Image processing for identification and quantification of filamentous bacteria in in situ acquired images

Philipe A. Dias, Thiemo Dunkel, Diego A.S. Fajado, Erika de León Gallegos, Martin Denecke, Philipp Wiedemann, Fabio K. Schneider, Hajo Suhr

Research output: Contribution to journalArticlepeer-review

24 Scopus citations

Abstract

Background: In the activated sludge process, problems of filamentous bulking and foaming can occur due to overgrowth of certain filamentous bacteria. Nowadays, these microorganisms are typically monitored by means of light microscopy, commonly combined with staining techniques. As drawbacks, these methods are susceptible to human errors, subjectivity and limited by the use of discontinuous microscopy. The in situ microscope appears as a suitable tool for continuous monitoring of filamentous bacteria, providing real-time examination, automated analysis and eliminating sampling, preparation and transport of samples. In this context, a proper image processing algorithm is proposed for automated recognition and measurement of filamentous objects. Methods: This work introduces a method for real-time evaluation of images without any staining, phase-contrast or dilution techniques, differently from studies present in the literature. Moreover, we introduce an algorithm which estimates the total extended filament length based on geodesic distance calculation. For a period of twelve months, samples from an industrial activated sludge plant were weekly collected and imaged without any prior conditioning, replicating real environment conditions. Results: Trends of filament growth rate-the most important parameter for decision making-are correctly identified. For reference images whose filaments were marked by specialists, the algorithm correctly recognized 72 % of the filaments pixels, with a false positive rate of at most 14 %. An average execution time of 0.7 s per image was achieved. Conclusions: Experiments have shown that the designed algorithm provided a suitable quantification of filaments when compared with human perception and standard methods. The algorithm's average execution time proved its suitability for being optimally mapped into a computational architecture to provide real-time monitoring.

Original languageEnglish
Article number64
JournalBioMedical Engineering Online
Volume15
Issue number1
DOIs
StatePublished - Jun 11 2016
Externally publishedYes

Funding

The present project is result of a collaboration between the Departments of Information Technology and Biotechnology (Mannheim University of Applied Sciences), the Institute for Urban Water and Waste Management (University of Duisburg-Essen) and two industrial plants (Currenta GmbH & Co. OHG and INEOS Köln GmbH), which we acknowledge for funding. Moreover, the image processing algorithm here described was developed at both Mannheim University of Applied Sciences and the Federal University of Technology of Paraná. We acknowledge CAPES for the financial support in Brazil.

FundersFunder number
Coordenação de Aperfeiçoamento de Pessoal de Nível Superior

    Keywords

    • Digital image processing
    • Filamentous bacteria recognition
    • Filamentous bulking and foaming
    • Filamentous microorganism
    • In situ microscopy
    • Wastewater treatment

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