ES2944617B2 - DEVICE FOR THE MASS PRODUCTION OF AEROBIC AQUATIC LARVAE AND PROCEDURE USED - Google Patents

Description

DESCRIPTION

DEVICE FOR THE MASS PRODUCTION OF AEROBIC AQUATIC LARVAE

AND PROCEDURE USED

TECHNIQUE SECTOR

The present invention is framed in the breeding and mass production of aerobic aquatic larvae.

BACKGROUND OF THE INVENTION

The artificial breeding protocols for eristaline hoverflies (Insecta: Diptera, Syrphidae) are based on larval development through the use of systems that imitate or replicate the nutritional composition of the media they use in nature. For this reason, breeding methods based on organic matter (of animal or plant origin) dissolved in liquid or semi-solid media have traditionally been used.

Specific media based on the fermentation of cereals such as oats, barley or wheat, or balanced prepared media composed of the mixture of different specific components (such as soy casein, milk casein, forage, corn, agar, yeast, sawdust) are also known. and microbial growth stabilizing compounds).

To date, in the media there is little control over larval growth and development closely related to fermentation and associated microbial action. This considerably limits its industrial scaling since it is very difficult to dose the amount of food necessary throughout larval development, progressively increasing waste substances; This frequently leads to low production rates or even the mortality of all the larvae. Additionally, a large amount of waste is generated that cannot be used to continue breeding in subsequent generations.

Kobayashi, M. disclosed in various publications [Problems in the utilization ofEnstaliscerealisas pollinator. Shokubutsu Boeki, 26, 473-8 (1972)], [Studies on artificial multiplied protection and utilization of flower-visiting insects (2). Artificial multiplied ofEristalis cerealisFabricius. Bulletin of the Iwate Horticultural Experiment Station, 2, 1-27, 1972], [A study on multiplication and utilization of insects pollinating horticultural crops. Bulletin of the Iwate Horticultural Experiment Station, Special Issue 1, 159pp, 1979] related to the development of complex larval media (for E. cerealis and related species) based on the mixture of various components such as soybean and milk casein, forage, corn, agar, yeast, sawdust and microbial growth stabilizing compounds.

Subsequently, Gladis (1989, 1994a, 1994b, 1994c) developed media based on moistened fermented cereals for the breeding of species such as Eristalis tenax, Eristalis shrubrum or Eristalinus aeneus. Specifically, from Gladis, T. we highlight the following publications: Die Nutzung einheimischer Insekten ( Hymenopteren und Dipteren) zur Bestaubung von Kulturpflanzen in der Genbank Gatersleben. [The utilization of local insects (Hymenoptera and Diptera) as pollinators of crops in the Gatersleben genebank]. Die Kulturpflanze, 37, 79-126 (1989). https://doi.org/10.1007/BF01984582 ; Laborzucht einiger Eristalinen (Diptera, Syrphidae) und Moglichkeiten für ihren Einsatz in der Pflanzenzüchtung. [Laboratory rearing of some eristalines (Diptera, Syrphidae) and the possibility of their use in plant cultures]. Verhandlungen der westdeutscher Entomologentag, 139-152 (1994); Aufbau und Nutzung einer Massenzucht vonEristalis tenax(Diptera, Syrphidae) in der Genbank Gatersleben. [Establishment and utilization of a mass rearing of Eristalis tenax(Diptera, Syrphidae) in the Gatersleben genebank]. Insecta, 1, 287-294 (1994); Zuchtmethoden and Nutzungsmoglichkeiten für einheimische Insekten als Bestauber allogamer Kulturpflanzenarten. [Rearing methods and beneficial likelihood for native insects as pollinators of outcrossing cultivated plant species]. In Wildbienen. Biolgie -Lebensraume - Bestaubung - Gefahrdung und Haltung, Schriftenreihe des Landerinstituts für Bienenkunde Hohen Neuendorf e.V. Band 1. C. Hedtke (Ed.), 10-23 (1994).

