Durchflusszytometrie – Funktionsprinzip und Anwendungsbeispiele

Anbieter zum Thema

NETZSCH-Gerätebau GmbH

Elementar Analysensysteme GmbH

Ohaus Europe GmbH

IWW Rheinisch-Westfälisches Institut für Wasserforschung Gemeinützige GmbH

Literatur

Ashbolt NJ. 2015. Environmental (Saprozoic) Pathogens of Engineered Water Systems: Understanding Their Ecology for Risk Assessment and Management. Pathogens 4:390-405.

Hammes F, Berney M, Vital M, Egli T. 2007a. A protocol for the determination of total cell concentration of natural microbial communities in drinking water with FCM. Techneau report, Deliverable 3.3.7. Techneau, Niederlanden. https://www.techneau.org/fileadmin/files/Publications/Publications/Deliverables/D3.3.7.pdf.

Hammes F, Egli T. 2007b. A flow cytometric method for AOC determination. Techneau report, Deliverable 3.3.1. Techneau, Niederlanden. http://www.techneau.org/fileadmin/files/Publications/Publications/Deliverables/D3.3.1.pdf.

Hammes F, Vital M, Berney M. 2008a. Cultivation-independent assessment of viability with flow cytometry. Techneau report, Deliverable 3.3.8. Techneau, Niederlanden. https://www.techneau.org/fileadmin/files/Publications/Publications/Deliverables/D3.3.8.pdf.

Hammes F, Berney M, Wang Y, Vital M, Köster O, Egli T. 2008b. Flow-cytometric total bacterial cell counts as a descriptive microbiological parameter for drinking water treatment processes. Water Research 42:269–277

Gatza E, Hammes F, Prest E. (2013). Assessing water quality with the BD Accuri™ C6 flow cytometer. White paper. BD Biosciences.

Besmer MD, Weissbrodt DG, Kratochvil BE, Sigrist JA, Weyland MS, Hammes F. 2014. The feasibility of automated online flow cytometry for in-situ monitoring of microbial dynamics in aquatic ecosystems. Frontier in Microbiol. 5:265.

Egli T, Hammes F. 2010. Neue Methoden zur Beurteilung der mikrobiologischen Wasserqualität. Gas – Wasser – Abwasser (gwa) 90: 315–324.

Egli T, Kötzsch S. 2013. Schnelle Beurteilung der Trinkwasserqualität. Wasserwirtschaft Wassertechnik 6: 8-12. Verfügbar unter http://www.wwt-online.de/sites/default/files/fachartikel/wwt0613-08-12.pdf.

Gillespie S, Lipphaus P, Green J, Parsons S, Weir P, Juskowiak K, Jefferson B, Jarvis P, Nocker A. 2014. Assessing microbiological water quality in drinking water distribution systems with disinfectant residual using flow cytometry. Water Res. 65:224-34.

Harry IS, Ameh E, Coulon F, Nocker A. 2016. Impact of Treated Sewage Effluent on the Microbiology of a Small Brook Using Flow Cytometry as a Diagnostic Tool. Water Air Soil Pollut. 227:57.

Helmi K, Watt A, Jacob P, Ben-Hadj-Salah I, Henry A, Méheut G, Charni-Ben-Tabassi N. 2014. Monitoring of three drinking water treatment plants using flow cytometry. Water Science & Technology: Water Supply 14 (5):850-856.

Oliver JD. 2010. Recent findings on the viable but nonculturable state in pathogenic bacteria. FEMS Microbiology Reviews. Volume 34, Issue 4, pages 415–425

Lipphaus P, Hammes F, Kötzsch S, Green J, Gillespie S, Nocker A. 2014. Microbiological tap water profile of a medium-sized building and effect of water stagnation. Environ Technol. 35(5-8):620-628.

Ramamurthy T, Ghosh A, Pazhani GP, Shinoda S. 2014. Current Perspectives on Viable but Non-Culturable (VBNC) Pathogenic Bacteria. Front Public Health. 2:103.

Szewzyk U, Szewzyk R, Manz W, Schleifer KH. 2000 Microbiological safety

of drinking water. Annu. Rev. Microbiol. 54: 81–127.

Ultee A., N. Souvatzi, K. Maniadi and H. König. 2004. Identification of the culturable and nonculturable bacterial population in ground water of a municipal water supply in Germany. Journal of Applied Microbiology 96, 560–568

Zhang S, Ye C, Lin H, Lv L, Yu X. 2015. UV disinfection induces a VBNC state in Escherichia coli and Pseudomonas aeruginosa. Environ Sci Technol. 49(3):1721-8.

* Dr. A. Nocker: IWW Zentrum Wasser, 45476 Mülheim an der Ruhr

(ID:44143560)