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Ozone Applications

1,4-Dioxane removal with ozone A New Formulation Based on Ozonated Sunflower Seed Oil: In Vitro Antibacterial and Safety Evaluation AOP Agri-Food Processing Air Treatment Antibacterial Activity of Ozonized Sunflower Oil, Oleozón, Against Staphylococcus aureus and Staphylococcus epidermidis. Antifungal Activity of Olive Oil and Ozonated Olive Oil Against Candida Spp. and Saprochaete Spp. Aquaculture BTEX Remediation under Challenging Site Conditions Using In-Situ Ozone Injection and Soil Vapor Extraction Technologies: A Case Study BTEX removal with ozone Beef (Red Meat) Processing with Ozone Benzene Body Odors Bottled Water Cannabis Catalytic Ozonation of Gasoline Compounds in Model and Natural Water in the Presence of Perfluorinated Alumina Bonded Phases Clean in Place (CIP) Combined Ozone and Ultrasound for the Removal of 1,4-Dioxane from Drinking Water Concrete Cooling Tower Cost Effectiveness of Ozonation and AOPs for Aromatic Compound Removal from Water: A Preliminary Study Create your own Ozonated Oils Dairy Farms Degradation of tert-Butyl Alcohol in Dilute Aqueous Solution by an O3/UV Process Drinking Water Drinking Water Disinfection E.coli O157:H7 Reduction with Ozone Effectiveness of Ozone for Inactivation of Escherichia coli and Bacillus Cereus in Pistachios Efficiency of Ozonation and AOP for Methyl-tert-Butylether (MTBE) Removal in Waterworks Ethylbenzene Evaluation of Ozone AOP for Degradation of 1,4-Dioxane Exploring the Potential of Ozonated Oils in Dental Care Exploring the Potential of Ozonated Oils in Hair Care Fire Restoration Food Odors Force Main Treatment Germicidal Properties of Ozonated Sunflower Oil Grain Treatment Groundwater Remediation Hoof Bath Hydroponic Greenhouses In Vitro Antimicrobial Activity of Ozonated Sunflower Oil against Antibiotic-Resistant Enterococcus faecalis Isolated from Endodontic Infection Influence of Storage Temperature on the Composition and the Antibacterial Activity of Ozonized Sunflower Oil Insect Control in Grains Kinetic Analysis of Ozonation Degree Effect on the Physicochemical Properties of Ozonated Vegetable Oils Laundry Laundry Listeria Inactivation with Ozone MTBE removal with ozone Machine Coolant Tanks Measurement of Peroxidic Species in Ozonized Sunflower Oil Mitigation strategies for Salmonella, E. coli O157:H7, and Antimicrobial Resistance Throughout the Beef Production Chain Mold Removal in Grain Mold/Mildew Odors Municipal Water Treatment Mycotoxin Reduction in Grain Nanobubbles Odor Removal Oxidation of Methyl tert-Butyl Ether (MTBE) and Ethyl tert-Butyl Ether (ETBE) by Ozone and Combined Ozone/Hydrogen Peroxide Oxidize Tannins from Water with Ozone Oxy-Oils Ozonated Oils Ozonated Ice & Fish Storage Ozonated Mineral Oil: Preparation, Characterization and Evaluation of the Microbicidal Activity Ozonated Oils: Nature's Remedy for Soothing Bug Bites Ozonated Olive Oil Ozonated Olive Oil Enhances the Growth of Granulation Tissue in a Mouse Model of Pressure Ulcer Ozonated Olive Oil with a High Peroxide Value for Topical Applications: In-Vitro Cytotoxicity Analysis with L929 Cells Ozonation Degree of Vegetable Oils as the Factor of Their Anti-Inflammatory and Wound-Healing Effectiveness Ozonation of Soluble Organics in Aqueous Solutions Using Microbubbles Ozone Gas and Ozonized Sunflower Oil as Alternative Therapies against Pythium Insidiosum Isolated from Dogs Ozone Inactivation of E.Coli at Various O3 Concentrations and Times Ozone Regulations in Food Processing Ozone Regulations in Organic Food Production Ozone in Air Applications Ozone in Sanitation Ozone in Seafood Processing Ozone use for Post-Harvest Processing of Berries Ozone use for Surface Sanitation on Dairy Farms Pet Odors Physico-chemical Characterization and Antibacterial Activity of Ozonated Pomegranate Seeds Oil Pool & Spa Proinflammatory Event of Ozonized Olive Oil in Mice RES Case Studies Resolution Concerning the Use of Ozone in Food Processing Spectroscopic Characterization of Ozonated Sunflower Oil Stability Studies of Ozonized Sunflower Oil and Enriched Cosmetics with a Dedicated Peroxide Value Determination Study of Ozonated Olive Oil: Monitoring of the Ozone Absorption and Analysis of the Obtained Functional Groups Study of Ozonated Sunflower Oil Using 1H NMR and Microbiological Analysis Surface Sanitation TBA Removal with ozone Teat Wash Tobacco Odors Toluene Treatment of Groundwater Contaminated with 1,4-Dioxane, Tetrahydrofuran, and Chlorinated Volatile Organic Compounds Using Advanced Oxidation Processes Treatment of groundwater contaminated with gasoline components by an ozone/UV process Ultra-Pure Water Utilization of Ozone for the Decontamination of Small Fruits Various Antimicrobial Agent of Ozonized Olive Oil Vertical Farming with Ozone Waste Water Treatment Water Re-use Water Treatment Water Treatment Well Water Treatment Xylene

