Abstract
To obtain a mathematical model that adequately describes the time lag between biomass generation and lactic acid production of lactic fermentations. Seven experimental kinetics from other research works were studied to validate our proposal: four studies of Fungal Submerged Fermentation and three cases of Bacterial Submerged Fermentation, including the data recollected by Luedeking and Piret. We introduce a modification to the Luedeking and Piret model that consist in the introduction of a time delay parameter in the model, this parameter would account for the lag time that exists between the production of biomass and lactic acid. It is possible to determine this time delay in a simple way by approximating the biomass and product formation considering that they behave as a first order plus dead time system. The duration of this phenomenon, which is not described with the classical Luedeking and Piret model, is a function of microorganism physiology (ease of biomass growth), environment (nutrients) and type of inoculum. The Luedeking and Piret with delay model applications reveal an increase of the R2 in all cases, evidencing the quality of fit and the simplicity of the method proposed. These model would improve the accuracy of bioprocess scaling up.
Highlights
The concept of bioeconomy has emerged several years ago as an eco-friendly alternative to stop using petrochemicals as precursors in chemical synthesis, and having the goal to use and revalue biomass, including lignocellulosic waste from agroindustry, as a solid substrate for obtaining a wide range of biosubstances
We propose the use of an alternative mathematical model to fit de kinetic growth of different fermentative process
We took an example of Fungal Submerged Fermentation (FSF) of corn waste stream using R
Summary
The concept of bioeconomy has emerged several years ago as an eco-friendly alternative to stop using petrochemicals as precursors in chemical synthesis, and having the goal to use and revalue biomass, including lignocellulosic waste from agroindustry, as a solid substrate for obtaining a wide range of biosubstances. The objectives of bioeconomy are: sustainable development and circular economy (Bugge et al 2016). One type of bioproduct that has been intensively studied in recent years is the lactic acid (LA). Lactic acid is a natural occurring organic acid, it has applications in pharmaceutical, cosmetic, chemical and food industry (Gündüz 2005). Lactic acid has received attention for its use as a monomer in the production of polylactic acid, a completely biodegradable polymer Lactic Acid had a world demand in 2016 of 1,220 kilo-ton
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