< Crop Kits Biocupe Biocupe is a spore-based biofungicide containing Chaetomium cupreum for foliar and soil use against fungal diseases. Product Enquiry Download Brochure Dual Mode of Action Combats pathogens through substrate competition and enzymatic degradation of host cell walls, boosting natural plant defenses. Broad-Spectrum Disease Suppression Effective against a wide range of pathogens including rust, early scourage, late curse, leaf spot, stem decay, and tuber decay. IPM Compatibility Functions as a valuable component of Integrated Pest Management programs, helping reduce chemical inputs and creating a safer growing environment. Improves Plant Health and Yield Enhances overall plant wellbeing, resulting in higher productivity and profitability. Benefits Content coming soon! Composition Dosage & Application Additional Info Dosage & Application Foliar application Dose: 5g/L water 1 Acre dose: 1kg 1 Ha dose: 2.5kg Additional Info Mode of Action Substrate Competition for space and Nutrients: Chaetomium cupreum colonizes maximum space and absorbs maximum nutrients available at the target site and thereby controls the pathogens by starving them for food and competing for space — Domino effect. Enzyme production: Chaetomium cupreum produces certain enzymes which dissolve the host cell wall and penetrate and inactivate the host defense mechanism. Storage Requirements Store below 40°C in a cool, dry, well-ventilated place. Keep away from sunlight, children, and animals. Do not store in metallic containers. Keep tightly closed when not in use. Handling Precautions Use standard hygiene and safety practices for agricultural products. Related Products Aminomax SP Annomax BioProtek Neem Plus Seed Protek Silicomax Dates Pro BloomX More Products Resources Read all

Looking for mycorrhizal fungi products supplier & manufacturer company in USA? Stop Searching.. Contact +1 437 774 3831 or send email biosolutions@indogulfgroup.com Arbuscular Mycorrhizal Fungi | Trusted Manufacturer & Exporter Even though this idea could seem counter-intuitive, the truth is that the radicular system of a healthy plant does not end with its roots. Not with its own roots, at least. Beyond the roots of the plant itself, a network of fungi expands and brings from the deepest parts of the soil all of the necessary nutrients for the plant’s tasks of producing food and sustaining itself. This type of fungi is called mycorrhizal fungi, from the Greek words ‘mýkes’ and ‘rhiza’; ‘fungus’ and ‘root’ respectively, and these mycorrhizal fungi and plants maintain a mutualistic relationship that goes back millions of years. A symbiotic association between mycorrhiza fungi liquid and plants is established at the root level. To allow two-way nutrition exchange, these mycorrhiza liquids envelop and, in some cases, penetrate the structure of plant roots. Arbuscular mycorrhizal fungi use their mycelium to expand the roots of the plants they interact with, making it easier for them to obtain nutrients, minerals, and water from a greater distance. Photosynthesized sugars are given to the fungus by the mycorrhizal plant in exchange. Some arbuscular mycorrhizal fungi examples are ectomycorrhiza (the fungi responsible for a lot of the mushrooms that can be found in a forest), orchid mycorrhiza (those help orchids and similar plants obtain nutrients from the air), and arbuscular mycorrhiza. Arbuscular mycorrhizal is the most widespread type, occurring in over 85% of all plant families and throughout most crop species. What are the benefits of mycorrhizal associations? Extending the reach of the plant’s roots (often doubling and triplicating them, under favorable conditions) thus increasing not only the depth they can reach but also the amount of surface covered by root mass. Stimulating the absorption of all important nutrients (nitrogen, potassium, iron, manganese, magnesium, copper, zinc, boron, sulphur and molybdenum) by enhancing their availability. Particularly improving the rate of uptake and mobilization of phosphate across all crops, thus reducing phosphorus fertilization requirements. Outcompeting harmful pathogens by rapidly colonizing the roots of the plants, creating a protective barrier against root diseases. Mycorrhizal soil is much harder for pests to colonize, simply because there’s no space for them. Generating an immune response in the plant that, while not killing mycorrhizal fungi, increases the resistance of the plant to future fungal diseases, thus serving as something akin to a ‘plant vaccine’. Producing chemical compounds that attract pest predators when a plant is under attack by pests, mirroring the processes that the plant uses to produce such compounds and boosting predator attraction. Dramatically increasing plant resistance to changing climate and soil conditions such as drought, heat, and even salinity increase. Water absorption, in particular, is enhanced by the mycelia of mycorrhizal fungi serving as root hairs for this purpose. Increasing the overall yield of your plants, by the combined functions of improved nutrient and water absorption and increased resistance to disease and climate conditions. Reducing soil erosion through the production of glomalin by the mycorrhizal fungi, which serves as a binding agent that improves soil structure and increases carbon content. When applied to soil mycorrhizal fungi will produce this protein to coat their hyphae, beneficially releasing it into the ground when they die. A case in practice: mycorrhizal inoculation in corn crops For a simple answer to the question of what are mycorrhizal fungi (and, above all, why do they matter), in the image at left it is possible to see a graphic depiction of how well corn responds to a mycorrhizal fungi inoculation. Arbuscular mycorrhizal fungi grow from within the cells of the roots themselves, serving as ‘branches’ for the expansion of the root system. The fungi associate themselves with the cellular structure of the roots, and begin expanding their hyphae through the soil, bringing nutrients and water to the plant and increasing their reach as their plant host grows stronger and larger. This increases the efficiency with which the plant absorbs the nutrients present in the soil, reducing nutrient runoff and fertilization requirements, as well as improving resistance to drought and disease; ultimately increasing yields and overall plant health. Methods of application of mycorrhizal fungi: The following table provides a basis for how to use arbuscular mycorrhizal fungi in different scenarios, detailing, in particular, the doses required according to each method and to the type of plant being grown (annuals vs. perennials): 1. Application by seed dressing: In an appropriate container for the volume of product required, mix the mycorrhizal inoculant with crude sugar at a proportion of two parts of sugar for one part of mycorrhizal inoculant (for 20-100 kilograms of seed, 100 grams of sugar per 50 grams of mycorrhizal inoculant) insufficient water to make a slurry. Use this liquid preparation to coat the seeds, and allow them to dry in the shade before sowing, casting or dibbling them in the field. Do not store the coated seeds for more than 24 hours before planting. 