KR101443851B1 - Production system and method for seed of prawn - Google Patents

Abstract

The present invention provides a system and a method for increasing the productivity of prawn seed by raising survival rates of initial larvae of prawn seeds. Prawn larvae can be collected and fed by using the production system of the prawn according to the present invention, which increases the number of larvae for producing prawn by mother shrimps facilitating the hatch of the prawn, secures excellent prawns by strengthening growth and the components in the body and increases the survival rate, leading to effective use in the shrimp farming industry.

Description

PRODUCTION SYSTEM AND METHOD FOR SEED OF PRAWN OF SHRIMP SEEDS

The present invention relates to a shrimp seed production system and a production method.

Various types of shrimp have been widely cultivated all over the world including the Pacific coast and Asia. In Korea, for the first time, about 100 tons have been produced in private farms in 2004, and the annual production has increased to 500 annual festival farms It is becoming a major aquaculture variety producing 3,000 tons.

In the past, shrimp farming methods have been developed by putting the seedlings directly into farms. As a result of the increase in the stress of the larvae, which are less adaptive to the environment, the mortality rate in the first month reaches 20%. This increases the possibility of mass mortality And is a major factor in the decrease in productivity due to a decrease in survival rate.

In addition, studies on the methods of breeding most shrimp have been carried out mainly on shrimp that live in the shrimp family of the barley shrimp, which is mainly located on the west coast. Even this is the case of mass mortality caused by infectious disease and water quality destabilization at the larval stage And low productivity. In addition, when the larvae live in the same way as the shrimp of the barley shrimp, it is appropriate to supply floating food such as rotifers and alteamia. However, the shrimp and shrimp living in the benthos have not been supplied with food It is difficult to secure a high survival rate, and the shrimp and shrimp have a rapid release period. However, the shrimp of the shrimp that live in bamboo life is about 3 ~ 4 months until it grows to about 1.5 cm, There is a great difficulty in using the shrimp culture method or the seed production method. Therefore, there is a continuous need for research on production methods and production systems capable of securing seedlings through breeding and larval rearing of shrimp with benthic life characteristics in the coastal habitat mainly on the east coast.

Therefore, the present invention is required in the whole aquaculture industry in order to increase the survival rate of early larvae of shrimp and to increase the yield.

KR 20100091989A

In order to solve the problems of the prior art, the present invention is to provide a shrimp seed production method and a production system capable of increasing the survival rate of an early larval stage of shrimp to increase production of shrimp seeds.

In order to accomplish the above object, the present invention provides a fish tank, A frame located inside the breeding water tank and having holes through which larvae can move; A first region inside the breeding tank; A second region inside the frame, and a structure provided so that larvae located in the first region can adhere to and hide from the shrimp seedling production system.

Also, the present invention provides a method for producing a shrimp including shrimp seedling production including a parent shrimp management step for feeding the parent shrimp to promote the hatching of the larvae, a structure provided for allowing the larval to adhere and hiding, ≪ / RTI >

Unless otherwise specified in the specification of the present invention, 'prawn (shrimp)' is a generic term for animals belonging to the deciduous shrimp subspecies, and refers to individuals who have reached the adult period, which is distinguished from the larvae of the shrimp. Also, among the above shrimp, an individual having an egg is referred to as a parent shrimp or Mohara.

Unless otherwise stated in the specification of the present invention, the term 'seed' refers to a fish species that is used as a form of fish, such as fry, gardenia, dementia, fluids or larvae, And aquatic organisms that are used for water. Also, 'seed production' is also called seed rearing. It means to nurture or breed marine life that is the basic of the culture, and it means to include both natural seedling and artificial seedling production.

Unless otherwise specified in the specification of the present invention, "larvae" are young individuals of a living organism, and are predominantly different in morphology from adult to adult in the development of multicellular animals, , And the term " shrimp " means the shrimp larva in the specification of the present invention.

Hereinafter, the present invention will be described in more detail.

The present invention relates to a shrimp seed production system, comprising: a breeding tank; A frame located inside the breeding water tank and having holes through which larvae can move; A first region inside the breeding tank; A second region inside the mold; And a structure in which the larvae located in the first region are provided so as to be able to hide; .

