Agroplasma Technology
AGROPLASMA TECHNOLOGY
The products contain proteins, natural amino acids, cytokinin, auxin, algae cells/soil extract, and a complete formula of natural nutrients. ICE (intercellular exchange) technology will transfer all nutrients to plant cells immediately. This new technology is designed to improve yield in quality and quantity, and to grow stronger and healthier crops.
The unique feature of the different cells used in Agroplasma technology is that they have the ability to consume large amounts of nutrients. The cells store nutrients in biological form and recreate in their own body nutrients, such as proteins, amino acids, trace elements and vitamins. The complex formula of our products also includes soil/water cell extracts, a complete nutritional formula and naturally prepared materials that will be used during the different stages of the crops.
Studies have shown that plant systems are stimulated in treated plants, resulting in greater root mass, greater leaf area, greater number of flowers, fruit and early ripening.
Unique product with advanced technology that is composed of 16 unicellular algae and types of bacteria that penetrate the leaf instantly. In addition, it stabilizes auxins and cytokinins within the plant, which is important for plant growth and for producing a homogeneous crop.
It is 100% natural and we recommend using any fertilization program to obtain a superior crop, a more homogeneous product and a better size and sale price.
The conditions required for cytoplasmic transmission are:
A functional connection system between two cells:- plasmadesmata (cytoplasm chains). A surrounding medium of lower concentration than the two cells. The diluted intercellular space or soil solution.
A difference in plasma concentration in two adjacent cells:- Agroplasma cells and plant cells.
Agroplasma product cells are considerably more concentrated than the surrounding solution. Leaf cells contain a solution that is considerably less concentrated than Agroplasma cells. This difference in concentration initiates the intercellular exchange of nutrients in the leaves of the plant. The same process applies to the transfer of nutrients to the root of the plant when it is in the soil. Here, the Agroplasma cell is associated with root hairs and the plasma medium enters the soil solution in the immediate vicinity of the hairs.
Although cells appear to be self-contained units, there are tiny pores in the cell wall, through which cytoplasm chains can pass. These strands, called plasmadesmata, play a vital role in providing an interconnection between adjacent cells such that the cytoplasm is continuous between the cells.
CYTOPLASM CURRENT
Cytoplasmic transmission, or intercellular exchange (ICE), is the mechanism by which the movement of nutrients occurs in plant cells. ICE is most active in living young cells, particularly those found in the leaves and roots.
GRAPHICAL VIEW OF INTERELULAR EXCHANGE
If we magnify the sheet and represent it in a three-dimensional section, we would see that it is composed of cells, pores and space for air and water. If we focus our sight on the pore of a leaf, or stomata, the Agroplasma cell is smaller than the stomata and, therefore, can enter the leaf of the plant when foliar is applied. It passes through the stomata to spaces around the various leaf cells known as spongy layers. These spaces are occupied with a diluted solution of nutrients and air. It is here that the unique benefits of Agroplasma are realized, since the nutrients are transferred to the plant. Transfer is a phenomenon known as the Pressure Transfer Phenomenon or cytoplasmic transmission.
GRAPHIC VIEW OF CYTOPLASM STREAMING
Nutrients will flow from high concentration areas to low concentration areas to achieve balance.
Nutrient-rich Agroplasma cells transfer the cytoplasm to nutrient depleted leaf cells, which in turn are transferred to other cells and parts of the plant for storage, growth, regeneration and reproduction.
TRANSFER OF NUTRIENTS IN SOIL APPLICATIONS
Agroplasma cells in the soil will also unlock nutrients in the soil and transfer them to the plant. The result will be a diffusion of water in the Agroplasma cell from the leaf cell. The Agroplasma cell, which contains cytoplasm with its nutrients, will be transported in a mass flow to the leaf cell. The mass flow will cease when sufficient nutrients have been moved from the Agroplasma cell to the leaf cell to balance the concentration of both solutions.
The probable scenario, after achieving this balance, is that the Agroplasma cell will die and release the remaining nutrients in the intercellular medium or soil solution. These nutrients are available for diffusion through the cell membrane by active transport.
WHY Ecoganic SHOULD BE AN INTEGRAL PART OF YOUR PROGRAM?
Agroplasma is not only a source of nutrients, but also helps the plant use the nutrients in the leaf tissue and soil more effectively. The intercellular exchange capacity within plant cells means that their response rate, in terms of plant growth, is greatly improved. You will see a better root structure, more superior growth and higher yields with more homogeneous fruits and longer shelf life.