BR102021006072A2 - BIODEGRADABLE COATING FOR PELLETIZING VEGETABLES SEEDS - Google Patents

Abstract

The present invention refers to the production process of a polymeric coating for pelletizing vegetable seeds, with the main advantages of protecting the seed and preserving its physiological quality, in addition to modifying its size and shape, facilitating precision sowing. Coatings can still be used as a vehicle for inputs, such as nutrients, biostimulants, protectors and other substances of importance to the plant, as well as beneficial microorganisms for plant growth. This invention describes the use of a completely biodegradable polymer matrix obtained from raw materials from a renewable source (starch, gelatin and lignocellulosic vegetable fibers), which is characterized by its degradation by the action of physical agents (humidity and temperature) and of soil microorganisms, without leaving contaminants in the soil. Another advantage is that the proposed composition for the coating allows the incorporation of several active compounds.

Description

BIODEGRADABLE COATING FOR VEGETABLE SEED PELLETIZING FIELD OF INVENTION

[001] The cultivation of vegetables requires improvements in the sowing system that guarantee greater technical and economic success of agricultural activities, contribute to planting density and enable the production of food in adequate quantity and quality without harming the ecosystem. The scenario we are currently facing is one of growing food demand, requiring a 70 to 100% increase in production to be able to supply the population in 2050, and limited agricultural territory. Thus, precision agriculture is presented as being essential for the commercial future of agriculture.

[002] The technical challenges involved in planting vegetables can be associated with the characteristics of the seeds since their reduced size and weight and irregular shape impair the precision and efficiency of planting, which can increase the cost of production. Due to their characteristics, vegetable seeds have problems obtaining uniform distribution, their irregular shape and reduced size and weight make them difficult to be individualized, and this can lead to irregular spacing and sowing density, which can compromise harvest productivity. , that is, precision and efficiency of planting, and generate a great loss of seeds.

[003] In addition to these problems, there are other factors commonly related to seeds that cannot be ignored, such as germination uniformity, infestation by insects and microorganisms, dormancy, performance after periods of storage, among others. .

[004] Knowing that agricultural equipment is suitable for planting seeds that are homogeneous in size and shape to obtain a higher planting density, and considering that the irregularity of spacing and sowing density imposes the use of a greater amount of seeds to obtain a stand of satisfactory plants and that these operations require greater use of labor, the use of seeds with unfavorable characteristics can increase the cost of production.

[005] An efficient method for pre-planting seed treatment must be economically viable, contribute to seed quality, increase productivity and profit, and be safe. Synthetic materials commonly used in commercial coatings and toxic pesticides added as additives, such as imidacloprid and carbofuran, can cause damage to the environment, contamination of soils, atmosphere, surface and underground waters, and food, therefore, raw materials raw materials must be well selected so that they do not threaten the safety of the environment or human health.

BACKGROUND OF THE INVENTION

[006] Patent US2579734(A) entitled “Seed pellet” registered in 1951, which suggests a seed pelleting method. However, the proposal has as limitations the difficulty of guaranteeing that each pellet, in the end, will have only one seed, the addition of water that is not standardized, according to the author the amount of water in the formulation is not fixed, it is defined by observation. Furthermore, the method does not employ any adhesive material in the formulation, which can compromise the adherence of the coating to the seed and therefore the final quality of the pellet produced.

[007] Patent AU475490(B2), entitled “Improvements in or relating to pasture establishment”, from 1974, presents a method of pelletizing seeds with complex materials resulting in more than one seed per pellet, which has not yet been proven to be something positive for the development of vegetables.

[008] Patent US4551165 entitled “Mycorrhizal seed pellets”, suggests a seed pelleting method resulting in very light pellets, the author even proposes the addition of sand to increase weight, as in this way the seeds can withstand strong winds. This fact is not interesting when looking precisely to increase the weight of seeds, and it completely differs from this required invention.

