Maximizing batch fermentation efficiency by constrained model‐based optimization and predictive control of adenosine triphosphate turnover

Abstract: We present a constrained model‐based optimization and predictive control framework to maximize the production efficiency of batch fermentations based on the core idea of manipulating adenosine triphosphate (ATP) wasting. In many bioprocesses, enforced ATP wasting —rerouting ATP use towards an energetically possibly suboptimal path— allows increasing the metabolic flux towards the product, thereby enhancing product yields and specific productivities. However, this often comes at the expense of lower biomass yie… Show more

“…We are also working on extending the scope of the presented metabolic cybergenetic framework to include synthetic microbial communities (cf. e.g., Espinel‐Ríos et al, 2023, n.d).…”

“…As foreseeable, the higher the induction capacity strength of the CcaS/CcaR system, the higher the net ATPase enzyme expression, and therefore the higher the net increase in product yield. In previous works dealing with dynamic ATP turnover in one‐stage batch fermentations, the increase in product yield was correlated with a loss in volumetric productivity (Espinel‐Ríos, Bettenbrock, et al, 2022; Espinel‐Ríos, Morabito, Bettenbrock, et al, 2022b). Here, we show that with a fed‐batch system, it is possible to increase both the product yield via the ATP turnover mechanism and the volumetric productivity via the introduction of a feeding rate.…”

“…e.g., Boecker et al, 2021; Hädicke et al, 2015; Zahoor et al, 2020). Dynamic manipulation of the ATPase expression, and thereby the ATPase flux, can thus be exploited to modulate the product yield and volumetric productivity in bioprocesses (Espinel‐Ríos, Bettenbrock, et al, 2022; Espinel‐Ríos, Morabito, Bettenbrock, et al 2022).…”

“…The dynamics of the lactate fermentation are based on an existing deFBA model (Espinel‐Ríos, Bettenbrock, et al, 2022). See Figure 3 for a summary of the resource allocation model.…”

“… Note : (1) Assumed biologically sound values inferred from feasible deFBA simulations (Espinel‐Ríos, Bettenbrock, et al, 2022) for different induction strength scenarios ($$\,{{\rm{S}}}_{i}$$). (2) Estimated as $${d}_{\text{ATPase}}=\frac{\mathrm{ln}(2)}{{t}_{0.5}}$$, where $${t}_{0.5}$$ is the ATPase protein half‐life time (Benito et al, 1991).…”

Toward a modeling, optimization, and predictive control framework for fed‐batch metabolic cybergenetics

“…We are also working on extending the scope of the presented metabolic cybergenetic framework to include synthetic microbial communities (cf. e.g., Espinel‐Ríos et al, 2023, n.d).…”

“…As foreseeable, the higher the induction capacity strength of the CcaS/CcaR system, the higher the net ATPase enzyme expression, and therefore the higher the net increase in product yield. In previous works dealing with dynamic ATP turnover in one‐stage batch fermentations, the increase in product yield was correlated with a loss in volumetric productivity (Espinel‐Ríos, Bettenbrock, et al, 2022; Espinel‐Ríos, Morabito, Bettenbrock, et al, 2022b). Here, we show that with a fed‐batch system, it is possible to increase both the product yield via the ATP turnover mechanism and the volumetric productivity via the introduction of a feeding rate.…”

“…e.g., Boecker et al, 2021; Hädicke et al, 2015; Zahoor et al, 2020). Dynamic manipulation of the ATPase expression, and thereby the ATPase flux, can thus be exploited to modulate the product yield and volumetric productivity in bioprocesses (Espinel‐Ríos, Bettenbrock, et al, 2022; Espinel‐Ríos, Morabito, Bettenbrock, et al 2022).…”

“…The dynamics of the lactate fermentation are based on an existing deFBA model (Espinel‐Ríos, Bettenbrock, et al, 2022). See Figure 3 for a summary of the resource allocation model.…”

“… Note : (1) Assumed biologically sound values inferred from feasible deFBA simulations (Espinel‐Ríos, Bettenbrock, et al, 2022) for different induction strength scenarios ($$\,{{\rm{S}}}_{i}$$). (2) Estimated as $${d}_{\text{ATPase}}=\frac{\mathrm{ln}(2)}{{t}_{0.5}}$$, where $${t}_{0.5}$$ is the ATPase protein half‐life time (Benito et al, 1991).…”

Toward a modeling, optimization, and predictive control framework for fed‐batch metabolic cybergenetics

Optimal control and dynamic modulation of the ATPase gene expression for enforced ATP wasting in batch fermentations

Soft sensor for monitoring dynamic changes in cell composition