeding commercial feed in the later stage;

control five: feeding low-fat and low-sugar feed at the early stage (namely, the first treatment of the first test), and feeding high-fat and low-sugar feed at the later stage (namely, the first treatment of the second test);

the invention comprises the following steps: the low-fat and low-sugar feed was fed at the early stage (treatment three in test one) and at the later stage (treatment three in example two).

2. Fish and culture management for experiment

The experiment adopts the current year micropterus salmoides, divides the average weight of the micropterus salmoides into 30 boxes according to 70 per box (2 m × 2m × 1.5.5 m), the initial weight of each box is basically consistent, randomly divides 30 net cage fish into 6 treatments, each treatment is repeated for 5 times, and the initial weight difference between each treatment is not significant (P is more than 0.05). The formal test (the feed amount is increased by 10% every week in the early stage of cultivation, and the feed amount is increased by 30-60 days in the later stage of cultivation) is fed for 3 times every day, the feeding time is respectively 07:30, 14:00, 19:00, the feeding amount is 2-4%, the feeding amount is properly adjusted according to the weather, the feeding amount is increased by 10% every week, the oxygenation system is started regularly to ensure that the dissolved oxygen is more than 4mg/L, the water temperature is measured regularly every day, the dissolved oxygen, ammonia nitrogen and nitrite are measured regularly every week, the preventive medication and the water quality is adjusted according to the measurement condition, and the water quality is.

3. Results of the experiment

The effect of each treatment group on the liver health of micropterus salmoides was shown in fig. 8. it can be seen from fig. 8 that the weight gain was the highest and the feed factor was the lowest in the treatment groups using the method of the present invention compared to the control groups not using the method of the present invention.

The influence of each treatment group on the liver health condition of micropterus salmoides is shown in fig. 9, and as can be seen from fig. 9, the liver of the treatment group using the method is ruddy, full and healthy compared with the control group not using the method of the present invention.

The effect of each treatment group on the total antioxidant capacity and the malondialdehyde content of the liver of micropterus salmoides juvenile fish is shown in fig. 10, and it can be seen from fig. 9 that the treatment group using the method has high total antioxidant capacity in the liver and low malondialdehyde content in the liver, compared with the control group not using the method of the present invention.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. A nutriology method for regulating and controlling health development of micropterus salmoides liver is characterized in that the nutriology method divides the micropterus salmoides juvenile fish period into an initial growth development stage and a later growth development stage, and respectively carries out accurate regulation and control; the method specifically comprises the following steps:

for juvenile fish in the early stage of growth and development, the feed is fed as follows: the feed contains 50-55% of protein and 9-11% of fat, and is added with 0.5-0.9% of bile acid and 0.1-0.5% of taurine;

for juvenile fish in the later stage of growth and development, the feed is as follows: the feed contains 47-52% of protein and 13-15% of fat, and is added with 0.1-0.6% of bile acid and 0.5-1.0% of taurine.

2. The method of claim 1,

the early stage of the growth and development of the juvenile fish specifically comprises the following steps: the weight of the juvenile fish is less than or equal to 70 g;

the later stage of the growth and development of the juvenile fish specifically comprises the following steps: the weight of the juvenile fish is 70-200 g.

3. The method according to claim 1 or 2, wherein the juvenile fish feed at the early stage of growth and development is prepared from the following raw materials in parts by weight:

380 portions of fish meal, 160 portions of rice protein powder, 40 to 80 portions of casein, 240 portions of bean pulp, 40 to 80 portions of strong flour, 30 to 50 portions of fish oil, 10 to 25 portions of soybean lecithin, 15 to 25 portions of mineral premix, 15 to 25 portions of vitamin premix, 7 to 15 portions of phagostimulant, 5 to 9 portions of bile acid and 1 to 5 portions of taurine.

4. The method according to claim 1 or 2, wherein the juvenile fish feed for the later stage of growth and development is prepared from the following raw materials in parts by weight:

420 parts of 370-grade fish meal, 150 parts of 120-grade rice protein powder, 50-70 parts of casein, 220 parts of 160-grade soybean meal, 55-70 parts of strong flour, 60-80 parts of fish oil, 25-35 parts of soybean lecithin, 15-25 parts of mineral premix, 15-25 parts of vitamin premix, 8-12 parts of phagostimulant, 1-6 parts of bile acid and 5-10 parts of taurine.

