Hydrogen peroxide is definitely acknowledged to contain wide range of advantages - typically it has been frequently known as successful against a huge array of micro-organisms, is a superb virucide and breaks down into water and oxygen. However, it has a serious drawback and that is it's out of control response as soon as it comes into contact with micro-organisms as well as organics - it means that it is actually not effective and that there is a lot waste. Aquaza overcams this problem.
This document describes a 6-in-1 product that provides hospital-grade disinfection, eliminates odors, kills mold and mildew, eliminates allergens, kills and prevents biofilms, and can be used as a no-rinse sanitizer. It works by using chlorine dioxide to selectively oxidize viruses, bacteria, and other microbes. It is effective against a wide range of pathogens and does not require personal protective equipment.
Hydra Re-Gen is a product that fabricate three performance to your septic system. The product is effecient in clearing blocked drains, removes bad septic smells and effectively meet the expense of aerobic bacteria fight in system. Get more details here: http://septo-air.com/clearing-blocked-drains.html
This document summarizes key microorganisms commonly found in water and discusses water purification methods. It describes several pathogens like Cryptosporidium, Giardia lamblia, Hepatitis A, Legionella, and Anabaena sp. that can contaminate water and cause illness. It also mentions other microbes like rotifers, copepods, E. coli, and fungi that may be present. Water quality indicators like turbidity and different types of bacteria are discussed. Methods for purifying water include separation techniques, filtration, oxidation, and a history of food preservation is provided.
This document discusses microorganisms found in water bodies. It describes that water habitats macroorganisms like fish and microorganisms like bacteria, viruses, and protozoa. Several pathogens that can be transported through water and infect humans are discussed, including bacteria like E. coli and Legionella, parasites like Giardia and Cryptosporidium, and the protozoan Toxoplasma gondii. The document also covers viruses, fungi, algae and other microbes found in water.
This presentation includes;
1.INTRODUCTION to Algae
2.HABITAT of Algae
3.SELECTION OF SOURCE- soil & Water
4.ENRICHMENT OF CULTURE- parameters
5.ISOLATION TECHNIQUES:
Establishing Unialgal culture- 6 types
Establishing Axenic culture- 4 steps
4.ISOLATION OF ALGAE FROM WATER- protocol
5.ISOLATION OF ALGAE FROM SOIL- protocol
6.CONCLUSION AND DISCUSSION
7.Reference books
This document discusses microbiology in water. It describes common waterborne pathogens like E. coli, Salmonella, Cryptosporidium, and Giardia lamblia. It also discusses indicator bacteria used to test drinking water quality, including coliform bacteria. Total coliforms are often found naturally but fecal coliforms and E. coli specifically indicate fecal contamination. Tests are used to isolate and enumerate coliforms to determine compliance with EPA guidelines of less than 1 CFU per 100 ml. The document also discusses limitations of different indicators and notes alternatives used for recreational waters.
This document describes a 6-in-1 product that provides hospital-grade disinfection, eliminates odors, kills mold and mildew, eliminates allergens, kills and prevents biofilms, and can be used as a no-rinse sanitizer. It works by using chlorine dioxide to selectively oxidize viruses, bacteria, and other microbes. It is effective against a wide range of pathogens and does not require personal protective equipment.
Hydra Re-Gen is a product that fabricate three performance to your septic system. The product is effecient in clearing blocked drains, removes bad septic smells and effectively meet the expense of aerobic bacteria fight in system. Get more details here: http://septo-air.com/clearing-blocked-drains.html
This document summarizes key microorganisms commonly found in water and discusses water purification methods. It describes several pathogens like Cryptosporidium, Giardia lamblia, Hepatitis A, Legionella, and Anabaena sp. that can contaminate water and cause illness. It also mentions other microbes like rotifers, copepods, E. coli, and fungi that may be present. Water quality indicators like turbidity and different types of bacteria are discussed. Methods for purifying water include separation techniques, filtration, oxidation, and a history of food preservation is provided.
This document discusses microorganisms found in water bodies. It describes that water habitats macroorganisms like fish and microorganisms like bacteria, viruses, and protozoa. Several pathogens that can be transported through water and infect humans are discussed, including bacteria like E. coli and Legionella, parasites like Giardia and Cryptosporidium, and the protozoan Toxoplasma gondii. The document also covers viruses, fungi, algae and other microbes found in water.
This presentation includes;
1.INTRODUCTION to Algae
2.HABITAT of Algae
3.SELECTION OF SOURCE- soil & Water
4.ENRICHMENT OF CULTURE- parameters
5.ISOLATION TECHNIQUES:
Establishing Unialgal culture- 6 types
Establishing Axenic culture- 4 steps
4.ISOLATION OF ALGAE FROM WATER- protocol
5.ISOLATION OF ALGAE FROM SOIL- protocol
6.CONCLUSION AND DISCUSSION
7.Reference books
This document discusses microbiology in water. It describes common waterborne pathogens like E. coli, Salmonella, Cryptosporidium, and Giardia lamblia. It also discusses indicator bacteria used to test drinking water quality, including coliform bacteria. Total coliforms are often found naturally but fecal coliforms and E. coli specifically indicate fecal contamination. Tests are used to isolate and enumerate coliforms to determine compliance with EPA guidelines of less than 1 CFU per 100 ml. The document also discusses limitations of different indicators and notes alternatives used for recreational waters.
Water is the medium of life and covers 71% of the Earth's surface. It exists in various forms such as atmospheric water, surface water, ground water, fresh water, marine water, and estuarine water. The document discusses the types of microorganisms found in water such as viruses, bacteria, protozoa, fungi and algae. It describes various waterborne diseases caused by these microorganisms and their symptoms. The aquatic environment influences the microbial population with factors like temperature, hydrostatic pressure, light, salinity, turbidity, and pH varying widely between streams, estuaries and oceans.
Microbial contamination of pharmaceutical products can lead to spoilage or health hazards. Contamination can occur during manufacturing from water, the environment or packaging. It can be prevented through good manufacturing practices and controlling moisture, temperature, pH and packaging design. Spoilage results from microbial growth and causes product deterioration or infection. Factors influencing spoilage include the contaminant type/level, nutrients, moisture, temperature, pH and packaging. Strict control of these factors is needed to prevent issues.
1) The document discusses using genetically engineered endophytic bacteria to aid in the phytoremediation of soils contaminated with heavy metals and organic pollutants.
2) It focuses on using the endophytic bacterium Burkholderia cepacia, engineered to degrade toluene, to help yellow lupine plants remediate toluene-contaminated soil.
3) The results showed that lupine plants inoculated with the engineered B. cepacia strain had the lowest evapotranspiration of toluene compared to control plants and plants inoculated with other B. cepacia strains.
To study the effect of guava leaf extract on biofilm formation in Pseudomonas...iosrjce
IOSR Journal of Dental and Medical Sciences is one of the speciality Journal in Dental Science and Medical Science published by International Organization of Scientific Research (IOSR). The Journal publishes papers of the highest scientific merit and widest possible scope work in all areas related to medical and dental science. The Journal welcome review articles, leading medical and clinical research articles, technical notes, case reports and others.
