Optimal operation of high-pressure homogenization for intracellular product recovery

An optimal control methodology for the homogenization of bacterial cells to recover intracellular products is presented. A Fluent computational fluid dynamics (CFD) model is used to quantify the hydrodynamic forces present in the homogenizer, and empirical models are used to relate these forces to experimentally obtained cell disruption and product recovery data. The optimal homogenizer operation, in terms of either constant cell breakage or maximum intracellular product recovery, is determined using these empirical models. We illustrate this methodology with an Escherichia coli bacterial system used to produce DNA plasmids. Homogenization is performed using an industrial APV–Gaulin high-pressure homogenizer. The modeling and optimization results for this E. coli–DNA plasmid system show good agreement with the experimental data.     

High-performance countercurrent chromatography for lutein production from a chlorophyll-deficient strain of the microalgae Parachlorella kessleri HY1

Green microalgae are a recognized lutein source; however, processing for lutein production requires additional operations such as extraction and saponification, mainly due to the high green pigment and lipid content in the biomass. In this study lutein was isolated from a chlorophyll-deficient Parachlorella kessleri HY1 strain using high-performance countercurrent chromatography (HPCCC). The lower phase of the biphasic solvent system composed of n-heptane–ethanol–water, 5:4:1.5, v/v/v was used both as biomass extraction solvent and HPCCC mobile phase conferring a high selectivity to the lutein production process. For the HPCCC isolation, a multiple injection method was developed, and ten consecutive sample injections (300 mg per each) were performed. To favor the economics of the process, the HPCCC mobile and stationary phases were separately formulated based on nuclear magnetic resonance (NMR) analyses. This strategy enabled to avoid obtaining immiscible liquid phases from their parent biphasic solvent system, which led to the reduction of the separation process duration and solvent consumption. Overall, 3 g of P. kessleri HY1 strain extract was processed by HPCCC yielding 150 mg of lutein (95% purity, 97% recovery). The results presented here form an efficient and economical basis for the large-scale production of microalgae-sourced lutein.

     

Abiotic synthesis of purines and other heterocyclic compounds by the action of electrical discharges

Summary The synthesis of purines and pyrimidines using Oparin-Urey-type primitive Earth atmospheres has been demonstrated by reacting methane, ethane, and ammonia in electrical discharges. Adenine, guanine, 4-aminoimidazole-5-carboxamide (AICA), and isocytosine have been identified by UV spectrometry and paper chromatography as the products of the reaction. The total yields of the identified heterocyclic compounds are 0.0023%. It is concluded that adenine synthesis occurs at a much lower concentration of hydrogen cyanide than has been shown by earlier studies. Pathways for the synthesis of purines from hydrogen cyanide are discussed, and a comparison of the heterocyclic compounds that have been identified in meteorites and in prebiotic reactions is presented.     

Health applications of bioactive compounds from marine microalgae

Marine microalgae and cyanobacteria are very rich in several chemical compounds and, therefore, they may be used in several biological applications related with health benefits, among others. This review brings the research up-to-date on the bioactive compounds produced by marine unicellular algae, directly or indirectly related to human health. It covers and goes through the most studied applications of substances such as PUFA, sterols, proteins and enzymes, vitamins and pigments, in areas so diverse as human and animal nutrition, therapeutics, and aquaculture. The great potential of marine microalgae and the biocoumpounds they produce are discussed in this review.     

Bioactive compounds from cyanobacteria and microalgae: an overview

Cyanobacteria (blue-green algae) are photosynthetic prokaryotes used as food by humans. They have also been recognized as an excellent source of vitamins and proteins and as such are found in health food stores throughout the world. They are also reported to be a source of fine chemicals, renewable fuel and bioactive compounds. This potential is being realized as data from research in the areas of the physiology and chemistry of these organisms are gathered and the knowledge of cyanobacterial genetics and genetic engineering increased. Their role as antiviral, anti-tumour, antibacterial, anti-HIV and a food additive have been well established. The production of cyanobacteria in artificial and natural environments has been fully exploited. In this review the use of cyanobacteria and microalgae, production processes and biosynthesis of pigments, colorants and certain bioactive compounds are discussed in detail. The genetic manipulation of cyanobacteria and microalgae to improve their quality are also described at length.     

