KR101183123B1 - Method for inoculation of cordyceps militaris seed mushroom to silkworm, and method for cultivation of cordyceps militaris using the same - Google Patents

Abstract

The present invention relates to a method of inoculating Cordyceps spp. On a silkworm pupa and a method of cultivating Cordyceps sinensis using the same.
The inoculation method of Cordyceps sinensis in the silkworm pupae of the present invention comprises the steps of containing the Cordyceps Sinensis liquid seed in a container; It comprises a step of immersing the silkworm pupa to the Cordyceps liquor seedlings contained in the container; and after closing the container, the process of pressurizing to penetrate the Cordyceps pulp liquid seed to the silkworm pupa.
According to the present invention, while the existing cultivation process of Cordyceps sinensis can be obtained by the advantage of reducing labor and productivity, while the year-round cultivation silkworm pupae inoculation method of Cordyceps fungi seedlings and methods of cultivating Cordyceps sinensis using the same are provided.

Description

METHODS FOR INOCULATION OF CORDYCEPS MILITARIS SEED MUSHROOM TO SILKWORM, AND METHOD FOR CULTIVATION OF CORDYCEPS MILITARIS USING THE SAME}

The present invention relates to an inoculation method of Cordyceps spp. Which easily inserts Cordyceps spp. Into silkworm pupa through a pressurizing method, and a method of easily cultivating Cordyceps spp. Using the same.

In general, Cordyceps sinensis is a kind of medicinal mushroom derived from insects based on insects, which is a kind of filamentous fungus, and is known to grow mainly in China, Nepal, Japan, South America, and Korea.

The path of inoculation of Cordyceps influenza depends mainly on the transdermal inoculation, which occurs when conidia spores scatter and adhere to the epidermis. When spores adhere to the epidermis and meet conditions such as temperature and humidity, they germinate to penetrate the epidermis of the insect. In the mycelial growth of the body, after the death of the insect mycelium forms the fruiting body on the epidermis of host insects.

Fruiting bodies form 1.5 ~ 10cm sized filamentous, club-shaped, cylindrical, etc., consisting of the diseased part and the fruiting part of the tip. The color of the fruiting body varies from species to cordyceps.

Cordyceps sinensis, which has the same physiological and ecological characteristics as above, has been the subject of much interest and research today because of its pharmacological effects on various diseases.

For example, in China, Cordyceps sinensis has been widely known as a elixir of firemen and has been preferred as a valuable medicine for protecting the lungs and strengthening the kidneys. Cordyceps sinensis, including Azibongbongcho, has been reported to be effective in a wide range of diseases by species.

According to recent research results from China and Japan, Cordyceps sinensis contains components that enhance immune function. When Cordyceps sinensis extract is administered to the human body, it significantly enhances immune function by promoting cellular immunity and humoral immunity, thereby preventing various tumor and virus infections. It appeared to be effective in increasing the resistance to.

In addition, Cordyceps sinensis has a very wide field of use because it is effective in relieving fatigue quickly when there is a lot of physical strength due to severe exercise and in relieving stress of those who work mentally.

There are about 300 species of Cordyceps sinensis that show various effects, and a large number of species are known to show different efficacies. Therefore, they are expected to be a raw material of natural medicines, but they are smaller than other mushrooms and medicinal plants. Its distribution density is also low, making it difficult to find and collect in outdoor mountains, and it is not only able to secure the mass demand but also the absolute amount necessary for various studies such as drug search and clinical trials.

Therefore, active research on the artificial cultivation method of cordyceps is underway by understanding the types of cordyceps, host insects, inoculation pathways, fruiting body formation conditions, etc., and further understanding the characteristics of caterpillars.

However, in the existing researches, spraying the inoculation to the host by inoculating the spores to inoculate the spores in the production of cordyceps, this method consumes manpower in the process of separating the inoculated host from the surrounding wind, respectively. There is a problem that requires a separate inoculation room.

And, there is a problem that the surrounding air pollution due to the spray is generated, the time consumption caused by the spray is generated.

An object of the present invention is to provide a method for inoculating Cordyceps spp. Which can easily inoculate Cordyceps spp.

In addition, another object of the present invention is to provide a cordyceps cultivation method that can increase the productivity by simplifying the method of cultivating cordyceps through the inoculation method.

In order to achieve the above object, the inoculation method of Cordyceps sinensis seedlings in the silkworm pupae of the present invention comprises the steps of containing the Cordyceps Sinensis liquid seed in a container; It comprises a step of immersing the silkworm pupa to the Cordyceps liquor seedlings contained in the container; and after closing the container, the process of pressurizing to penetrate the Cordyceps pulp liquid seed to the silkworm pupa.

In the immersion step, the silkworm pupae is immersed in Cordyceps sinensis liquid seed for 0.5 to 3 minutes.

