Assessment of <Emphasis Type="Italic">Nannochloropsis gaditana</Emphasis> growth and lipid accumulation with increased inorganic carbon delivery

Algal biomass refineries for sustainable transportation fuels, in particular biodiesel, will benefit from algal strain enhancements to improve biomass and lipid productivity. Specifically, the supply of inorganic carbon to microalgal cultures represents an area of great interest due to the potential for improved growth of microalgae and the possibility for incorporation with CO₂ mitigation processes. Combinations of bicarbonate (HCO₃^?) salt addition and application of CO₂ to control pH have shown compelling increases in growth rate and lipid productivity of fresh water algae. Here, focus was placed on the marine organism, Nannochloropsis gaditana, to investigate growth and lipid accumulation under various strategies of enhanced inorganic carbon supply. Three gas application strategies were investigated: continuous sparging of atmospheric air, continuous sparging of 5% CO₂ during light hours until nitrogen depletion, and continuous sparging of atmospheric air supplemented with 5% CO₂ for pH control between 8.0 and 8.3. These gas sparging schemes were combined with addition of low concentrations (5 mM) of sodium bicarbonate at inoculation and high concentration (50 mM) of sodium bicarbonate amendments just prior to nitrogen depletion. The optimum scenario observed for growth of N. gaditana under these inorganic carbon conditions was controlling pH with 5% CO₂ on demand, which increased both growth rate and lipid accumulation. Fatty acid methyl esters were primarily comprised of C16:0 (palmitic) and C16:1 (palmitoleic) aliphatic chains. Additionally, the use of high concentration (50 mM) of bicarbonate amendments further improved lipid content (up to 48.6%) under nitrogen deplete conditions when paired with pH-controlled strategies.     

Carbon dioxide injection method for enhancing hydrogenotrophic denitrification of secondary wastewater effluent in fixed bed reactor

This study presents an optimal injection method for using carbon dioxide as a carbon source for the hydrogenotrophic denitrification of secondary wastewater effluent in a laboratory-scale fixed bed reactor (FBR). The FBR was operated under three conditions: a continuous CO₂ supply, periodic CO₂ supply, and without a CO₂ supply. The continuous operation of the FBR without carbon dioxide injection resulted in an increase in pH to 10 and a noticeable level of nitrite accumulation. The continuous co-injection of carbon dioxide and hydrogen gas decreased the pH to a range of 6 ～ 8, but the denitrification efficiency decreased to 29%. The co-injection of carbon dioxide decreased the maximum dissolved hydrogen concentration and hydrogen mass transfer rate by 25 and 61%, respectively. Compared to the continuous injection method, a periodic injection of carbon dioxide increased the denitrification efficiency from 28.6 to 85% as the hydrogen flow rate and hydraulic retention time (HRT) increased. With the periodic injection of carbon dioxide, the nitrite accumulation appeared to be insignificant as the hydrogen flow rate increased.     

沙丁胺醇、布地奈德不同雾化吸入联合头孢哌酮钠舒巴坦钠对AECOPD患者血气指标和肺功能的影响

目的:探讨沙丁胺醇、布地奈德不同雾化吸入联合头孢哌酮钠舒巴坦钠对慢性阻塞性肺疾病急性加重期(AECOPD)患者血气指标和肺功能的影响。方法:选取本院2015年1月至2018年10月期间收治的210例AECOPD住院患者作为研究对象,随机分为对照组(头孢哌酮钠舒巴坦钠治疗)、持续雾化组(沙丁胺醇、布地奈德持续雾化治疗+头孢哌酮钠舒巴坦钠)、先后雾化组(先给予沙丁胺醇雾化、后给予布地奈德雾化治疗+头孢哌酮钠舒巴坦钠),每组各70例,对比三组的临床疗效、血气指标、肺功能及不良反应。结果:先后雾化组总有效率为91.43%,高于持续雾化组的78.57%及对照组的67.14%(P0.05)。先后雾化组患者治疗5天后氧分压(PaO_2)、氧饱和度(SaO_2)高于持续雾化组及对照组,且持续雾化组高于对照组(P0.05);先后雾化组患者治疗5天后二氧化碳分压(PaCO_2)低于持续雾化组及对照组,且持续雾化组低于对照组(P0.05)。先后雾化组患者第一秒用力呼气容积(FEV_1)、用力肺活量(FVC)、第一秒用力呼吸容积占用力肺活量的百分比(FEV_1/FVC%)、第一秒用力呼气容积占预计值百分比(FEV_1%)高于持续雾化组及对照组,且持续雾化组高于对照组(P0.05)。三组不良反应总发生率比较无统计学差异(P0.05)。结论:沙丁胺醇、布地奈德先后雾化吸入联合头孢哌酮钠舒巴坦钠治疗AECOPD患者疗效确切,可提高患者肺功能,改善血气相关指标。     