Kinetic exploration of nitrate-accumulating microalgae for nutrient recovery

Within sustainable resource management, the recovery of nitrogen and phosphorus nutrients from waste streams is becoming increasingly important. Although the use of microalgae has been described extensively in environmental biotechnology, the potential of nitrate-accumulating microalgae for nutrient recovery has not been investigated yet. The ability of these marine microorganisms to concentrate environmental nitrate within their biomass is remarkable. The aim of this study was to investigate the application potential of nitrate-accumulating diatoms for nutrient recovery from marine wastewaters. The intracellular nitrate storage capacity was quantified for six marine diatom strains in synthetic wastewater. Amphora coffeaeformis and Phaeodactylum tricornutum stored the highest amount of nitrate with respectively 3.15 and 2.10 g N L^?1 of cell volume, which accounted for 17.3 and 4.6 %, respectively, of the total nitrogen content. The growth and nitrate and phosphate uptake of both diatoms were further analyzed and based on these features P. tricornutum showed the highest potential for nutrient recovery. A mathematical model was developed which included intracellular nitrate storage and the kinetic parameters were derived for P. tricornutum. Furthermore, a simulation study was performed to compare the performance of a proposed microalgal nutrient recovery unit with a conventional denitrification system for marine wastewater treatment. Overall, this study demonstrates the potential application of P. tricornutum for saline wastewater treatment with concurrent nitrogen and phosphorus recycling.     

Effect of static magnetic fields on the growth,photosynthesis and ultrastructure of Chlorella kessleri microalgae

Microalgal biotechnology could generate substantial amounts of biofuels with minimal environmental impact if the economics can be improved by increasing the rate of biomass production. Chlorella kessleri was grown in a small‐scale raceway pond and in flask cultures with the entire volume, 1% (v/v) at any instant, periodically exposed to static magnetic fields to demonstrate increased biomass production and investigate physiological changes, respectively. The growth rate in flasks was maximal at a field strength of 10 mT, increasing from 0.39 ± 0.06 per day for the control to 0.88 ± 0.06 per day. In the raceway pond the 10 mT field increased the growth rate from 0.24 ± 0.03 to 0.45 ± 0.05 per day, final biomass from 0.88 ± 0.11 to 1.56 ± 0.18 g/L per day, and maximum biomass production from 0.11 ± 0.02 to 0.38 ± 0.04 g/L per day. Increased pigment, protein, Ca, and Zn content made the biomass produced with magnetic stimulation nutritionally superior. An increase in oxidative stress was measured indirectly as a decrease in antioxidant capacity from 26 ± 2 to 17 ± 1 µmol antioxidant/g biomass. Net photosynthetic capacity (NPC) and respiratory rate were increased by factors of 2.1 and 3.1, respectively. Loss of NPC enhancement after the removal of magnetic field fit a first‐order model well (R² = 0.99) with a half‐life of 3.3 days. Transmission electron microscopy showed enlarged chloroplasts and decreased thylakoid order with 10 mT treatment. By increasing daily biomass production about fourfold, 10 mT magnetic field exposure could make algal oil cost competitive with other biodiesel feedstocks. Bioelectromagnetics 33:298–308, 2012. © 2011 Wiley Periodicals, Inc.     

Enhanced disruption of Candida utilis using enzymatic pretreatment and high-pressure homogenization

The enhancement of the overall disruption of a native strain of Candida utilis (ATCC 9226) was studied using a combination of two methods, namely, pretreatment in the form of partial enzymatic lysis by Zymolyase followed by mechanical disruption in a Microfluidizer high-pressure homogenizer. The cells were grown in both batch and continuous cultures to examine the effect of specific growth rate on disruption. Cell suspensions ranging in concentration from 7 to 120 g DW/L were disrupted with and without enzymatic pretreatment. For yeast grown in batch culture, final total disruption obtained using the combined protocol approached 95% with four passes at a pressure of 95 MPa, as compared with only 65% disruption using only mechanical homogenization. A modified model was developed to predict the fraction disrupted by the enzymatic pretreatment-mechanical homogenization two-stage process. Predicted disruptions agreed favorably with experimental observations (maximum deviation of 20%) over a wide range of operating conditions. (c) 1994 John Wiley & Sons, Inc.     