Water microbiology is the study of microorganisms in water environments. Various types of water contain diverse microbes including viruses, bacteria, protozoa, fungi and helminths. Many microbes can cause water-associated diseases classified as water-borne, water-washed, water-based or water-related depending on the transmission route which may involve ingesting contaminated water, poor hygiene, an aquatic host or an insect vector. Common pathogenic microbes found in water are various bacteria and viruses that can cause diarrhea, hepatitis, polio and typhoid as well as parasitic protozoa like Giardia and Plasmodium which causes malaria.
Lect. 2 (economic significance of microorganisms)Osama Rifat
Microorganisms, which are only visible under a microscope, play both beneficial and harmful roles. Beneficially, they fix nitrogen in soil, decompose organic waste to recycle nutrients, produce antibiotics, and aid in food production and sewage treatment. However, some microbes cause infectious diseases in humans and plants. Pathogenic bacteria and viruses can directly damage tissues or produce toxins. Diseases are controlled through prevention, treatment, and food preservation methods that kill microorganisms or stop their growth.
Microbes can serve as bioindicators of pollution in the environment. Different types of microbes indicate different types of pollution, such as algae indicating organic pollution and lichens being sensitive to air pollution like nitrogen oxides. Bacteria are the most abundant microbes in wastewater and changes in their presence and activity can signify the condition of the wastewater treatment process. Viruses can also act as indicators of human fecal pollution in aquatic environments. Overall, monitoring microbes allows for a cost-effective way to assess pollution levels and the performance of treatment systems.
Management of biofilm in endodontics. History, Classification, use of sodium hypochlorite, EDTA, Chlorhexidine, recent irrigants, LASERS, Ultrasonics, Natural agents, Nanoparticles and probiotics
The document describes BIO-UV's ultraviolet water treatment system as a chlorine-free alternative for pools. It discusses how UV light purifies water by destroying microorganisms, outlines the components and specifications of BIO-UV's product line, and provides installation and operation instructions. The system pairs a UV sterilizer with an automatic REMANENT injector to sanitize pool water without chemicals or residuals. BIO-UV offers warranties for system components and touts the system's simplicity, reliability, cost savings, and environmental friendliness.
The document discusses various microorganisms found in water and their roles. It describes that water is essential for life and acts as a medium for cellular reactions. It discusses different types of water bodies and habitats that contain diverse microbes like bacteria, viruses, protozoa, fungi, algae, and helminths. Many of these microorganisms can cause water-borne diseases if the water is contaminated. Proper treatment is needed to ensure water is safe for drinking and other uses. Maintaining good hygiene is important for preventing water-washed and water-related illnesses.
The document discusses the cultivation and growth of bacteria. It describes:
1) The nutritional, temperature, pH, gas, and other physical requirements bacteria need to grow and multiply.
2) The different types of bacteria classified based on their nutrient sources and environmental tolerances.
3) Common methods for culturing bacteria, including various types of media and isolation techniques like streak plating.
Indian Dental Academy: will be one of the most relevant and exciting training center with best faculty and flexible training programs for dental professionals who wish to advance in their dental practice,Offers certified courses in Dental implants,Orthodontics,Endodontics,Cosmetic Dentistry, Prosthetic Dentistry, Periodontics and General Dentistry.
This slide contains all information you need on Microbiology of water and wastewater. Methods of water purification and water borne diseases have also been discussed in this slide
Fish can be affected by toxins produced by algae, cyanobacteria, fungi, and bacteria. Algal toxins include cyanotoxins from blue-green algae and euglenophycin from Euglena algae. Cyanotoxins contain neurotoxins and hepatotoxins. Fungi can produce mycotoxins like aflatoxins and F2 toxins in contaminated fish feed which can cause liver damage and decreased sperm production in fish. Clinical signs depend on the specific toxin but may include abnormal swimming, loss of appetite, reddening of gills, and mortality. Diagnosis involves identifying the causative organism and treating contaminated water or feed.
INTRODUTION A biofertilizer is a substance which contains living microorganisms, when applied to seed, plant surfaces, or soil, colonizes the rhizosphere or the interior of the plant and promotes growth by increasing the supply or availability of primary nutrients to the host plant.
The document discusses biofilms, which are complex aggregations of microorganisms that grow on surfaces in aquatic environments. Biofilms form when bacteria adhere to a surface and excrete a glue-like substance. They are found in places like rocks, water environments, living tissues, and industrial settings. Biofilms pose challenges for human health and industry because they are resistant to antibiotics and cause fouling. However, biofilms can also be beneficial in applications like water treatment. The document outlines the structure, formation process, impacts and threats of biofilms as well as some preventive measures and references on the topic.
examples of biofilms, control of biofilms, microbes and biofilms, uses of biofilms, hydrocarbon degrading bacteria, sewage treatment, waste water treatment
This document discusses microbial insecticides as an alternative to chemical insecticides. It describes how single-celled microorganisms like bacteria, fungi, viruses, and protozoa can be produced and formulated similar to insecticides. Key types discussed are the bacteria Bacillus thuringiensis, which produces crystal proteins that kill insect larvae, and fungi like Beauveria and Metarrhizium, which infect insects through the cuticle. Viruses like baculoviruses can also be insect-specific and infect via ingestion. Microbial insecticides offer advantages over chemicals like host specificity and no toxic residues.
Isolation and characterization of fungi associated with in can degradation of...Alexander Decker
This study isolated and characterized fungi associated with degradation of paint samples in their containers. Various paint samples were collected from locations in southwest Nigeria and cultured on selective media. The predominant fungi isolated were Rhizopus and Aspergillus species. Other fungi isolated included Fusarium, Alternaria, Mucor, Penicillium, and Cladosporium species. Water-based paints supported more fungal growth than emulsion paints. The results provide information for paint manufacturers to improve preservation methods and prevent microbial degradation of paint samples.
Silver Hydrogen Peroxide, an eco-friendly disinfectant, with a variety of uses. It breaks down into water and oxygen after work. Oxidizing in nature, and silver provides extra benefit of long lasting disinfection.
Used for disinfection of soil, dairy, water, etc.
Compatible with most materials and can be used in any media.
The document provides an overview of D-H/S IONS, a disinfectant solution containing hydrogen peroxide stabilized with silver ions. It describes the product's mechanism of action, involving the synergistic effects of hydrogen peroxide and silver ions. The document also outlines the product's advantages like broad-spectrum effectiveness, safety, and environmental friendliness. Finally, it discusses potential applications of D-H/S IONS in areas like water treatment, food/beverage processing, healthcare facilities, and more.
Water is the medium of life and covers 71% of the Earth's surface. It exists in various forms such as atmospheric water, surface water, ground water, fresh water, marine water, and estuarine water. The document discusses the types of microorganisms found in water such as viruses, bacteria, protozoa, fungi and algae. It describes various waterborne diseases caused by these microorganisms and their symptoms. The aquatic environment influences the microbial population with factors like temperature, hydrostatic pressure, light, salinity, turbidity, and pH varying widely between streams, estuaries and oceans.
Microbial contamination of pharmaceutical products can lead to spoilage or health hazards. Contamination can occur during manufacturing from water, the environment or packaging. It can be prevented through good manufacturing practices and controlling moisture, temperature, pH and packaging design. Spoilage results from microbial growth and causes product deterioration or infection. Factors influencing spoilage include the contaminant type/level, nutrients, moisture, temperature, pH and packaging. Strict control of these factors is needed to prevent issues.
1) The document discusses using genetically engineered endophytic bacteria to aid in the phytoremediation of soils contaminated with heavy metals and organic pollutants.
