CHALLENGES AND FUTURE FORECASTS OF MEASUREMENT TECHNOLOGIES IN WATER MICROBIOLOGY Dr. Elias Hakalehto Adjunct Professor, University of Eastern Finland R&D Director, Samplion Ltd.
AREAS OF WATER MICROBIOLOGY RESEARCH NATURAL WATERS Lakes Rivers Run-off water Ground water Wet depostitions DRINKING AND HOUSEHOLD WATERS Tap waters Bottled waters Water machines and dispensers Storage of drinking water INDUSTRIAL WATERS Food industry Pharmaceuticals Cosmetic industry Chemical industry Forest industry Fish farming The water content of the products, wash waters etc. RE- CREATIONAL WATERS Swimming pools Jacuzzis Water parks Spas WASTE- WATERS Residential wastewaters Industrial wastewaterst Mining effluents Hospital wastewaters Agricultural load Waste water load from the environment DISTRIBUTION OF INFECTIONS, EPIDEMICS AND ANTIBIOTIC- RESISTANT MICROBIAL STRAINS SHALL BE PREVENTED
STANDARD DEVELOPMENT IN WATER MICROBIOLOGY The responsibility of preparation and updating of STANDARD METHODS OF WATER MICROBIOLOGY (ISO/TC 147/SC4) in Finland lies with The National Institute for Health and Welfare (THL) (ref: Finland s Environmental Administration 2009: Environmental standardisation. Helsinki) Laboratory activities of social and health care administration are based on either national laws or regulations or international agreements, which must be met (Report by the laboratory workshop of Social and Health Care Administration. STM 31.10.2008). THREATS ARE DIVERSE, NOVEL METHODS ARE NEEDED! EPIDEMICS, LONG-RANGE CARRYOVER SPOILAGE OF TAP WATER NETWORK SYSTEMS NEW PATHOGENS, DRUG RESISTANCE
INDICATOR BACTERIA are bacteria which can be found downstream from the sources of very diverse types of pollution are easy to enrich, cultivate, count and handle Coliforms and Enterococci are common bacteria living in the intestines of human beings and warm-blooded animals. They are used as indicators of faecal contamination. Indicator bacteria can be found also from the natural environments without faecal load. Advanced analytics is therefore needed to trace the source of contamination. PMEU technology helps to detect indicator bacteria from samples where their counts are low or they are in bad condition. It is also a tracing tool whenever the origin of the microbes shall be found ( sourcetracking ).
APPLICATION OF INDICATOR BACTERIA: Escherichia coli Enterococci Total count of coliforms Pseudomonas aeruginosa, Clostridium perfringens TOTAL COUNT OF HETEROTROPHIC BACTERIA INDICATION OF PATHOGENS Salmonella Campylobacter VIROLOGIC ANALYSES
TRADITIONAL CULTIVATION METHODS ACCELERATED ENRICHMENT CULTIVATION (PMEU) METHODS OF MOLECULAR BIOLOGY Membrane filtration Plate cultures MPN ( Most Probable Number ) broth tubes Colilert immunoassays PCR biosensors, chips TESTING METHODS IN WATER HYGIENE Dos. Elias Hakalehto, Itä-Suomen yliopisto "Veden Vaarat", Tampere 25.- 26.8.2010
COMBINATION OF PMEU ENRICHMENT METHOD AND COLILERT TM BROTH E.coli (three syringes in the middle) growing in Colilert TM broth where yellow color is the indicator for all coliforms Fluorescence of three E.coli cultures, when illuminated with UV, in Colilert TM broth; this fluorescence is a specified indication of only E. Coli; other bacteria are non-fluorescent Dos. Elias Hakalehto, Itä-Suomen yliopisto "Veden Vaarat", Tampere 25.- 26.8.2010
CHROMOGENIC NUTRIENT MEDIA (ChromAGAR TM plates, Becton Dickinson Inc (Invented by Alain Rambach)) ARE ONE ALTERNATIVE FOR RAPID IDENTIFICATION E.coli Klebsiella mobilis Enterococcus sp. Bacillus cereus
DETECTION OF MICROBES IS A CHAIN PROCEDURE SAMPLING TRANSPORT + PRE- ENRICHMENT ENRICHMENT CULTIVATION DETECTION ANALYSIS Dos. Elias Hakalehto, Itä-Suomen yliopisto "Veden Vaarat", Tampere 25.- 26.8.2010
