NOT JUST ANY CARBOHYDRATES, BUT THE RIGHT ONES FOR YOUR PLANTS
Carboloading your plants requires a specialty formula. In actuality, your plants best absorb simple or complex carbohydrates when they are present as
Arabinose, Dextrose, Glucose, Maltose and Xylose from Raw Cane Extract, Malt Extract, Cranberry Extract and other premium carbohydrate sources. (All different sources of Sugar.)
Not only does this end mid-bloom slump but these materials fuel beneficial bacteria and fungi in your root zone.
When you've installed beneficial bacteria and fungi in your root zone, they thrive best when they have externally-provided carbos to feed on. (we all know that fungi and bacteria like different types of sugar.)
Beneficial bacteria and fungi increase root mass, increase nutrient absorption, protect roots, and produce hormones that stimulate floral size, potency and value.
So now that you've seen how to use the right kinds of carbos to provide energy and root enhancement, what else can you do to create gourmet flowers with enhanced taste, size, potency, and aroma?
As it turns out, by providing the list of carbo sources we just discussed, you're also enhancing the taste and aroma of your plants.
THE BENEFITS OF USING AMINO ACIDS AND OTHER COMPOUNDS IN THE CORRECT FORM FOR YOUR PLANTS
Here's something else to keep in mind: the advantages provided by what you feed your crops depends on the quality of specific ingredients in the products.
For example, you see hydroponics formulas that contain "molasses." But as with almost every individual ingredient in hydroponics formulas, there are many grades and types of molasses, and the differences between them decide whether they will deliver your bigger, better yields.
Fact is, most types of molasses are loaded with sulphur or made from materials or processes that lower their sugar content and quality.
When sulphured, low-grade molasses are in a hydroponics formula, its extraneous minerals throw off your nutrient ratios while providing smaller percentages of sugars.
Now take a minute and let me show you how this relates to the types and forms of amino acids in hydroponics formulas.
Amino acids are crucial building blocks for proteins that fuel metabolic processes and physical structure in your flowering plants. Few hydroponics formulas contain amino acids, but almost all the ones that have aminos provide them in a form called "D-Aminos."
Although these aminos are cheaper to source and manufacture, they unfortunately are not very helpful to your plants.
On the other hand, the L-form of amino acids is totally biologically available for rapid uptake and formation of proteins that rapidly increase your crop health and yield.
(Amino Acids
Crops
Identification
Chemical Names:
The model used to illustrate amino acids used in crop production is glycine, or aminoacetic acid. Other Names:
See attached list for the amino acids most often found in protein. The model amino acids for crop production is glycine.
Characterization
Specific Uses:
Chelating / complexing agents for cation nutrients, plant growth regulators, substrate for microbiological products, fertilizer source of nitrogen.
Action:
Plant uptake of metal nutrients are a function of the absolute levels, relative levels to each other, soil pH, oxidative state, and solution. The amino acids found in soil organic matter help protect metal cations from harmful reactions with plants and help to regulate plant uptake (Brady, 1974). A number of synthetic compounds have been developed to mimic this natural phenomenon. When a single ligand binds to a cation, that cation is considered 'complexed.' If a metal cation is joined with an organic compound at two or more exchange sites to form a ring structure, then that structure is considered a metal chelate (Meister, 1999). Two amino acids will bind to a metal to form a chelate (Ashmead et al, 1986). Chelation makes otherwise unavailable compounds plant available under normal pH conditions (AAPFCO, 1998). Chelated nutrients are more plant available than complexed nutrients, and complexed nutrients are more plant available than uncomplexed nutrients. Other amino acids used to complex or chelate cation micronutrients include lysine, glutamic acid (Miller, 1998), cysteine, and histidine (Baker and Ammerman, 1995).
AminoethoxyVinylGlycine (AVG) is used as a plant growth regulator to slow the maturation process of pome fruit by temporarily suppressing ethylene production. Other amino acids used as plant growth regulators include L-glutamic acid and gamma amino butyric acid (GABA). These act by stimulating nutrient uptake.
All amino acids have the potential to decompose into amines that can go into solution as plant-available nitrogen. Glycine appears to be the most used as a fertilizer source.
Combinations:
The metal cations most often chelated are calcium, copper, iron, magnesium, manganese, potassium, and zinc. These are usually in sulfate or occasionally in oxide form. Many formulations will be combined with synthetic fertilizers. For example, the combination of amino acid chelated nutrients with urea enhanced nutrient uptake (Ashmead, 1986).
When used as plant growth regulators, amino acids are combined with various inert ingredients used as surfactants, dispersants, carriers, fillers, spreader-stickers, and wetting agents. Many of these are synthetic. In turn, glycine and other amino acids may be included as inert ingredients in biorational pesticide formulations as part of a culture media used to grow certain microbial products.
Various complex protein sources may be decomposed into amino acids that are then turned into available nitrogen sources. Certain commercial formulations of soil amendments and foliar feeds claim 'amino acids' on the label when they are in fact using denatured protein sources such as blood meal, fish meal, whey, soy isolate or other plant or animal by-product.
Different amino acids may serve as the base for certain pesticides. For example, glycine combined with methyl phosphonate forms the herbicide glyphosate (Meister, 1999).
Status
OFPA
May be considered non-synthetic from certain sources. Not clear if synthetic amino acids fit into any exempted category for use in plant crop production, except perhaps as chelating agents for micronutrients and inert ingredients, such as nutrients in fermentation substrates for naturally occurring microorganisms. Regulatory
Chelating agents for micronutrients regulated by state plant food control officials (AAPFCO, 1998). Plant growth regulator use is EPA regulated under the Federal Insecticide, Fungicide and Rodenticide Act (FIFRA--7 USC 136 et seq.). GABA and L-glutamic acid are considered to be reduced risk pesticides by EPA (EPA, 1998).
