1 / 30

Mycotoxins in Grain and Feed Industries

Mycotoxins in Grain and Feed Industries. II. Best Practices in Handling and Testing. Erin Bowers, Iowa State University, Agricultural Engineering Charles Hurburgh, Iowa State University, Agricultural Engineering Alison Robertson, Iowa State University, Plant Pathology.

gay-keller
Download Presentation

Mycotoxins in Grain and Feed Industries

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Mycotoxins in Grain and Feed Industries II. Best Practices in Handling and Testing Erin Bowers, Iowa State University, Agricultural Engineering Charles Hurburgh, Iowa State University, Agricultural Engineering Alison Robertson, Iowa State University, Plant Pathology

  2. Learning Objectives • This learning module will focus on the sampling, testing, and storage of grains containing mycotoxins • Module Objectives: • Learn BMP for testing for mycotoxin contamination and for consignment of inbound ingredients (grains) that potentially contain toxins. • Learn BMP for preventing the production of mycotoxins in grain or grain sample storage. **BMP=Best Management Practices

  3. Basics: Agriculturally Important Mycotoxins • Fungi contaminate grains, food, and feed worldwide • Mycotoxins are chemical compounds produced by some fungi • More than 400 mycotoxins identified worldwide, 30 concerning for human or animal health • 5 principle mycotoxins affect cereal grains (corn, wheat, rye, barley, oats) • aflatoxins, fumonisins, deoxynivalenol (vomitoxin), zearalenone, and ochratoxin A Gibberella Ear Rot caused by Gibberella zeae Wheat Scab

  4. Developing Fungus is Dependent onthe Environmental Conditions During Pollination and Early Grain Development

  5. Basics: Mycotoxinsin Grain and Feed • Environmental stresses increase susceptibility • Planting, harvest, and storage practices also contribute to mycotoxin risk • Most mycotoxins remain intact after cooking, drying, freezing or storage conditions. • Mycotoxins at very low concentrations (ppm or ppb) are capable of causing serious health problems for humans as well as animals. • There is usually no treatment for mycotoxin poisoning (mycotoxicosis). ppm: parts per million ppb: parts per billion

  6. Poisonous Ingredients in Food • Federal Food, Drug, and Cosmetic Act • §402 [21 U.S.C. 342] • A food shall be deemed adulterated—(a)(1) If it bears or contains any poisonous of deleterious substance which may render it injurious to health; but in case the substance is not an added substance such food shall not be considered adulterated under this clause if the quantity of such substance does not ordinarily render it injurious to health.

  7. Mycotoxin Management Plan • Most mycotoxin contamination happens in the field • Prevent contaminated grain from entering the facility • Pre-harvest preventative controls • Scouting and pre-harvest observations • Climate and weather conditions • At-receiving mycotoxin testing procedure

  8. Mycotoxin testing procedure Procedural component 1) Sampling • Sample size reduction (if necessary) 2) Sample Preparation • Grinding • Mixing • Subdividing 3) Analysis Output • Laboratory Sample • Analysis Sample • Mycotoxin Result An example of a grinder that would be used to grind a laboratory sample.

  9. Heterogeneous distribution • Mycotoxins are not distributed uniformly throughout fields, bins, or transportation containers • Localization of moldy grain • High variability among individual kernels • A few mycotoxin-affected kernels can limit grain use • Misclassification of grain Hypothetical distribution of an incoming load of corn with an average aflatoxin level of 10 parts-per-billion (ppb)

  10. Sampling (the laboratory sample) • The process of acquiring a sample of grain (laboratory sample) that is representative of the lot • Subject to sampling bias • Sample representativeness is increased by taking incremental samples • This is a time-consuming practice • Not practical to use for every load of grain entering a facility • Prescribed for compliance sampling (aflatoxin) • Incremental samples are aggregated and mixed to form the laboratory sample

  11. Sampling Equipment An Ellis sampler can be used to manually sample grain on a conveyor Hand grain probe (trier) Above: An example of a probing pattern to be used for sampling a flat-bottom truck or trailer. Bottom right: An illustration of the action of a diverter-type sampler. At set intervals a portion of the moving grain is captured and diverted to a sample receiving container by a moving receptacle. Receptacle Grain flow Mechanical grain probe sampling a truckload of grain at a receiving point x x Sample x x x x x

  12. Products for Surveillance Sampling Abbreviated list adapted from CPG 7307.001 Attachment A

  13. Aflatoxin Compliance Sampling Adapted from FDA Investigations Operations Manual, 2013, Ch. 4, Chart 6

  14. Sample preparation • Preparing the laboratory sample for analysis • Grinding the entire laboratory sample • The smaller the laboratory sample, the higher the uncertainty in the final analytical result • Mixing • Homogenize • Selecting analysis sample An example of a grinder that would be used to grind a laboratory sample.