[009] The invention WO2011/123602(A1), entitled, “Cast pellets for planting seeds”, from 2011 presents a method for pelletizing that results in multiple seeds per pellet (in this invention the seeds are individualized), leading the plants to develop if in close proximity. The author states that it can be advantageous for certain types of ornamental plants, but does not mention whether the same effect is valid for vegetables.

[010] Patent US2015/0101245(A1), entitled “Seed coating compositions”, from 2015, which describes a coating method that involves very complex and difficult-to-obtain components, with raw materials different from those used in this work.

[011] The patent US2015/0040268(A1) of 2015 of the invention “Methods and compositions for the delivery of nucleic acids to seeds” suggests a coating method of great complexity, in addition the final product will probably have a high added value, which is not in the interest of agricultural producers, especially in the case of large plantations

[012] The patent WO 2004/036975(A1), proposes a seed pelleting method that involves a wide variation in drying temperature (25 to 80°C) and resulting pellets with variable size and shape, which demonstrates poor quality in standardization . In addition, depending on the target seed, high temperatures can be harmful.

[013] The patent US20060048446(A1), exposes the seed pelleting method that involves a wide variation in drying temperature (25 to 80°C) and resulting pellets with variable size and shape, which demonstrates poor quality in standardization. In addition, depending on the target seed, high temperatures can be harmful.

[014] The patent US2006/0196117(A1) of 2006, entitled “Pellet of bulbous plants, a method of pelletization and a cultivation method of plants using the same”, exposes the method of pelletizing seeds that involves a large variation in the temperature of drying (25 to 80°C) and resulting pellets with variable size and shape, which shows poor standardization quality. In addition, depending on the target seed, high temperatures can be harmful.

[015] Patent DE112004000203(T5), entitled “Method for seed pelleting”, presents a pelleting method having as a limitation the difficulty to guarantee that each pellet will contain a single seed.

[016] Patent CN103058764(B) of 2012, entitled “A coating agent and a method for pelleting seeds of Cynodondactylon (Linn.) Pers by using the coating agent” proposes seed pelleting using pelleting equipment, the method makes it difficult to guarantee that, at the end of the process, each pellet will contain a single seed.

[017] Patent CN103069950(A), entitled “Pelleting processing method of Eurya emarginata seeds”, from 2013, proposes a formulation for pelletizing seeds involving a complex mixture of raw materials, different from those used in this invention.

[018] In the article by SPREY, L. M.; FERREIRA, S. A. N. “Physiological quality of pelleted tomato seeds”, The proposed pelleting was carried out in equipment manufactured in-house, and the production generated pellets with contents ranging from 1 to 3 seeds per pellet and variable size, leading to the disposal of seeds that did not have the desired size. The results indicated that the physical barrier caused a delay in germination, which, according to the authors, may be common for pelleted seeds.

[019] In the article RUFINO, C. A.; TAVARES, L. C.; MARTÍN-RAMOS, P.; FERNANDESVIEIRA, J.; JUNIOR, J. S. A.; SILVA, F. J. A.; FERNANDES-CORREA, M.; MARTÍNGIL, J. “Performance of seed soybeanlings upon nutrient application by seed coating”, evaluates the performance of soybean seedlings upon application of nutrients through seed coating. The proposed formulation uses commercial pesticide, polymer and inoculant and the results do not indicate good performance of the produced formulation.

[020] In the article SUO, H. C.; LI, W.; WANG, K.H.; ASHRAF, U.; LIU, J.H.; HU, J.G.; LI, Z.J.; ZHANG, X.L.; XIE, J.; ZHENG, J. R. “Plant growth regulators in seed coating agent affect seed germination and seedling growth of sweet corn”, Verified the application of plant growth regulators in coating agent in corn seeds and the effect on germination and seedling growth. The coating made without growth regulators hindered the germination and vigor of the plant, as well as the formulations with insufficient concentration of regulators. The polymer used in the formulation is industrial/commercial and the filming technique is limited to vegetables, as it did not modify the size of the seeds nor add much weight to them.