2. Application directly into soil: Mycorrhizal fungi can be directly applied into the soil through several different strategies, detailed next. Mix the mycorrhizal inoculant with compost at the required dosages, and apply this mixture directly into the soil at the early life stages of the plants, along with any other biofertilizers that may be used. Mix the mycorrhizal inoculant with water at the required dosages, and apply this mixture directly into the soil at the early life stages of the plants, along with any other biofertilizers that may be used. Apply the mycorrhizal inoculant mixed with water under a drip irrigation scheme, filtering out the solution before adding it to the drip tank if any insoluble particles are noticed during its preparation. Use mycorrhizal fungi to boost the continued growth of perennial plants by dissolving the mycorrhizal inoculant in water at the adequate dosage, and drenching the soil where the roots are (for trees, use the drip line as a reference) twice a year. It is recommended to make a first application of this mixture before the onset of the spring, rainfall season or first monsoon, and the second application after the end of the main monsoon, rainfall season or spring season. 3. Application of mycorrhizal fungi as spray. It is recommended that mycorrhizal fungi are applied as close as possible to the roots they will colonize, to ensure maximum effectivity and inoculation rate. If applying as a spray, mix the mycorrhizal liquid at a proportion of 5 milliliters per liter of water, and spray at the drip line of the canopy of the plant. The total volume of the mycorrhizal mixture required may vary depending on the canopy size (and its corresponding drip line). Shelf life and packaging: Shelf life: The product is best before 24 months. Store at room temperature, away from sunlight, heat and humidity. Packaging: The product arrives in a one-kilogram pouch. Relative to plants and their roots, mycorrhizal fungi tend to have a wider temperature tolerance, which may reflect their ability to produce protective compounds. [Read more ] Downloads Product Information Label Information Click here for Product Enquiry Related Articles Let’s take a moment to appreciate the importance of soil inoculants for an organic future It’s no secret that conventionally-cultivated soils tend to become, by themselves, poor. They’re often managed under exploitative... Could mycorrhizal fungi serve as a defense barrier against climate change? The presence of mycorrhizal fungi is a part as vital to sustainable agricultural production as our own intestinal flora is to our nutrition. Mycorrhizal fungi, alongside beneficial bacteria, form the basis of the soil ecosystem and are the first organisms that really break down the nutrients present there into a form that is truly available for plants to use them. But recent research shows that they can also do more: they could be our first line of defense against climate ch

Paracoccus denitrificans is a beneficial bacterium known for its nitrate-reducing properties, specifically its ability to convert nitrate to nitrogen gas. < Microbial Species Paracoccus denitrificans Paracoccus denitrificans is a beneficial bacterium known for its nitrate-reducing properties, specifically its ability to convert nitrate to nitrogen gas. Strength 1 x 10⁸ CFU per gram / 1 x 10⁹ CFU per gram Product Enquiry Download Brochure Benefits Treatment Efficiency Returns alkalinity to the treatment process, supporting efficient wastewater treatment. Groundwater Protection Prevents groundwater pollution by reducing nitrate levels from agricultural or residential fertilizers. Nitrogen Management Reduces inorganic nitrogen to nitrous oxide, aiding in environmental nitrogen management. Water Quality Improvement Removes nitrogen from sewage and municipal wastewater, improving water quality. Dosage & Application Additional Info Scientific References Mode of Action FAQ Scientific References Olaya-Abril, A., Luque-Almagro, V. M., Manso, I., Moreno-Vivián, C., & Roldán, M. D. (2018). Exploring the Denitrification Proteome of Paracoccus denitrificans PD1222. Frontiers in Microbiology , 9, 1137. DOI: 10.3389/fmicb.2018.01137 Bordel, S., Rodríguez, Y., Muñoz, R., & Lebrero, R. (2024). Genome-scale metabolic model of the versatile bacterium Paracoccus denitrificans Pd1222. mSystems , 9(1), e01077-23. DOI: 10.1128/msystems.01077-23 Hahnke, S. M., Moosmann, P., Erb, T. J., & Strous, M. (2014). An improved medium for the anaerobic growth of Paracoccus denitrificans Pd1222. Frontiers in Microbiology , 5, 18. DOI: 10.3389/fmicb.2014.00018 Kumar, S., Ridge, J. P., Arce-Rodriguez, A., Jeuken, L. J. C., Richardson, D. J., & Hough, M. A. (2017). Environmental and Genetic Determinants of Biofilm Formation in Paracoccus denitrificans. Applied and Environmental Microbiology , 83(18), e01350-17. DOI: 10.1128/AEM.01350-17 Olaya-Abril, A., Hidalgo-Carrillo, J., Luque-Almagro, V. M., Fuentes-Almagro, C., Moreno-Vivián, C., Richardson, D. J., & Roldán, M. D. (2021). Effect of pH on the denitrification proteome of the soil bacterium Paracoccus denitrificans. Scientific Reports , 11, 17261. DOI: 10.1038/s41598-021-96559-2 Baumann, B., Snozzi, M., Zehnder, A. J., & van der Meer, J. R. (1996). Dynamics of denitrification activity of Paracoccus denitrificans during changes from aerobic to anaerobic growth conditions and vice versa. Journal of Bacteriology , 178(16), 4678-4687. Giannopoulos, G., Sullivan, M. J., Hartop, K. R., Rowley, G., Gates, A. J., Watmough, N. J., & Richardson, D. J. (2017). Tuning the modular Paracoccus denitrificans respirome to adapt from aerobic respiration to anaerobic denitrification. Environmental Microbiology , 19(12), 4953-4964. Jarman, O. D., Biner, O., Hirst, J., & Sazanov, L. A. (2021). Paracoccus denitrificans: a genetically tractable model system for studying respiratory complex I. Scientific Reports , 11, 10143. DOI: 10.1038/s41598-021-89575-9 Mode of Action Paracoccus denitrificans operates through a sophisticated four-step denitrification pathway that makes it highly valuable for agricultural and environmental applications : pmc.ncbi.nlm.nih+2 Sequential Reduction Process Nitrate → Nitrite: Via nitrate reductase (NAR/NAP) Nitrite → Nitric Oxide: Through cytochrome cd₁ nitrite reductase Nitric Oxide → Nitrous Oxide: Using nitric oxide reductase (NOR) Nitrous Oxide → Nitrogen Gas: Final step via nitrous oxide reductase (NosZ) This complete pathway effectively removes excess nitrogen from soil and water systems, preventing environmental pollution and supporting sustainable agriculture. wikipedia+1 Paracoccus denitrificans demonstrates multiple sophisticated biochemical mechanisms that make it a valuable bacterial species for agricultural and environmental applications: Denitrification Pathway The primary mode of action involves a sequential four-step reduction process under anaerobic conditions: Nitrate Reduction: Membrane-bound nitrate reductase (NAR) and periplasmic nitrate reductase (NAP) convert nitrate (NO₃⁻) to nitrite (NO₂⁻) Nitrite Reduction: Cytochrome cd₁ nitrite reductase (NIR) reduces nitrite to