1. RISK TO HEALTH FROM THE LAND APPLICATION OF SLUDGE Dr. Joseph B. Farrell, Consultant 1117 Stormy Way Cincinnati, Ohio 45230 Phone/Fax: 513-231-7451 FARRELLJ44UND@AOL.COM

2. Required Reading “Biosolids applied to Land: Advancing Standards and Practices”. 2002. Prepared by Committee on Toxicants and Pathogens in BIosolids Applied to Land, National Research Council, Pub. National Academy Press, Wash., D.C. Smith, J.E., Jr. et al. 2005. “Infectious Disease Agents in Sewage Sludge and Manure.” Pub. The JG Press, Emmaus, PA.

3. NRC Committee Chairman’s Comment on LA Report “The Science of Recycling Sewage Sludge” by Thomas A. Burke. 2002. Buckeye Bulletin, p. 34, November, Burke’s comment on the NAS report, “We found no evidence of an urgent public health risk from exposure to land- applied biosolids, based on our review of the scientific literature.”

4. NRC Report’s Top Recommendations Use improved risk-assessment methods Conduct new survey of chemicals and pathogens in sludge. Implement human health investigations. Increase EPA resources for biosolids

5. Makeup of Raw Sewage Sludge Paper Fecal matter Kitchen wastes Bacterial mass from WW treatment Gray water residues Solids in street runoff Industrial wastes

6. Chemical Makeup of Sewage Sludge Bulk organics (carbohydrate, protein, fat, mineral oil) Trace organics (hormones, plasticizers, dioxins, PCBs) Nitrogen-phosphorus-potassium Industry (insoluble or absorbed inorganic or organic chemicals)

7. What Substances are Health Risks? Inorganic chemicals (heavy metals) – cumulative. Trace organics (dioxins, PCBs) – cumulative Pathogens (viruses, bacteria, parasites) – immediate Dead bacteria (gram-negative bacteria cell walls) - immediate

8. Quantifying The Risk By Risk Assessment: Concentrations and dose/response must be known ConcentrationDose/response Metalsyes Toxic organicsYesMuch knowledge Pathogens, dead bacteria NoGreat variations

9. BASIS OF RULE Risk-based for chemical contaminants (heavy metals, organic chemicals) Based on best judgment for pathogens

10. Pathways of Toxicants and Pathogens in Biosolids to Man Land Application of Biosolids: Exposure Route Surface Water Ingestion Ground Water Ingestion Direct Soil Ingestion Plant Ingestion Inhalation Host/Pathogen Interaction: Disease Transmission

11. Why no Risk Assessment for Pathogens? Pathogen densities are not conserved Die-off rates are not well-quantified Infectious dose vary widely (But, we know enough to establish reasonable controls)

12. Dose/Response for Pathogens OrganismInfective Dose Protozoa1-50 cysts Enteroviruses1-50 PFU HelminthsOne egg Pathogenic bacteria100-1,000,000 CFU

13. Bacterial Pathogens of Potential Concern in Biosolids Major Concern Salmonella Shigella enteropathogenic E. coli Yersinia enterocolitica Campylobacter jejuni Vibrio cholera Leptospira Fecal coliform New issues E. coli 0157:H7 Listeria Helicobacter Mycobacteria Aeromonas Legionella Burkholderia Endotoxins Antibiotic resistance

14. Human Enteric Viruses (from Gerba) Virus GroupNo. of Types Enterovirus (polio, coxsackie, echo) 69 Hepatitis A virus1 Reoviruses3 Rotaviruses8 Adenoviruses49 Astroviruses7 Hepatitis E virus1 Caliciviurses3?

15. Major Helminths/Protozoa in Sludge Protozoa Cryptosporidium spp. Giardia spp. Helminths Ascaris spp. Toxocara spp. Trichuris spp. Taenia

17. Diseases of Special Concern SARS: It is not enteric. It has almost disappeared (but could come back). It is spread by inhalation of large suspended droplets. Prion Diseases: Consumption of contaminated meat by animals or man. Resist thermal treatment but perhaps not biological digestion. Keep it out of sewers. (CWD, BSE, vCJ disease). CWD does not cross species barrier.

