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Sampling and detection of microorganisms in the environment

Sampling and detection of microorganisms in the environment. Gwy-Am Shin Department of Environmental and Occupational Health Sciences. Sampling. The challenges. Different microbe types Different media types Low numbers of pathogens in the environment. Infectious diseases.

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Sampling and detection of microorganisms in the environment

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  1. Sampling and detection of microorganisms in the environment Gwy-Am Shin Department of Environmental and Occupational Health Sciences

  2. Sampling

  3. The challenges • Different microbe types • Different media types • Low numbers of pathogens in the environment

  4. Infectious diseases • 1415 human pathogens (2001) • 217 viruses and prions • 538 bacteria and rickettsiae • 307 fungi • 66 protozoans • 287 helminths

  5. Transmission of infectious disease • Person-to-person • Direct: person-to-person or animal-to-person • Indirect : droplet, fomites (toys), other vehicles • Environment • Airborne • Waterborne • Foodborne • Vectorborne

  6. Low numbers of pathogens in the environment

  7. Transmission of enteric pathogens

  8. Low number of microbes in the environment • Need large volumes • Need to separate microbes from other materials

  9. Steps in pathogen sampling in the environment • Concentration • Purification/Reconcentration • Analysis

  10. Concentration in Individual media

  11. Sampling microbes in water • Filtration is typically used for concentration • Several formats utilized: • Membrane, pleated capsule, cartridge, hollow fiber • Several types of media • cellulose ester, fiberglass, nylon, polycarbonate, diatomaceous earth, polypropylene, cotton, polysulfone, polyacrylonitrile, polyether sulfone

  12. Filters to Recover and Concentrate Microbes from Liquids

  13. Sampling microbes in air • Filters • Not recommended due to low sampling efficiency • Impingers • AGI sampler • Biosampler (SKC) sampler • Impactors • Anderson single and multistage sampler • Slit sampler • Rotary arm sampler • Centrifugal samplers • Cyclone sampler • Centrifugal sampler

  14. Impingers

  15. Impactors (I)

  16. Impactors (II)

  17. Centrifugal samplers

  18. Sampling microbes from surfaces • Swabs • cotton, dacron, calcium alginate, sponge • Swipes/Wipes • cotton, nitrocellulose membranes, polyester bonded cloth, velvet or velveteen • Vacuum Filtration • Hepa bag vac, wet vac • Contact Plates and Paddles (RODAC) • New Methods • Adhesive Strips and Paddles • Scraping/Aspiration Yamaguchi, et al. 2003; Cloud, et al. 2002; Lemmen, et al, 2001; Poletti, 1999; Craythorn, et al. 1980; Osterblad, et al. 2003; Taku, et al. 2003

  19. Purification/re-concentration

  20. Purification/re-concentration • PEG (polyethylene glycol) • Organic Flocculation • IMS (Immunomagnetic separation) • Ligand capture • BEaDs (Biodetection Enabling Device) • Capillary Electrophoresis • Microfluidics • Nucleic Acid Extraction • Spin Column Chromatography • Floatation • Sedimentation • Enrichment

  21. Immunomagnetic Separation Y Antibody Bead Y Y Y Microbe

  22. Immonomagnetic separation assay

  23. Summary (Sampling) • Sampling methods are lagging behind detection methods • Speed isn’t everything • Negative results don’t necessarily mean target not there • There is a need to focus on the reliability and sensitivity of concentration methods • Difficulties with a single platform for any one media because of wide range of organisms and environmental conditions

  24. Detection methods

  25. Light microscope

  26. Electron microscope

  27. Sizes of microorganisms

  28. Cultural methods (bacteria) Traditional approach • 1st step • pre-enrich and/or enrich using non-selective and then selective broth media • grow colonies on membrane filters • 2nd step • Transfer to differential and selective agars • Recover presumptive positive colonies • Biochemical, metabolic and other physiological testing • Serological or other immunochemical typing • Other characterization: phage typing, nucleic acid analyses, virulence tests

  29. Enrichment Cultures • Observe for growth by turbidity, clearing, gas production, color change, etc. • Score as presence-absence (positive or negative) • (sometimes) Quantify using replicate and different volumes to compute a Most Probable Number Left: negative Right: positive (color change)

  30. Cultural methods (bacteria) • Plating methods • Spread plating technique • Pour plating technique • Most Probable Number (MPN) technique

  31. Different bacterial colonies on general media

  32. Cultural methods (viruses and protozoa) • Animal infectivity assays • Mouse • Gerbils • Champagnes • Human • Cell-culture infectivity assays • Primary cell lines • Established cancer cell lines

  33. Immunological methods

  34. Antigen and antibody reaction

  35. Immunological methods • Immunoprecipitation assays • Immunoblotting assays • Enzyme-Linked Immunosorbent assays (ELISA)

  36. Nucleic acid-based methods

  37. Structure of DNA

  38. Nucleic-acid based methods • Gene probing • Southern and northern hybridization • Microarray • Polymerase Chain Reaction (PCR)

  39. Gene probe detection

  40. Real-Time PCR and Quantitative Fluorogenic Detection • Molecular beacon. Several 5' bases form base pairs with several 3' bases; reporter and quencher in close proximity. • If reporter is excited by light, its emission is absorbed by quencher & no fluorescence is detected. • Detection of PCR product by molecular beacon. • Beacon binds to PCR product and fluoresces when excited by the appropriate light. • [Fluorescence] proportional to [PCR product amplified]

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