nitric oxide (NO) Nitric Oxide Reduction: Nitric oxide reductase (NOR) converts NO to nitrous oxide (N₂O) Nitrous oxide Reduction: Nitrous oxide reductase (NosZ) completes the pathway by reducing N₂O to nitrogen gas (N₂) This complete denitrification pathway effectively removes excess nitrogen from soil and water systems, preventing environmental pollution and eutrophication. Metabolic Versatility P. denitrificans exhibits remarkable metabolic flexibility: Facultative anaerobe: Can switch between aerobic respiration and anaerobic denitrification Chemolithoautotrophic capabilities: Can utilize various carbon sources including C1 compounds (methanol, formate) Energy conservation: Couples denitrification to ATP synthesis through respiratory chain Enzyme Regulation The bacterium employs sophisticated regulatory mechanisms: FnrP transcription factor: Responds to oxygen levels, activating denitrification genes under anoxic conditions NarR, NirI, and NosR regulators: Specifically control expression of nitrate, nitrite, and nitrous oxide reductase genes Trace element dependency: Requires iron, molybdenum, copper, and zinc for optimal enzyme function Additional Info Shelf Life: Stable within 1 year from the date of manufacturing. Packing: We offer tailor-made packaging as per customers' requirements. Dosage & Application Contact us for more details FAQ Is Paracoccus denitrificans pathogenic? No, Paracoccus denitrificans is completely non-pathogenic to humans, animals, and plants. Research confirms it's classified as a beneficial environmental bacterium with no known health risks. Unlike pathogenic bacteria, it's widely used safely in agricultural applications and bioaugmentation programs. aquaculturesciencemanagement.biomedcentral+1 Key Differences: Paracoccus vs Pseudomonas denitrificans These are distinct bacterial species with different applications : wikipedia+1 Paracoccus denitrificans Alpha-proteobacteria, spherical morphology Environmental nitrogen cycling and soil health Complete denitrification capabilities Agricultural and wastewater treatment applications Pseudomonas denitrificans Gamma-proteobacteria, rod-shaped Industrial vitamin B12 production (up to 198+ mg/L) Pharmaceutical manufacturing Biotechnological applications Environmental Habitat and Distribution Paracoccus denitrificans is ubiquitously distributed across multiple environments : pmc.ncbi.nlm.nih+2 Soil ecosystems: Primary habitat in agricultural and forest soils Wastewater treatment facilities: Naturally occurring in activated sludge Marine environments: Sediments and water columns Plant rhizosphere: Root zone associations Biofilm communities: Surface-attached growth in aquatic systems Industrial Biotechnology Applications Both species have significant biotechnology potential: journals.asm+2 Paracoccus denitrificans Promising cell factory for metabolic engineering Genetic tractability for strain development Bioremediation applications Wastewater treatment systems Pseudomonas denitrificans Major industrial vitamin B12 producer 120,000L fermenter operations Pharmaceutical compound manufacturing Enzyme production systems Environmental Importance Denitrifying bacteria provide critical ecosystem services : indogulfbioag+2 Nitrogen Cycle Regulation Convert excess nitrates back to atmospheric nitrogen Prevent nitrogen accumulation disrupting ecosystems Control nitrogen availability in terrestrial and aquatic systems Pollution Control Remove agricultural nitrate pollution from groundwater Prevent eutrophication and harmful algal blooms Protect water quality and drinking water safety Climate Impact Minimize N₂O greenhouse gas emissions when properly managed Support methane oxidation in aquatic systems Contribute to soil carbon sequestration Is Paracoccus denitrificans pathogenic? No, Paracoccus denitrificans is not pathogenic to humans or plants. It is classified as a non-pathogenic, beneficial environmental bacterium. Research has confirmed that P. denitrificans poses no known health risks and is widely used in agricultural and environmental applications. Unlike some bacterial species that can cause disease, P. denitrificans is considered safe for use in bioaugmentation and soil improvement programs. What is the meaning of Pseudomonas denitrificans? Pseudomonas denitrificans refers to a different bacterial species (now classified as part of the P. pertucinogena group) that was first isolated from garden soil in Vienna, Austria. The name "Pseudomonas" means "false unit" in Greek, while "denitrificans" indicates its ability to perform denitrification. This gram-negative aerobic bacterium is primarily known for its vitamin B12 overproduction capabilities and has been used industrially for cobalamin (vitamin B12) manufacturing. What is the function of Pseudomonas denitrificans? Pseudomonas denitrificans serves several important functions: Vitamin B12 Production: Primary industrial use for manufacturing cobalamin through fermentation Denitrification: Converts nitrate to nitrogen gas under anaerobic conditions Methionine Synthesis: Uses vitamin B12 for amino acid metabolism Biotechnological Applications: Engineered strains are used in pharmaceutical production Environmental Role: Participates in nitrogen cycling in soil ecosystems Where is Paracoccus denitrificans commonly found? Paracoccus denitrificans is ubiquitously distributed in various environments: Soil ecosystems: Most common habitat, particularly in agricultural soils Sewage treatment plants: Naturally occurring in activated sludge systems Marine environments: Found in sediments and water columns Plant rhizosphere: Associates with root zones of various crops Wastewater systems: Thrives in nitrogen-rich industrial effluents Biofilms: Forms surface-attached communities in aquatic environments The bacterium shows particular preference for environments with fluctuating oxygen conditions, making it well-adapted to dynamic agricultural and treatment system environments. How does Paracoccus denitrificans help in the nitrogen cycle? Paracoccus denitrificans plays a critical role as a nitrogen cycle closer through complete denitrification: Primary Functions Nitrate Removal: Converts excess soil nitrates (NO₃⁻) to harmless nitrogen gas (N₂) Pollution Prevention: Prevents nitrate leaching into groundwater and surface water bodies Atmospheric Return: Returns fixed nitrogen back to the atmospheric reservoir Eutrophication Control: Reduces nutrient loads that cause algal blooms in water bodies Environmental Benefits Soil Health: Prevents nitrate accumulation that can harm soil microbiology Water Quality: Reduces nitrogen pollution in aquatic ecosystems Greenhouse Gas Mitigation: Properly managed denitrification minimizes N₂O emissions Sustainable Agriculture: Provides biological nitrogen management solution Is Pseudomonas denitrificans used in vitamin B12 production? Yes, Pseudomonas denitrificans is extensively used for industrial vitamin B12 production. It is one of only two major bacterial strains (alongside Propionibacterium shermanii) used commercially for cobalamin manufacturing. Key aspects include: Production Capabilities High Yield: Can produce up to 198+ mg/L of vitamin