A high gas fraction, reduced power, syngas bioprocessing method demonstrated with a <i>Clostridium ljungdahlii</i> OTA1 paper biocomposite

Schulte, Mark J.; Wiltgen, Jeff; Ritter, John J.; Mooney, Charles; Flickinger, Michael C.

doi:10.1002/bit.25966

Cited by 24 publications

(11 citation statements)

References 53 publications

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“…Very few studies have been reported so far on the application of trickle-bed reactors for syngas fermentation on a laboratory-scale (e.g. Bredwell et al, 1999;Yasin et al, 2015;Devarapalli et al, 2016;Schulte et al, 2016;Shen et al, 2017). High CO conversion rates of up to 91% were observed with Clostridium ragsdalei in a trickle-bed reactor with non-porous glass beads of 6 mm as carriers (Devarapalli et al, 2016).…”

Section: Bioprocess Developmentsmentioning

confidence: 99%

Using gas mixtures of CO, CO₂ and H₂ as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Takors

Kopf

Mampel

et al. 2018

Microbial Biotechnology

133

107

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SummaryThe reduction of CO 2 emissions is a global effort which is not only supported by the society and politicians but also by the industry. Chemical producers worldwide follow the strategic goal to reduce CO 2 emissions by replacing existing fossil‐based production routes with sustainable alternatives. The smart use of CO and CO 2/H2 mixtures even allows to produce important chemical building blocks consuming the said gases as substrates in carboxydotrophic fermentations with acetogenic bacteria. However, existing industrial infrastructure and market demands impose constraints on microbes, bioprocesses and products that require careful consideration to ensure technical and economic success. The mini review provides scientific and industrial facets finally to enable the successful implementation of gas fermentation technologies in the industrial scale.

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Section: Bioprocess Developmentsmentioning

confidence: 99%

Using gas mixtures of CO, CO₂ and H₂ as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Takors

Kopf

Mampel

et al. 2018

Microbial Biotechnology

133

107

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“…Some common biocoating deposition techniques include extrusion [34,90,91], spray drying [92], the wire wound rod drawdown Mayer rod coating method [13,67,93], 3-D ink-jet deposition [94] and the convective assembly [12,47,95]. Recently, dielectrophoresis (DEP) has also been used to generate photoreactive cyanobacteria cell monolayers on top of polyelectrolyte adhesives [96].…”

Section: Preparation Of Biocoatingsmentioning

confidence: 99%

“…PCC7002 (cyanobacterial aerobic phototroph). Investigation of C. ljungdahlii biocoated papers, coated without adhesive latex, has recently be extended by Schulte et al [91], who optimized surface area, with mass-transfer power input reduced by 3 orders of magnitude compared to traditional bioreactors and reduced liquid volume. His approach intensified the rate of CO uptake by over 17 fold.…”

Section: Example Of Environmental Applications Of Biocoatings Intensimentioning

confidence: 99%

Biocoatings: A new challenge for environmental biotechnology

Cortez

Nicolau

Flickinger

et al. 2017

Biochemical Engineering Journal

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Adhesive biocatalytic coatings (biocoatings) have a nanoporous microstructure generated by partially coalesced waterborne polymer particles that entrap highly concentrated living cells in a dry state stabilized by carbohydrate osmo-protectants. Biocoatings can be deposited by high speed coating technologies, aerosol delivery or ink-jet printed in multilayered, patterned coatings on flexible nonporous or nonwoven substrates, preserving 10 10-10 12 non-growing viable microorganisms per m 2 in 2-50 m thick layers. Cells are rehydrated to restore their metabolism. The layers reactive half-life following rehydration can be 1000 s of hours. The planar structure of biocoatings enable uniform illumination of a high concentration of photo-reactive microorganisms or algae and contact these microbe with thin liquid films for efficient mass transfer. This review highlights recent advances in biocoating technology for pollutants degradation, photo-reactive coatings, stabilization of hyperthermophiles for biocatalysis, environmental biosensors, and biocomposite fuel cells. Engineering cells for desiccation tolerance, unveiling the metabolism of nongrowing cells, and engineering the interaction between the cell surface and adhesive polymer binders are fundamental challenges to open the door to vast future applications of biocoatings for environmental sensing and remediation.