The shrimp preferably includes shrimp belonging to the shrimp family, and the shrimp belonging to the shrimp family has the characteristic of living a bamboo life as a stable shrimp. Examples of shrimp belonging to the shrimp family include the north pink shrimp, southern prawn shrimp, northern prawn shrimp, prawn shrimp, mollusk red prawns, long-tender prawns, spotted prawns and narrow scaled prawns.

The larva means preferably a juvenile of a shrimp, and preferably a juvenile of a shrimp belonging to a zoea stage to a later larval stage. The shrimp larvae are transformed into the zoea stage, the Mysis stage, and the post-larvae stage, which are stages immediately after hatching of eggs, And the second stage (Z2). In the present invention, the shrimp seedling preferably refers to a young shrimp, i.e., a subspecies, of the late stage stage, which has been transformed from the M stage to the late stage.

The larvae of shrimp are high in mortality rate. Especially, the larvae of shrimp in shrimp that live benthic life are longer compared to the larvae of shrimp and barley shrimp, Systems and methods are needed to increase production

The shrimp seed production system comprises a breeding tank (1); A frame 2 located inside the breeding water tank and having holes through which larvae can move; A first zone (10) inside the breeding tank; A second region (20) inside the mold; And a structure (3) located in the first area and provided so that the larva can hide.

The first region 10 refers to the inside of the breeding water tank and specifically includes the upper part of the breeding water tank where the mold 2 is located and the lower part of the breeding water tank where the silver credit structure 3 is located. The first region may be filled with breeding water, and the shrimp may be placed to produce breeding and shrimp seedlings.

The second region 20 refers to the inside of the frame located inside the breeding water tank. In the production of the shrimp seedlings, when the mother shrimp is placed in the inner side (20) of the frame, the larvae hatching from the mother shrimp are moved to the first area and the larvae are raised in the space separated from the mother shrimp, It is possible to efficiently produce shrimp seedlings by improving the survival rate of the larvae.

The breeding water tank 1 is not limited to the size, material, or shape as long as it is a water tank filled with breeding stock and capable of producing shrimp seeds.

For example, the shape of the breeding tank may be cylindrical, but when it is formed into a cylindrical shape, the water flow and formation of water flow are improved, thereby improving the efficiency of the breeding. The breeding water tank 1 may have a diameter of 7 times or more, preferably a diameter-height ratio of 7: 1 to 15: 1 with respect to the height of the cylinder. For example, the breeding tank may have a diameter of 4 m or more and a height of 50 cm or more. The material of the breeding tank may be, for example, concrete or high density polyethylene (HDPE).

The breeding water tank may further include a breeding water inlet 4 and a breeding water outlet 5 and may further include an on-off valve 6 connected to the inlet or outlet. The catching water inlet 4 and the catching water outlet 5 may be in the form of a filter net or a filtering net to prevent discharge of living creatures and to prevent contamination of the pollutants and deterioration of water quality.

The mold (2) is formed with a hole through which the larvae can move, and the movement of the larvae is transmitted through the hole to the first region which is outside the second region which is the inner side of the frame, It means moving to the first area. The mold 2 may preferably be at least partially open, and more preferably, the portion facing the vertical direction may be open. The hole formed in the frame 2 may be formed in a regular or irregular shape, and may be preferably a network structure, and the average length of one side of rhombus of the network structure is 5 mm to 10 mm Lt; / RTI > When the frame having the holes is used, the shrimp larvae hatched from the parent shrimp breeding in the second region 20 are moved to the first region 10 through the holes, and the larvae and the shrimp are separated and raised, The survival rate can be improved and shrimp seedlings can be efficiently produced.

 The structure 3 is provided so that the larvae can hide, and can be located in the first area, and preferably in the lower part of the first area. Shrimp larvae, especially benthic living shrimp larvae, can survive attached to structures by structures, which can improve the survival rate.

The structure 3 can be used without limitation as long as it can adhere to the shrimp larva. In a preferred form, the structure 3 includes a brush shape in which fibers are radially fixed on the central axis, a blanket in which the fibers are woven, A pump shape forming a bundle shape, and a combination thereof, and most preferably, a brush shape structure can be used. When a brush-shaped structure is provided as a hideout, the larvae can enter the brush-shaped structure, thereby securing the activity space of the larvae, thereby increasing the survival rate in breeding.