B12 in large-scale fermenters Aerobic Process: Produces B12 under oxygen-rich conditions (unlike most B12 producers) Cost-Effective: Uses inexpensive substrates like maltose syrup and corn steep liquor Genetic Engineering: Strains with overexpressed cob genes achieve enhanced production Commercial Applications Pharmaceutical Industry: Primary source for B12 supplements and medications Food Industry: Used in fortified foods and animal feed additives Biotechnology: Research model for cobalamin biosynthesis studies What role does Paracoccus denitrificans play in denitrification? Paracoccus denitrificans is considered a model organism for complete denitrification due to its exceptional capabilities: Complete Pathway Execution All Four Steps: Performs the entire nitrate → nitrite → nitric oxide → nitrous oxide → nitrogen gas sequence High Efficiency: Achieves rapid and complete nitrogen oxide reduction Minimal Intermediates: Produces primarily N₂ with minimal accumulation of harmful intermediates like N₂O Unique Characteristics Respiratory Coupling: Links denitrification to energy generation for growth Oxygen Tolerance: Can perform "aerobic denitrification" under low oxygen conditions Metabolic Flexibility: Uses various organic substrates as electron donors Environmental Adaptation: Functions effectively across wide pH and temperature ranges Applications Wastewater Treatment: Used in biological nutrient removal systems Bioremediation: Cleans up nitrogen-contaminated environments Agricultural Systems: Natural soil denitrification processes Can Pseudomonas denitrificans be used in industrial biotechnology? Yes, Pseudomonas denitrificans has significant industrial biotechnology applications: Current Industrial Uses Vitamin B12 Manufacturing: Primary commercial application in 120,000L fermenters Pharmaceutical Production: Source of therapeutic cobalamin compounds Enzyme Production: Produces industrially relevant dehydrogenases and reductases Metabolic Engineering Platform: Chassis for producing various biochemicals Biotechnology Potential Genetic Tractability: Amenable to genetic modifications and strain improvement Process Optimization: Responds well to fermentation parameter control Substrate Flexibility: Can utilize various carbon sources including waste materials Scale-Up Capability: Successfully operates at industrial production scales Research Applications Cobalamin Pathway Studies: Model for understanding B12 biosynthesis Metabolic Engineering: Platform for producing novel compounds Systems Biology: Well-characterized genome and proteome for systems-level studies How are Paracoccus and Pseudomonas denitrificans different? Paracoccus denitrificans and Pseudomonas denitrificans are distinct bacterial species with different taxonomic classifications and primary functions: Taxonomic Differences Paracoccus denitrificans: Alpha-proteobacteria, spherical (coccoid) morphology Pseudomonas denitrificans: Gamma-proteobacteria, rod-shaped morphology Primary Functions Paracoccus: Environmental nitrogen cycling, complete denitrification, bioremediation Pseudomonas: Industrial vitamin B12 production, pharmaceutical manufacturing Metabolic Characteristics Paracoccus: Versatile carbon source utilization, biofilm formation, soil adaptation Pseudomonas: Specialized cobalamin overproduction, aerobic B12 synthesis Applications Paracoccus: Agriculture, wastewater treatment, environmental remediation Pseudomonas: Pharmaceutical industry, biotechnology, vitamin manufacturing Environmental Roles Paracoccus: Soil health, nitrogen pollution control, ecosystem balance Pseudomonas: Limited environmental role, primarily industrial applications Why are denitrifying bacteria like Paracoccus and Pseudomonas important in the environment? Denitrifying bacteria are essential environmental regulators that provide critical ecosystem services: Nitrogen Cycle Completion Atmospheric Return: Convert excess soil nitrates back to atmospheric nitrogen Cycle Balance: Prevent nitrogen accumulation that would disrupt ecosystem balance Natural Regulation: Control nitrogen availability in terrestrial and aquatic systems Pollution Control Nitrate Remediation: Remove agricultural nitrate pollution from groundwater Eutrophication Prevention: Reduce nitrogen loads causing harmful algal blooms Water Quality Protection: Maintain safe drinking water by controlling nitrate levels Climate Impact Greenhouse Gas Regulation: When properly managed, minimize N₂O emissions Methane Oxidation: Some denitrifiers also consume methane in aquatic systems Carbon Sequestration: Support soil organic matter accumulation through ecosystem health Agricultural Sustainability Soil Health Maintenance: Prevent toxic nitrate buildup in agricultural soils Natural Fertility Cycling: Support sustainable nitrogen management systems Biological Remediation: Provide natural solutions for nitrogen-contaminated sites Ecosystem Services Biodiversity Support: Maintain balanced nutrient cycles supporting diverse communities Habitat Protection: Preserve aquatic and terrestrial ecosystem integrity Resource Conservation: Reduce need for expensive chemical remediation technologies Related Products More Products Resources Read all

Indogulf BioAg is a Manufacturer & Global Exporter of Larvicides for plants, bacillus thuringiensis israelensis, Lysinibacillus Sphaericus & other Bacterias. Contact us @ +1 437 774 3831 < Microbial Species Larvicides Larvicides are highly effective solutions for managing the larval stages of harmful pests in agriculture and public health. By targeting larvae directly, larvicides disrupt pest life cycles, reducing populations and minimizing damage to crops and the environment. These products offer a sustainable and precise alternative to broad-spectrum pesticides, especially when integrated with environmentally conscious farming practices. Product Enquiry What Why How FAQ What it is Larvicides are biological or chemical substances specifically designed to kill insect larvae. In agricultural and pest management contexts, larvicides are crucial for controlling pests that cause significant damage, such as plant hoppers and soil-borne insect pests. Key larvicidal agents include beneficial bacteria like Lysinibacillus sphaericus , Bacillus thuringiensis israelensis , Bacillus popilliae , and Bacillus thuringiensis kurstaki , which provide environmentally friendly pest control solutions. Larvicides are substances or agents specifically designed to kill the larval stage of insects, particularly mosquitoes and other pest species. Larvicides are crucial tools in integrated vector management (IVM) programs aimed at controlling insect-borne diseases such as malaria, dengue fever, and Zika virus. Why is it important Larvicides are biological or chemical substances specifically designed to kill insect larvae. In agricultural and pest management contexts, larvicides are crucial for controlling pests that cause significant damage, such as plant hoppers and soil-borne insect pests. Key larvicidal agents include beneficial bacteria like Lysinibacillus sphaericus , Bacillus thuringiensis israelensis , Bacillus popilliae , and Bacillus thuringiensis kurstaki , which