[021] In the article by ZENG, D.; FAN, Z.; TIAN, X.; WANG, W.; ZHOU, M.; LI, H. “Preparation and mechanism analysis of an environment-friendly maize seed coating agent”, proposed the preparation and analysis of an environmentally friendly coating agent for corn seeds. Presentation of the formulation uses generic terms such as “natural polysaccharide” and “homemade growth regulator”, making it impossible to understand the material used. In addition, he does not mention the method of application of the formulation to the surface of the seed, even though the filming technique does not change the size of the seeds nor does it add much weight. When presenting his results, he does not compare them with those of other authors.

SUMMARY OF THE INVENTION

[022] The pelleting technique aims to benefit planting conditions, plant development, crop productivity, food safety, and can also contribute to reducing production costs, generating greater profit. Obtaining a satisfactory stand of vegetable plants requires a large amount of seeds, which increases the production cost, however, since pelleted seeds become larger and heavier, their loss is reduced. In addition, depending on the pelleting method used, the seeds are protected from biotic and abiotic stresses that interfere with plant growth, crop health and crop yield, which is why pelleting can make the use of pesticides and fertilizers be reduced, minimizing the environmental impacts generated, which is in line with the population growth trend, as well as the increased demand for food, which only tends to aggravate soil degradation.

[023] The seed pelleting is configured as an alternative, it is a promising pre-planting technique being recommended for seeds that may have the development of the plant affected because they are small, light, rough, have an irregular shape or because they contain hairs, thorns and edges. This technique represents the possibility of regulating planting conditions such as temperature, water availability and soil acidity; stress from accelerated aging (such as fungal invasion); favoring germination during changes in soil moisture (especially in the suboptimal range); reduction in the leaching of inhibitors present in seed coatings and favoring plant growth under saline stress.

[024] Pelletizing brings some advantages from a productive and operational point of view, since it facilitates the handling and distribution of seeds in mechanical seeders, allowing precision sowing to be carried out, which results in reduced seed consumption. In addition, coatings can still be used as a vehicle for inputs, such as nutrients, biostimulants, protectors and other substances of importance to the plant, as well as beneficial microorganisms for plant growth, leading to improvements in the health of the seeds and the establishment of seedlings through the incorporation of such nutrients.

DETAILED DESCRIPTION OF THE INVENTION

[025] The present invention refers to the production process of a fully biodegradable polymeric coating obtained from raw materials from a renewable source for vegetable seeds, which are considered high-cost inputs, due to their susceptibility to microbial contamination and by size and shape, which make precision sowing difficult.

[026] This invention brings in its composition mainly the mixture of two biodegradable polymers, starch and gelatin, in addition to the presence of glycerol and vegetable fibers used as filler. It describes the use of a polymer matrix obtained from biodegradable polymers, which will be completely degraded by the action of physical agents (humidity and temperature) and soil microorganisms, without leaving contaminants in the soil.

[027] Using tomato seeds as a model to study the viability of coatings, changes in shape, decrease in density and increase in seed mass were obtained with the pelletizing process. Pelleted tomato seeds have an average mass of 0.0739 g and an average density of 0.1798 g/cm3, compared to the same non-pelleted seeds, which have a mass of 0.0028 g and density of 0.3778 g/cm3. The pH of pelleted seeds is in the range of 6.09 to 6.55, which is an interesting characteristic, considering that these materials can be used as polymeric matrices for immobilization of nutrients and/or microorganisms. The average moisture content of pelleted seeds is 8.13%, and these results are very satisfactory because, at this moisture level, pelleted seeds are storage stable. Moisture content is considered one of the most important factors influencing seed viability during storage; in general, if the moisture content increases, the shelf life decreases. A high moisture content (≥ 13%) results in fungal growth, while too low a moisture content (<4%) can result in extreme seed desiccation; thus, moisture content between 5 and 13% is generally considered safe for the storage of most seeds (FAO, 2018). The germination of pelleted seeds was 76%, and the values obtained were higher than those determined by the Ministry of Agriculture, Livestock and Supply in Brazil (MAPA, 2019) for tomato seeds, which establishes a minimum germination percentage of 70% for distribution , transportation and commercialization of tomato seeds throughout the Brazilian territory.