In the step of penetrating, the pressure of the press is characterized in that 0.5 ~ 2㎏ / ㎠.

Cordyceps cultivation method of the present invention comprises the step of cultivating cordyceps through silkworm pupae inoculated with the cordyceps fungi spawn.

According to the present invention, the existing cultivation process of Cordyceps sinensis can be simplified to obtain the advantages of labor and productivity increase.

In addition, by improving the existing cultivation process of Cordyceps sinensis can also obtain the advantage that can be grown year round.

1 is a view showing the overall configuration of the device used when inoculating silkworm pupae with Cordyceps fungi in the present invention.
Figure 2 is a view showing in sequence the method of inoculating Cordyceps sinensis spawn to the silkworm pupae of the present invention through the apparatus of Figure 1;
Figure 3 is a photographic diagram showing up to fruiting body formation from Cordyceps sinensis seed inoculation state of the present invention silkworm pupa.
Figure 4 is a graph showing the inoculation rate of Cordyceps sinensis spawn according to immersion time under no pressure.
5 is a graph showing the cordyceps fruiting body formation rate of silkworm pupae by immersion time in a non-pressurized state.
Figure 6 is a graph showing the inoculation rate of Cordyceps sinensis spawn according to the pressing conditions.
Figure 7 is a graph showing the fruiting body formation rate of Cordyceps sinensis pupa according to the pressing conditions.
Figure 8 is a graph showing the inoculation rate of Bacillus silkworm chrysalis under pressure conditions.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The same elements in the drawings are denoted by the same reference numerals wherever possible, and detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

Example 1 Inoculation Method of Cordyceps Sinensis on Silkworm Pupa

In the present invention is a view showing the overall configuration of the device used when inoculating silkworm pupa with Cordyceps fungi.

Referring to FIG. 1, the apparatus used in the present invention includes a container 10 capable of pressurizing and a pressurizing device 20 for pressurizing the inside of the container 10.

The container 10 is formed so as to contain the Cordyceps sinensis liquid seed 30 inside, the outer side of the container 10 is formed with a connecting portion 11 is connected to the pressurizing device 20 to apply an internal pressure.

Using the thus formed device was carried out a method of inoculating Cordyceps sinensis spawn to the silkworm pupa of the present invention as follows.

Figure 2 is a view showing in order how to inoculate Cordyceps sinensis spawn to the silkworm pupae of the present invention through the above apparatus.

Specifically, the Cordyceps sinensis liquid seed 30 is contained in the container 10 and immersed by adding silkworm pupa 40 to it.

Then, after the container was sealed, pressurization was carried out through the pressurizing device 20 to infiltrate the Cordyceps pulp liquid seed 40 into the silkworm pupa 40 to inoculate the Cordyceps pulp spawn to the silkworm pupa.

Example 2 Cultivation Method of Cordyceps sinensis after Inoculation of Cordyceps Sinensis to Silkworm Pupa

As shown in FIG. 3 (1), silkworm pupae 2 days after the inoculation of Cordyceps sinensis seed was collected through Example 1.

As shown in FIG. 3 (2), it was confirmed that the mycelia of Cordyceps spp. Were formed on the silkworm pupae on the 5th day of inoculation.

As shown in FIG. 3 (3), it was confirmed that the mycelium was developed at 7 days of inoculation.

As shown in FIG. 3 (4), it was confirmed that fruiting bodies were formed at 10 to 15 days of inoculation.

Fruiting bodies formed as described above were grown in the culture chamber to grow Cordyceps sinensis.

Experimental Example 1 Measurement of the Inoculation Status of Cordyceps Sinensis on Silkworm Chrysalis During Dipping

1. Experimental Method

By dipping the silkworm pupae in the fungus liquid spawn (1 × 10 ⁸ / ml) to the pressureless state to determine the state of the inoculated seed fungus radish abscisic immersion time silkworm pupae it was performed this experiment.

Immersion time conditions of this experiment are described in Table 1 below.

Processing time
(minute) Reaction during immersion Processing result Immediate Vibration reaction (light), fine after infiltration proper 0.5 Vibration reaction (light), fine after infiltration proper One Vibration reaction (light), fine after infiltration proper 2 Vibration reaction (light), fine after infiltration proper 3 Vibration reaction (light), fine after infiltration fitness 4 Vibration reaction (medium), fine movement decrease after infiltration incongruity 5 Vibration reaction (medium), fine movement decrease after infiltration incongruity

2. Experimental results

As a result of the experiment, Cordyceps sinensis inoculation rate of silkworm chrysalis as shown in Figure 4 was confirmed that the good appears to 80 ~ 92% regardless of the immersion time.

However, as shown in FIG. 5, the fruiting body formation rate was mostly lower than the inoculation rate, and the fruiting body formation rate was the highest at 55% without damage to the silkworm pupa surface during the 2-minute immersion treatment.

