Production Rate‐Dependent Key Performance Indicators for a Systematic Design of Biochemical Downstream Processes

Brandt, Katrin; Schembecker, Gerhard

doi:10.1002/ceat.201500428

Cited by 12 publications

(14 citation statements)

References 32 publications

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“…The downstream processing costs to recover products from these dilute streams have been analyzed in the literature, especially for biofuels from microalgae (Davis et al, 2011;Rizwan et al, 2013), and most studies indicate that more than 70% of the overall production costs are incurred during separations (Brandt and Schembecker, 2016;Kiss et al, 2015;Shaeiwitz et al, 2000;Sikdar et al, 1989).…”

Section: Eff (1)mentioning

confidence: 99%

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A roadmap for the synthesis of separation networks for the recovery of bio-based chemicals: Matching biological and process feasibility

Yenkie

Clark

et al. 2016

Biotechnology Advances

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Microbial conversion of renewable feedstocks to high-value chemicals is an attractive alternative to current petrochemical processes because it offers the potential to reduce net CO emissions and integrate with bioremediation objectives. Microbes have been genetically engineered to produce a growing number of high-value chemicals in sufficient titer, rate, and yield from renewable feedstocks. However, high-yield bioconversion is only one aspect of an economically viable process. Separation of biologically synthesized chemicals from process streams is a major challenge that can contribute to >70% of the total production costs. Thus, process feasibility is dependent upon the efficient selection of separation technologies. This selection is dependent on upstream processing or biological parameters, such as microbial species, product titer and yield, and localization. Our goal is to present a roadmap for selection of appropriate technologies and generation of separation schemes for efficient recovery of bio-based chemicals by utilizing information from upstream processing, separation science and commercial requirements. To achieve this, we use a separation system comprising of three stages: (I) cell and product isolation, (II) product concentration, and (III) product purification and refinement. In each stage, we review the technology alternatives available for different tasks in terms of separation principles, important operating conditions, performance parameters, advantages and disadvantages. We generate separation schemes based on product localization and its solubility in water, the two most distinguishing properties. Subsequently, we present ideas for simplification of these schemes based on additional properties, such as physical state, density, volatility, and intended use. This simplification selectively narrows down the technology options and can be used for systematic process synthesis and optimal recovery of bio-based chemicals.

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Section: Eff (1)mentioning

confidence: 99%

“…One of the major goals in the design of a large scale commercial process is the minimization of processing cost while maintaining product specifications. In the production of biochemicals, downstream separation is the major cost driver (Brandt and Schembecker, 2016;Kiss et al, 2015;Shaeiwitz et al, 2000).…”

Section: Separation Schemesmentioning

confidence: 99%

A roadmap for the synthesis of separation networks for the recovery of bio-based chemicals: Matching biological and process feasibility

Yenkie

Clark

et al. 2016

Biotechnology Advances

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“…A bioreactor effluent is often dilute (less than 20 wt% product) [17] and the purity requirement for chemicals is relatively high. Therefore, downstream separation tends to be expensive, accounting for 60-80% of the total production cost in many cases [10,18,19]. Thus, the synthesis of an effective downstream bio-separation process is a critical but at the same time challenging task because multiple technologies are usually available for a given separation task, and thus a large number of alternative process networks exists.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and analysis of separation processes for extracellular chemicals generated from microbial conversions

Yenkie

Maravelias

2019

BMC Chem Eng

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Recent advances in metabolic engineering have enabled the production of chemicals via bio-conversion using microbes. However, downstream separation accounts for 60-80% of the total production cost in many cases. Previous work on microbial production of extracellular chemicals has been mainly restricted to microbiology, biochemistry, metabolomics, or techno-economic analysis for specific product examples such as succinic acid, xanthan gum, lycopene, etc. In these studies, microbial production and separation technologies were selected apriori without considering any competing alternatives. However, technology selection in downstream separation and purification processes can have a major impact on the overall costs, product recovery, and purity. To this end, we apply a superstructure optimization based framework that enables the identification of critical technologies and their associated parameters in the synthesis and analysis of separation processes for extracellular chemicals generated from microbial conversions. We divide extracellular chemicals into three categories based on their physical properties, such as water solubility, physical state, relative density, volatility, etc. We analyze three major extracellular product categories (insoluble light, insoluble heavy and soluble) in detail and provide suggestions for additional product categories through extension of our analysis framework. The proposed analysis and results provide significant insights for technology selection and enable streamlined decision making when faced with any microbial product that is released extracellularly. The parameter variability analysis for the product as well as the associated technologies and comparison with novel alternatives is a key feature which forms the basis for designing better bioseparation strategies that have potential for commercial scalability and can compete with traditional chemical production methods.

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“…Renewable and environmentally friendly production of biochemicals and fuels via conversion of readily available plant biomass and waste streams is of major importance for society, economy, and environment in the 21st century [1,2]. Microbial fermentation of waste gas streams and synthesis gas (syngas; comprised mainly of CO and H 2 ), which represent a significant quantity of reduced carbon and can be produced relatively cheaply from a wide variety of biomass sources, is an emerging conversion route with wide feedstock versatility [3,4].…”

Section: Introductionmentioning

confidence: 99%

“…1 shows a simplified schematic diagram of a bubble-column reactor for microbial syngas fermentation. The gas stream containing CO, H 2 , and possibly other components such as CO 2 is introduced into the bottom of the column and exits the top of the column. The liquid stream containing media components such as vitamins, minerals, nitrogen, and phosphorus required for cellular growth also is introduced into the bottom of the column.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Matrix Control of a Bubble‐Column Reactor for Microbial Synthesis Gas Fermentation

Liang

Henson³

et al. 2017

Chem Eng & Technol

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A spatiotemporal metabolic model of a representative syngas bubble-column reactor was applied to design and evaluate dynamic matrix control (DMC) schemes for regulation of the desired by-product ethanol and the undesired by-product acetate. This model was used to develop linear step response models for controller design and also served as the process in closed-loop simulations. A 2 2 DMC scheme with manipulation of the liquid and gas feed flows to the column provided a superior performance to proportional integral (PI) control due to slow process dynamics combining the multivariable and constrained nature of the control problem. Ethanol concentration control for large disturbances was further improved by adding the flow of a pure hydrogen stream as a third manipulated variable. The advantages of DMC for syngas bubble-column reactor control are demonstrated and a design strategy for future industrial applications is provided.

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Production Rate‐Dependent Key Performance Indicators for a Systematic Design of Biochemical Downstream Processes

Cited by 12 publications

References 32 publications

A roadmap for the synthesis of separation networks for the recovery of bio-based chemicals: Matching biological and process feasibility

A roadmap for the synthesis of separation networks for the recovery of bio-based chemicals: Matching biological and process feasibility

Synthesis and analysis of separation processes for extracellular chemicals generated from microbial conversions

Dynamic Matrix Control of a Bubble‐Column Reactor for Microbial Synthesis Gas Fermentation

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