One of the problems derived from the known methodology is the lack of control of the exact quantity and composition of the nutrients accessible to the larvae, which basically derive from the natural fermentation and decomposition of these media. In the aforementioned studies, estimates are made of the amount of breeding medium necessary to obtain a certain number of larvae, but the specific nutritional component of these media is really unknown, and in many cases there is an excess of undigested or indigestible organic matter. This excess also represents an added problem since it entails the production of a large amount of waste, the elimination and management of which entails added costs. As an example, each breeding container of known media based on moistened cereals produces around one kilo of organic waste, which on an industrial scale would mean hundreds of kilos or even tons of organic waste.

On the other hand, in the specific case of eristaline hoverflies and other species with potential (in the adult phase) for use as pollinators, it should be noted that their aerobic aquatic larvae need to be subject to a substrate from which they can feed and make small movements. . This requirement is essential as these are species that feed passively on microorganisms and microparticles dissolved in water. In this sense, current breeding systems focus specifically on the feeding requirements of the larvae, but do not mention this specific need or the characteristics of a physical structure (independent of the food itself) that allows the support and anchoring of the larvae as priority aspect for artificial breeding and controlled industrial production.

On the other hand, in international patent application no. WO2020118366A1 discloses a process and materials that, in our opinion, do not allow their use for the mass rearing of aerobic semi-aquatic larvae, for example, of eristaline hoverflies, because their behavior is very different from that of crabs and other aquatic arthropods. that are cited in it.

Specifically, eristaline hoverfly larvae are aerobic, so to breathe they stretch a siphon (respiratory spiracle) until they reach the surface behind the surface film of water.

In this sense, we understand that the main drawbacks offered by the aforementioned patent are based on the following points:

- The larval breeding containers specified in patent no.

WO2020118366A1 (Figs. 3 and 4) have holes on the sides in order to facilitate the entry of the nutritional liquid for the crab larvae (which do not need to contact the surface and need to attach themselves to a substrate, breathing the oxygen dissolved in the water ). In the case of eristaline hoverflies, the semi-aquatic larvae do not attach to the substrate and need to move freely through the breeding containers. If containers with these holes are used, the hoverfly larvae would move and escape to the outside of the container, producing numerous uncontrolled leaks that would make production unviable.

- The larval support shown in patent no. WO2020118366A1 consists of a filamentous material (Fig. 5), which is initially prepared in a container where the eggs hatch so that the newborn larvae adhere to it (Figs. 7, 8, 9 and 10) and, They are subsequently transported (Figs. 6 and 7) to the larval rearing containers (Fig. 4). This separation process between the egg hatching containers and the larval rearing containers does not exist in the case of rearing eristaline hoverfly larvae, where the eggs are placed on the surface of the water or on the structures of the invention until their hatching (in no case submerged as in the case of crabs) and the larvae are kept throughout their cycle in the same container.

- The use of the filamentous substrate presented in patent no. WO2020118366A1 creates a certain compartmentalization of the medium. However, it does not meet the biological requirements of eristaline hoverfly larvae, which have to project their spiracle to the surface to carry out aerobic respiration. Our experience with this type of materials is that they tend to become trapped among themselves, since the telescopic spiracle they have is intertwined with the filamentous material and even with that of other larvae, which ultimately causes their death due to drowning and difficulty in movement. .

- On the other hand, in Figs. 3 and 4 of patent no. WO2020118366A1 it can be seen that the system used involves leaving a large amount of free volume inside the container, around the holding structure for the larvae. This would again imply a considerable increase in larval mortality, especially during the first days of the larval cycle. The newborn larvae would be exposed in these spaces with water since they would not have the structure available to fixate that is presented in our patent, posing a risk to them. This is because, since the larvae do not have access to a holding structure for a long time, they die of exhaustion due to persistent movements made in order to move through the liquid in any way in order to find a surface to hold on to. This situation has been observed on many occasions during the artificial breeding of these insects, being one of the most critical factors to take into account in their production.