18. Survival Times of Pathogens on Soils and Plants

19. Reductions due to Processing Anaerobic digestion Lime treatment composting, pasteurize Fecal coliform 1/30>>1/100 Pathogenic bacteria 1/10>>1/100 enterovirus1/10>>1/100 Helminth eggs 1/3?, 1/10>>1/100

20. Approach to Controlling Risk from Pathogens Class A Eliminate pathogens by extreme processing such as pasteurization. Then reduce vector attraction. Class B Reduce pathogens by conventional processing. Reduce vector attraction. Surround use with restrictions that eliminate all paths to man, crops and animals.

21. VAR AND PR Pathogen Reduction (PR) and Vector Attraction Reduction (VAR) are required. For Class A, PR must take place before or at the same time as VAR.

22. Vector Attraction Reduction (VAR) Methods Reduce volatile solids content Reduce specific oxygen uptake rate Compost for 14d above 40 0 C Raise pH above 12, >11.5 at 24h. Dry to 90%, 75%, depending on sludge. Inject below the soil surface Surface apply but plow in promptly (Details are found in 40CFR Part 503)

23. PFRP Processes (Class A) Composting Heat drying Heat treatment Thermophilic aerobic digestion Irradiation Pasteurization High pH and temperature/time treatment (for each process, minimum processing conditions are specified in 40CFR PART503)

24. ADDITIONAL CLASS A PROCESSES Prior Testing for Enteric Virus & Viable Helminth Routine monitoring of each batch of treated sewage sludge. Use PFRP Equivalent Process.

25. Class B Biosolids Microbiological Criteria Reduce fecal coliform density to less than 2,000,000 per gram of solids. This is 1/100 of density in wastewater solids. OR, treat the sludge by a specific stabilization process defined in the regulation (a PSRP)

26. PSRP PROCESSES Aerobic Digestion Air Drying Anaerobic Digestion Composting Lime Stabilization (for each process, specific minimum conditions are specified)

27. Class B Restrictions: Site Access If high public use (ball field), no public access for 12 months. If low public access ( a farm), no public access for 30 days.

28. Class B Site Restrictions: Harvesting Above-ground food crops that touch the soil, 14 months after application Below-ground food crops, 20 months if first 4 months are on soil surface. 38 months if < 4 months on surface. No crops harvested within 30 days of application.

29. Class B Restrictions: Turf and Grazing Turf: If high public access (a front lawn), no harvest before one year after application. Grazing: No grazing until 30 days after application.

30. Is the Practice of LA safe? Comment: The US NRC says the rule is sufficiently protective (with caveats) Objection: How can one rule fit the entire United States? Any state can add more stringent requirements tailored to their conditions.

31. Some State Actions Specify distance to water table (Florida) Specify maximum allowable slope (NY) Decreased some allowable metal concentrations (NY, Nova Scotia) Increased most time restrictions

32. Problems with 40CFR PART 503 Hard to modify the regulation Are the processes working properly PSRP should have been dropped Grazing restrictions should key to temp. Aerobic digestion PFRP should be fixed Low public use access restriction for Class B should be modified Slow pace of Federal research

33. Improving Reliability Increase Government oversight, toughen penalties Require certification of satisfactory operation by independent evaluators (e.g., the Biosolids Partnership)

35. Concn.: Exceptional Qual. Biosolids METAL (mg/kg)NOVA SCOTIAUS EPA Arsenic1341 Cadmium339 Chromium2101200 Cobalt34 Copper4001500 Mercury0.817 Molybdenum518 Nickel62420 Lead150300 Selenium236 Zinc7002800

36. What the Federal Rule Establishes General requirements (must give details about the site, sludge, planned practice) Pollutant limits (e.g., max. metal concns.) Management practices (e.g., 10m from US waters) Monitoring frequency

37. More on what the FR establishes Operatinal standards (spells out how one must achieve pathogen and VA reduction) Recordkeeping (Certify rule is being kept under penalty of law if not true) Reporting (If > 1 MGD, a yearly report)

38. Approach to Controlling Risk from Metals to Man and Soil Determine metal concentrations in sludge Apply at agronomic rate (to prevent excessive N/P/K loading) Establish max. concn. in the biosolids Establish max. annual and total loading to the soil. Establish concentration below which no harm will occur.

39. Class A Sludge Microbiological Criteria Salmonella –< 3 MPN per 4 grams of TS Fecal Coliforms –< 1000 MPN per gram of TS Enteric Viruses –< 1 plaque forming unit per 4 grams of TS Viable Helminth Ova –< 1 per 4 grams of TS