DECENTRALIZED (REMOTE) CONTROL, CENTRALIZED RESULTS Total plate count coliformic bacteria E.coli cfu/100 ml cfu/100 ml cfu/100 ml 1day 2 days 6 days 1 day 3 days 5 days 1 day 3 days 5 days Sample point 0 2000 6000 0 0 0 0 0 0 1 Sample point 0 full full 0 0 0 0 0 0 2 Sample point 0 0 0 0 0 0 0 0 0 3 Sample point 0 0 0 0 0 0 0 0 0 4 Sample point 0 10 000 10 000 0 0 0 0 0 0 5 Sample point 0 0 10 000 0 1000 1000 0 0 0 6 Sample point 0 4000 4000 0 20 20 0 0 0 7 Raw water 0 0 0 0 20 0 0 0 0 Lake water full full full full full full full full full Purified water 0 0 0 0 40 0 0 0 0 Bacteriological mapping of tap water network (Hakalehto et al. 2010) Share of Enterocci types in lake water samples (Heitto et al. 2009)
POLARIS national project for the development of total water quality control In Finland Basics: Current systems of water quality measurements cannot detect the spoilage of groud water. In most cases, contamination of tap water will be revealed only when first illnesses have been detected. Implementation: Risk assessment, ON LINE measurement technologies, effective modeling-supported picture of the situation and process optimization will all be applied into the project. Six Finnish water research institutes, Finnish Water and Waste Water Works Association (FIWA), 13 enterprises and three Finnish waterworks are joining this research project.
PMEU technology in POLARIS project Enrichment of the samples with PMEU equipment enhances and speeds up the detection of bacteria Application of Colilert TM broth in rapid coliform and E.coli detection in PMEU Real-time monitoring of the bacterial growth via Internet Recovery of environmental stress-suffering hygiene indicators and heterotrophs PMEU Spectrion POLARIS server Internet Updating every 10 min
PMEU technology in POLARIS project PMEU Tent PMEU Tent w/net connection Photos: Kevin King
PMEU acting in water works tests of Polaris project. Nutrient broth: Colilert TM. Reference analyses with traditional methods were performed in the Kuopio laboratory of THL / Dep. Of Water and Health. Every partner of this project has been able to follow the real-time results (growth curves) from PMEU via Internet. Next step of Polaris project includes testings of ASCS (Automated Sample Collection System) by SAMPLION Ltd. in water works environment and in tap water distribution network. Photo: Kevin King.
PMEU technology in POLARIS project Identification of E.coli (1 st from left) with UV in Colilert TM medium Next: results from current field trials of Polaris project.
25.5.2010 Sample from a groud water well. Total volume of 100 ml divided into two syringes. An example of clean water: no growth in 24 h
25.5.2010 Sample from a groud water well B. Total volume of 100 ml divided into two syringes. Growth was detected in one syringe in less than 20 h. Density of indicator bacterium in the beginning of the analysis was appr. 1 cell/100 ml.
25.5.2010 Sample from a groud water well C. Total volume of 100 ml divided into two syringes. Atypical growth, beginning after 14-16 hours from the start of the analysis.
Syringe 9 1.6.2010 Syringe 10 Microbial growth in replicate samples of lake water after 10 h from the beginning of the analysis.
Validation of Escherichia coli analysis with PMEU SPECTRION SALO, S. & WIRTANEN, G. (2010). VTT. PL 1000 02044 VTT Syringes No. 5 contained 10 5 E.coli cells/ml in the beginning of the test. Final density of E.coli in these syringes was 10 8 cells/ml. The values of E.coli densities in syringes No.1 were 2-4 cells/ml and 10 6 cells/ml, respectively. Incubation temperature: +37 o C.