2) It focuses on using the endophytic bacterium Burkholderia cepacia, engineered to degrade toluene, to help yellow lupine plants remediate toluene-contaminated soil.
3) The results showed that lupine plants inoculated with the engineered B. cepacia strain had the lowest evapotranspiration of toluene compared to control plants and plants inoculated with other B. cepacia strains.
To study the effect of guava leaf extract on biofilm formation in Pseudomonas...iosrjce
IOSR Journal of Dental and Medical Sciences is one of the speciality Journal in Dental Science and Medical Science published by International Organization of Scientific Research (IOSR). The Journal publishes papers of the highest scientific merit and widest possible scope work in all areas related to medical and dental science. The Journal welcome review articles, leading medical and clinical research articles, technical notes, case reports and others.
Water microbiology is the study of microorganisms in water environments. Various types of water contain diverse microbes including viruses, bacteria, protozoa, fungi and helminths. Many microbes can cause water-associated diseases classified as water-borne, water-washed, water-based or water-related depending on the transmission route which may involve ingesting contaminated water, poor hygiene, an aquatic host or an insect vector. Common pathogenic microbes found in water are various bacteria and viruses that can cause diarrhea, hepatitis, polio and typhoid as well as parasitic protozoa like Giardia and Plasmodium which causes malaria.
Lect. 2 (economic significance of microorganisms)Osama Rifat
Microorganisms, which are only visible under a microscope, play both beneficial and harmful roles. Beneficially, they fix nitrogen in soil, decompose organic waste to recycle nutrients, produce antibiotics, and aid in food production and sewage treatment. However, some microbes cause infectious diseases in humans and plants. Pathogenic bacteria and viruses can directly damage tissues or produce toxins. Diseases are controlled through prevention, treatment, and food preservation methods that kill microorganisms or stop their growth.
Microbes can serve as bioindicators of pollution in the environment. Different types of microbes indicate different types of pollution, such as algae indicating organic pollution and lichens being sensitive to air pollution like nitrogen oxides. Bacteria are the most abundant microbes in wastewater and changes in their presence and activity can signify the condition of the wastewater treatment process. Viruses can also act as indicators of human fecal pollution in aquatic environments. Overall, monitoring microbes allows for a cost-effective way to assess pollution levels and the performance of treatment systems.
Management of biofilm in endodontics. History, Classification, use of sodium hypochlorite, EDTA, Chlorhexidine, recent irrigants, LASERS, Ultrasonics, Natural agents, Nanoparticles and probiotics
The document describes BIO-UV's ultraviolet water treatment system as a chlorine-free alternative for pools. It discusses how UV light purifies water by destroying microorganisms, outlines the components and specifications of BIO-UV's product line, and provides installation and operation instructions. The system pairs a UV sterilizer with an automatic REMANENT injector to sanitize pool water without chemicals or residuals. BIO-UV offers warranties for system components and touts the system's simplicity, reliability, cost savings, and environmental friendliness.
The document discusses various microorganisms found in water and their roles. It describes that water is essential for life and acts as a medium for cellular reactions. It discusses different types of water bodies and habitats that contain diverse microbes like bacteria, viruses, protozoa, fungi, algae, and helminths. Many of these microorganisms can cause water-borne diseases if the water is contaminated. Proper treatment is needed to ensure water is safe for drinking and other uses. Maintaining good hygiene is important for preventing water-washed and water-related illnesses.
The document discusses the cultivation and growth of bacteria. It describes:
1) The nutritional, temperature, pH, gas, and other physical requirements bacteria need to grow and multiply.
2) The different types of bacteria classified based on their nutrient sources and environmental tolerances.
3) Common methods for culturing bacteria, including various types of media and isolation techniques like streak plating.
Indian Dental Academy: will be one of the most relevant and exciting training center with best faculty and flexible training programs for dental professionals who wish to advance in their dental practice,Offers certified courses in Dental implants,Orthodontics,Endodontics,Cosmetic Dentistry, Prosthetic Dentistry, Periodontics and General Dentistry.
This slide contains all information you need on Microbiology of water and wastewater. Methods of water purification and water borne diseases have also been discussed in this slide
Fish can be affected by toxins produced by algae, cyanobacteria, fungi, and bacteria. Algal toxins include cyanotoxins from blue-green algae and euglenophycin from Euglena algae. Cyanotoxins contain neurotoxins and hepatotoxins. Fungi can produce mycotoxins like aflatoxins and F2 toxins in contaminated fish feed which can cause liver damage and decreased sperm production in fish. Clinical signs depend on the specific toxin but may include abnormal swimming, loss of appetite, reddening of gills, and mortality. Diagnosis involves identifying the causative organism and treating contaminated water or feed.
INTRODUTION A biofertilizer is a substance which contains living microorganisms, when applied to seed, plant surfaces, or soil, colonizes the rhizosphere or the interior of the plant and promotes growth by increasing the supply or availability of primary nutrients to the host plant.
The document discusses biofilms, which are complex aggregations of microorganisms that grow on surfaces in aquatic environments. Biofilms form when bacteria adhere to a surface and excrete a glue-like substance. They are found in places like rocks, water environments, living tissues, and industrial settings. Biofilms pose challenges for human health and industry because they are resistant to antibiotics and cause fouling. However, biofilms can also be beneficial in applications like water treatment. The document outlines the structure, formation process, impacts and threats of biofilms as well as some preventive measures and references on the topic.
examples of biofilms, control of biofilms, microbes and biofilms, uses of biofilms, hydrocarbon degrading bacteria, sewage treatment, waste water treatment
This document discusses microbial insecticides as an alternative to chemical insecticides. It describes how single-celled microorganisms like bacteria, fungi, viruses, and protozoa can be produced and formulated similar to insecticides. Key types discussed are the bacteria Bacillus thuringiensis, which produces crystal proteins that kill insect larvae, and fungi like Beauveria and Metarrhizium, which infect insects through the cuticle. Viruses like baculoviruses can also be insect-specific and infect via ingestion. Microbial insecticides offer advantages over chemicals like host specificity and no toxic residues.
Isolation and characterization of fungi associated with in can degradation of...Alexander Decker
This study isolated and characterized fungi associated with degradation of paint samples in their containers. Various paint samples were collected from locations in southwest Nigeria and cultured on selective media. The predominant fungi isolated were Rhizopus and Aspergillus species. Other fungi isolated included Fusarium, Alternaria, Mucor, Penicillium, and Cladosporium species. Water-based paints supported more fungal growth than emulsion paints. The results provide information for paint manufacturers to improve preservation methods and prevent microbial degradation of paint samples.
Silver Hydrogen Peroxide, an eco-friendly disinfectant, with a variety of uses. It breaks down into water and oxygen after work. Oxidizing in nature, and silver provides extra benefit of long lasting disinfection.
Used for disinfection of soil, dairy, water, etc.
Compatible with most materials and can be used in any media.
The document provides an overview of D-H/S IONS, a disinfectant solution containing hydrogen peroxide stabilized with silver ions. It describes the product's mechanism of action, involving the synergistic effects of hydrogen peroxide and silver ions. The document also outlines the product's advantages like broad-spectrum effectiveness, safety, and environmental friendliness. Finally, it discusses potential applications of D-H/S IONS in areas like water treatment, food/beverage processing, healthcare facilities, and more.
