Enzymatic cell wall degradation of Chlorella vulgaris and other microalgae for biofuels production

Gerken, Henri; Donohoe, Bryon S.; Knoshaug, Eric P.

doi:10.1007/s00425-012-1765-0

Cited by 372 publications

(231 citation statements)

References 48 publications

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“…Although lignin is not a component of algal cells, similar cross-linked macromolecular structures exist in the cell walls offering protection to the cell contents or simply making the cell wall carbon non-digestible [47,48]. Mussgnug et al [42] noted that Scenedesmus obliquus and Chlorella kessleri have hemicellulose-containing carbohydrate-based walls which make them tougher to digest, S. obliquus especially so as it contains a sporopollenin-like biopolymer.…”

Section: Discussionmentioning

confidence: 99%

“…A wide range of microalgal cell wall compositions and structures have been reported in the literature, some of which reflect intrinsic differences between species [47,49]. In a detailed study of the susceptibility of C. vulgaris and other micro-algae to enzymatic degradation Gerken et al [48] also noted, however, that major changes in cell wall composition might depend on very small differences in growth conditions, as well as on factors such as the culture age. To draw firm conclusions on the optimum strategies to enhance anaerobic degradation, further fundamental work is required looking both at the composition and molecular structure of micro-algal cells, and at factors affecting this.…”

Section: Discussionmentioning

confidence: 99%

“…Harvesting and storage methods may themselves act as pre-treatments [48,51], with both freezing and centrifugation potentially capable of rupturing cells and thus leading to increased methane yields or improved production kinetics. T. pseudonana has a solid silica cell wall consisting of two frustules, which can open during centrifugation: this may have contributed to the high values for BMP and for TMP conversion on a VS basis compared to those for the micro-algae with organic cell walls in the current study.…”

Section: Discussionmentioning

confidence: 99%

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Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion

2016

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. Comparative testing of energy yields from microalgal biomass cultures processed via anaerobic digestion. Renewable Energy, 87,[744][745][746][747][748][749][750][751][752][753] http://www.sciencedirect.com/science/article/pii/S0960148115304286 doi:10.1016/j.renene.2015.11.009 __________________________________________________________________________________ Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion Keiron P. Roberts, Sonia Heaven, Charles J. Banks Faculty of Engineering and the Environment, University of Southampton, Southampton, SO17 1BJ, UK (Email K.P. Roberts@soton.ac.uk, S.Heaven@soton.ac.uk, C.J.Banks@soton.ac.uk) Abstract Although digestion of micro-algal biomass was first suggested in the 1950s, there is still only limited information available for assessment of its potential. The research examined six laboratory-grown marine and freshwater micro-algae and two samples from large-scale cultivation systems. Biomass composition was characterised to allow prediction of potentially available energy using the Buswell equation, with calorific values as a benchmark for energy recovery. Biochemical methane potential tests were analysed using a pseudo-parallel first order model to estimate kinetic coefficients and proportions of readily-biodegradable carbon. Chemical composition was used to assess potential interferences from nitrogen and sulphur components. Volatile solids (VS) conversion to methane showed a broad range, from 0.161-0.435 L CH 4 g -1 VS; while conversion of calorific value ranged from 26.4-79.2%. Methane productivity of laboratory-grown species was estimated from growth rate, measured by changes in optical density in batch culture, and biomass yield based on an assumed harvested solids content. Volumetric productivity was 0.04-0.08 L CH 4 L -1 culture day -1 , the highest from the marine species Thalassiosira pseudonana. Estimated methane productivity of the large-scale raceway was lower at 0.01 L CH 4 L -1 day -1 . The approach used offers a means of screening for methane productivity per unit of cultivation under standard conditions.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion

2016

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“…The layer has a high cellulose content (Rodrigues and da Silva Bon, 2011), and chitin-like glycan is a predominant amino sugar in the rigid cell wall. The rigid wall components embedded within a more plastic polymeric matrix are composed of uronic acids, rhamnose, arabinose, fucose, xylose, mannose, galactose, glucose, and pectin (Gerken et al, 2013). In addition, the outer cell wall of different species may include a trilaminar algaenan or form a thin homogeneous monolayer.…”