Campylobacter coli ANALYSES WITH PMEU METHOD (Laboratory of FINNOFLAG Ltd., 2005) Campylobacter analyses with PMEU in 2005 (Campylobacter coli) The uppermost curve shows the result of an enrichment cultivation where bacterial density was even 100 000 000 000 cells/ml (10 11 ) at the end of the analysis Increased speed of the analysis with PMEU method is also visible The validation of PMEU Campylobacter method, performed in cooperation with THL (prev. KTL), was based on these preceding tests Results of this scientific research have been reported in 2009 (Canadian Journal of Microbiology)
pesäkemäärä (cfu/ml) Campylobacter coli CULTIVATIONS WITH PMEU METHOD (Laboratory of FINNOFLAG Ltd., 2005) 1E+11 C. coli rikastuskoe 16.12.2005 1E+10 1E+09 1E+08 1E+07 1E+06 100000 10000 1000 100 10 1 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 rikastusaika (h) aerobi, liemiputki a aerobi, liemiputki b mikroaerofiili, liemiputki a mikroaerofiili, liemiputki b aerobi, kuplitettu a aerobi, kuplitettu b mikroaerofiili, kuplitettu a mikroaerofiili, kuplitettu b mikroaerof, kuplitettu, CCDB
Relative Change Relative Change Enrichment and detection of Salmonella sp., inoculated in a tap water sample, with portable PMEU Scentrion R unit (manuscript in press; Hakalehto et al. 2010). These cultures have started from one cfu/ml (colony forming unit) of salmonella in the tap water sample. The analytical response in less than 9 hours can be seen as the drop of the detector charge, caused by the gaseous metabolites of the culture. 1.2 1 1.2 0.8 1 0.6 MOS 2 MOS 3 0.8 0.4 0.6 MOS 2 MOS 3 0.2 0.4 0 0 1 2 3 4 5 6 9 10 11 12 13 14 15 16 24 25 TIME [h] 0.2 0 0 1 2 3 4 5 6 9 10 11 12 13 14 15 16 24 25 TIME [h]
Gaseous emissions, produced by the metabolism of water indicator bacteria in PMEU Scentrion cultures - Identification of bacterial contaminants
Environmental spread of paper industry waste waters can be followed with bacteriological mapping Upper row: 48 h cultivation without preenrichment Lower row: pre-enrichment in PMEU (6 h) + 24 h cultivation on DryCult TM medium (Orion Diagnostica)
CHALLENGES OF MEASUREMENT TECHNIQUES IN WATER MICROBIOLOGY DEVELOPMENT OF SAMPLING PROCEDURE FOR BOTH CONTINUOUS MONITORING (ASCS) AND CONVENTIONAL CONTROL COMBINED DETECTION OF INDICATOR BACTERIA, PATHOGENIC MICROORGANISMS AND TOTAL LOAD OF HETEROTHROPHIC BACTERIA DEVELOPMENT OF REMOTE CONTROL OF WATER QUALITY AND EARLY-WARNING SYSTEM IDENTIFICATION OF NEW THREADS (INCL. STRAINS WITH ANTIBIOTIC RESISTANCES) INVESTIGATIONS OF THE LOAD ORIGIN ( SOURCE-TRACKING ) DETECTION OF MICROBES SUFFERING FROM ENVIRONMENTAL STRESS AND/OR TO BE PRESENTED IN SMALL QUANTITIES CONTINUOUS DEVELOPMENT OF METHODS IS A NECESSITY A SINGLE CELL, VIRUS OR VIRUS PARTICLE IS A POTENTIAL HAZARD!
Literature Hakalehto, E. 2010. Hygiene monitoring with the Portable Microbe Enrichment Unit (PMEU). 41st R 3 Nordic Symposium. Cleanroom technology, contamination control and cleaning. Espoo Finland. May 2010. VTT Publications 266. Hakalehto, E., Pesola, J., Heitto, L., Närvänen, A. and Heitto, A. 2007. Aerobic and anaerobic growth modes and expression of type 1 fimbriae in Salmonella, Pathophysiology 14(1): 61-69. Hakalehto, E., Pesola, J., Heitto, A., Bhanj Deo, B., Rissanen, K., Sankilampi, U., Humppi, T.and Paakkanen, H. 2009. Fast detection of bacterial growth by using portable microbe enrichment unit (PMEU) and ChemPro100i gas sensor, Pathophysiology 16 (1): 57-62. Hakalehto, E., Heitto, A., Heitto, L., Humppi, T., Rissanen, K., Jääskeläinen, A., Paakkanen, H.and Hänninen, O. 2010. Monitoring of water distribution system with portable PMEU enrichment unit- Measurement of volatile compounds of coliformic indicator bacteria and Salmonella sp. Manuscript in preparation. Heitto, L., Heitto, A. & Hakalehto, E. 2009. Tracing waste waters with faecal enterococci. Poster presentation in European Large Lakes Symposium, Norrtälje 2009. Pitkänen, T., Bräcker, J., Miettinen, I.T., Heitto, A., Pesola, J. and Hakalehto, E. 2009. Enhanced enrichment and detection of thermotolerant Campylobacter species from water using the Portable Microbe Enrichment Unit (PMEU) and realtime PCR. Canadian Journal of Microbiology: 55 (7): 849-858. Wirtanen, G. and Salo, S. 2010. PMEU-laitteen validointi koliformeilla. (Report VTT-S-01705-10) VTT Expert Services Oy, Espoo, Finland