This lecture note describes the process of Effluent Treatment (ET). Emphasis is give to the biological aspects of ET. Free to reuse, remix, modify and share for non-commercial and commercial purposes.
Farm Bio-security with Nano Silver Hydrogen Peroxide based Alstasan SilvoxSilverHydrogenPeroxide
Silver hydrogen peroxide based Alstasan Silvox is an eco-friendly agriculture disinfectant, is hydrogen peroxide stabilized with the addition of silver proves well effective in farms.
Water treatment is any process that improves the quality of water to make it appropriate for a specific end-use. The end use may be drinking, industrial water supply, irrigation, river flow maintenance, water recreation or many other uses, including being safely returned to the environment. Water treatment removes contaminants and undesirable components, or reduces their concentration so that the water becomes fit for its desired end-use. This treatment is crucial to human health and allows humans to benefit from both drinking and irrigation use.
Water pollution adversely affects aquatic life. Fishes are particularly impacted and die from pesticide pollution from nearby farms. Large quantities of untreated wastes from leather and other industries also pollute water bodies. Sewage discharge near coasts can poison shellfish and make swimming unsafe. Bioremediation uses microorganisms to break down pollutants into less toxic forms and helps clean contaminated ponds, soils and water. It has benefits over other remediation methods like being natural, lower cost, and less disruptive to the environment. Both in situ and ex situ bioremediation can be used to treat different types of contamination.
This document provides information on ozone and the Viriditec nanotechnology system. It defines ozone as an unstable gas that is a powerful natural sanitizer. It oxidizes contaminants in water and air. The Viriditec system uses a patented process to transform ozone bubbles into nanobubbles that can last up to 4 hours in solution. Testing showed the Viriditec solution significantly reduced ATP readings on surfaces like floors and equipment in food processing plants, indicating reduction of microbes. The solution is a cost-effective alternative to chemicals that is safe, leaves no residues, and decomposes into oxygen and water.
This document discusses bioremediation and the role of biotechnology in aquaculture and traceability. It describes how bioremediation uses microorganisms to break down pollutants in fish ponds to improve water quality. There are three main types of bioremediation: biostimulation, bioaugmentation, and intrinsic bioremediation. The document also discusses how biotechnology is used in fish breeding, disease prevention, and developing transgenic fish with desirable traits. It concludes by covering cryopreservation techniques and the importance of traceability in the fish industry.
Aquaponics require only 5% of the usual water intake for growing Food, Feed, Herbs, Fish and other high-value agri products. It is a revolutionary concept already adopted by UAE by creating one of the largest farms in the world. Interesting reading and great business potential.
This document provides an overview of aquaponics, which combines aquaculture and hydroponics into a symbiotic system. It discusses the history of hydroponics and intensive aquaculture, how aquaponics systems work, and the essential components including fish tanks, biofilters, and hydroponic grow beds. The document also addresses water quality parameters, suitable plants and fish for aquaponics, and how the system functions with a nutrient cycle benefiting both fish and plants. Advantages include water and land efficiency while producing both fish and vegetables, though initial costs are high and monitoring is required. Aquaponics shows potential for sustainable local food production.
This document provides an overview of aquaponics, which combines aquaculture and hydroponics in a symbiotic system. Key points include:
- Aquaponics grows fish and plants together in a closed-loop system, with the fish waste providing nutrients for plant growth and the plants filtering the water for the fish.
- It uses less water and space than traditional agriculture and provides organic food production year-round.
- A variety of vegetables and some fruits can be grown, including lettuce, tomatoes, and carrots. Tilapia and trout are common fish varieties used.
- Both small backyard systems and large commercial operations are possible. Initial costs are higher but the system requires low ongoing inputs.
Role of microbes in soil and water quality management in aquacultureKRISHNA Jaiswal
This document discusses the roles of microorganisms in soil and water quality management for aquaculture. It covers how microorganisms are important for productivity, nutrient cycling, water quality, disease control, and environmental management. It describes microbial processes like heterotrophic and autotrophic bacteria and their impacts. Beneficial microorganisms are important for decomposing organic matter, nutrient cycling, and maintaining ecological balance. The document also discusses uses of probiotics, biofloc technology, bioremediation, biofertilizers, and biofilters to manage water quality and productivity in aquaculture. Key challenges are the lack of understanding of microecology and effective application of beneficial microorganisms.
Phytoremediation uses living plants to remove, degrade, or stabilize contaminants in soil, sludges, sediments, and groundwater through natural processes. Key methods include phytoextraction, where plants uptake and concentrate contaminants; rhizofiltration, where contaminants are absorbed or adsorbed onto root surfaces; and phytodegradation, where plants or their associated microbes break down organic pollutants. Phytoremediation offers a low-cost, solar-powered, and aesthetically-pleasing approach to remediation of sites with lower-level contamination.
aquaponics production soilless cultures components,diseases,pests,automation ...Raheel Tariq
This document provides an overview of aquaponics, which combines aquaculture and hydroponics. It describes the basic components of an aquaponics system, including tanks for raising fish, settling bowls, biofilters, hydroponic subsystems, and sumps. Living components include plants, fish, and nitrifying bacteria. The water from the fish tanks flows to the hydroponic subsystem where the plants filter out waste before the water is returned to the tanks. Proper operation requires balancing inputs like water, oxygen, light, and fish feed. Aquaponics can produce both fish and vegetables sustainably with efficient water and nutrient recycling and little land or water needed.
This document discusses various methods for preserving microorganisms, including freeze-drying, cryopreservation, periodic transfer to fresh media, saline suspension, and the oil overlay method. It also describes DNA and RNA, DNA replication, recombinant DNA technology, and the distribution of microorganisms in different environments such as soil, air, water, and indoor and outdoor settings.
The document discusses various methods of disinfecting water, including their advantages and disadvantages. It describes boiling, ozone, bromine, iodine, UV rays, potassium permanganate, silver, and excess lime processes. Chlorine is highlighted as a widely used and effective disinfectant, though it can produce undesirable byproducts. The document also lists several purposes of chlorine in water treatment processes.
Envir Eau Technologies General Presentation 2009Tremtan
EnvirEau Technologies manufactures mineral-based biocides as eco-friendly alternatives to chemicals for water and food environments. Their products use ionic forms of copper, zinc, and silver to naturally control microorganisms and pathogens. Their product lines include Polydex, BioDex, HooFix, ICC, BlueMagic, and Protexx which are used in applications like drinking water, agriculture, livestock, wastewater, and food processing. EnvirEau is seeking partners in new markets to help sell and potentially manufacture their products locally.
Biofilm is a microbial community characterized by cells attached to a surface and embedded in an extracellular matrix. Biofilms form in root canals and on materials placed in root canals. They are resistant to disinfection and prevent healing. Sodium hypochlorite, chlorhexidine, and MTAD are used to eradicate biofilms, but they often persist. Advanced techniques like lasers, photodynamic therapy, and ultrasound improve disinfection but sometimes biofilms still remain.