Agri-Food Processing

Ozone was given GRAS approval by the FDA and the USDA in 2001. This GRAS approval allows the use of ozone for direct contact with food as an antimicrobial intervention. Ozone use can provide safer food that will have a longer shelf-life due to lower bacteria levels. Ozone can be used on many food products.

Application Details

Food safety and shelf life of red meat can benefit from the proper implementation of ozone in aqueous and/or gaseous form.  Ozone is effective at eliminating the most common food-borne microorganisms causing spoilage and illness.  There is a great deal of research and real-world applications of ozone use for the inactivation of Escherichia coli, and Listeria monocytogenes.  

Beef (Red Meat) Processing with Ozone

Ozone is useful in the reduction and elimination of E.coli O157:H7 in food processing both as an antimicrobial intervention and a disinfectant.

E.coli O157:H7 Reduction with Ozone

Ozone can be used to destroy aflatoxin in grain, along with remove insects, odors, and mold.

Grain Treatment

Listeria Inactivation with Ozone is a viable solution in food processing applicatoins.

Listeria Inactivation with Ozone

Ozonated Ice & Fish Storage

Ozonated Ice & Fish Storage

USDA and FDA regulations granting GRAS staus to ozone along with additional information on the use of ozone in organic crop production. All ozone food regulations found HERE

Ozone Regulations in Food Processing

Ozone is a powerful oxidizing agent that can be used to disinfect and clean equipment and surfaces in a variety of industries, including food and beverage, pharmaceutical, and water treatment. In a CIP (Clean-In-Place) system, ozone is generated on-site and used to clean and sanitize equipment without the need for chemicals or hot water.

Ozone in Sanitation

Ozone in Seafood Processing

Ozone in Seafood Processing

Ozone use for Post-Harvest Processing of Berries

Ozone use for Post-Harvest Processing of Berries

Resolution Concerning the Use of Ozone in Food Processing from the original EPRI food study used to petition the USDA and FDA to gain GRAS approval for ozone use in food processing applications.

Resolution Concerning the Use of Ozone in Food Processing

Surface Sanitation

Surface Sanitation

Ozone has a variety of uses in vertical farming applications using hydroponics for irrigation. Ozone provides water disinfection and higher dissolved oxygen levels in water.

Vertical Farming with Ozone

Ozone can be used on dairy farms for many applications. Teat wash, hoof bath, and other applications help improve milk production and improve overall herd health.

Dairy Farms

Ozone can be used in hydroponic greenhouses to improve plant growth, conserve water, and overall save costs while improving productivity of your system.

Hydroponic Greenhouses

With the booming growth of the Cannabis industry, it is important to note all of the ways that Ozone can help maximize Cannabis growth, cleanliness, and upkeep.

Cannabis

 

How it works:

Ozone effect on Bacteria

Ozone as an oxidant is useful in the inactivation of all pathogens yet reverts to oxygen after oxidation leaving no undesirable by-products on food products.  Ozone is effective at eliminating all pathogenic bacteria, along with viruses and mold.  Ozone is effective against bacteria at very low levels as the ozone reaction with bacteria causes lysis of the cell wall causing the cell wall to rupture through the oxidation process.  However, chlorine requires the diffusion of HOCL through the cell membrane.  There are no "ozone resistant" bacteria strains.  Inactivation rates of bacteria due to ozone will be dependent upon ozone concentrations, time, temperature and humidity (in gas phase).