The central axis can be used without restriction as long as it is not deformed in water and can fix the fibers, and preferably stainless steel can be used. The fibers are preferably synthetic fibers, more preferably polyamide fibers, polyethylene fibers, polyvinyl alcohol fibers, and combinations thereof. Fibers can be used, and polyethylene fibers can be most preferably used.

In the brush-type structure, the length of the fiber and the distance between the fixed fibers can be connected uniformly or nonuniformly, and various lengths, intervals, and gaps in the fiber are included together can do.

The structure 3 may be placed in a lower part of the inside of the breeding tank, or may be located in a fixed form, and may be a single layer or a multi-layer structure of two or more layers.

When the above shrimp seed production system is used, it is possible to breed and nurture the larvae and shrimp of the shrimp in a separate space, so that the survival rate of the shrimp larvae, which has a high mortality rate during the breeding stage, can be improved.

The shrimp seed production system of the present invention is not limited to the embodiments and drawings described below, but may be applied to a range of applications to those skilled in the art to which the present invention belongs.

The present invention also relates to a method for producing shrimp seedlings, which comprises providing a shrimp shrimp management step for feeding the shrimp with food and promoting the hatching of the larvae, and providing a structure for allowing the larval hiding, Includes breeding stages.

The feedstock may be one selected from the group consisting of gut, artemia, feed, and combinations thereof obtained from the food clam.

The feeding of the larvae is based on the dry weight of the food and the volume of the tank, from 0.002 g / L / day to 0.02 g / L / day for the day after hatching (1 day after hatching) L / day to 0.03 g / L / day, from 16 days after hatching, to 16 days after hatching, and preferably from 0.006 g / L / day to 0.009 g / From day 0, the larvae can be fed by feeding 0.015g / L / day to 0.0025g / L / day.

The artemia includes all of the larvae hatching from the eggs of animals belonging to the genus Artemia, and egg shells can be preferably used as food. When the artemia is fed as food, it can be supplied together with artemia and mixed with different kinds of biological feeds, and it can be provided by mixing with additives for biological feed, excipients, suspensions, emulsifiers or biological feeds have.

The feeds include all those manufactured or marketed for breeding or cultivation of shrimp, and may be used without limitation to the components and the form thereof as long as they are used for the growth of crustaceans or shrimp.

The gut contains all that is obtained from the clams, and preferably can feed the flesh obtained from the clams which can be used for edible purposes. In particular, the gorges obtained from clams belonging to the lily family can be fed as food. The hamburger may be mixed with a different kind of biological feed, and may be provided by mixing with an additive for biological feed, an excipient, a suspending agent, an emulsifying agent or a biological feed.

The shells may be, for example, clams, shortnecked clams, cockles, surf clams, mussels, arctic shells, Arca avellana Lamarck , scallop, Meretrix lusoria , (eg, Arsh shell, Scapharca broughtonii ), Mynar shell, Mya arenaria , Rhododendron shell, Dish shell, Saxidomus purpuratus , and combinations thereof.

The feeding of the prey in the step of controlling the shrimp can be preferably carried out with a feed rate of 0.1 g / L / day to 0.5 g / L / day based on the dry weight of the food and the volume of the breeding tank, Can be supplied at 0.13 g / L / day to 0.25 g / L / day. In the case of parent shrimp, it does not require additional energy for hatching. However, when feeding the shrimp with eggs, the number of larvae hatched from parent shrimp is significantly increased, effectively securing larvae for seedling production, Increase the intramuscular RNA content of the parent shrimp to promote hatching of the larvae.

The feeding of the larvae in the larval stage may be carried out by feeding the larvae of the larvae, and when the larvae are fed with the larvae, the total length and the length of the larvae are long, (Wet weight) is the highest, and the survival rate (%) is excellent. Since the DNA content and RNA / DNA ratio in the body are high, excellent shrimp seeds can be produced. Feeding the larvae in the larval stage may be carried out by laying the barnyard on the bottom of the breeding tank.

The feeding of the gill can be controlled by feeding the size of the gill in a self-evident range according to the growth stage of the gill. For example, in the early gill stage, the gill can be used to feed the gill, It can be supplied in a mixed state. In consideration of the variety of sizes in the water tank, it is possible to mix and supply small sized crushed granules and large sized granules.

In the production method of the present invention, when feeding the gilts with food, it is possible to prevent the food from being deteriorated and contaminated due to floating in the water tank, such as artemia or compound feed, It is effective to improve the yield and quality of shrimp seedlings by making it easy to secure the food.