Introduction to Recirculating Aeration System - AirOxi TubeAirOxi Tube
A RAS is perfect solution for fish farming on land, we manufacture aeration tubes to help this system to perform better. With our tubes you can attain a better rate of DO in a short span of time. For more information visit: http://www.airoxitube.com/aeration-tubing-products/airoxi-tubes/
Similar to Nursery and floriculture and how Aquaza can help (20)
Introduction to Recirculating Aeration System - AirOxi Tube
Nursery and floriculture and how Aquaza can help
1. NURSERY &
FLORICULTURE
OXYGATION – Aquaza encapsulated oxygen delivery for increased
health, rooting and growth of cuttings, seedlings, flowers & plants
INTRODUCTION:
Oxygation is the science of adding Oxygen to irrigation water in order to change the growing environment from
anaerobic to aerobic and thus improve plant health and growth.
Aquaza OXY 300 is dosed at between 20 - 50 ppm in the irrigation water, and due to its unique form of stability it
brings the following advantages to horticulture and floriculture;
1.) Pathogen & Chlorine elimination in irrigation water
2.) Biofilm eradication in irrigation systems
3.) Increased depth of pathogen free aerobic root environment
4.) Enhanced success and rooting of grafts and cuttings during propagation
5.) Reduction of plant stress due to under watering, re-planting, excess salinity & fertilizer/chemical overload
6.) Enhancement of plant immune system and response to pathogenic infection
7.) Increased vascular systems leading to increased water and nutrient uptake
8.) Quicker and increased vegetative (biomass) and regenerative growth (harvest yield)
c
Aquaza OXY 300 uses molecular encapsulation technology to deliver and selectively release Oxygen from a Food
Grade Hydrogen peroxide carrier. OXY 300 Hydrogen peroxide molecules are encapsulated in a vegetable glycerine
sheath that selectively controls the decomposition of the H2O2 into water and Oxygen.
The controlled reactivity of Aquaza OXY 300 allows for accurate dosing and efcient efcacy at extremely low ppm
dilutions. The usual chain reaction decomposition of Hydrogen peroxide is severely limited by the encapsulation
technology, resulting in no phytotoxic burn effect and maximum use of each and every available Oxygen atom.
Aquaza has a long lasting effect as only the necessary amount of Oxygen to neutralize the Biological Oxygen Demand
is released, the balance of the Hydrogen peroxide remains “On Guard” until more organic pollution is encountered.
AQUAZA cc reg. 1992/002813/23 – D302 Sandhurst Gardens, Sandton, 2010, Rep of South Africa
Email: info@aquaza.com - Web: www.aquaza.com Page 1
2. NURSERY &
FLORICULTURE
Oxygation is usually atempted by inefcient means such as Venturi Inlets, Ozone or standard Hydrogen peroxide,
but now it can be done economically and efciently with Aquaza OXY 300.
VENTURI INLETS:
Venturi inlets only add small quantities of O2 to the water. O2 is not a reactive Oxygen species, so has a very limited
and short-lived efcacy. While it does increase the dissolved Oxygen levels slightly, it does not remove Biofilm or
benefit plant health greatly.
OZONE:
Ozone is O3, and when added to water it forms Hydrogen peroxide (H2O2). This is the most unstable form of
Hydrogen peroxide and it's efcacy is extremely short-lived as it decomposes back into water and Oxygen within 10 -
20 minutes. The Oxygen atoms quickly lose their reactive capabilities by forming O2 and dissipating into the air.
HYDROGEN PEROXIDE:
Hydrogen peroxide is H2O2 - water with an extra Oxygen atom - and has long been known for its positive effect on
plants. Science has proven that it is a known signaler for plant growth and stress mediation, as well as being the first
line of defence against infection. Please see Annex 1 for a list of scientific research completed in this area.
The disadvantages of regular Hydrogen peroxide are;
a.) H2O2 is highly unstable, making it uneconomical and inefcient – between 70 to 90% of the available Oxygen is
wasted and dissipates as O2 into the atmosphere.
b.) H2O2 readily decomposes in chain reactions which result in phytotoxic burn and shock to plants.
c.) Due to the instability of H2O2 stabilisers are usually added, but these toxic chemicals and heavy metals remain
behind as unwanted residues, making stabilised Hydrogen peroxides unsuitable for horticulture and floriculture.
AQUAZA OXY 300 HYDROGEN PEROXIDE:
With Aquaza OXY 300, Oxygen is only released in direct response to the Biological Oxygen Demand present, the
balance of the Hydrogen peroxide carrier remains stable in the water until such time as more organic pollution is
introduced.
Aquaza OXY 300 is formulated using organic ingredients, so does not leave any toxic chemical or heavy metal
residues once it has performed its task and decomposed into water and Oxygen.
1.) PATHOGEN & CHLORINE ELIMINATION: In intensive horticulture/floriculture production, sound hygiene can
minimise disease problems and maximise production, as well as extend the shelf life and quality of the end product.
A good standard of hygiene depends largely upon the quality of water used in cleaning and irrigation from the
moment the cutting or seed is planted right through to post-harvest treatment.
80% of the diseases which affect the health of plants originate from the water distribution system. Contaminated
water and a fouled irrigation system put increasing pressure on a plant's immune system with each irrigation. The
plants have to spend considerable energy in defending themselves against continual infection – energy which could
beter be used in growth and yield production.
Addition of Aquaza OXY 300 to the irrigation water eliminates all known anaerobic pathogens, plus Aquaza also
reduces chlorine levels and removes organo-chlorides such as Trihalomethanes. When added to water reservoirs,
Aquaza precipitates suspended and dissolved solids and kills Cyanobacteria – Blue-Green algae.
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Micro-Organism Spectrum:
Hydrogen peroxide has proven effective against all pathogens tested in laboratory trials;
(Partial list)
• E. coli • Candida albicans
• Powdery mildew • Legionella pneumophilia
• Downy mildew • Agrobacterium
• Botrytis cinerea • Fusarium incarnatum
• Phytophthora cinnamomi • Clavibacter michiganensis
• P. capsici • Pithium
• P. nicotianae • Rhizoctonia
• Pseudomonas aeruginosa • Aspergillus niger
• Enterococcus faecalis • Bacillus subtilis
• E. hirae • Staphylococcus aureus
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2.) BIOFILM ERADICATION: The main source of micro-organism pollution is the biofilm present in the water
distribution system. The only way to address and eliminate microbial contamination through the irrigation system is
to strip the biofilm and prevent its re-growth by killing the micro-organisms responsible.
Micro-organisms in biofilm are very aggressive and resistant and form a continuous source of contamination for
plants (y. Pachepsky; J. Morrow; A. Guber; D. Shelton; R. Rowland; G. Davies; 2012). Sessile bacteria in biofilms are
10 to 1000 times more resistant to disinfectants than 'free swimming' planktonic bacteria of the same species.
Bacteria in biofilm form the most persistent hygiene problem in horticulture and the greatest source of disease.
(Prosser, B. L. et al. (1987); Nickel, J.C. et al.(1985); Gristina, A.G. et al. (1987); Evans, R.C. and Holmes, C.J. (1987)).
Biofilm is defined by Wikipedia as:
A biofilm is an aggregate of micro-organisms in which cells
adhere to each other on a surface. These adherent cells are
frequently embedded within a self-produced matrix of
extracellular polymeric substance (EPS). Biofilm EPS, which is
also referred to as slime (although not everything described
as slime is a biofilm), is a polymeric conglomeration generally
composed of extracellular DNA, proteins, and
polysaccharides. Bacteria in biofilms are much more resistant
to toxic substances such as antibiotics and detergents.
Biofilms may form on living or non-living surfaces and can be
prevalent in natural, industrial and hospital settings. The
microbial cells growing in a biofilm are physiologically distinct from planktonic cells of the same organism,
which, by contrast, are single-cells that may float or swim in a liquid medium.
