A phenomenological model of planktonic microbial cultures, reported in previous papers, sug-gests that the whole growth progress seems planned by the microbial population since a pre-growth latency phase, during which the population level remains at its starting level. This model is in line with recent suggestions about the behavior of complex systems, as long as it al-lows for the gathering of the growth trends of a number of real batch cultures in a single master plot of reduced variables, in spite of their metabolic and physiological differences. One important issue of the model concerns the origin of the time scale for the microbes that can differ from that for the observer. The present paper reports some consequences of the model in view of its po-tential use in predictive microbiology and proposes an extension to the steady and decay phases of the culture evolution suggesting that, consistent with the assumptions about the growth phase, the decay occurs by a scan of the cell generation steps. This view leads to the conclusion that the steady phase between growth and decay trends actually corresponds to the loss of the oldest cell generations, which represents minor fractions of the microbial population. Such early decay is almost undetectable in a log scale, looking like a steady phase. To account for cases that show a broad maximum instead of an intermediate steady trend, a single continuous function, still re-lated to the model, can describe the whole growth and decay trend of the microbial culture.
The Growth Curve of Microbial Cultures: A Model for a Visionary Reappraisal / A. Schiraldi. - In: APPLIED MICROBIOLOGY. - ISSN 2673-8007. - 3:(2023 Mar), pp. 288-296. [10.3390/applmicrobiol3010020]
The Growth Curve of Microbial Cultures: A Model for a Visionary Reappraisal
A. Schiraldi
Primo
Writing – Review & Editing
2023
Abstract
A phenomenological model of planktonic microbial cultures, reported in previous papers, sug-gests that the whole growth progress seems planned by the microbial population since a pre-growth latency phase, during which the population level remains at its starting level. This model is in line with recent suggestions about the behavior of complex systems, as long as it al-lows for the gathering of the growth trends of a number of real batch cultures in a single master plot of reduced variables, in spite of their metabolic and physiological differences. One important issue of the model concerns the origin of the time scale for the microbes that can differ from that for the observer. The present paper reports some consequences of the model in view of its po-tential use in predictive microbiology and proposes an extension to the steady and decay phases of the culture evolution suggesting that, consistent with the assumptions about the growth phase, the decay occurs by a scan of the cell generation steps. This view leads to the conclusion that the steady phase between growth and decay trends actually corresponds to the loss of the oldest cell generations, which represents minor fractions of the microbial population. Such early decay is almost undetectable in a log scale, looking like a steady phase. To account for cases that show a broad maximum instead of an intermediate steady trend, a single continuous function, still re-lated to the model, can describe the whole growth and decay trend of the microbial culture.File | Dimensione | Formato | |
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