The continuum heterogeneous biofilm model with multiple limiting substrate Monod kinetics

ABSTRACT We describe a novel procedure to estimate the net growth rate of biofilms on multiple substrates. The approach is based on diffusion‐reaction mass balances for chemical species in a continuum biofilm model with reaction kinetics corresponding to a Double‐Monod expression. This analytical mo...

Full description

Saved in:
Bibliographic Details
Published in:Biotechnology and bioengineering 2014-11, Vol.111 (11), p.2252-2264
Main Authors: Gonzo, Elio Emilio, Wuertz, Stefan, Rajal, Veronica B.
Format: Article
Language:English
Subjects:
Ammonium Compounds - metabolism
Bacteria, Aerobic - drug effects
Bacteria, Aerobic - metabolism
Bacteria, Aerobic - physiology
biofilm model
Biofilms
Biofilms - drug effects
Biofilms - growth & development
Comparative analysis
Constraining
continuum heterogeneous biofilm
Continuums
Diffusivity
effectiveness factor
Estimates
Mathematical analysis
Mathematical models
Monod kinetics
multiple-substrate limitation
Oxidation-Reduction
Oxygen
Oxygen - metabolism
Reaction kinetics
Substrates
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:ABSTRACT We describe a novel procedure to estimate the net growth rate of biofilms on multiple substrates. The approach is based on diffusion‐reaction mass balances for chemical species in a continuum biofilm model with reaction kinetics corresponding to a Double‐Monod expression. This analytical model considers a heterogeneous biofilm with variable distributions of biofilm density, activity, and effective diffusivity as a function of depth. We present the procedure to estimate the effectiveness factor analytically and compare the outcome with values obtained by the application of a rigorous numerical computational method using several theoretical examples and a test case. A comparison of the profiles of the effectiveness factor as a function of the Thiele modulus, φ, revealed that the activity of a homogeneous biofilm could be as much as 42% higher than that of a heterogeneous biofilm, under the given conditions. The maximum relative error between numerical and estimated effectiveness factor was 2.03% at φ near 0.7 (corresponding to a normalized Thiele modulus φ* = 1). For φ  1.4, the relative error was less than 0.5%. A biofilm containing aerobic ammonium oxidizers was chosen as a test case to illustrate the model's capability. We assumed a continuum heterogeneous biofilm model where the effective diffusivities of oxygen and ammonium change with biofilm position. Calculations were performed for two scenarios; Case I had low dissolved oxygen (DO) concentrations and Case II had high DO concentrations, with a concentration at the biofilm–fluid interface of 10 g O2/m3. For Case II, ammonium was the limiting substrate for a biofilm surface concentration, CNs, ≤13.84 g of N/m3. At these concentrations ammonium was limiting inside the biofilm, and oxygen was fully penetrating. Conversely, for CNs > 13.84 g of N/m3, oxygen became the limiting substrate inside the biofilm and ammonium was fully penetrating. Finally, a generalized procedure to estimate the effectiveness factor for a system with multiple (n > 2) limiting substrates is given. Biotechnol. Bioeng. 2014;111: 2252–2264. © 2014 Wiley Periodicals, Inc. Observed (net) rate of biomass growth as a function of ammonium substrate concentration at two different oxygen concentrations. At low oxygen concentration the net growth rate reaches a plateau when oxygen is consumed completely. At high oxygen concentration the growth rate increases continuously with ammonia concentration. However, when the con
ISSN:0006-3592
1097-0290
DOI:10.1002/bit.25284