When a pathogenic cell switches to the sessile biofilm mode of growth, it undergoes a phenotypic shift in behaviour
in which large suites of genes are differentially regulated, resulting in a far more infectious and virulent microbe than
it was in the planktonic waterborne state.
Dispersal of cells from the biofilm colony is an essential stage of the biofilm life cycle. Dispersal enables biofilms to
spread and colonise new surfaces and infect the soil and plants.
Five stages of biofilm development: (1) Initial atachment, (2) Irreversible atachment, (3) Maturation I, (4) Maturation II, and (5) Dispersion.
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When micro-organisms (M.O.) are released during the sloughing or dispersion of biofilm at stage 5, they typically
number in the tens of thousands and are released simultaneously. Suddenly we have a huge infestation of virulent
M.O. dispersed into the irrigation water and coming into contact with the soil and plants.
Although plants can easily deal with a limited number of pathogenic M.O. in their water source, they have litle
chance against the huge numbers of virulent M.O. released by biofilm dispersion and disease then rapidly follows.
There are a number of ways to try and remove Biofilm available, but not all are suited for optimum hygiene:
a.) Chlorine:
Chlorine can be a good disinfectant when used under the right circumstances, but should not be
continuously applied. This is because micro-organisms rapidly develop resistance to chlorine (H.F. Ridgway;
B.H. Olson; 1982 & Rodney m. Donlan and J. William Costerton, 2002). The water’s pH is also highly
important. Chlorine works optimally at a pH between 6 and 7.5. Outside of this range its effect rapidly
decreases. The environmental impact of chlorine is relatively high, when it reacts with organic mater, it
results in the formation of toxic by-products such as Trihalomethanes (THM) and other organo-chlorides.
Furthermore chlorine is extremely corrosive and scientific research shows that chlorine is barely effective in
breaking down Biofilm. (Dirk de Beer; Rohini Srinivasa; Philips Stewarts; 1994). In addition, chlorine has no
positive effect on plant growth – small overdoses can do hefty damage.
The use of chlorine has some important disadvantages for horticulture/floriculture production. It is not the
optimum disinfectant for the control of biofilm, the greatest hygiene problem in the greenhouse, and most
often negatively effects plant growth.
b.) Acid:
Acid is an excellent product for removing inorganic pollution such as mineral salts and calcium. It also has an
effect on micro-organisms. The effect on the organic Biofilm (the bulk of the biofilm) is non-existent. Acid is
best used in combination with Hydrogen peroxide. First apply the acid and follow this up with a minimum of
5% Hydrogen peroxide.
c.) Hydrogen peroxide (in combination with acid or not):
Hydrogen peroxide is a very good disinfectant for horticulture and floriculture. It kills almost all micro-
organisms, is fairly insensitive to pH, allow no build-up of resistance and has a very good effect on Biofilm.
The disadvantage of Hydrogen peroxide is the uncontrolled chain reaction. Once it comes into contact with
organic mater the reaction of the Hydrogen peroxide cannot be stopped.
This makes the use of Hydrogen peroxide extremely inefcient and short-lived. After 10 - 20 minutes the
product is all used up in uncontrolled chain reactions that merely waste Oxygen. Adding acid (e.g.: peracetic
acid) to Hydrogen peroxide has no influence on the duration of the reaction. It does make the reaction
stronger, but it remains extremely inefcient. During use, one can see the concentration decreasing rapidly
decrease as one measures down the irrigation system from the point of application.
d.) AQUAZA OXY 300 – Encapsulated & Activated Food Grade Hydrogen Peroxide Solutions:
The Aquaza OXY 300 process is a new generation in irrigation system cleaning. The controlled oxidization
process will eliminate practically all built up encrustations, bacteria, slime, algae and mineral deposits in a
way which is time efcient, ecologically harmless, safe on materials and which does not harm operating
personnel. The Aquaza process is unlike other chemical treatments, since it is entirely environmentally
friendly, yet uses powerful products giving thorough results. Furthermore, accidental spillage will not
damage the soil or plants.
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Aquaza Biofilm Treatment Methods:
Cleaning of irrigation lines results in higher water quality and increased flow rate of water and plant nutrition. To
treat biofilm in water systems Aquaza can be used in 2 ways:
a.) Shock Treatment:
Shock treatment is usually used to clean the system of biofilm and micro-organisms in one rapid treatment
(occasionally it may be necessary to repeat the treatment, but in practice this only happens 1-2 times out of
100, the reason being the type of biofilm in the system).
Generally shock treatment with Aquaza occurs at the end of a crop cycle. The treatment involves dosing 2%
Aquaza into the water system and leaving this in the system for 1 or more hours, after which the system is
flushed with water containing 1% Aquaza until the whole volume of the system has been flushed 1-2 times.
After this normal procedure can be resumed, though in most cases growers continue with continual dosage.
← Test in greenhouse irrigation system of W. Koorneef in Maasdijk
in The Netherands 2010.
1. First water out of the system after 2% treatment for 30 minutes
with Aquaza OXY 300. The colour of the water shows the high level
of biofilm that was in the system.
2. After several minutes flushing the water starts to clear.
3. Water is completely clear and clean after the whole system is
flushed out. All drippers are running properly and giving equal
water.
b.) Continual dosage:
Continual dosage with Aquaza is usually carried out when there is no crop downtime - generally in
greenhouses with flower/plant cultivations or after shock treatment to maintain a clean system and water
hygiene. The treatment involves dosing 20 to 50 ml/m3 water.
Continual dosage slowly breaks down the biofilm in a controlled way until eventually (after weeks/months)
the entire biofilm is removed and slowly flushed from the system, leaving a clean system free of biofilm and
no longer a source of plant disease. The downside is that occasionally large bits of biofilm may be released
causing blockage – particularly in very old systems (1-2-times per 100 systems). Generally though this is not a
problem and the biofilm is oxidised to very fine particles and flushed from the systems through the drippers.
Micro-organisms that are released from the biofilm are also oxidised and eliminated.
Another advantage of continual dosage is that the breakdown of Aquaza provides extra oxygen to the roots.
It is advisable to double/triple (no more than 100 ppm) the dosage of Aquaza treatment once every 2 month
for 1 day as an extra hygiene measure.
Conclusion of Biofilm Test – Kerma Power Generation and Sustainables - The Netherlands:
Test results show that continuous Aquaza dosing at a concentration of 0.5 mg/l active hydrogen peroxide in the water flow
prevents biofilm formation in fresh water 'once through' utilities.
From the determination of the effectiveness of Aquaza in the mitigation of biofilms in fresh water utilities, it can be concluded
that AQUAZA OXY 300 is effective in the mitigation of sessile microbes (biofilms) and planktonic waterborne microbes.