In summary, the main problems in the use of known methods and systems for the controlled production of aerobic aquatic larvae are:

- The lack of control of the nutritional composition of the environment itself over time and of the nutrients accessible to the larvae (the larvae filter the water, selecting part of the microorganisms and food substances present there, which are part of their diet) .

- The waste generated in current systems produces leftover organic matter that is not usable in larval feeding and must be specifically eliminated.

- High mortality rates derived from the lack of support structures, limiting/preventing the feeding of a large number of larvae for a given volume of liquid medium in the containers used for their development.

Therefore, the applicant of the present patent application detects a limitation in the known techniques of mass larval production and proposes an invention that makes it possible to increase the efficiency of the process per unit of volume, increase the survival rate and reduce the production of derived waste. during aerobic aquatic larval rearing.

DESCRIPTION OF THE INVENTION

The device and procedure recommended in the present invention offers a notable advance in the mass and controlled breeding and production of aerobic aquatic larvae, since it allows solving the problems previously detailed.

The object of the invention concerns a device and procedure using said device for the breeding and production of aerobic aquatic larvae that allows controlling the amount of food (including prefabricated feed or nutritionally adequate pulverized food) consumed by said aerobic aquatic larvae.

The device used to carry out the process of mass production of aerobic aquatic larvae of the invention is formed by a container that has a three-dimensional structure that defines a compartmentalization of the liquid volume of the container, and a mesh as a cover of the container to ventilation of the larval rearing container.

Thus, the three-dimensional structure of the larval breeding container is made up of a plurality of elements, where each element is provided with four cross-shaped arms that define a compartmentalization, generating holes as receptacles where the aerobic aquatic larvae are arranged. Precisely the receptacles allow the movement of the aerobic aquatic larvae and the cross-shaped arms of the elements that form the three-dimensional structure enable the anchoring of the aerobic aquatic larvae. It should be noted that the elements with cross-shaped arms are grouped randomly within the aforementioned larval rearing container.

It should be noted that, although a small part of the larvae's food may accumulate slightly in the breeding containers, the production of this waste is much lower than that produced by known traditional means.

Thus, each receptacle defined by the three-dimensional structure has a free passage of between 0.7 cm and 1.5 cm. The elements of the three-dimensional structure are made up of a mechanically resistant organic material or a polymeric material that is heavier than water. Precisely the presence of the three-dimensional structure and the formed receptacles allow the free movement and anchoring of the aerobic aquatic larvae.

Each receptacle of the three-dimensional structure of the device is covered by an aqueous food medium to feed in a controlled manner the aerobic aquatic larvae that are arranged in said receptacle.

On the other hand, advantageously the arrangement of the elements of the three-dimensional structure defines a majority of regions of the arms submerged in the aqueous food medium and some regions not bathed by the aqueous food medium or, in other words, free of medium. aqueous food that, as we will see later, offer areas where aerobic aquatic larvae emerge from the eggs.

The three-dimensional structure, made up of a mechanically resistant organic material or a polymeric material, generates holes as receptacles where the aerobic aquatic larvae reside. In fact, each receptacle of the three-dimensional structure is covered by an aqueous food medium to feed in a controlled manner the aerobic aquatic larvae that are arranged in said receptacle.

Preferably, each receptacle defined by the three-dimensional structure has a free passage of between 0.7 cm and 1.5 cm to facilitate the movement of aerobic aquatic larvae, such as the species Enstalis tenax and related species of eristaline hoverflies. However, this free passage can be adapted to the specific size of other species or even adapted to each stage of larval development.

The proposed device of the present invention offers the following advantages:

- The presence of the three-dimensional structure allows the use of nutritional components of great nutritional value that can be diluted in water, such as brewer's yeast powder, without the need to be mixed with other food components and facilitating the quantification of the total digested by aerobic aquatic larvae and controlling the amount of waste produced. Also proposed in this invention is the use of other nutritional means not previously used for feeding aerobic aquatic larvae of hoverflies and related species, as commercial feed for aquaculture animal species.