Determination of intracellular conductivity from electrical breakdown measurements

The intracellular resistivity (conductivity) of cells can be easily calculated with high accuracy from electrical membrane breakdown measurements. The method is based on the determination of the size distribution of a cell suspension as a function of the electrical field strength in the orifice of a particle volume analyser (Coulter counter). The underestimation of the size distribution observed beyond the critical external field strength leading to membrane breakdown represents a direct access to the intracellular resistivity as shown by the theoretical analysis of the data. The potential and the accuracy of the method is demonstrated for red blood cells and for ghost cells prepared by electrical haemolysis. The average value of 180 Ω - cm for the intracellular resistivity of intact red blood cells is consistent with the literature.     

Determination of intracellular conductivity from electrical breakdown measurements

The intracellular resistivity (conductivity) of cells can be easily calculated with high accuracy from electrical membrane breakdown measurements. The method is based on the determination of the size distribution of a cell suspension as a function of the electrical field strength in the orifice of a particle volume analyser (Coulter counter). The underestimation of the size distribution observed beyond the critical external field strength leading to membrane breakdown represents a direct access to the intracellular resistivity as shown by the theoretical analysis of the data. The potential and the accuracy of the method is demonstrated for red blood cells and for ghost cells prepared by electrical haemolysis. The average value of 180 omega X cm for the intracellular resistivity of intact red blood cells is consistent with the literature.     

Energy recovery from lipid extracted,transesterified and glycerol codigested microalgae biomass

The production of methane (CH₄) via the anaerobic digestion of microalgae biomass residues from the biodiesel production process has the potential to meet some of the energy requirements of the primary biomass to fuel conversion process. This paper investigates the practical CH₄ yields achievable from the anaerobic conversion of the microalgae residues (as well as codigestion with glycerol) after biodiesel production using both the conventional and in situ transesterification methods. Results demonstrate that the type of lipid extraction solvent utilized in the conventional transesterification process could inhibit subsequent CH₄ production. On the basis of actual CH₄ production, a recoverable energy of 8.7–10.5 MJ kg^?1 of dry microalgae biomass residue was obtained using the lipid extracted and transesterified microalgae samples. On codigesting the microalgae residues with glycerol, a 4–7% increase in CH₄ production was observed.     

Increased disruption resistance of Candida utilis grown from survivors of enzymatic lysis combined with high-pressure homogenization

The resistance of Candida utilis (ATCC 9226) to disruption as a result of enzymatic pretreatment combined with high-pressure homogenization was found to increase when the yeast was grown from an inoculum which had previously been subjected to enzymatic pretreatment combined with high-pressure homogenization. The inoculum thus consisted of a mixture of undisrupted, viable cells and non-viable cells. The enzyme preparation employed was Zymolyase, which depolymerizes various components of the cell walls of viable yeast. A Microfluidizer was used for the high-pressure homogenization step. In order to obtain the 'disruption-resistant' cell fraction for use as an inoculum, 'normal' C. utilis was enzymatically pretreated, and subsequently homogenized (herein referred to as Microfluidization) using either three or 10 passes through the Microfluidizer at an operating pressure of 95 MPa. Yeast grown from the survivors of the enzyme/3-pass treatment were found to be somewhat more resistant to disruption by either enzymatic pretreatment alone or to enzymatic pretreatment followed by Microfluidization. Cells grown from enzyme/ 10-pass treated inocula exhibited the highest resistance to disruption. The 'disruption-resistant' fraction exhibited this characteristic through three serial re-cultivations. Possible mechanisms for the increased 'disruption-resistance' of this isolated population of C. utilis are presented.     