• a. Uma solução filmogênica (3% m/v) de amido de mandioca e gelatina deve ser preparada na proporção 1:1 usando água como solvente;
• b. Para o preparo da solução filmogênica, a gelatina deve ser hidratada em água destilada à temperatura ambiente por 1 hora e após esse tempo foi solubilizada à 55 °C por 30 minutos. O amido de mandioca deve ser aquecido à 90 °C por 10 minutos. Por fim, gelatina e amido devem misturados, com agitação contínua em Banho Maria à 90 ºC por 30 minutos até obtenção de uma mistura homogênea;
• c. Numa segunda etapa, todos os outros componentes devem ser incorporados às soluções filmogênicas preparadas (g/100 mL de solução filmogênica): fosfato de rocha (3 - 4 g), tampão fosfato (8,0 - 8,5 mL), casca de aveia (15 - 25 g), glicerol (1 - 2 g) e óleo de neem (10 - 15 gotas);
• d. Os revestimentos devem ser aplicados sobre moldes de silicone com orifícios com cerca de 8 mm contendo as sementes de tomate individualizadas;
• e. Os moldes devem ser secos à temperatura ambiente ou em estufa a 25- 30ºC com circulação de ar por 24 horas, formando as sementes peletizadas no formato arredondado.

[028] Obtaining the biodegradable coating takes place through the following steps:

• The. A film-forming solution (3% m/v) of cassava starch and gelatin should be prepared in a 1:1 ratio using water as the solvent;
• B. For the preparation of the filmogenic solution, the gelatine must be hydrated in distilled water at room temperature for 1 hour and after that time it was solubilized at 55 °C for 30 minutes. Cassava starch must be heated at 90 °C for 10 minutes. Finally, gelatine and starch must be mixed, with continuous agitation in a water bath at 90ºC for 30 minutes until obtaining a homogeneous mixture;
• ç. In a second step, all the other components must be incorporated into the prepared film-forming solutions (g/100 mL of film-forming solution): rock phosphate (3 - 4 g), phosphate buffer (8.0 - 8.5 mL), oatmeal (15 - 25 g), glycerol (1 - 2 g) and neem oil (10 - 15 drops);
• d. The coatings must be applied over silicone molds with holes of about 8 mm containing the individualized tomato seeds;
• and. The molds must be dried at room temperature or in an oven at 25-30ºC with air circulation for 24 hours, forming the pelleted seeds in a round shape.

Claims (2)

Biodegradable coating for pelletizing vegetable seeds, characterized by the production process of a totally biodegradable polymeric coating obtained from raw materials from a renewable source for vegetable seeds; being present in its composition, mostly, the mixture of two biodegradable polymers, starch and gelatin, in addition to the presence of glycerol and vegetable fibers Biodegradable coating for pelletizing vegetable seeds, according to claim 1, characterized by obtaining the biodegradable coating through the following steps:

• a. A film-forming solution (3% m/v) of cassava starch and gelatin should be prepared in a 1:1 ratio using water as the solvent;
• b.For the preparation of the filmogenic solution, the gelatine must be hydrated in distilled water at room temperature for 1 hour and after that time it was solubilized at 55 °C for 30 minutes; Cassava starch must be heated at 90°C for 10 minutes; Finally, gelatine and starch must be mixed, with continuous agitation in a water bath at 90ºC for 30 minutes until obtaining a homogeneous mixture;
• ç. In a second step, all components must be incorporated into the prepared film-forming solutions (g/100 mL of film-forming solution): rock phosphate (3 - 4 g), phosphate buffer (8.0 - 8.5 mL), oat hulls (15 - 25 g), glycerol (1 - 2 g) and neem oil (10 - 15 drops);
• d. The coatings must be applied on silicone molds with holes of about 8 mm containing the individualized tomato seeds;
• e.The molds must be dried at room temperature or in an oven at 25-30ºC with air circulation for 24 hours, forming the pelleted seeds in a round shape