 In one embodiment of the present invention, the effect of increasing the production of shrimp seedlings and improving the quality of the seedlings was confirmed by feeding the shrimp from shrimp to shrimp or larvae.

The larval rearing step may be carried out by a method of providing a structure in which larvae can attach and hide. When the above-mentioned structure is provided to nurture the larvae, the nurse can live in the form attached to the structure, thereby increasing the amount of the nursery produced by placing the larval rearing density in the same rearing tank. In particular, The yield of larvae can be improved when producing seedlings.

The method of producing a shrimp seedling of the present invention may further include a step of separating the larvae hatching from the parent shrimp between the parent shrimp management step and the larval rearing step to a region separated from the parent shrimp. The survival rate of larvae can be increased by separating and cultivating the shrimp larvae and adult.

In the production of shrimp seedlings, it is possible to increase the number and hatching of larvae by feeding the parent shrimp, to improve the survival rate of larvae through separation of larvae and adults, The survival rate of the larvae can be increased and the quality of the shrimp seedlings produced can be improved and the quality and quantity of shrimp seedlings can be produced.

The method of producing the shrimp seedling of the present invention can be carried out using the shrimp seed production system. More specifically, the shrimp seedling production system can feed the parent shrimp in the second region 20, which is the inner side of the mold 2, A shrimp management step to promote the shrimp; A larvae separation step of moving the hatched larvae to a first region 20 inside the breeding tank 1 through holes formed in the frame 2; And a structure (3) provided in such a manner that the larva can attach and hide in the first area, and feeding the larvae. When producing the shrimp seeds according to the production method of the present invention using the shrimp seed production system, quality and quantity of shrimp seeds can be produced.

When collecting and raising the larva of the shrimp using the shrimp seed production system according to the present invention, it is possible to increase the number of larvae for producing the seedlings by promoting the hatching of the shrimp, and to enhance the external growth of the larva and the body components Thus, it is possible to secure a superior quality seedling and increase the survival rate, so that it can be effectively used in the shrimp farming industry.

1 is a schematic diagram of a shrimp seed production system of the present invention.
FIG. 2 is a graph showing the results of confirming the effect of feeding the food in the step of controlling the shrimp in an embodiment of the present invention. FIG. 2a shows the number of hatched larvae according to the feeding of food, Figure 2b shows the intramuscular RNA / DNA ratio of the parent shrimp according to the feeding, and the Y axis of the graph shows the muscle of the parent shrimp (ind./shirimp), and the axis X shows the elapsed time RNA / DNA ratio, X-axis represents the food supply group, and the food supply group (Non).
FIG. 3 is a graph showing the results of confirming the effect of the food type in the larval rearing step in the embodiment of the present invention, wherein the X axis is a treatment group according to the kind of food, AR is artemia treatment group, Group, AD means compound feed treatment group. FIG. 3A is a graph showing the difference in the total length of larvae according to the type of food. FIG. 3B is a graph showing the difference in the length of the larvae according to the type of food. FIG. 3C is a graph showing the difference in wet weight of larvae according to the type of food, Y axis indicates the wet weight (mg) of the larvae, FIG. 3D shows the survival rate . The Y axis represents the survival rate (%) of the larvae.
FIG. 4 is a graph showing the results of confirming the effect of feeding on the larval stages in the embodiment of the present invention. In FIG. 4, the X axis is the treatment group according to the kind of food, AR is artemia treatment group, Group, AD means compound feed treatment group. FIG. 4A is a graph showing the difference in RNA content of larvae according to the type of food. FIG. 3B is a graph showing the difference in the DNA content of larvae according to the type of food 4d is a graph showing the difference in RNA / DNA ratio of larvae according to the type of food, and the Y axis indicates the RNA / DNA ratio of the larvae. .
FIG. 5A is a graph showing the type of attachment and silver credit structures in accordance with an embodiment of the present invention, FIG. 5B is a graph showing a degree of attachment of larvae according to types and types of silver credit structures, (X-axis), x-axis (x-axis) and x-axis (x-axis) PB represents the blue surgical type structure providing group, PY represents the yellow type surgical structure providing group, and VB represents the black light shielding type providing structure group.