provide environmentally friendly pest control solutions. Larvicides are substances or agents specifically designed to kill the larval stage of insects, particularly mosquitoes and other pest species. Larvicides are crucial tools in integrated vector management (IVM) programs aimed at controlling insect-borne diseases such as malaria, dengue fever, and Zika virus. FAQ What are examples of larvicides? Common examples of larvicides include biological agents such as Bacillus thuringiensis israelensis (Bti) and Bacillus sphaericus , as well as chemical larvicides like methoprene and temephos. Biological larvicides are widely preferred due to their specificity and environmental safety. What is the function of larvicide? The primary function of a larvicide is to control mosquito populations by targeting and killing larvae before they develop into adult mosquitoes. This prevents breeding cycles and reduces the spread of mosquito-borne diseases. What are the forms of larvicides? Larvicides are available in several formulations, including: Tablets or briquettes Granules Liquid concentrates Water-dispersible powders Each form is designed for specific application environments such as standing water, ponds, drains, or large water bodies. Does larvicide kill mosquitoes? Larvicides do not typically kill adult mosquitoes. Instead, they specifically target mosquito larvae in water, preventing them from maturing into biting adults. This makes larvicides a highly effective preventive control method. What is the best chemical to get rid of mosquitoes? The “best” solution depends on the stage of the mosquito lifecycle. For larval control, biological larvicides like Bti are highly effective and environmentally safe. For adult mosquitoes, insecticides may be used, but integrated approaches combining larvicides and environmental management are most effective. What is the best time to apply larvicide? The best time to apply larvicides is early in the mosquito breeding cycle, when larvae are present in standing water. Regular monitoring and application after rainfall or water accumulation ensure optimal control. Are larvicides harmful to humans? Most modern larvicides, especially biological ones like Bti, are considered safe for humans, animals, and non-target organisms when used as directed. They specifically target mosquito larvae and have minimal environmental impact. How to use mosquito larvicide? To use mosquito larvicide effectively: Identify standing water where mosquitoes breed Apply the appropriate formulation (tablet, granule, or liquid) Follow recommended dosage instructions Reapply as needed, especially after rainfall Proper application ensures effective control of mosquito populations at the source. How it works Larvicides employ various modes of action to control mosquito larvae: Larvicides employ various mechanisms to control pest larvae, ensuring precision and effectiveness: Toxin Production : Beneficial bacteria like Bacillus thuringiensis (Bt) produce crystal proteins that disrupt the digestive systems of insect larvae, leading to their death. Bacillus thuringiensis israelensis (Bti), for example, is particularly effective against mosquito larvae, while Bacillus popilliae targets grubs of scarab beetles. Endotoxins and Pathogenicity : Lysinibacillus sphaericus produces highly specific endotoxins that paralyze mosquito larvae, reducing populations in stagnant water bodies and agricultural fields. Soil-Borne Pest Control : Bacterial larvicides combat root-feeding pests, preserving plant root health and promoting crop productivity. Chemical Larvicides : Chemical larvicides, such as synthetic insect growth regulators (IGRs) or organophosphates, disrupt the development of mosquito larvae, preventing them from reaching adulthood. Physical Larvicides : Some larvicides, such as oils or monomolecular films, create a physical barrier on the water surface, suffocating mosquito larvae by blocking their access to oxygen. Integrated Larvicidal Strategies Effective larvicidal programs often involve a combination of larvicides with larval habitat management, community engagement, and surveillance efforts. This integrated approach maximizes the impact of larvicides while minimizing environmental risks and promoting sustainable pest management practices. Larvicides Our Products Explore our range of premium Larvicides tailored to meet your agricultural needs, providing effective control over larvae populations and safeguarding your crops. Bacillus popilliae Bacillus popilliae a beneficial bacterium targeting Japanese beetle grubs. Safe for non-target organisms, no adverse effects on humans or environment. Provides long-term pest control without residue. View Species Bacillus thuringiensis israelensis Bacillus thuringiensis israelensis (Bti) is a naturally occurring bacterium that has revolutionized pest control with its environmentally friendly and highly effective approach. Bti specifically targets the larvae of mosquitoes, blackflies, and fungus gnats, making it an essential tool for managing pests in residential, agricultural, and commercial settings. When applied to breeding sites, Bti releases protein toxins that are ingested by the larvae. These toxins disrupt the larvae's digestive system, leading to their death within hours. Remarkably, Bti’s mechanism of action is species-specific, ensuring that it poses no harm to beneficial insects, plants, animals, or humans. Additionally, it breaks down quickly in the environment, leaving no harmful residues behind. This powerful yet safe solution is a cornerstone in integrated pest management, trusted by professionals worldwide for its ability to protect public health and the environment. From controlling mosquitoes that spread diseases to managing agricultural pests, Bti provides a sustainable alternative to chemical insecticides. View Species Bacillus thuringiensis subsp. kurstaki Bacillus thuringiensis subsp. kurstaki (Btk) is a gram-positive, spore-forming bacterium naturally found in soils worldwide. It is renowned for its specificity and effectiveness in managing lepidopteran pests, particularly during the larval stage. As a biological insecticide, Btk has become a cornerstone of integrated pest management (IPM) and organic agriculture, combining high efficacy with environmental safety. View Species Lysinibacillus sphaericus Lysinibacillus sphaericus, bacterium targeting mosquito larvae and other insect pests like gold-fringed moths and rice stem borers. Safe for non-target species and rapidly degrades in the environment. View Species 1 1 ... 1 ... 1 Resources Read all