Enzymatic hydrolysis combined with mechanical shearing and high-pressure homogenization for nanoscale cellulose fibrils and strong gels

Toward exploiting the attractive mechanical properties of cellulose I nanoelements, a novel route is demonstrated, which combines enzymatic hydrolysis and mechanical shearing. Previously, an aggressive acid hydrolysis and sonication of cellulose I containing fibers was shown to lead to a network of weakly hydrogen-bonded rodlike cellulose elements typically with a low aspect ratio. On the other hand, high mechanical shearing resulted in longer and entangled nanoscale cellulose elements leading to stronger networks and gels. Nevertheless, a widespread use of the latter concept has been hindered because of lack of feasible methods of preparation, suggesting a combination of mild hydrolysis and shearing to disintegrate cellulose I containing fibers into high aspect ratio cellulose I nanoscale elements. In this work, mild enzymatic hydrolysis has been introduced and combined with mechanical shearing and a high-pressure homogenization, leading to a controlled fibrillation down to nanoscale and a network of long and highly entangled cellulose I elements. The resulting strong aqueous gels exhibit more than 5 orders of magnitude tunable storage modulus G' upon changing the concentration. Cryotransmission electron microscopy, atomic force microscopy, and cross-polarization/magic-angle spinning (CP/MAS) 13C NMR suggest that the cellulose I structural elements obtained are dominated by two fractions, one with lateral dimension of 5-6 nm and one with lateral dimensions of about 10-20 nm. The thicker diameter regions may act as the junction zones for the networks. The resulting material will herein be referred to as MFC (microfibrillated cellulose). Dynamical rheology showed that the aqueous suspensions behaved as gels in the whole investigated concentration range 0.125-5.9% w/w, G' ranging from 1.5 Pa to 105 Pa. The maximum G' was high, about 2 orders of magnitude larger than typically observed for the corresponding nonentangled low aspect ratio cellulose I gels, and G' scales with concentration with the power of approximately three. The described preparation method of MFC allows control over the final properties that opens novel applications in materials science, for example, as reinforcement in composites and as templates for surface modification.     

Simultaneous recovery of extracellular and intracellular DNA suitable for molecular studies from marine sediments

The occurrence of high extracellular DNA concentrations in aquatic sediments (concentrations that are 3 to 4 orders of magnitude greater than those in the water column) might play an important role in biogeochemical cycling, as well as in horizontal gene transfer through natural transformation. Since isolation of extracellular DNA from sediments is a difficult and unsolved task, in this study we developed an efficient procedure to recover simultaneously DNA associated with microbial cells and extracellular DNA from the same sediment sample. This procedure is specifically suitable for studying extracellular DNA because it avoids any contamination with DNA released by cell lysis during handling and extraction. Applying this procedure to different sediment types, we obtained extracellular DNA concentrations that were about 10 to 70 times higher than the intracellular DNA concentrations. Using specific targeted prokaryotic primers, we obtained evidence that extracellular DNA recovered from different sediments did not contain amplifiable 16S rRNA genes. By contrast, using DNA extracted from microbial cells as the template, we always amplified 16S rRNA genes. Although 16S rRNA genes were not detected in extracellular DNA, analyses of the sizes of extracellular DNA indicated the presence of high-molecular-weight fragments that might have contained other gene sequences. This protocol allows investigation of extracellular DNA and its possible participation in natural transformation processes.     

A process for high yield and scaleable recovery of high purity eicosapentaenoic acid esters from microalgae and fish oil

A low expense process is developed for recovering esterified eicosapentaenoic acid (EPA) from microalgae and fish oil. Over 70% of the EPA content in the esterified crude extract of microalgae were recovered at purities exceeding 90%. The recovery scheme utilizes either wet or freeze-dried algal biomass. The process consists of only three main steps: 1) simultaneous extraction and transesterification of the algal biomass; 2) argentated silica gel column chromatography of the crude extract; and 3) removal of pigments by a second column chromatographic step. Argentated silica gel chromatography recovered about 70% of the EPA ester present in the crude fatty ester mixture of fish oil, but at a reduced purity ( approximately 83% pure) compared to the microalgal derived EPA. The optimal loading of the fatty ester mixture on the chromatographic support was about 3% (w/w) but loadings up to 4% did not affect the resolution significantly. The process was scaled up by a factor of nearly 320 by increasing the diameter of the chromatography columns. The elution velocity remained constant. Compared to the green alga Monodus subterraneus, the diatom Phaeodactylum tricornutum had important advantages as a potential commercial producer of EPA. For a microalgal EPA process to be competitive with fish oil derived EPA, P. tricornutum biomass (2.5% w/w EPA) needs to be obtained at less than $4/kg. If the EPA content in the alga are increased to 3.5%, the biomass may command a somewhat higher price. The quality of microalgal EPA compares favorably with that of the fish oil product. Compared to free fatty acid, EPA ester is more stable in storage. Shelf-life is extended by storing in hexane. The silver contamination in the final purified EPA was negligibly small (<210 ppb).     