Hereinafter, the present invention will be described in more detail with reference to the following examples. However, the scope of the present invention is not limited to the following examples in accordance with the gist of the present invention.

Example 1. Design of a system for shrimp seed production

In order to secure a system suitable for the production of shrimp seeds, a production system was prepared and used as shown in Fig.

The 30L water tank is fixed to the upper part of the breeding tank using a basket as a frame to promote hatching of the larva from the hatching and the larvae hatching through the mesh-shaped holes formed in the basket are moved to the lower part of the breeding tank, It is designed so that it can be raised independently.

The water tank was filled with 25 liters of water for breeding, and the water was supplied at 8 ° C (water flow rate: 1 L / min) to maintain the temperature. The following experiment was conducted.

Example 2. Confirmation of Influence of Feeding in the Mohr Stage

In order to obtain larvae for the production of shrimp seeds, the influence of feeding conditions on the hatching rate of larvae was examined in the control stage of shrimp (shrimp).

Among the matured individuals of mulberry red shrimp collected in the nearby waters of Yangyang and Nanae areas in Gangwon province, which were used for the experiment, the average weight was 30g, the estimated age ranged from 3 to 5 years, and yellow and orange or pinkish- Respectively. A 30L water tank was filled with 25 liters of water and maintained at a temperature of 8 ° C with a flow rate of 1 L / min. Twelve small shrimp red prawns were housed in aquaculture, divided into feeder groups supplying food to the mother and non-feeding groups not feeding the food. Was supplied at 5 g / 30 L / day. The RNA / DNA ratios in the larval hatching and parental muscle of each treatment group were measured to determine the effects of feeding the larvae in the brood stage.

The results of the measurement of the number of hatched larvae are shown in FIG. 2A, and the results of measuring the intramuscular RNA / DNA ratio of the fetuses are shown in FIG. 2B.

As shown in FIG. 2A, in the group feeding the feed, hatching of larvae started from the next day of feeding, and a large amount of larvae hatches on the 2nd and the 3rd day after the hatching, and all the larvae hatch and survive on the 13th day after the hatching Respectively. On average, the number of hatched larvae on the 14th day after storage was 285 per bird. However, the average number of larvae hatched on the 14th day in the feeding group was 15 per bird. The number of larvae fed from the 14th day of feeding was measured again. As a result, the number of larvae hatched from the day after feeding was increased, and the number of hatched larvae on the third day after feeding was averaged It was 65 per bird, and on average, it was 185 per bird.

As shown in FIG. 2B, the intramuscular RNA / DNA ratio of the rabbits was 20% higher ( P <0.05) in the feed group fed with clam meat than in the feed fed group. The high content of intramuscular RNA means that the cell viability of the individual is high. When the feed is fed in the breeding stage, the cell viability of the breeding is increased and the hatching of the larvae is promoted. Respectively.

From the above results, it was confirmed that feeding the shrimp larvae in the broodstock increases the hatching rate of the shrimp larvae, and the following experiment was conducted to confirm the growth conditions of the larvae hatched from the broodstock.

Example 3-1. Identification of the effect of food species on larval survival

In order to supply effective food for larval growth, larval length, taste field, wet weight and survival rate of larvae were determined according to the type of food.

A 30L water tank was filled with 25 liters of water, and 8 Â ° C water was supplied at a flow rate of 1 L / min. The treatment groups were divided into two groups: treatment group 1 (treatment group 1), nutrition-enhanced artemia treatment group 2 (treatment group 2), and shrimp feed treatment group 3 (treatment group 3, (DW) of 0.2g / 30L / day for each of the diets and 0.6g / 30L / day for 16 days after hatching (Table 1). On the 46th day after hatching, the battle field, taste field, wet weight and survival rate of the red mullet larvae were measured, and the results are shown in Fig.