Leading manufacturer & exporter of Nitromax Liquid Nano Fertilizer. Enhance plant growth with our advanced, eco-friendly nano technology solutions. < Nano Fertilizers Nitromax A nanotechnology-based nitrogen fertilizer enhancing nutrient availability and plant growth, providing sustainable solutions for smart agriculture and climate change adaptation. Product Enquiry Download Brochure Benefits Contains Non-Ammoniacal Nitrogen Utilizes nitrogen in a form that reduces ammonia emissions. Enhances Protein Content Supports increased protein levels in agricultural products. Improves Crop Output Enhances yield and productivity of crops. Economical Cost-effective solution for agricultural nitrogen needs. Components Composition (%) w/w B 0.20% Total Nitrogen 11.00% Organic Acid 5.80% Amino Acids 0.60% Biopolymers 0.40% Enzymes 0.40% Herbal Extracts 0.30% Aqua q.s. Composition Dosage & Application Why choose this product Key Benefits Sustainability Advantage Additional Info FAQ Additional Info Compatibility: Compatible with chemical fertilizers and chemical pesticides Shelf life: Best before 24 months when stored at room temperature Packaging: 5 Ltx2/Corrugated Cardboard Box Why choose this product? Content coming soon! Key Benefits at a Glance Content coming soon! Sustainability Advantage Content coming soon! Dosage & Application Mix 5-10 ml of Nitromax in one liter of water and spray oncrop leaves at its active growth stages FAQ What is Nitromax? Nitromax is an advanced nanotechnology-based nitrogen fertilizer that revolutionizes plant nutrition through precision nutrient delivery. This liquid formulation contains 25% ammonical nitrogen along with organic acids, amino acids, enzymes, and bioactive compounds encapsulated in nano-scale particles for enhanced bioavailability. indogulfbioag+2 Unlike conventional fertilizers that suffer from low nutrient use efficiency and significant losses, Nitromax utilizes charged nano-particles under 100 nanometers that remain in plant-available ionic form and move systemically through xylem and phloem to reach high-demand plant zones. The product represents a breakthrough in sustainable agriculture, providing smart solutions for climate change adaptation while delivering superior plant growth and yield outcomes. pmc.ncbi.nlm.nih+2 The formulation includes 12.5% organic acids, 15% reducing agents, 10.5% amino acids, and 1% enzymes working synergistically to enhance nitrogen uptake and utilization efficiency. This advanced nano-matrix technology overcomes limitations of conventional fertilizers by improving delivery precision while reducing environmental losses. indogulfbioag+2 What are the benefits of NitroMax? Nitromax delivers multiple agronomic and environmental benefits through its advanced nanotechnology platform: Enhanced Nutrient Efficiency Up to 80% improvement in nutrient use efficiency compared to conventional fertilizers nanodap+1 Multimodal absorption through stomata, cuticle microchannels, and root epidermis ensuring uptake even under stress conditions indogulfbioag Systemic nutrient mobility allowing nutrients to reach high-demand plant zones with minimal metabolic conversion loss indogulfbioag Crop Performance Benefits Significant yield increases with studies showing 10-28% yield improvements across various crops pmc.ncbi.nlm.nih+1 Enhanced chlorophyll content and photosynthetic efficiency leading to improved plant vigor bmcplantbiol.biomedcentral+1 Improved stress tolerance helping plants withstand drought, salinity, and temperature stress hsibv+1 Better root development and overall plant architecture mdpi+1 Environmental Advantages 50% reduction in fertilizer application volumes while maintaining or enhancing yields nanodap+1 Minimized nutrient runoff and groundwater contamination protecting water resources microbiologyjournal+1 Reduced greenhouse gas emissions from decreased fertilizer production and application bmcplantbiol.biomedcentral+1 No residue formation and complete solubility preventing equipment clogging indogulfbioag Economic Benefits Reduced input costs through lower application rates and improved efficiency indogulfbioag+1 Compatible with existing equipment requiring no additional investment indogulfbioag Extended shelf life of 24 months ensuring product stability indogulfbioag What is Nitromax Pro used for? While the specific "Nitromax Pro" formulation details weren't found in the search results, based on the Nitromax nanotechnology platform, advanced nitrogen fertilizers in this category are typically used for: Precision Agriculture Applications High-value crop production including vegetables, fruits, and ornamental plants requiring precise nutrition pmc.ncbi.nlm.nih+1 Protected cultivation in greenhouses and hydroponic systems where nutrient efficiency is critical indogulfbioag Organic farming operations seeking sustainable nitrogen supplementation envirobiotechjournals+1 Specialized Crop Management Stress condition farming in arid, saline, or compacted soil environments where conventional fertilizers fail bmcplantbiol.biomedcentral+1 Intensive cropping systems requiring multiple harvests with sustained soil fertility frontiersin+1 Quality enhancement programs focusing on improved nutritional content and market value academic.oup+1 Professional Growing Operations Commercial vegetable production for leafy greens, tomatoes, peppers, and cucumbers horizonepublishing+1 Fruit orchards requiring consistent nutrition for quality fruit development pmc.ncbi.nlm.nih Nursery and landscape applications for ornamental plant production indogulfbioag Foliar and Root Applications Foliar spray programs for rapid nutrient correction and stress mitigation pmc.ncbi.nlm.nih+1 Drip irrigation systems for precise soil application and root zone nutrition indogulfbioag Seed treatment applications for enhanced germination and early plant vigor indogulfbioag The nanotechnology platform ensures optimal nutrient delivery regardless of soil conditions and provides sustained nutrition throughout the growing cycle, making it suitable for both conventional and precision agriculture operations. The compatibility with chemical fertilizers and pesticides allows for integration into existing crop management programs without disruption. indogulfbioag+2 Related Products Nano Urea Hydromax Anpeekay NPK Nano Boron Nano Calcium Nano Chitosan Nano Copper Nano Iron More Products Resources Read all

Neem extracts from Azadirachta indica contain Azadirachtin, toxic to pests, acting as antifeedant, repellent, and sterilizer. Organic gardeners use it for pest control. < Microbial Species Neem Extracts from Azadirachta Indica Tree Neem extracts from Azadirachta indica contain Azadirachtin, toxic to pests, acting as antifeedant, repellent, and sterilizer. Organic gardeners use it for pest control. Strength 1 x 10⁸ CFU per gram / 1 x 10⁹ CFU per gram Product Enquiry Download Brochure Benefits Environmental Compatibility Neem extracts degrade rapidly, leaving no harmful residues and posing minimal risk to non-target species and ecosystems. Sterilizing Effect on Pests Neem extracts induce sterility in insect pests, reducing their reproductive capabilities and population growth. Insect Repellent Properties Neem extracts, containing Azadirachtin, act as antifeedants and repellents against insect pests, disrupting feeding and reducing infestation. Antifungal Activity Azadirachtin in neem extracts exhibits fungicidal properties, effectively controlling fungal diseases like powdery mildew and leaf rust. Dosage & Application Additional Info Scientific References Mode of Action FAQ Scientific References Content coming soon! Mode of Action Content coming soon! Additional Info Target pests: Aphids, whiteflies, spider mites, powdery mildew, leaf rust Recommended Crops: Cereals, millets, pulses, oilseeds, fibre crops, sugar crops, forage crops, plantation crops, vegetables, fruits, spices, flowers, medicinal crops, aromatic crops, orchards, and ornamentals Compatibility: Compatible with Bio Pesticides, Bio Fertilizers, and Plant growth hormones but not with chemical fertilizers and chemical pesticides. Shelf Life: Stable within 1 year from the date of manufacturing. Packing: We offer tailor-made packaging as per customers' requirements. Dosage & Application Contact us for more details FAQ Content coming soon! Related Products More Products Resources Read all