- It allows both the food suspended on the surface of the water to be consumed by the aerobic aquatic larvae, as well as the food that is gradually submerged. In fact, all aerobic aquatic larvae can access this food, thus being able to control the amount of food that the larvae ingest, unlike in known breeding systems in which it is not feasible to estimate the amount of food ingested or adjust the parameters. nutritional requirements that they need at each specific moment of their development.

- Feeding aerobic aquatic larvae with known quantities adjusted to their level of development, as well as establishing specific diets for a specific species.

- The three-dimensional structure serves as a support so that aerobic aquatic larvae can be held in an aquatic environment (that is, in the aqueous food environment), preventing their drowning and, therefore, reducing their mortality.

- A compartmentalization of the larval breeding container is generated, which contains a homogeneous aqueous food medium that increases the efficiency of the production process by being able to produce a greater number of larvae per container volume. - The three-dimensional structure is made up of mechanically resistant organic material, for example, a cellulosic organic material, or a polymeric material. When the three-dimensional structure is integrated with a polymeric material, it can be reusable through simple cleaning, significantly reducing the organic waste generated and reducing production costs.

On the other hand, the recommended procedure includes the following stages:

- Compartmentalization of a larval breeding container by introducing inside it a three-dimensional structure made up of a mechanically resistant organic material or a polymeric material in which a plurality of receptacles are defined, where each receptacle preferably has a free passage of between 0.7 cm and 1.5 cm. It should be noted that said three-dimensional structure allows the anchoring of aerobic aquatic larvae and is defined by a plurality of elements where each element is provided with four cross-shaped arms so that they generate regions of the arms submerged in the aqueous food medium and regions free of aqueous food medium.

- Filling the larval breeding container with water and food that form an aqueous food medium. Preferably, the food is introduced in a powder or granular format.

- Introduction into the larval breeding container of the eggs from the adult insect colonies.

- Sealing the upper part of the larval breeding container using a mesh as a cover.

- Emergence (birth) of aerobic aquatic larvae from eggs in regions free of aqueous food medium (cross-shaped arms of the three-dimensional structure that are not bathed in aqueous food medium) and natural movement of aerobic aquatic larvae to the aqueous food medium.

- Feeding of the aerobic aquatic larvae through the aqueous food medium and respiration of the aerobic aquatic larvae through the projection of their respiratory spiracle to the surface of the aqueous food medium, - Attachment of the aerobic aquatic larvae to the receptacles of the three-dimensional structure, allowing its development, movement and rest in the arms of the elements of the three-dimensional structure,

Optionally, the procedure may include an additional step in which an additional specific amount of food can be dosed with respect to the amount initially introduced in the filling of the larval rearing container and thus enable the complete development of the aerobic aquatic larvae depending on their development or specific characteristics of the cultivated species.

At a later stage, preferably when the aerobic aquatic larvae have completed their development, the larval rearing container without the cover is introduced into a larger container. The largest container contains a dry substrate, preferably vermiculite or similar, and is sealed at the top with a mesh as a cover. After completing their growth period, the larvae leave the breeding container and take refuge in the external dry substrate (e.g. vermiculite) until they transform into pupae.

To separate and select the pupae, it is necessary to isolate the aerobic aquatic larvae that have not pupated, that is, the dry substrate where the larvae have taken refuge is sieved after the end of the growth period. Immediately afterwards, the aerobic aquatic larvae will be selected based on their size, separating them on an appropriate dry substrate to achieve their transformation into pupae in the next 24 hours.

The detailed procedure is preferably carried out at a temperature of between 25 and 30°C, with a relative humidity of between 50% and 65% and a photoperiod of 12 hours of light and 12 hours of darkness, although it can be adapted to the specific conditions of the species.

The advantage offered by the detailed procedure is that the amount of food used for the formation of the aqueous food medium corresponds to the specific amount of food necessary for the aerobic aquatic larvae at each moment of their development, increasing the efficiency of the process and eliminating the problems associated with the accumulation of undigested food in current breeding systems. On the other hand, another advantage offered by the present invention lies in the fact that the three-dimensional structure contained in the larval breeding container offers the support of the aerobic aquatic larvae and their movement.