5. The method according to any one of claims 1 to 3, wherein the juvenile fish feed for the early stage of growth and development is prepared from the following raw materials in parts by weight:

410 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 210 parts of soybean meal, 60 parts of high gluten flour, 40 parts of fish oil, 20 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 8 parts of bile acid and 2 parts of taurine.

6. The method according to any one of claims 1 to 4, wherein the juvenile fish feed for the later stage of growth and development is prepared from the following raw materials in parts by weight:

390 parts of fish meal, 140 parts of rice protein powder, 60 parts of casein, 190 parts of soybean meal, 60 parts of high gluten flour, 70 parts of fish oil, 30 parts of soybean lecithin, 20 parts of mineral premix, 20 parts of vitamin premix, 10 parts of phagostimulant, 3 parts of bile acid and 7 parts of taurine.

7. The method according to any one of claims 4 to 5, wherein the feed is prepared by a method comprising the steps of:

(1) the material preparation step: weighing other raw materials except the vitamin premix, the fish oil and the phagostimulant according to the weight parts, and putting the raw materials into a mixer to be uniformly mixed for 30-60 s;

(2) a granulation step: putting the uniformly mixed material obtained in the step (1) into a granulator for granulation, and pre-cooling by adjusting the air intake to reduce the temperature of a puffing cavity to below 65 ℃;

(3) post-spraying: spraying vitamin premix, adjusting the limit vacuum value to 15mbar, controlling the temperature to be 34 ℃, and avoiding the expansion and inactivation of the vitamin; spraying fish oil, adjusting the limit vacuum value to be 18mbar, controlling the temperature to be 46 ℃, spraying oil for 4 minutes, and standing for 15 minutes after spraying; and finally spraying a phagostimulant, adjusting the limit vacuum value to be 12mbar, and controlling the temperature to be 26 ℃.

8. A feed for regulating and controlling the liver health of micropterus salmoides is characterized in that,

for juvenile fish in the early stage of growth and development, the feed has the protein content of 50-55 percent and the fat content of 9-11 percent, and contains 0.5-0.9 percent of bile acid and 0.1-0.5 percent of taurine in mass ratio of the feed;

for juvenile fish in the later stage of growth and development, the feed has the protein content of 47-52 percent and the fat content of 13-15 percent, and contains bile acid accounting for 0.1-0.6 percent of the mass ratio of the feed and taurine accounting for 0.5-1.0 percent of the mass ratio of the feed.

9. The feed of claim 8,

when the juvenile fish is in the early stage of growth and development, the feed is prepared from the following raw materials in parts by weight:

380 portions of fish meal, 160 portions of rice protein powder, 40-80 portions of casein, 240 portions of bean pulp, 40-80 portions of strong flour, 30-50 portions of fish oil, 10-25 portions of soybean lecithin, 15-25 portions of mineral premix, 15-25 portions of vitamin premix, 7-15 portions of phagostimulant, 5-9 portions of bile acid and 1-5 portions of taurine;

when the juvenile fish is in the later stage of production and development, the feed is prepared from the following raw materials in parts by weight:

420 parts of 370-grade fish meal, 150 parts of 120-grade rice protein powder, 50-70 parts of casein, 220 parts of 160-grade soybean meal, 55-70 parts of strong flour, 60-80 parts of fish oil, 25-35 parts of soybean lecithin, 15-25 parts of mineral premix, 15-25 parts of vitamin premix, 8-12 parts of phagostimulant, 1-6 parts of bile acid and 5-10 parts of taurine.

10. The feed according to claim 8 or 9, characterized in that it is prepared by a process comprising the following steps:

(1) the material preparation step: weighing other raw materials except the vitamin premix, the fish oil and the phagostimulant according to the weight parts, and putting the raw materials into a mixer to be uniformly mixed for 30-60 s;

(2) a granulation step: putting the uniformly mixed material obtained in the step (1) into a granulator for granulation, and pre-cooling by adjusting the air intake to reduce the temperature of a puffing cavity to below 65 ℃;

(3) post-spraying: spraying vitamin premix, adjusting the limit vacuum value to 15mbar, controlling the temperature to be 34 ℃, and avoiding the expansion and inactivation of the vitamin; spraying fish oil, adjusting the limit vacuum value to be 18mbar, controlling the temperature to be 46 ℃, spraying oil for 4 minutes, and standing for 15 minutes after spraying; and finally spraying a phagostimulant, adjusting the limit vacuum value to be 12mbar, and controlling the temperature to be 26 ℃.

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