Ozone can be used in the gas and aqueous phase for effective inaction of food-borne pathogens.

 

Aqueous Ozone:

The most common method of using ozone for pathogen reduction is dissolving ozone into water. Aqueous ozone is very stable, safe, and easy to manage. Typically ozone is dissolved into water using an ozone injection system and then sprayed onto the surface requiring disinfection. This surface may be a hard equipment surface, or the surface of a food product.

Ozone spray beef brisket

 

Ozone levels dissolved into water of only 2.0 ppm or above are commonly used for bacteria inactivation. Only a few seconds of contact time of the aqueous ozone with the pathogen is necessary for inactivation.  While greater ozone levels in water can be used with no adverse effects to the food, there is minimal benefit to initial sanitation using higher levels of ozone

See the chart below for details.

E.coli reduction

Paper reference HERE

 

Using this data a determination of spray nozzles, spray bars, or even conveyers can be established. It is clearly shown that 2.0 ppm of aqueous ozone is very effective in only a short period of time, while higher ozone levels show only marginal improvement.

It is important to note that ozone reverts to oxygen quickly.  Therefore tanks of ozone water to dip food products into is normally not effective as the water will lose the ozone dissolved in water quickly.  It is normally best to spray adequate levels of water on food products with sufficient dissolved ozone levels in this water.  

 

Gaseous Ozone:

The use of gaseous ozone for the elimination of pathogens is also viable.  The application of gaseous ozone is dependent upon the temperature, humidity, contact time, and ozone levels. Research has been conducted to determine that gaseous ozone will reduce and inactivate pathogens.  However, this application normally requires closer adherence to specific temperatures and humidity in the room as the reaction rate of ozone gas will vary based on these factors.

Ozone gas hanging beef

 

Ozone GRAS Approval:

Ozone was granted GRAS (Generally Regarded as Safe) by the USDA and FDA due to a petition filed by the EPRI (Energy Partners Research Institute) in an effort to gain more widespread use of ozone in food processing as an effort to reduce energy consumption.  Both the original petition and the final handbook assembled by the EPRI are available in the links below.  Additional information on ozone regulations can be found HERE. 

Due to GRAS approval granted for the use of ozone the implementation of ozone is allowable for all food applications in the USA with minimal additional regulation.  

 

Ozone in Organic Food Production:

USDA Organic with ozone

Ozone is allowed for use in the organic production of food products.  The National Organic Program (NOP) has allowed for the use of ozone to varying degrees in various applications.  For more information on the use of ozone in organic food production follow this link.

 

Potential Water Savings:

Ozone has been implemented in various applications to lower water consumption or waste along with reclaiming water for re-use in a food plant.  

Closed-loop water systems can benefit from ozone use as ozone will oxidize organics in water while leaving no or minimal by-products when compared to other chemical options.  By keeping water disinfected while maintaining clearer, cleaner, odor free, and chemical by-product free water system change-outs can be minimized saving water and saving processing time.

Ozone can be used to reclaim water from processes by offering disinfection, color removal, and odor removal from that water for use in secondary applications within the plant.  

When used in CIP, or surface sanitation applications ozone can be used as a final sanitizer and rinsing step in one.  As ozone reverts to oxgen there is no need for a secondary rinse step in various applications.

 

Benefits of Food Processing with Ozone:

     -Bacteria reduction during processing will also extend shelf life

     -Greater elimination of bacteria is realized with ozone 

     -Ozone was given GRAS approval by both the FDA and the USDA in 2001

     -Fewer disinfection by-products will be created with the use of ozone, ozone reverts to oxygen

     -Water savings may provide system pay-back

     -Less chemicals = better flavor

     -Lower chemical costs, overall lower costs

     -Less chemicals in the environment ensures improved human safety

 

Ozone Food Processing Applications:

This list is not comprehensive but links to various pages on our website with application specific information.  Should you have questions about your unique application, contact our office, we would be glad to help.

 

Additional Links:

Ozone Regulations in Food Processing

Ozone regulations in Organic food production

Resolution Concerning the Use of Ozone in Food Processing from original EPRI documents

Original EPRI Direct Food Additive Petition used to gain GRAS approval for ozone

EPRI Global Ozone Handbook

Book - Ozone in Food Processing

 

 

View the Questionnaire for Meat Processing Plant so we can help design your Ozone System

 

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