For all of the above, the present invention makes it possible to increase the efficiency of rearing aerobic aquatic larvae, since it allows greater production per volume of liquid used. On the other hand, the reuse of structures on an industrial scale is facilitated, as well as the reduction of derived waste. The result is larval production rates higher than those obtained with currently known systems.

Optionally, a purification system for the liquid medium can be added to this device for the controlled feeding of aerobic aquatic larvae, so as to allow its continuous use on an industrial production scale.

Advantageously, the present procedure and device for the controlled production of aerobic aquatic larvae enables industrial production of diptera, such as eristaline hoverflies, which have aquatic development larvae. The adults derived from this production can be marketed as pollinating agents in agriculture in a complementary or substitutive manner to other traditional pollinators such as bees or bumblebees.

On the other hand, the procedure of the present invention allows the commercial production of these insects for other purposes such as, for example: fishing baits, a live food source for insectivorous animals, a source of protein and other components for the production of animal feed. or the obtaining of biomolecules such as chitosan. So its application is widely demonstrated.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that will be made below and in order to help a better understanding of the characteristics of the invention, in accordance with a preferred example of its practical implementation, a set of plans is attached as an integral part of said description. where, for illustrative and non-limiting purposes, the following has been represented:

Figure 1 shows a side view of the device for the controlled production of aerobic aquatic larvae made in accordance with a preferred embodiment of the object of the present invention, which is introduced into a larger container for the release of larvae.

Figure 2 shows a top view of the device of the invention represented in the previous figure where the mesh as a cover is not represented.

Figure 3 shows a top view of the device of the invention represented in Figure 1.

Figure 4 shows a perspective representation of a cross-shaped element, in accordance with the preferred embodiment of the invention, used for the formation of the three-dimensional structure that compartmentalizes the device for the mass production of aerobic aquatic larvae.

Figure 5 shows a graphic representation of the results obtained in relation to the survival rate of the larval, pupal and total pre-adult phases for the three species studied: Eristalis shrubrum, Eristalinus taeniopsy and Myathropa florea reared in different test conditions.

Figure 6 shows a graphic representation of the results obtained in relation to the weight of the pupae on their first and second day of development and the weight of the adults for the three species studied, raised in different test conditions.

PREFERRED EMBODIMENT OF THE INVENTION

Figures 1, 2 and 3 show a device according to a preferred embodiment for carrying out the procedure of the present invention. In this sense, the device for the mass production of aerobic aquatic larvae is integrated by a larval breeding container (1) with a three-dimensional structure that defines a compartmentation, generating holes as receptacles (2) where the aerobic aquatic larvae are arranged. , the three-dimensional structure being composed of a mechanically resistant organic material or a polymeric material. The aforementioned figures show the larval breeding container (1) introduced into a larger container (8).

The larval breeding container (1) has a mesh (5) as a cover for ventilation.

As seen in Figures 1, 2 and 3, each receptacle (2) of the three-dimensional structure is covered by an aqueous food medium (6) to feed in a controlled manner the aerobic aquatic larvae that are arranged in said receptacle (2). .

The three-dimensional structure is formed, in the first embodiment represented in Figures 1, 2 and 3, by a plurality of units of cross-shaped elements (3) of plastic material for compartmentalizing the larval breeding container.

Figure 3 shows a representation of the elements (3) in a cross shape whose randomly stacked arrangement defines gaps as receptacles (2) where the aerobic aquatic larvae move freely, while Figure 4 shows a representation of a element (3) in cross shape.

Specifically, tests are carried out to determine the survival rate in the larval, pupal and total pre-adult phases (mean ± standard error) for the following species: Eristalis shrubrum (represented in figure 5 letter A), Eristalinus taeniops (represented in figure 5 letter B) and Myathropa florea (represented in figure 5 letter C).