An Apparatus to Produce Gas Mixtures with Controlled CO(2), O(2), and Water Vapor Concentrations

An apparatus to produce continuous gas mixtures for use in measurements of plant gas exchange is described. A wide range of CO₂ and water vapor concentrations can be provided and O₂ concentration can be varied from 0 to 21%. Changes in the concentrations of the components are accomplished conveniently, rapidly, and independently. With occasional adjustments, CO₂ and O₂ concentrations can be maintained to within ± 1 μl/l and ± 0.1%, respectively. Dew point of the gas mixture can be maintained to within ± 0.05 C.     

Control of growth and differentiation of bioreactor cultures of Physcomitrella by environmental parameters

The effect of physical and chemical environmental parameters on growth and differentiation of suspension cultures of the moss Physcomitrella patens in bioreactors was investigated. By supplementation of the aeration gas with 2% (v/v) CO₂ as well as by continuous illumination, growth of this photoautotrophic growing batch culture was markedly enhanced, resulting in a doubling time of 1.2d. The growth rate of semicontinuously growing bioreactor cultures was not affected by controlling the pH of the culture medium with set points at 4.5 or 7.0. However, growth of the culture at pH 7.0 resulted in increased caulonema development, thus showing a distinct effect on moss differentiation. The impact on research and plant biotechnological applications of the potential to control moss growth and differentiation by environmental parameters is discussed.     

The cultivation of animal cells at controlled dissolved oxygen partial pressure

A 3-liter culture vessel has been developed for the growth of animal cells in suspension at controlled pH and dissolved oxygen partial pressure (pO₂). The culture technique allows metabolically produced CO₂ to be measured; provision can be made to control the dissolved CO₂ partial pressure. In cultures containing a low serum concentration, gas sparging to control pO₂ was found to cause cell damage. This could be prevented by increasing the serum concentration to 10%, or by adding 0.02% of the surface-active polymer Pluronic F68. The growth of mouse LS cells in batch culture without pO₂ control was found to be limited by the availability of oxygen. Maximum viable cell populations were obtained when dissolved pO₂ was controlled at values within the range 40–100 mm Hg.     

Gas-phase methyl ethyl ketone biodegradation in a tubular biofilm reactor: microbiological and bioprocess aspects

A novel type of bioreactor was designed to clean VOCs-containing air.The operation of this reactor consists in mixing the polluted gas and a mistof nutrient solution in the presence of microorganisms in order to maximizecontact and transfer between gas, liquid and microorganisms and to promotethe degradation kinetics and the relative removal efficiency of thepollutant. A bacterial consortium acclimatized to MEK and containing apreponderance of Alcaligenes denitrificans was established under non-axenicconditions. On the tubular reactor's glass walls, a continuous biofilm wasdeveloped. This biofilm was rapidly contaminated by two fungi able todegrade MEK: Geotrichum candidum and Fusarium oxysporum. Their abundance inthe reactor is probably linked to the acidic conditions inside the biofilmand to their broader tolerance for low pH values concomitant with MEKdegradation. In the reactor, a maximum volumetric degradation rate of 3.5 kgMEK/m³ _reactor·d was obtained for arelative removal efficiency of 35%, whereas the latter was maintainedat 70% for more modest applied loadings of 1.5 kgMEK/m³ _reactor ·d. In liquid batchcultures, a biomass originating from the biofilm was able to degrade 0.40g_MEK/g_DCW·h at the optimal pH of 7. Aregular cycle of detachment-recolonization was observed during the operationof the bioreactor. The maximal degradation activity was obtained with a thinbiofilm and was not increased as the biofilm grew in thickness. The overalldegradation rate of the process did not appear to be limited by thediffusion of oxygen inside the biofilm. Over short periods of time, the MEKtransfer from the gaseous phase to the biofilm was neither affected by thepresence of the mist nor by the wetting of the biofilm. A better control ofthe biofilm pH led to improved performance in terms of removal rate but notin terms of relative elimination efficiency.     