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“…Stabilization of anaerobic bacteria that are capable of assimilating single carbon gases, such as C . ljungdahlii , and other clostridia, could prove to be highly beneficial in developing bioprocess-oriented large scale gas treatment technologies [ 5 – 7 ].…”

Section: Introductionmentioning

confidence: 99%

“…In this study, a thin-film coating based approach of embedding the microbial samples in paper based biocomposite was undertaken [ 5 , 20 ], and a simple convective drying mechanism using inert argon gas purge technique was used for dry-processing the samples. The technique employed here is significantly different and simpler from the conventional drying modalities commonly used in the bioprocessing industry such as lyophilization and spray drying.…”

Section: Introductionmentioning

confidence: 99%

A technique for lyopreservation of Clostridium ljungdahlii in a biocomposite matrix for CO absorption

Schulte¹,

Solocinski²,

Wang³

et al. 2017

PLoS ONE

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A system capable of biocatalytic conversion of distributed sources of single carbon gases such as carbon monoxide into hydrocarbons can be highly beneficial for developing commercially viable biotechnology applications in alternative energy. Several anaerobic bacterial strains can be used for such conversion. The anaerobic carbon monoxide-fixing bacteria Clostridium ljungdahlii OTA1 is a model CO assimilating microorganism that currently requires cryogenic temperature for storage of the viable strains. If these organisms can be stabilized and concentrated in thin films in advanced porous materials, it will enable development of high gas fraction, biocomposite absorbers with elevated carbon monoxide (CO) mass transfer rate, that require minimal power input and liquid, and demonstrate elevated substrate consumption rate compared to conventional suspended cell bioreactors. We report development of a technique for dry-stabilization of C. ljungdahlii OTA1 on a paper biocomposite. Bacterial samples coated onto paper were desiccated in the presence of trehalose using convective drying and stored at 4°C. Optimal dryness was ~1g H2O per gram of dry weight (gDW). CO uptake directly following biocomposite rehydration steadily increases over time indicating immediate cellular metabolic recovery. A high-resolution Raman microspectroscopic hyperspectral imaging technique was employed to spatially quantify the residual moisture content. We have demonstrated for the first time that convectively dried and stored C. ljungdahlii strains were stabilized in a desiccated state for over 38 days without a loss in CO absorbing reactivity. The Raman hyperspectral imaging technique described here is a non-invasive characterization tool to support development of dry-stabilization techniques for microorganisms on inexpensive porous support materials. The present study successfully extends and implements the principles of dry-stabilization for preservation of strictly anaerobic bacteria as an alternative to lyophilization or spray drying that could enable centralized biocomposite biocatalyst fabrication and decentralized bioprocessing of CO to liquid fuels or chemicals.

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A high gas fraction, reduced power, syngas bioprocessing method demonstrated with a Clostridium ljungdahlii OTA1 paper biocomposite

Cited by 24 publications

References 53 publications

Using gas mixtures of CO, CO₂ and H₂ as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Using gas mixtures of CO, CO₂ and H₂ as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Biocoatings: A new challenge for environmental biotechnology

A technique for lyopreservation of Clostridium ljungdahlii in a biocomposite matrix for CO absorption

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A high gas fraction, reduced power, syngas bioprocessing method demonstrated with a Clostridium ljungdahlii OTA1 paper biocomposite

Cited by 24 publications

References 53 publications

Using gas mixtures of CO, CO2 and H2 as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Using gas mixtures of CO, CO2 and H2 as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Biocoatings: A new challenge for environmental biotechnology

A technique for lyopreservation of Clostridium ljungdahlii in a biocomposite matrix for CO absorption

Contact Info

Product

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Using gas mixtures of CO, CO₂ and H₂ as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale

Using gas mixtures of CO, CO₂ and H₂ as microbial substrates: the do's and don'ts of successful technology transfer from laboratory to production scale