The comparative analysis carried out for the three species includes the rearing of the aerobic aquatic larvae using a larval rearing container that has one of the following test conditions:

- The larval breeding container contains a well-known medium based on moistened oats that acts as support and also food (D).

- The larval breeding container contains a rigid three-dimensional structure composed of a plurality of stacked units of elements of polymeric and inert material in the shape of a cross (F).

In this way, Figure 5 represents the survival rate (expressed in %, mean ± standard error) on the ordinate axis, while the test conditions (D and F) and the type of larval stage (H, I, J) of the species analyzed (A, B or C).

Thus, the bars contained in the graphic representation of figure 5 allow us to observe the survival of the larva (H), the survival of the pupae (I) and the total survival of the preadult (J) for each of the species studied (A , B and C).

The results obtained allow us to conclude that the use of the procedure developed in the present invention allows, at least, to equal larval survival with respect to that obtained with the traditional medium consisting of moistened oat grains (represented by D in Figure 5).

In this sense, focusing on an analysis of the survival rates obtained for the species E. taeniops(represented by B in figure 5) andM. florea (represented by C in figure 5) it is concluded that survival rates do not present significant differences between all larval media (D and F).

However, the species E. bushrum (represented by A in figure 5) showed an improvement in larval, pupal and pre-adult survival (p < 0.05), as observed when comparing the data obtained with F with respect to D in figure 5 A. By increasing the larval survival by up to 18.89% and pupal survival by up to 26.81% (better quality of larval development), total survival was increased by up to 34%. This guarantees a considerable increase in the final production of individuals using the method and device developed in the present invention.

On the other hand, in the tests carried out, the weight of the pupae obtained on their first day of development (K), on the second day of development (L) and in the adult phase (M) is also determined. The results are represented in figure 6 according to the tests carried out for the following species: Eristalis bushrum (represented in figure 6 letter A), Eristalinus taeniops (represented in figure 6 letter B) and Myathropa florea (represented in figure 6 letter C).

In this way, Figure 6 represents the weight on the ordinate axis (expressed in grams, mean ± standard error), while the test conditions (D and F) and the moment of development are identified on the abscissa axis. of the aerobic aquatic larvae during their breeding (K, L, M) of the analyzed species (A, B or C).

Thus, the bars contained in the graphic representation of figure 6 allow us to observe that the weight of the pupae on their first day of development (K), the weight of the pupae on their second day of development (L) and the weight on the adult phase (M) were significantly different (p < 0.05) for each of the species studied (A, B and C).

From the results obtained, we observed that the weights of the pupae and adults of E. bushrum (represented by A in figure 6), E. taeniops(represented by B in figure 6) andM. florea (represented by C in figure 6) obtained in the tests carried out showed significant differences between the new test condition proposed in the present invention (represented by F) and the traditional medium (represented by D).

In this sense, in the cases of E. bushrum (represented by A in figure 6), E. taeniops(represented by B in figure 6) andM. florea (represented by C in figure 6), the weights obtained with F were significantly greater than those obtained with D (p < 0.05) with increases in the weight of the adults of approximately 5, 13 and 19% in each case , thus showing a higher quality of the adults obtained.

It should be noted that the direct relationship between the amount of food and the development of these aerobic aquatic larvae has been observed in the evolution of the results obtained with E. bushrumyE. taeniopsen the conditions described for F. In the first trial, half the food was used, providing 4 g every 3 days for 19 days for E. bushrumy 21 days for E. taeniops(28 g and 32 g in total respectively). During the second trial - the results of which are included herein -, 4 and 5 g of food were supplied daily for 12 and 15 days (48 g and 75 g in total), respectively.

The results of this change in larval diet using the three-dimensional structure described in F showed an increase in larval survival of up to 47.22% in E. bushrumy 35.56% in E. taeniops (p< 0.05).

Furthermore, aerobic aquatic larvae developed better, showing an increase in pupal survival of up to 52.78% in E. bushrumy 50.06% in E. taeniops (p< 0.05).