Vertical thin-layer photoreactor for controlled cultivation of cyanobacteria

Nostoc sp. was cultivated in an air-lift reactor with continuous recirculation of the head gas phase that aerated and agitated the cyanobacterial suspension at regulated flow rates. The supply of inorganic carbon for growth was coupled with pH control, in the range of 7.7 to 8.1, by intermittent sparging of CO₂-head gas mixtures. The formation of irregular bubbles with swirling motion at the photostage of the reactor promoted efficient CO₂ transference in dense populations of Nostoc sp. (1.1 g/l) when bubbling at flow rates of 10 l/min. Biomass productivity was almost six-fold higher in the photoreactor (16.4 mg/l.h) than in a conventional system (2.8 mg/l.h). The exponential growth phase of cultures in the photoreactor amounted to 60% of the total growth period.The authors are with the Laboratorio de Alimentos, Area Microbiologia, Facultad de Quimica Bioquimica y Farmacia, Universidad Nacional de San Luis, Chacabuco y Pedernera, 5700 San Luis, Argentina     

Sulfide-controlled continuous culture of sulfate-reducing bacteria

In continuous culture set-up for sulfate-reducing bacteria a sulfide electrode (made from silver wire) is used to control the electron donor supply and the medium pump. The sulfied concentration of the medium is kept at a low level by continuosly flushing out H₂S and replacing it with CO₂. The pH is controlled automatically by regulating the CO₂ content of the gas mixture flushed through the medium. With the sulfide-controlled set-up sulfate-reducing bacteria can be grown in chemostat culture under electron donor as well as electron acceptor limitation. Furthermore, by continuously washing out the culture to a preselected residual sulfide concentration, cells can be grown in sulfidostat culture under non-limiting conditions at maximal growth rate. Growth yields of Desulfotmaculum orientis, when growth in this system with hydrogen as electron donor, were considerably higher than previously reported.     

Effect of Modified Atmospheres on the Growth and Extracellular Enzyme Activities of Psychrotrophs in Raw Milk

The conservation of food products within a controlled atmosphere is efficient in packaging. To extend the cold storage of raw milk, the effects of five gas atmospheres enriched with carbon dioxide and nitrogen were investigated. Treated and control milk were stored at 7 °C for 10 days and analyzed for microbial counts, pH, proteolysis and lipolysis. The addition of CO₂, N₂, or their mixture had a significant inhibitory effect on psychrotrophic growth. The generation times of these microorganisms were significantly longer in treated milk, particularly for yeasts where they amounted to 16.63 h. The maximum inhibition was observed when a gas mixture of 50 % CO₂ and 50 % N₂ was used. As a result, psychrotrophic growth was affected to 98 % whereas this inhibition did not exceed 78 % when CO₂ and 41 % N₂ were applied. Milk treatment under the conditions of 50 % CO₂ and 50 % N₂ gave significantly lower counts for all groups of psychrotrophs being more efficient against Enterobacteriaceae with 99.5 % of inhibition. Storage of raw milk under the tested atmospheres had a different effect on extracellular enzyme productions. Significant decreases in protease and lipase activities were observed during the storage at 7 °C. These enzyme activities were not detectable with pure CO₂ and a 50 % CO₂ and 50 % N₂ mixture. N₂ has shown to be the less efficient treatment against lipases (65 %) and proteases (95 %). With regard to growth, the course of the pH and the protease and lipase activities, the tested gas mixture of 50 % CO₂ and 50 % N₂ was more suitable for extending the shelf life of raw milk.     