Status among Certifiers
Amino acids are not restricted separately from the other generic categories in which they appear. For example, those used as chelating agents for micronutrients are regulated as micronutrients. Plant growth regulators from non-synthetic sources are often restricted.
Historic Use
The greatest and longest-standing use of amino acids in organic production has been as chelating or complexing agents for micronutrients used for documented deficiencies. Several certifiers have accepted the use of amino acids as chelating agents and plant growth regulators under the assumption that they are non-synthetic.
***THIS ISN'T MY WORK. THE WHOLE ARTICLE WAS FOUND HERE-http://www.omri.org/Amino_acid_crops.html ***
Effect Of Amino Acids On Plants Agriculture production is a very intensive business and is related to better quality and better yield leading to better profitability. Every Farmers dreams to achieve this goal. However to achieve this goal with advancement of technology, use of fertilizer and pesticides is not adequate. Now is the time to look at Bioenergetics and Biochemical aspects of plants, to achieve the goals of Farmerss. Every plant like any organism needs certain components for growth over and above soil, sun, rain and air. The basic component of living cells is Proteins, with building block material, Amino Acids. Proteins are formed by sequence of Amino Acids. Plants synthesize Amino Acids from the Primary elements, the Carbon and Oxygen obtained from air, Hydrogen from water in the soil, forming Carbon Hydrate by means of photosynthesis and combining it with the Nitrogen which the plants obtain from the soil, leading to synthesis of amino acids, by collateral metabolic pathways. Only L-Amino Acids are part of these Proteins and have metabolic activity. The requirement of amino acids in essential quantities is well known as a means to increase yield and overall quality of crops. The application of amino acids for foliar use is based on its requirement by plants in general and at critical stages of growth in particular. Plants absorb Amino Acids through Stomas and is proportionate to environment temperature. Amino Acids are fundamental ingredients in the process of Protein Synthesis. About 20 important Amino Acids are involved in the process of each function. Studies have proved that Amino Acids can directly or indirectly influence the physiological activities of the plant. Amino Acids are also supplied to plant by incorporating them into the soil. It helps in improving the microflora of the soil thereby facilitating the assimilation of nutrients. Foliar Nutrition in the form of Protein Hydrolysate (Known as Amino Acids Liquid) and foliar spray provide readymade building blocks for Protein synthesis.
Protein Synthesis Proteins have a structural function, metabolic function (enzymes), a transport function and a stock of Amino Acids function. Only L - Amino Acids are assimilated by plants. D - Amino Acids are not recognised by the enzymatic locus and therefore can not participate in protein synthesis.
Hence Amino Acids obtained by organic synthesis are not well assimilated. Stress Resistance
Stress such as High temperature, Low humidity, Frost, Pest attack, Hailstorm, Floods have a negative effect on plant metabolism with a corresponding reduction in crop quality and quantity.
The application of Amino Acids before, during and after the stress conditions supplies the plants with Amino Acids which are directly related to stress physiology and thus has a preventing and recovering effect. Effect of Photosynthesis
Plants synthesize carbohydrates by photosynthesis, Low photosynthesis rate implies a slow growth leading to death of the plant, chlorophyll is the responsible molecule for the absorption of the light energy.
Glycine and Glutamic Acid are fundamental metabolites in the process of formation of vegetable tissue and chlorophyll synthesis.
These Amino Acids help to increase chlorophyll concentration in the plant leading to higher degree of photosynthesis. This makes crops lush Green.
L-Glutamine and L-Glycine are used for healthy veg. L-Alanine, L-Valine and L-Leucine improve fruit quality. L-Histidine helps in proper fruit ripening)
As with molasses and other ingredients in hydroponics formulas, it matters a lot what forms and manufacturing processes are used.
SWEETER FLOWERS ARE WORTH MORE
Sweeter flowers are yours when you boost your crop's taste, potency and aroma by furnishing anthocyanins, isoflavonoids, polyphenols, isoterpenes and tannins found in cranberry and grape extracts. (And here we have the Fermented Plant Extracts (organic people feel free to chime in on FPEs)...which as we all know are plants with different HORMONES and enzymes being broke down. Lot of different chemicals and diff things working there)
Growers using these compounds report that a sudden bouquet of pleasant scent arises from their flowers within moments of the compounds being fed to plants in water.
And after harvest, you and your friends will enjoy the extra-sweet aroma and taste that your flowers provide, and there'll be more flowers to enjoy too.
Another technique for upgrading the aroma, taste and value of your crop is to feed vitamins to your plants.
For example, Vitamin C stimulates photosynthesis and cell replication while also protecting your plants from negative effects of intense light and heat. To go along with Vitamin C, studies show that feeding your plants B vitamins provides many flower-boosting benefits while also protecting crops from stress.
(In aerobic organisms, the citric acid cycle is part of a metabolic pathway involved in the chemical conversion of carbohydrates, fats and proteins into carbon dioxide and water to generate a form of usable energy. Other relevant reactions in the pathway include those in glycolysis and pyruvate oxidation before the citric acid cycle, and oxidative phosphorylation after it. In addition, it provides precursors for many compounds including some amino acids and is therefore functional even in cells performing fermentation.wiki)
So how can you get this extensive menu of crop-boosting compounds you've just found out about? Fortunately,
Advanced Nutrients scientists have successfully managed the complex task of sourcing, processing, and combining all these aminos, carbs, and vitamins so
Bud Candy delivers bigger, sweeter buds to you right away.