For all these reasons, the final production of adults increased up to 60.50% in E. bushrumy 50.27% in E. taeniops. The increase in the quality of the aqueous food medium that enables larval development was also observed reflected in the weight of the adults obtained in this second trial, being up to 28.57% higher in E. bushrumy 12.67% higher in E. taeniopscompared with the results of the first trial.

These results confirm the potential capacity of the controlled production process of aerobic aquatic larvae of the present invention for the artificial breeding of these insects.

To all this we must add that, although certain parameters for some species are somewhat similar to those obtained when known means are used for the aforementioned breeding (which correspond to the data represented by D), the new procedure for the mass production of aquatic larvae Aerobic farming has the advantage of generating less organic waste derived from breeding itself.

An example of the procedure carried out for the mass production of aerobic aquatic larvae of Eristalis tenax is detailed below:

- A larval breeding container (1) of plastic material with a 2.8 liter capacity (9 cm high x 13 cm wide x 20 cm long) is prepared, making a rectangular central opening in the lid. The central opening is sealed with silicone using a fine mesh (5), as a cover, which allows ventilation of the larval breeding container (1), while preventing the entry of other insects into the larval environment.

- 15 units of grids (2) of plastic material are placed inside the larval breeding container (1), stacked one on top of another, or 1000 units of cross-shaped elements (3) of plastic material are introduced to compartmentalize the breeding container. larval (1). The three-dimensional structure allows the anchoring of aerobic aquatic larvae. Figure 4 shows a representation of a cross-shaped element (3) whose arrangement defines gaps as receptacles (2) where the aerobic aquatic larvae move freely.

- Fill the container with 700 - 750 ml of water.

- From colonies of adult insects, 150 eggs are collected and placed in the previously prepared larval breeding container (1).

- After two days, when the aerobic aquatic larvae have emerged from the eggs, 6 g of food (granulated or powdered valid for larval feeding) is placed. In this way, the water and food form an aqueous nutritional medium (6) on which the larvae feed for breeding.

- 6 g of food are deposited each day up to a total of 65 g of food until the aerobic aquatic larvae fully develop after 11 - 13 days.

- The larval rearing container (1) is placed inside another larger container (8) (for example, 18 cm high x 22 cm wide x 33 cm long) with a layer of 2 - 3 cm of vermiculite as a substrate. dry for pupation.

- The larval rearing container (1) must allow the exit of the aerobic aquatic larvae so that the pupation can form outside where vermiculite has been previously deposited (or other dry substrate compatible with pupation such as sawdust, sand, etc.) . Therefore, the mesh cover (5) is removed from the larval breeding container (1), while the larger container (8) is sealed in its upper part by means of a mesh (5) as a cover on its lid. (4). In this way, the exit of the larvae from the larval rearing container (1) to the larger container (8) is facilitated.

- The pupae are collected by sieving the vermiculite. Larvae that have not yet pupated are placed back in the vermiculite.

The detailed larval rearing procedure takes place at a temperature of between 25°C and 30°C, with a relative humidity of between 50 and 65% and a photoperiod of 12:12 hours of light and darkness.

For all of the above, it is concluded that by using the detailed invention, larval survival is increased, and therefore the final number of individuals produced compared to currently known means. Furthermore, waste production is considerably reduced both by the reuse of the compartmentalization structures of the aqueous food medium and by the possibility of feeding the aerobic aquatic larvae with the exact food necessary for their development. All of this considerably increases the control and optimization of the artificial breeding of these insects.

That is to say, the developed procedure enables the controlled mass breeding of aerobic aquatic larvae of dipterous hoverflies, as well as species with related biologies, with larval production being viable that can be scaled to mass production. Therefore, the present invention optimizes insect production, reducing waste and controlling the amount of food necessary to obtain a specific number of larvae, as well as monitoring their development over time.