Kinds Moisture content
(weight%) Feed supply (DW g / day) 0 - 15 days 16 - 45 days Treatment group 1 The gangbang (CM) 81.1 ± 1.14 0.2 0.6 Treatment group 2 Artemia (AR) 86.9 ± 0.15 0.2 0.6 Treatment group 3 Shrimp feed (AD) 8.6 ± 0.16 0.2 0.6

As shown in FIG. 3A, the total length of larvae was 10.2 mm in the artemia treatment group and the crude egg treatment group, respectively, and longer than the total length of 9.5 mm in the compound feed treatment group. As shown in FIG. 3B, the average length of the uropod length was 2.2 mm in the crude egg treatment group, which was longer than that in the artemia treated group and the mixed feed treated group. As shown in FIG. 3C, the wet weight was the highest at 13.3 mg / ind. In the group treated with crude protein, and the lowest at 9.5 mg / ind. In the group treated with compounded feed. As shown in FIG. 2d, the survival rate (%) of the larval-treated larval was 60%, which was about twice as high as the survival rate in the artemia treated group (35%) or the artificial feed treated group Respectively. Therefore, it was confirmed that it is more effective for the growth of larvae when used as a prey.

Example 3-2. The RNA / DNA ratio of the larvae,

In order to confirm the influence of the feeding type on the larval rearing, the RNA, DNA content and RNA / DNA ratio of each of the vernacular vertebrate larvae raised in the same conditions as in Example 2-1 were checked, The results are shown in Fig. In each treatment group, the protein content per individual was the same as 0.14 mg / ind.

As shown in FIG. 4A, the RNA content of the larvae of the larvae treated with the larvae was the highest at 0.10 ug / ind., And the DNA content of the larvae of the larvae was 3.6 ug / ind., As shown in FIG. 4b. As shown in FIG. 4c, the ratio of RNA / DNA was 0.028 in the group treated with ham and the highest in the group treated with artemia and mixed feed. Therefore, it was confirmed that it is more effective for the growth of larvae when used as a prey.

Example 4 confirms the degree of breeding of larvae according to the types of credit structures

In order to confirm the effect of the type of shelter provided at the larval stage on the growth of larvae and the density of the larvae, the breeding conditions were the same as those of Example 3-1, . The control group (Non), the plastic shading group (VB), the yellow tanning group (PY), the black tanning group (PB), the green tanning group (PG) (Fig. 5a), and after 48 hours from the start of breeding, the number of adhering larvae (ind./400 cm ² ). The results are shown in Fig. 5B.

As shown in FIG. 5B, the lowest adhesion density was obtained at an adhesion density of 17.0 ind./400 cm ² when the hide was not used, and 120.7 ind./400 cm ² showed the highest adhesion density. Therefore, it was found that the density of the larvae was higher when the hiding place was provided, so that the breeding density could be increased. In particular, it was confirmed that providing the brush type silver credit structure was the most efficient to breed larvae and produce seedling.

1: Breeding tank 10: First area
2: frame 20: second region
3: Silver Credit Structure
4: Breeding water inlet
5: Breeding water outlet
6: opening / closing valve

Claims (8)

Breeding tank;
A first region inside the breeding tank;
A frame having a mesh-shaped hole located at an upper portion of the first region and having an average length of one side of the rhombus from which the larvae can move is 5 mm to 10 mm;
A second region inside the mold; And
A brush-shaped structure disposed below the first region and having polyethylene as a central axis, the stainless steel being installed to allow the larva to attach and hide; A shrimp production system of shrimp and shrimp. delete The method according to claim 1,
Wherein the shrimp belonging to the shrimp family is any one selected from the group consisting of northern pink shrimp, southern prawn shrimp, northern prawn shrimp, prawn shrimp, vermiculite red shrimp, long-necked shrimp, spotted shrimp, and narrow- Seedling production system of shrimp and shrimp. The method according to claim 1,
Wherein the frame is at least partially open. delete delete A method for producing seedling of shrimp and shrimp using the seedling production system of shrimp and shrimp according to claim 1,
A mother shrimp management step of feeding a mackerel to a mother shrimp located in a second area inside the frame to promote hatching of the larva; And
There is provided a method of manufacturing a bird's nest, comprising the steps of: providing a structure in the form of a brush in which polyethylene fibers are radially connected with stainless steel, Production method of shrimp and shrimp. 8. The method of claim 7,
In the step of controlling the shrimp, the crude shrimp is fed to the shrimp in an amount of 0.13 g / L / day to 0.25 g / L / day based on the dry weight of the shrimp and the volume of the breeding tank,
The larval rearing step was performed at a rate of 0.006 g / L / day to 0.009 g / L / day for 1 day after hatching and 15 days after hatching, and 0.015 g / L / day to 0.0025 g / L / day for 16 days after hatching And the method for producing seeds of shrimp and shrimp.

Images