Effective bioreactor pH control using only sparging gases

pH control is critical in bioreactor operations, typically realized through a two-sided control loop, where CO₂ sparging and base addition are used in bicarbonate-buffered media. Though a common approach, base addition could compromise culture performance due to the potential impact from pH excursions and osmolality increase in large-scale bioreactors. In this study, the feasibility of utilizing control of sparge gas composition as part of the pH control loop was assessed in Chinese hamster ovary (CHO) fed-batch cultures. Fine pH control was evaluated in multiple processes at different setpoints in small-scale ambr®250 bioreactors. Desired culture pH setpoints were successfully maintained via air sparge feedback control. As part of the pH control loop, air sparging was increased to improve CO₂ removal automatically, hence increase culture pH, and vice versa. The effectiveness of this pH control strategy was seamlessly transferred from ambr®250 to 200 L scale, demonstrating scalability of the proposed methodology. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2743, 2019     

Influence of aeration–homogenization system in stirred tank bioreactors,dissolved oxygen concentration and pH control mode on BHK-21 cell growth and metabolism

This work focused on determining the effect of dissolved oxygen concentration (DO) on growth and metabolism of BHK-21 cell line (host cell for recombinant proteins manufacturing and viral vaccines) cultured in two stirred tank bioreactors with different aeration-homogenization systems, as well as pH control mode. BHK-21 cell line adapted to single-cell suspension was cultured in Celligen without aeration cage (rotating gas-sparger) and Bioflo 110, at 10, 30 and 50 % air saturation (impeller for gas dispersion from sparger-ring). The pH was controlled at 7.2 as far as it was possible with gas mixtures. In other runs, at 30 and 50 % (DO) in Bioflo 110, the cells grew at pH controlled with CO₂ and NaHCO₃ solution. Glucose, lactate, glutamine, and ammonium were quantified by enzymatic methods. Cell concentration, size and specific oxygen consumption were also determined. When NaHCO₃ solution was not used, the optimal DOs were 10 and 50 % air saturation for Celligen and Bioflo 110, respectively. In this condition maximum cell concentrations were higher than 4 × 10⁶ cell/mL. An increase in maximum cell concentration of 36 % was observed in batch carried out at 30 % air saturation in a classical stirred tank bioreactor (Bioflo 110) with base solution addition. The optimal parameters defined in this work allow for bioprocess developing of viral vaccines, transient protein expression and viral vector for gene therapy based on BHK-21 cell line in two stirred tank bioreactors with different agitation–aeration systems.     

Simple adaptive pH control in bioreactors using gain-scheduling methods

A simple well-performing adaptive control technique for pH control in fermentations of recombinant protein production processes is described and its design procedure is explained. First, the entire control algorithm was simulated and parameterized. Afterwards it was tested in real cultivation processes. The results show that this simple technique leads to significant reductions in the fluctuations of the pH values in microbial cultures at a minimum of expenditures. The signal-to-noise ratio and thus the information captured by the pH signal were increased by about an order of magnitude. This leads to a substantial improvement in the noise of many other process signals that are used to monitor and control the process. For instance, respiratory off-gas data of CO₂ and its derived carbon dioxide production rate signals from the cultures carry much less noise as compared to those values obtained with conventional pH control. Detailed process analysis revealed that even very small pH jumps of 0.03 values during the fermentation were shown to result in pronounced deflections in CO₂-volume fraction of 8% (peak to peak). The proposed controller, maintaining the pH within the interval of 0.01 around the setpoint, reduces the noise considerably.     