Post Harvest Treatment - Lactic Cultures is a bio-preservation technique with the use of Lactic Acid Bacteria (LAB). < Microbial Species Post Harvest Treatment Post Harvest Treatments involve biological or chemical methods applied to harvested crops to prevent spoilage, extend shelf life, and maintain quality during storage and transportation. Product Enquiry What Why How FAQ What it is Post-harvest treatments refer to the various techniques and practices employed to preserve the quality, freshness, and shelf life of agricultural produce after harvesting. These treatments aim to minimize post-harvest losses, prevent spoilage, and maintain the nutritional value of fruits, vegetables, grains, and other perishable commodities during storage, transportation, and marketing. Why is it important Extended Shelf Life : Post-harvest treatments help prolong the shelf life of agricultural produce, allowing for longer storage periods and reducing the risk of spoilage and waste. Quality Preservation : Treatments such as washing, waxing, and packaging help maintain the appearance, texture, and flavor of fruits and vegetables, enhancing consumer appeal and marketability. Reduced Economic Losses : By minimizing post-harvest losses due to spoilage, rot, or physical damage, post-harvest treatments contribute to improved profitability and economic sustainability for growers, distributors, and retailers. How it works Types of Post-Harvest Treatments Cleaning and Sanitation : Washing and sanitizing fruits, vegetables, and packaging materials remove dirt, debris, and microbial contaminants, reducing the risk of decay and microbial spoilage. Waxing and Coating : Applying edible coatings or waxes to produce forms a protective barrier that reduces moisture loss, inhibits microbial growth, and enhances the appearance and shelf life of fruits and vegetables. Temperature Management : Cooling and refrigeration slow down physiological processes such as respiration and ripening, preserving the freshness and quality of perishable commodities during storage and transportation. Modified Atmosphere Packaging (MAP) : Packaging produce in controlled atmospheres with reduced oxygen and elevated carbon dioxide levels slows down ripening, inhibits microbial growth, and extends shelf life. Chemical Treatments : Application of fungicides, insecticides, or antimicrobial agents helps control post-harvest diseases, pests, and microbial spoilage, ensuring product quality and safety. Integrated Post-Harvest Management Effective post-harvest management involves the integration of multiple treatments and practices tailored to specific crops, storage conditions, and market requirements. By adopting a holistic approach to post-harvest handling, growers and stakeholders can maximize product quality, minimize losses, and meet consumer demand for fresh, safe, and nutritious food. FAQ Content coming soon! Post Harvest Treatment Our Products Explore our range of premium Post Harvest Treatment options tailored to meet your agricultural needs, extending shelf life and preserving quality from harvest to market. Lactic Cultures Lactic Cultures use Lactic Acid Bacteria (LAB) to preserve freshness post-harvest by producing antimicrobial compounds that inhibit harmful microorganisms. View Species 1 1 ... 1 ... 1 Resources Read all

< Crop Kits Stem Borers Stem borers damage rice stems, leading to lodging and yield loss. Effective pest management is crucial for healthy crop development. Product Enquiry Download Brochure Benefits Composition Dosage & Application Additional Info Dosage & Application Additional Info Related Products Aminomax SP Annomax BioProtek Biocupe Neem Plus Seed Protek Silicomax Dates Pro More Products Resources Read all

Leading manufacturer & exporter of Nano Manganese Fertilizers. Boost crop health with advanced nano technology. Quality guaranteed for global markets. < Nano Fertilizers Nano Manganese Nano manganese particles, essential for plant growth and enzyme functions, offering a high surface area for efficient absorption, promoting optimal plant development. Product Enquiry Download Brochure Benefits Enzyme Cofactor Manganese is an important cofactor of enzymes involved in isoprenoid biosynthesis, supporting various metabolic pathways essential for plant growth, development, and defense mechanisms. Essential for Photosynthesis Manganese serves as an essential cofactor for the oxygen-evolving complex (OEC) of the photosynthetic machinery, catalyzing the water-splitting reaction in photosystem II (PSII), which is the first step of photosynthesis. Promotes Photosynthesis As the causant of the water-splitting reaction in PSII, Mn directly contributes to the efficient functioning of photosynthesis, ensuring optimal energy production for plant growth and development. Supports Metabolic Processes Mn sustains metabolic roles within different plant cell compartments and plays a crucial role in diverse processes of a plant's life cycle, including photosynthesis, respiration, scavenging of reactive oxygen species (ROS), pathogen defense, and hormone signaling. Components Composition (%) w/w Manganese as Mn 1.75% Citric Acid 20% Lysine 2.50% Preservatives 0.15% Emulsifiers 0.50% Composition Dosage & Application Why choose this product Key Benefits Sustainability Advantage Additional Info FAQ Additional Info Compatibility: Compatible with chemical fertilizers and chemical pesticides Shelf life: Best before 24 months when stored at room temperature Packaging: 5 Ltx2/Corrugated Cardboard Box Symptoms of Manganese Deficiency: Yellowing between leaf veins (interveinal chlorosis) Mottled or spotted leaves Poor fruit set Stunted growth Why choose this product? Content coming soon! Key Benefits at a Glance Content coming soon! Sustainability Advantage Content coming soon! Dosage & Application Leaf development – until beginning of stemelongation: 500–1250 ml/Ha• Beginning of inflorescence development:625–1750 ml/Ha FAQ Content coming soon! Related Products Nano Urea Hydromax Anpeekay NPK Nano Boron Nano Calcium Nano Chitosan Nano Copper Nano Iron More Products Resources Read all