Efficient mechanical disruption of Lactobacillus helveticus,Lactococcus lactis and Propionibacterium freudenreichii by a new high-pressure homogenizer and recovery of intracellular aminotransferase activity

Microbiological studies often involve bacterial cell fractionation, which is known to be difficult for Gram-positive as compared to Gram-negative bacteria. Our purpose was to test the breaking efficiency of a new high-pressure pilot homogenizer for three Gram-positive species involved in dairy technology and to assess the activity of an intracellular aminotransferase. Varied pressures (50, 100 and 200 MPa) were applied to concentrated bacterial suspensions (1.2 mg dry weight/ml) of Lactobacillus helveticus, Lactococcus lactis and Propionibacterium freudenreichii. Breaking efficiency was estimated by decreases in optical density at 650 nm, cellular dry weight and viability. The proteins released were quantified and the residual intracellular aminotransferase activity was estimated using leucine as substrate. One run at 50 MPa was sufficient to break 80% of lactobacilli cells whereas 200 MPa were required for the same efficiency for L. lactis and P. freudenreichii. Whatever the pressure, leucine aminotransferase activity was recovered in the supernatant after cell breaking. This new high-pressure pilot homogenizer can allow rapid (20 s/run), easy, continuous and highly efficient cell breaking for intracellular enzyme recovery or other purposes. As the species tested were not phylogenetically related, and had different morphologies and cell wall compositions, we conclude that most Gram-positive bacteria may be broken efficiently by this new device. Electronic Publication     

Biosorption of tributyltin and other organotin compounds by cyanobacteria and microalgae

Biosorption of triorganotin compounds by the cyanobacteria Synechocystis PCC 6803 and Plectonema boryanum and the microalga Chlorella emersonii, incubated in 2-(N-morpholino)ethanesulphonic acid (MES) buffer, pH 5.5, in the presence of 0.5 mm organotin (supplied as chlorides), increased with molecular mass of the organotins, the order being triphenyltin > tributylin (Bu₃SnCl) > tripropyltin >- trimethyltin >- triethylin. In the butylin series, monobutyltin biosorption was lowest, although levels of dibutyltin uptake were greater than for Bu₃SnCl. Cyanobacterial Bu₃SnCl biosorption was complete in 5 min with no subsequent accumulation. In contrast, a second phase of uptake in C. emersonii resulted in an approximate 2.4-fold increase in cellular Bu₃SnCl between 5 min and 2 h. The external pH had a marked influence on biosorption of Bu₃SnCl by Synechocystis PCC 6803 and P. boryanum, with maximal uptake at pH 5.5 and 6.5, respectively. Effects of pH were less evident in C. emersonii. In all the organisms examined, no inhibition of Bu₃SnCl biosorption was observed between 0.05 and 50 mm NaCl. However, an increase in the external NaCl concentration from 50 to 500 mm resulted in an approximate 55–65% reduction in Bu₃SnCl uptake. Biosorption increased at increasing Bu₃SnCl concentrations (0.25–3.0 mm). Saturation of Bu₃SnCl biosorption at the higher concentrations was most evident in the cyanobacteria, although uptake levels were greater in these organisms at <- 2 mm Bu₃SnCl. Theoretical maximum biosorption levels at complete cell saturation, derived from reciprocal Langmuir plots, were approximately 565, 525 and 1050 nmol Bu₃SnCl mg^–1 dry weight, for Synechocystis PCC 6803, P. boryanum and C. emersonii, respectively. Correspondence to: G. M. Gadd