Claims (1)

1st.- Device for the mass production of aerobic aquatic larvae, characterized in that it comprises a larval rearing container (1) that presents: - a three-dimensional structure made up of a plurality of elements (3) provided with four cross-shaped arms that define compartmentalization, generating holes as receptacles (2) where the aerobic aquatic larvae are arranged so that each receptacle (2) defined by the three-dimensional structure, it has a free passage of between 0.7 cm and 1.5 cm, the three-dimensional structure being composed of a mechanically resistant organic material or a polymeric material, - a mesh (5) as a container cover for ventilation of the larval breeding container (1), where each receptacle (2) of the three-dimensional structure is covered by an aqueous food medium (6) to feed in a controlled manner the aerobic aquatic larvae that are arranged in said receptacle (2), so that the arrangement of the elements (3 ) of the three-dimensional structure define regions of the arms submerged in the aqueous food medium (6) and regions free of aqueous food medium (6). 2nd.- Device for the mass production of aerobic aquatic larvae, according to claim 1a, characterized in that the three-dimensional structure is made up of a mechanically resistant cellulosic organic material. 3rd.- Device for the mass production of aerobic aquatic larvae, according to any of the previous claims, characterized in that the three-dimensional structure is arranged randomly stacked. 4th.- Device for the mass production of aerobic aquatic larvae, according to claim 1a, characterized in that it includes a device for purifying the aqueous food medium (6). 5th.- Procedure for the mass production of aerobic aquatic larvae, using the device detailed in claims 1a to 4a, characterized by being carried out in accordance with the following steps: - Compartmentalization of a larval breeding container (1) by introducing inside it a three-dimensional structure made up of a mechanically resistant organic material or a polymeric material, the three-dimensional structure being defined by a plurality of elements (3) provided with four arms. in the shape of a cross so that they generate regions of the arms submerged in the aqueous food medium (6) and regions free of aqueous food medium (6), - Filling the larval breeding container (1) with water and food that form a medium food watery (6), - Introduction of eggs from adult insect colonies into the larval breeding container (1), - Sealing the upper part of the larval breeding container (1) using a mesh (5) as a cover, - Emergence of aerobic aquatic larvae from eggs in regions free of aqueous food medium (6) and movement of aerobic aquatic larvae to the aqueous food medium (6), - Feeding of the aerobic aquatic larvae in the aqueous food medium (6) and respiration of the aerobic aquatic larvae by projecting their respiratory spiracle to the surface of the aqueous food medium (6), - Attachment of the aerobic aquatic larvae to the receptacles (2) of the three-dimensional structure, allowing their development, movement and rest in the arms of the elements (3) of the three-dimensional structure, where the amount of food used for the formation of the aqueous food medium (6) corresponds to the amount of food consumed by the aerobic aquatic larvae, while the three-dimensional structure enables the attachment and movement of the aerobic aquatic larvae. 6th.- Procedure for the mass production of aerobic aquatic larvae, according to claim 5a, characterized in that it is carried out at a temperature of between 25 and 30°C, with a relative humidity of between 50% and 65% and a photoperiod of 12 hours of light and 12 hours of darkness, 7th.- Procedure for the mass production of aerobic aquatic larvae, according to claim 5a, characterized in that an additional amount of food is dosed with respect to the amount introduced when filling the larval breeding container (1) for the complete development of the larvae. aquatic aerobics. 8th.- Procedure for the mass production of aerobic aquatic larvae, according to claim 5a, characterized in that the larval breeding container (1) is introduced into a larger container (8), where the larger container (8) contains a dry substrate (7) in which the aerobic aquatic larvae take refuge after emerging outside the larval breeding container (1); so that the exit of the aerobic aquatic larvae is facilitated by removing the mesh cover (5) from the larval breeding container (1), while the larger container (8) is sealed in its upper part by a mesh ( 5) as a cover. 9th.- Procedure for the mass production of aerobic aquatic larvae, according to claim 8a, characterized in that the dry substrate is sieved (7) 10th.- Procedure for the mass production of aerobic aquatic larvae, according to claim 8a, characterized in that the dry substrate (7) is vermiculite. 11.- Procedure for the mass production of aerobic aquatic larvae, according to claim 5a, characterized in that the food used is in powder or granular format.