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3.) INCREASED AEROBIC SOIL DEPTH:
Once the irrigation system is free of Biofilm, the continuous dose of Aquaza applied to the irrigation water is free to
enter the soil and root environment. This results in increased Oxygen in the root environment, progressively
deepening the aerobic layer. This deeper aerobic layer allows for increased breakdown of nutrients by the “good”
bacteria and micro-risals, and therefore increased assimilation of nutrients by the roots. Soil organisms need Oxygen
and moisture. (A Farmer's Guide to Life in the Soil – New South Wales Department of Primary Industries & Australian
Department of International Agriculture – June 2009)
Hydrogen peroxide has been shown to increase the Oxygen content of heavily compacted soils and negate the
negative effects of waterlogged soil where the Oxygen is pushed out by the water level. (Effect of injecting Hydrogen
Peroxide into heavy clay loam soil on plant water status, net C O2 assimilation, biomass and vascular anatomy of
avocado trees. Pilar M. Gil M.1, 2*, Raúl Ferreyra E.1, 2, Cristián Barrera M.1, Carlos Zúñiga E.1, and Luis Gurovich R.)
In cases of flooded fields, dosing of a relatively high concentration of Aquaza OXY 300 brings two benefits; a.) it
prevents root rot by sterilising the root environment and b.) it adds Oxygen to the root environment, thus preventing
Oxygen starvation of the plant. When plants in flooded fields begin to starve of Oxygen, they increase their water
uptake in an effort to assimilate more Oxygen and this often leads to burst fruit and a ruined harvest.
Aquaza has no effect on Nematodes or (pot)worms. However it does have an effect on the eggs of nematodes and
(pot)worms. Rapports from users as well as from research indicates that Aquaza oxidises the eggs of nematodes and
(pot)worms, whereby a natural decline in the nematode and (pot)worm infestation occurs. Research also clearly
shows that the presence of low levels of H2O2 in the root area also triggers the plant-host defence mechanism making
it beter able to prevent nematode infestation.
Runia & Amsing (1996) tested activated hydrogen peroxide for the control of R. similis (Nematode). They found that
hydrogen peroxide was effective at a concentration of 400 ppm or higher for at least 24 hours. With a different
formulation, only 200 ppm for 24 hours was required to completely eliminate R. similis (Runia & Amsing, 1996).
Aquaza, being uniquely stable, achieves the same effect at dosages as low as 50 ppm.
4.) ENHANCED ROOTING:
Ludwig's Roses – South Africa. Trials of Aquaza dosed at 50 ml/m 3 in irrigation water increased successful rose
propagation from rootstock from an average of 70% to 100%. The trial was was repeated 3 times on 30 000 standard
rose cuttings with the same results. Further trials have shown that even on the more sensitive rose species, where
propagation normally in only results 30 - 40% rooting, Aquaza again delivered 100% rooting.
Control of “crazy roots” (Agrobacterium). Netherlands – Greenhouse 2Ha – tomatoes. Grower had problems with
control of crazy-roots in his tomato crop. He had used chlorine in the past and was using a mixture of H2O2 and
peracetic acid to control the spread of the infection. He changed to Aquaza during the clean-out, disinfected his
greenhouse and surfaces with Aquaza and cleaned and disinfected his irrigation system using shock treatment. He
followed this up with continual dosage of 30 ml/m 3 water. Result was that he went from a 20% infection back to a
1% infection and that the infection stayed at 1% during the whole growing season. This had never happened before
with any other product. Even if there was a decrease in infection after the clean-up, it always increased during the
growing season.
Control “crazy-roots” (Agrobacterium). Netherlands – Greenhouse 2 x 6Ha – tomatoes. Grower used 2 different
disinfectants to control crazy-root infection in his greenhouse. In one half he used chlorine, in the other half he used
Aquaza dosed at 50 ml/m3 water. In the chlorine treated half, crazy-root was present in ±50% of plants. In the
Aquaza treated half there was no crazy-root infection.
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5.) REDUCTION IN PLANT STRESS & 6.) ENHANCEMENT OF PLANT IMMUNE SYSTEM:
Dosing irrigation water with Aquaza has also been shown to effectively alleviate plant stress caused by re-planting,
under watering, excess salinity and over fertilization. The role of reactive oxygen species, especially H2O2, in plant
response to stresses has been the focus of much atention. Hydrogen peroxide has been postulated to play multiple
functions in plant defence against pathogens. (1) H2O2 may possess direct microbicidal activity at the sites of
pathogen invasion. (2) It is used for cell-wall reinforcing processes: lignification and oxidative cross-linking of
hydroxyproline-rich proteins and other cell-wall polymers. (3) It was found to be necessary for phytoalexin synthesis.
(4) H2O2 may trigger programmed plant cell death during the hypersensitive response that restricts the spread of
infection. (5) H2O2 has been suggested to act as a signal in the induction of systemic acquired resistance and (6) it
induces defence genes. Recently H2O2 has been proposed to be involved in the signal transduction pathways leading
to acclimation and protection from abiotic stresses. (The involvement of hydrogen peroxide in plant responses to
stresses. Elżbieta Kuźniak, Henryk Urbanek 2000)
7.) WOODIER STEMS & INCREASED VASCULAR SYSTEMS:
Hydrogen peroxide dosed in the irrigation water of cut rose plants resulted in hardier, woodier and longer stems. The
increased stem length was achieved in a shorter growth time and is the effect of increased vascular channels
allowing for increased water and nutrient uptake. (Effect of injecting Hydrogen Peroxide into heavy clay loam soil on
plant water status, net C O2 assimilation, biomass and vascular anatomy of avocado trees. Pilar M. Gil M.1, 2*, Raúl
Ferreyra E.1, 2, Cristián Barrera M.1, Carlos Zuñiga E.1, and Luis Gurovich R.)
8.) INCREASED VEGETATIVE (BIOMASS) AND REGENERATIVE (FLOWERING AND FRUITING) GROWTH
Zetler Strawberry Farm - South Africa - The 2 x control blocks, each 1.8 hectares, received continuous irrigation with
regular 50% H2O2 at 50 ppm or 50 ml per m 3. The 2 x Aquaza test blocks, each 1.8 hectares, received continuous
irrigation with Aquaza 30% H2O2 at 50 ppm. Flowering and fruiting figures are from a control and test section each
containing 750 strawberry plants.
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FURTHER AQUAZA APPLICATIONS:
1.) Foggers, humidifiers, misting systems:
The first treatment is generally 1% to insure a proper disinfection of the entire system, after which the dosage is
dropped to 20 - 50 ml/m3 water. This keeps the system clean and will prevent biofilm development as well as prevent
these systems from spraying micro-organisms all over your crops therefore increasing hygiene and lowering plant
infection rates. It is advisable to double/triple (no more than 100 ppm) the dosage of Aquaza treatment once every 2
months for 1 day as an extra hygiene measure.
2.) Surfaces, equipment, machinery & tools:
To maintain thorough hygiene as well as to prevent crop contamination it is important to regularly clean and
disinfect work surfaces, equipment, machinery and tools. This can easily be done using Aquaza using a dosage
between 0.5 – 2%. Obviously the advantages of a disinfectant with a long lasting effect are that it will protect any
surfaces it comes into contact with again re-infection from micro-organisms for much longer than traditional
disinfectants, also the fact that Aquaza has no smell will ensure a pleasant working environment. Another huge
benefit is that Aquaza will not affect stainless steel.
3.) Crop spraying:
Please note that Government regulations differ per country and that the use of any chemical as a crop treatment
chemical generally requires a pesticides approval. Currently Aquaza is not registered in the EU or South Africa for this
application and therefore may not be used for this application. Please check local legislation before using Aquaza for
this use.