Section: Cell Wall Types In Various Groups Of Microalgae and Cyanobacmentioning

confidence: 99%

Cell disruption technologies

Dhondt

Martín-Juárez

Bolado

et al. 2017

Microalgae-Based Biofuels and Bioproducts

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IntroductionAlgal cell walls separate the inside cell content from the environment to protect the cell against desiccation, pathogens, and predators while still allowing exchange of compounds. Toward application of algae biomass as a sustainable resource, disruption of this cell wall (¼cell disruption) is an essential pretreatment step to maximize product recovery in downstream processes of the algae biorefinery. Also for direct use of algae in feed or food, cell rupture is required to increase the bioavailability of algae constituents. Depending on the cell wall structure, the size, and the shape of algae, cell disruption can be challenging. A variety of cell disruption methods is currently available, and new approaches are being elaborated in parallel. Since downstream processing is responsible for a large part of the operational costs in the whole production chain, cell disruption technologies should be low cost and energy efficient and result preferably in high product quality. This chapter provides information on cell wall types and gives an overview of physical-mechanical and (bio-)chemical cell disruption technologies with attention to development stage, energy efficiency, product quality, costs, emerging approaches, and applicability on large scale. Cell wall types in various groups of microalgae and cyanobacteriaThe cell wall composition and architecture of algae and cyanobacteria are highly variable ranging from tiny membranes to multilayered complex structures. Despite the importance of algal cell wall properties in biotechnology, little structural information is available for most species (Scholz et al., 2014). Based on the complexity of surface structures, four cell types could be distinguished (Barsanti and Gualtieri, 2006;Lee, 2008) (Fig. 6.1). A simple cell membrane (Fig. 6.1, Type 1) is present in short-lived stages (e.g., gametes), chrysophytes, raphidophytes, green algae Dunaliella, and haptophytes Isochrysis. It consists of a lipid bilayer with integrated and peripheral proteins. Sometimes a cap of glycolipids and glycoproteins envelops the outer surface of cell membrane. Cell membranes with additional extracellular material are known in cyanobacteria and many groups of algae, including palmelloid phases. It is the most diverse cell wall type that includes various membrane-associated structures (cell wall, Microalgae-Based Biofuels and Bioproducts. http://dx

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“…However, the cell wall's resistance adversely affects the efficiency of algal bioprocesses such as genetic transformation, fermentation, anaerobic digestion, oil extraction and biodiesel production. Indeed, it leads to significant solvent requirements and energy load during the extraction processes [5]. For instance, direct FAME production requires a significant methanol to oil molar ratio, which can be as high as 1570:1 [6].…”

Section: Introductionmentioning

confidence: 99%

Effect of Soaking Pre-Treatment on Reactive Extraction/<i>in situ</i> Transesterification of <i>Nannochloropsis occulata</i> for Biodiesel Production

Salam¹,

Velásquez-Orta²,

Harvey³

2017

JSBS

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Microalgal phospholipid bilayer contributes to the molar excesses of methanol and high acid concentration required in reactive extraction to achieve high fatty acid methyl ester (FAME) yield. This study reports an investigation into the effects of pre-soaking Nannochloropsis occulata in methanol at 600:1 and 1000:1 methanol to oil molar ratios prior to acid-catalyzed in situ transesterification at 8.5:1 and 15:1 H 2 SO 4 to oil molar ratios on the FAME yield. The results showed that the pre-soaked Nannochloropsis occulata produced a higher FAME yield at the two tested methanol to oil molar ratios and acid concentrations than the un-soaked, resulting in a reduction in methanol volume and acid concentration. A maximum FAME yield of 98.4% ± 1.3% was obtained for the pre-soaked Nannochloropsis occulata at 1000:1 methanol to oil molar ratio and 15:1 H 2 SO 4 to oil molar ratio. Both the phosphorus mass balance and conversion of the isolated phospholipids into FAME revealed that pre-soaking solubilizes the phospholipid bilayer to some degree, and contributes to an increased FAME yield.

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Enzymatic cell wall degradation of Chlorella vulgaris and other microalgae for biofuels production

Cited by 372 publications

References 48 publications

Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion

Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion

Cell disruption technologies

Effect of Soaking Pre-Treatment on Reactive Extraction/<i>in situ</i> Transesterification of <i>Nannochloropsis occulata</i> for Biodiesel Production

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Enzymatic cell wall degradation of Chlorella vulgaris and other microalgae for biofuels production

Cited by 372 publications

References 48 publications

Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion

Comparative testing of energy yields from micro-algal biomass cultures processed via anaerobic digestion

Cell disruption technologies

Effect of Soaking Pre-Treatment on Reactive Extraction/&lt;i&gt;in situ&lt;/i&gt; Transesterification of &lt;i&gt;Nannochloropsis occulata&lt;/i&gt; for Biodiesel Production

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Effect of Soaking Pre-Treatment on Reactive Extraction/<i>in situ</i> Transesterification of <i>Nannochloropsis occulata</i> for Biodiesel Production