Soil Fertilizers Manufacturer & Exporter in USA, our product helps stimulate the growth of the plants and preserve the delicate microbiology of the soil. Call us Soil Fertilizers Enrich Your Soil, Enrich Your Harvest Our Soil Fertilizers are designed to replenish essential nutrients and enhance soil fertility, providing plants with the nourishment they need for vigorous growth and abundant yields. Formulated with premium-quality ingredients, including organic matter and micronutrients, our fertilizers promote soil health, improve soil structure, and support sustainable agriculture practices. Contact us What Why How FAQ What it is We specialize in soil fertilizer products meticulously formulated to deliver precise nutrient concentrations, ensuring optimal plant nutrition and growth. Our fertilizers are designed to minimize waste and environmental impact while enhancing soil health. Enriched with beneficial bacteria, known as ‘plant probiotics,’ they promote robust plant growth and consistently yield superior results. Why is it important Nutrient Supply: Fertilizers provide essential nutrients like nitrogen (N), phosphorus (P), and potassium (K) that are crucial for plant growth Improved Yield: Regular use of fertilizers can significantly increase crop yield and quality Soil Health: Organic fertilizers improve soil structure, aeration, and water retention, promoting healthy root systems Sustainable Farming: Using the right fertilizers can reduce the need for chemical inputs, supporting more sustainable agricultural practices How it works Nutrient Addition Fertilizers add nutrients directly to the soil. These nutrients are taken up by plant roots and used for growth and development. For example, nitrogen promotes leaf and stem growth, phosphorus supports root development and flowering, and potassium enhances overall plant health and disease resistance. Soil Conditioning Organic fertilizers, such as compost or manure, improve soil structure by increasing organic matter content. This enhances soil aeration and water-holding capacity, creating a better environment for root growth and microbial activity. Nutrient Transformation Some fertilizers contain microorganisms that transform soil nutrients into forms that are more easily absorbed by plants. For example, certain bacteria fix atmospheric nitrogen, converting it into a usable form for plants. Other microbes can solubilize phosphate, making it available for plant uptake. Hormone Production Certain bio-fertilizers contain substances that stimulate plant growth hormones. These hormones can promote root growth, improve stress resistance, and enhance nutrient uptake efficiency. Biopesticidal Effects Some fertilizers, particularly organic ones, contain natural compounds that can suppress harmful soil pathogens and pests, reducing the need for chemical pesticides. FAQ What are soil fertilizers? Soil fertilizers are substances added to soil to supply essential nutrients required for plant growth, such as nitrogen (N), phosphorus (P), and potassium (K). They can be organic (compost, manure) or inorganic (synthetic fertilizers) and are used to improve soil fertility and crop productivity. What is a soil amendment? A soil amendment is any material added to soil to improve its physical properties, such as structure, aeration, water retention, and drainage. Unlike fertilizers, amendments may not directly provide nutrients but enhance the soil environment for better plant growth. What is a soil conditioner? A soil conditioner is a type of soil amendment specifically designed to improve soil structure and microbial activity. It helps loosen compacted soil, enhance root penetration, and increase nutrient availability. What are the top 3 fertilizers? The three primary fertilizers are: Nitrogen (N) – promotes leaf and vegetative growth Phosphorus (P) – supports root development and flowering Potassium (K) – enhances overall plant health and stress resistance These are commonly referred to as NPK fertilizers. What is the best fertilizer for soil? The best fertilizer depends on soil type and crop needs. Generally, a balanced fertilizer combined with organic matter and beneficial microbes provides the most sustainable results by improving both nutrient availability and soil health. Can I just sprinkle fertilizer on top of soil? Yes, fertilizers can be surface-applied (top-dressed), but effectiveness depends on proper watering and timing. For best results, fertilizers should be lightly incorporated into the soil or followed by irrigation to ensure nutrient absorption and minimize losses. What is used to fertilize soil? Soil can be fertilized using: Organic materials (compost, manure, biofertilizers) Mineral fertilizers (NPK blends) Liquid fertilizers Microbial inoculants Each option supports plant nutrition in different ways. What is fertilizing soil? Fertilizing soil is the process of adding nutrients or biological inputs to improve soil fertility and support plant growth. It ensures that plants receive essential elements required for development and productivity. What is the best fertilizer for acidic soil? For acidic soils, lime-based amendments combined with balanced fertilizers are commonly used to raise pH and improve nutrient availability. Organic matter and microbial solutions can further enhance soil buffering capacity. What is the best fertilizer for alkaline soil? In alkaline soils, fertilizers that supply micronutrients like iron, zinc, and sulfur are effective. Organic inputs and biofertilizers also help improve nutrient uptake and soil structure. What is the fastest way to amend soil? The fastest way to amend soil is by incorporating well-decomposed compost, organic matter, or liquid soil conditioners. These materials quickly improve soil structure, moisture retention, and microbial activity. What are the types of soil amendments? Common types include: Organic amendments (compost, manure, biochar) Inorganic amendments (lime, gypsum) Biological amendments (microbial inoculants) Each type serves different functions in improving soil quality. What is another name for a soil amendment? Soil amendments are also commonly referred to as soil conditioners or soil improvers, depending on their function and composition. What is the difference between soil amendments and fertilizers? Fertilizers primarily supply nutrients to plants, while soil amendments improve the physical and biological properties of soil. Both are essential, but they serve different roles in plant growth and soil management. Soil Fertilizers Our Products Explore our range of premium Soil Fertilizers tailored to meet your agricultural needs, enriching soil fertility and promoting optimal nutrient availability for robust plant growth and development. Bio-Manna Organic manure with beneficial bacteria for effective nitrogen and phosphorus fixing, enriched with nutrients for better root and shoot growth. View Product Bio-Manure An all-purpose organic plant feed that improves plant health and yield. It is molasses-based and enhances crop cycle efficiency. View Product Fermogreen Bio fertilizer with plant-extracted nutrients and soil bacteria. Enhances soil aeration and texture, improving root health and nutrient uptake. View Product Neem Powder The residue from crushed Neem seed kernels used for oil extraction. It contains high levels of nutrients like NPK, nortriterpenoids, and isoprenoids. View Product Revive Bio Bio-fertilizer with nitrogen-fixing bacteria. Available in powder form, reduces the need for fertilizers and provides balanced nutrition for superior crop production. View Product 1 1 ... 1 ... 1 Resources Read all