We mention this application because of the experience some users have had with the use of Aquaza against plant
diseases such as Fusarium, Phythophtora, Rhizotomia, Mildew and such. Users report to us that they have
experimented with spraying Aquaza over their crops when such infections where present and have obtained
excellent results – in their own words, results not generally obtained when using standard chemicals for these
problems. Another important benefit was that Aquaza fully breaks down into water and oxygen, leaving no residue
on the plants or fruits/vegetables/flowers.
Dosages range from 0.3% to 2-3% depending on the type of crop, spraying frequency, the type of problem
encountered as well as the resistance of the plant against oxidation by H2O2. It is generally advisable to treat a small
number of plants to check on plant/leaf damage from H2O2 oxidation before treating all plants.
Spraying a 0.5 – 1% Aquaza solution before applying a foliage nutrient is also a strong recommendation. Aquaza will
oxidise organic pollution and open up bark and leaf pores significantly increasing the uptake of foliar nutrition. The
same applies to pesticides.
4.) Treating algae in water catchment basins:
Although Aquaza will effectively treat algae in water catchment basins, this is not the most economical use for
Aquaza. Actually the most economical method is not to treat the algae in the basin, but when it leaves the basin.
Standard practise often has growers lower the pH of water of pH 4, then pass it through a UV-C then raise the pH to
5 - 5.5. Aquaza treatment involves dosing Aquaza at 20 - 50 ml/m 3 water, passing through the UV-C and then into
further processing.
Passing Aquaza through the UV-C increases the effect of Aquaza by a factor 2-3, but also keeps the UV-C clean. It is
however not necessary to use a UV-C to achieve a satisfactory result, Aquaza can do the job without UV-C, but
depending on water organic pollution the dosage may need to be adjusted.
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5.) Greenhouse disinfection:
The end-of-season clean-up and disinfection is
essential to ensure the success of the following crop. A
good disinfection is essential and an important part in
disease management as it will go a long way in
preventing the carry-over of disease problems into the
next season. It is not only important to disinfect the
greenhouse itself, but also the reception and storage
areas.
Fogging and aerial disinfection are the most common
method of greenhouse disinfection. It is a fast method
and ensures the disinfectant gets everywhere. Aquaza has obtained excellent results when used for this application.
Furthermore, it allows growers to start-up as soon as the fog has setled. Meanwhile Aquaza will continue to work
for several days providing a thorough disinfection. Also, growers can easily measure the presence and residual effect
of Aquaza by using “peroxide test strips” on any surface they want to test. Even if the surface looks dry, if they simply
apply some water to the surface to be tested, the moisture will allow the test strip to activate. Generally growers are
able to measure Aquaza presence for at least 2 days.
6.) Crate washing:
To maintain hygiene, it is important that crates be washed and disinfected. Using Aquaza in the final rinse – dosed at
0,5 – 1% will provide an effective and long lasting disinfection.
7.) Frost protection:
Adding Aquaza 0.5% Aquaza to spray water will protect against freezing to -5 oC at least. Spray over crops, trees to
protect flowers against frost damage. Furthermore Aquaza is an oxidant and besides not freezing before at least
-5oC, Aquaza also produces heat through oxidation which adds an extra protection.
8.) Post-Harvest:
Aquaza can be used as a post-harvest treatment to wash fruit & vegetables, as well as an excellent additive for the
water that cut flowers are immersed in after harvest, where it acts as both sterilant and oxygen supply to extend
shelf-life.
MEASURING AQUAZA:
Although there are several ways of measuring the amount of H2O2 (active substance) in Aquaza, the easiest and most
practical is by using simple peroxide test strips. These are relatively accurate and can be obtained in several ranges: 0
- 100 ppm and 0 - 400 ppm. Generally the 0 - 100 ppm range are used.
CONCLUSIONS:
Continuous dosing of 20 -50 ppm Aquaza in irrigation water brings multiple benefits to horticulture and floriculture,
some of which are only now beginning to be understood by science.
The fact remains though, now that farmers have the ability to effectively and economically use Hydrogen peroxide
thanks to the advances of Aquaza OXY 300, increased plant health and harvest yield without the use of unnatural
chemical fertilizers is easily achieved.
Once the greenhouse and irrigation system have been cleaned and disinfected, continual dosing of the irrigation
water will prevent re-growth of biofilm and lift the level of hygiene in the entire propagation cycle, which will result
in healthier plants and increased yield.
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ADVANTAGES OF AQUAZA OXY 300:
• Fast and long lasting effect on surfaces and in water distribution systems (hours/days depending on dosage
and fouling of system).
• Elimination of planktonic waterborne & sessile biofilm pathogens in water systems.
• Highly effective even in low concentrations.
• Effective & fast sanitation program with spraying & fogging.
• Does contain nor leave any toxic chemical or heavy metal residues.
• Does not react with ammonia to form chloramines.
• Bacterial, algal and fungal control on rooted and un-rooted cuttings and cut flowers, seedbed soil and
planting cubes, irrigation systems, filter systems, walls, ceilings and floors.
• Non-corrosive on equipment.
• Does not have pH limitations and is effective at any temperature up to boiling point.
• Biodegradable, easy to apply, easy to monitor and very safe – breaks down completely into water and
Oxygen.
• Tasteless and odourless.
• Non-toxic, non-carcinogenic and non-mutagenic (pathogens cannot build up resistance to it over time).
• Eliminates chlorine which affects root development (plants really do not like chlorine).
RECOMMENDED DILUTIONS:
Application Dilution - %/ppm/per m3 Contact Time
0.5 - 2% 2 hrs - 30 min
Quick
5 000 - 20 000 ppm depending on
Shock Treatment
5 - 20 L per m3 level of fouling
0.2 - 0.5% 12 hrs
Overnight
2 000 - 5 000 ppm repeat if
Shock Treatment
2 - 5 L per m3 necessary
20 - 50 ppm
Continual Dosage 20 - 50 ml per m3 Continuous
1%
Fog Disinfection 10 000 ppm Non-rinse
10 L per m3
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Dilutions need to be calculated based on the fouling and the contact time. The more fouled the system, the higher
the ppm dilution needed. The longer the contact time, the lower the ppm dilution needed.
Note: Aquaza can not be used simultaneously with products that contain traces of Trichoderma. Solution: Do not add
Aquaza to the water for 1-2 days before or after using Trichoderma.
Aquaza: “what the users say’’
• Much beter root development
• Increase in capacity of the pump
• Significant decrease in dead plants
• Less disease
• Beter irrigation
• Less to no blockages of drippers
• No unpleasant odours
• Product effective for several hours / days
• Easy to use
• First product in a long time that actually does what it promises
• Saves money
• Easy to check presence with peroxide test strips
Aquaza OXY 300 is supplied as a Ready-To-Use 30% Food Grade Hydrogen peroxide solution or for large users we
supply the Aquaza GEL encapsulation and activation additive for addition to Hydrogen Peroxide on-site by the user.
For pricing and ordering please contact:
Craig G. Jones
International Sales Manager
Aquaza cc
Encapsulated & Activated Food Grade Hydrogen Peroxide Solutions
Cell: +27 (0)741 326 336
Email: craig@aquaza.com
Web: www.aquaza.com
The information contained herein is, to the best of our knowledge and belief, accurate. However, since the conditions of handling and use are beyond our control,
we do not guarantee any results, and we are not liable for any damage incurred by following these suggestions. Nothing contained herein is to be construed as a
recommendation for use in violation of any patents or of applicable laws or regulations.
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