The lower fruiting rate compared to the inoculation rate is thought to be the result of the Cordyceps spp. Attached to the surface of the silkworm chrysalis rather than penetrating into the interior of the silkworm chrysalis.

In addition, silkworm pupae immersed in the Cordyceps spp. For more than 4 minutes occurred before the fruiting body was formed, which is believed to be caused by physical stress on the silkworm pupae.

Therefore, it can be seen that the most suitable immersion time for inoculating Cordyceps sinensis in the silkworm pupae is 0.5 to 3 minutes.

<Experiment 2> Inoculation of Cordyceps sinensis spawn seed and fruiting body formation state of Cordyceps sinensis by pressure treatment

1. Experimental Method

In order to confirm the inoculation status of Cordyceps sinensis seedlings and the fruiting body formation state of Cordyceps sinensis, the experiments were carried out by immersion of silkworm pupae in Cordyceps sinensis liquid seedlings (1 × 10 ⁸ / ml).

At this time, the immersion time was applied to the optimum time (2 minutes) disclosed in Experimental Example 1.

Pressurization conditions in this experiment are described in Table 2 below.

Processing pressure Reaction during immersion Processing result Immediate Vibration reaction (light), fine after infiltration proper 0.5㎏ / ㎠ Vibration reaction (light), fine after infiltration proper 1㎏ / ㎠ Vibration reaction (light), fine after completion of penetration proper 2㎏ / ㎠ Vibration reaction (light), fine after completion of penetration proper 3㎏ / ㎠ Vibration reaction (medium), partial floating after infiltration incongruity 4㎏ / ㎠ Vibration reaction (medium), floating after infiltration incongruity

2. Experimental results

As a result of the experiment, as shown in Figure 6, in the pressure range of 3 ~ 4kg / cm ² , the inoculation rate of Cordyceps sinensis seed spawn was reduced, it is determined that the pressure applied to the silkworm chrysalis.

As shown in Figure 7, fruiting body formation was shown to be improved in most treatments, especially 1kg / cm ² Or 2kg / cm ^{2 in} the pressurized treatment showed an excellent fruiting body formation rate of 89 ~ 90%.

However, at 3 kg / cm ² pressure treatment, the development of silkworm chrysalis was slightly lowered at the same time as the inoculation rate was lowered, indicating that the silkworm chrysalis was decayed due to high pressure.

Therefore, it can be seen that the most suitable pressure when inoculating Cordyceps sinensis in the silkworm pupae is 0.5-2 kg / cm ² .

Experimental Example 3 Inoculation Rate of Bacillus Bacillus

1. Experimental Method

Leukemia is a fungus that does not form fruiting bodies.

Thus, the inoculation rate of Bacillus Bacillus, an incomplete fungus, was examined.

The silkworm pupae in the liquid spawn (1 × 10 ⁸ / ml) of Bacillus bacterium was pressurized for 2 minutes according to the conditions of Table 2 above.

2. Experimental results

As shown in Figure 8, the inoculation rate was the best 95% up to 1kg / cm ² pressurized treatment, 3kg / cm ² When pressurized, the effect was rather adverse.

Therefore, in the present invention, the optimum conditions for easily infiltrating the spawn into the silkworm pupa are immersion time 0.5 to 2 minutes, pressure of 0.5 to 2 kg / cm ² .

The present invention has been described with reference to preferred embodiments and experimental examples, and those skilled in the art to which the present invention pertains, within the essential technical scope of the present invention and other forms of implementation of the present invention Examples and experimental examples may be implemented.

Here, the essential technical scope of the present invention is shown in the claims, and all differences within the similar scope should be interpreted as being included in the present invention.

10 container 11: connecting portion
20: pressurization device 30: Cordyceps sinensis liquid spawn
40 silkworm pupa

Claims (5)

Storing Cordyceps sinensis liquid seed in a container;
Immersing the silkworm pupa into the Cordyceps sinensis liquid seed in the container; and
After closing the container, the pressure treatment to infiltrate the Cordyceps sinensis liquid spawn to the silkworm pupa; comprising
Inoculation method of Cordyceps sinensis on silkworm pupae.
The method of claim 1,
In the step of immersing, characterized in that the silkworm pupa immersed in Cordyceps liquid seedlings for 0.5 to 3 minutes,
Inoculation method of Cordyceps sinensis on silkworm pupae.
The method of claim 1,
The pressure of the pressure in the step of penetrating is characterized in that 0.5 ~ 2㎏ / ㎠,
Inoculation method of Cordyceps sinensis on silkworm pupae.
Comprising the step of cultivating Cordyceps sinensis through silkworm pupae inoculated Cordyceps fungus spawn according to any one of claims 1 to 3,
Cordyceps cultivation method.
Cultivated through silkworm pupae inoculated Cordyceps fungi spawn according to any one of claims 1 to 3,
Cordyceps sinensis.

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