  15. Operating characteristics of mycotoxin sampling plans What is the probability that a grain lot will be correctly quantified using a given sampling plan? All parameters the same except • Green=1 lblaboratory sample • Blue=5 lb laboratory sample • Orange=10 lb laboratory sample Probability of Accepting Lot (%) Lot Aflatoxin Concentration (ppb) www.fstools.org/mycotoxins/

  16. Operating characteristics of mycotoxin sampling plans Seller’s risk Commercial-false rejection of good quality grain Regulatory-false sanctions Buyer’s risk Commercial-false acceptance of poor quality grain Regulatory-compromises food and feed safety Seller’s Risk Probability of Accepting Lot (%) Buyer’s Risk Lot Aflatoxin Concentration (ppb) www.fstools.org/mycotoxins/

  17. Analysis • Using an appropriate method to determine the quantity or confirm the presence or absence of mycotoxins in the analysis sample • Qualitative or Quantitative • Rapid test or analytical laboratory • The choice of detection method will depend on the user’s needs and resources, the commodity being tested, and the decisions which will be made using the analytical result.

  18. Analysis • High Performance Liquid Chromatography (HPLC) • Require trained personnel to maintain and operate • Produces results with high • Precision • Accuracy • Repeatability • Sensitivity • Standard for mycotoxin confirmation analysis in compliance samples The image below shows an example of an HPLC instrument set up in a lab

  19. Analysis • Rapid test methods • Rapid relative to analytical chemistry methods • Common on-site analysis methods • Examples of rapid test methods • Enzyme-linked immunosorbent assay (ELISA) • Lateral flow assay • Flow through assay Left: an example of an ELISA test Right: examples of lateral flow assays

  20. Analysis • GIPSA provides outside laboratory validation of rapid test kits submitted by manufacturers • Not mandatory to use a GIPSA-approved kit • More information, http://www.gipsa.usda.gov/fgis/insp_weigh/raptestkit.html Left: an example of an ELISA test Right: examples of lateral flow assays

  21. Analysis • Blacklighting (IOM 427.04g) • Screening purposes (aflatoxin only) • Few false negatives, but many false positives • Direct quantitative testing to at-risk-loads • Thin-Layer Chromatography (TLC) Above: an example of bright greenish-yellow fluorescence produced when Aspergillusflavus-infected corn is viewed under blacklight

  22. Analysis • Benefits of rapid tests vs HPLC • Ease of use • Cost • Compact (size) • Minimal calibration • Less equipment maintenance/upkeep • Faster • Downfalls of rapid tests • Reduced sensitivity • Narrow operating range • Higher limits of detection • Not approved for regulatory decision-making • Confirmation analysis necessary by accepted analytical method • Compliance Policy Guide Manual, section 555.400

  23. Analysis • FSMA: Industry action required based upon reasonable suspicion of food/feed safety threat • Documentation to verify safe handling, processing, storage, and end use • Performance Monitoring: Check-samples ensure appropriateness of mycotoxin management (best practice) • Especially in facilities producing finished feed or food products

  24. Practical Considerations • Time requirement for testing is significant • Can’t test/sample every load • Can’t test for every mycotoxin • Know the risks and be strategic • Weather and climate are good indicators of mycotoxin risk • Cool, wet conditions- risk of deoxynivalenol and zearalenone • Hot, drought conditions- risk of aflatoxins • Warm, drought conditions-risk of fumonisins • Use this as a predictive tool to direct sampling and testing • Composite testing is good practice to monitor overall quality of incoming grain and of that which has been accepted

  25. Storage and Handling • Reduce the ability of fungi to survive and grow • Shelf life of grain is impacted by • Quality of stored grain • Water availability • Grain moisture • Grain temperature • Drying: Reduce grain moisture to stop fungal growth and mycotoxin production • Dry promptly: minimize time between harvest and drying to maximize shelf life of grain • Dry carefully: prevent stress cracks and reduce breakage • Kernel temperature ≤110°F • Grain moisture in equilibrium with 65% RH will prevent fungal activity

  26. Storage and Handling • Temperature is an important factor for grain storage • Cool temperatures (<60°F) minimize fungal growth • Aeration can be used to facilitate temperature control • Temperature uniformity • Minimize moisture movement • Monitor grain for changes in quality

  27. Blending • Aflatoxin is a food/feed adulterant • Grain >20 ppb cannot be deliberately blended • FDA blending dispensations have been allowed in rare instances when a large portion of the U.S. corn supply is affected • State by state basis • Resultant grain used only for specific livestock feed • >500 ppb aflatoxin grain has never been allowed to be blended

  28. Mycotoxins in grain handling facilities • Mycotoxin management can be accomplished using proper storage and handling practices, and through preventing contaminated grain from entering a facility • Testing domestic grain for mycotoxins is discretionary, export is mandatory for aflatoxin only • Each facility will likely handle mycotoxin management uniquely, depending on their individual structure, capabilities, and contract requirements • Look for evidence of proactive action • Strategic, informed plans and actions

  29. Proactive approaches } in combination with a threshold for acceptance • Contract terms for suppliers • Attention to growing conditions in the area • Pre-harvest scouting/survey • A mycotoxin sampling plan • Sampling • Sample preparation • Analysis • Monitoring the effectiveness of the sampling plan • Finished product checks and verification • Check sample analysis (third party laboratory) • Composite sample testing

  30. This training was a joint effort of www.iowagrain.org www.grains.ksu.edu *Funding for this Grain and Feed Mill Operations course was made possible, in part, by the Food and Drug Administration through grant (1U54FD004333-01), views expressed in written materials or publications and by speakers and moderators do not necessarily reflect the official policies of the Department of Health and Human Services; nor does any mention of trade names, commercial practices, or organization imply endorsement by the United States Government.*

More Related