Ocean Acidification Affects Hemocyte Physiology in the Tanner Crab (Chionoecetes bairdi)

We used flow cytometry to determine if there would be a difference in hematology, selected immune functions, and hemocyte pH (pH_i), under two different, future ocean acidification scenarios (pH = 7.50, 7.80) compared to current conditions (pH = 8.09) for Chionoecetes bairdi, Tanner crab. Hemocytes were analyzed after adult Tanner crabs were held for two years under continuous exposure to acidified ocean water. Total counts of hemocytes did not vary among control and experimental treatments; however, there were significantly greater number of dead, circulating hemocytes in crabs held at the lowest pH treatment. Phagocytosis of fluorescent microbeads by hemocytes was greatest at the lowest pH treatment. These results suggest that hemocytes were dying, likely by apoptosis, at a rate faster than upregulated phagocytosis was able to remove moribund cells from circulation at the lowest pH. Crab hemolymph pH (pH_e) averaged 8.09 and did not vary among pH treatments. There was no significant difference in internal pH (pH_i) within hyalinocytes among pH treatments and the mean pH_i (7.26) was lower than the mean pH_e. In contrast, there were significant differences among treatments in pH_i of the semi-granular+granular cells. Control crabs had the highest mean semi-granular+granular pH_i compared to the lowest pH treatment. As physiological hemocyte functions changed from ambient conditions, interactions with the number of eggs in the second clutch, percentage of viable eggs, and calcium concentration in the adult crab shell was observed. This suggested that the energetic costs of responding to ocean acidification and maintaining defense mechanisms in Tanner crab may divert energy from other physiological processes, such as reproduction.     

早期与晚期应用肺表面活性物质联合经鼻持续气道正压通气治疗新生儿呼吸窘迫综合征的比较研究

目的:比较早期与晚期应用肺表面活性物质(Ps)联合经鼻持续气道正压通气(NCPAP)治疗新生儿呼吸窘迫综合征(NRDS)的临床疗效。方法:选取海南省三亚市人民医院于2014年1月～2018年7月期间收治的NRDS患儿100例,根据随机数字表法将患儿分为对照组(n=50)和研究组(n=50),对照组给予NCPAP治疗,研究组在对照组基础上联合Ps治疗,并根据Ps注入时间的不同将研究组患儿分为早期组(出生6h内注入,n=25)和晚期组(出生6～12h注入,n=25)。观察并比较对照组、早期组、晚期组患儿的临床疗效,并比较三组患儿治疗前、治疗1d后动脉血酸碱度(pH)、动脉二氧化碳分压(PCO_2)、动脉血氧分压(PO_2)、呼气末正压通气(PEEP)、吸入氧浓度(FiO_2)以及并发症发生情况。结果:早期组患儿临床总有效率高于对照组、晚期组(P0.05);而对照组、晚期组患儿临床总有效率比较差异无统计学意义(P0.05)。治疗1d后,三组患儿PCO_2较治疗前降低,PO_2较治疗前升高,且早期组PCO_2低于对照组、晚期组,PO_2高于对照组、晚期组(P0.05);但对照组、晚期组PCO_2、PO_2比较差异无统计学意义(P0.05)。治疗1d后,三组患儿PEEP、FiO_2较治疗前降低,且早期组低于对照组、晚期组(P0.05);但对照组、晚期组PEEP、Fi O2比较差异无统计学意义(P0.05)。三组患儿并发症总发生率比较差异无统计学意义(P0.05)。结论:与晚期相比,早期应用Ps联合NCPAP治疗NRDS疗效确切,其改善患儿血气指标及NCPAP参数的效果更佳,同时不会增加不良反应。     

Determination of phenethylamine,a phenethyl isothiocyanate marker,in dog plasma using solid-phase extraction and gas chromatography-mass spectrometry with chemical ionization

Phenethyl isothiocyanate is unstable in aqueous media and at low pH, and rapidly degrades to phenethylamine. Concentrations of phenethylamine, a phenethyl isothiocyanate marker, in dog plasma, were determined utilizing solid-phase extraction and gas chromatography–mass spectrometry with chemical ionization using acetone as the reagent gas. Deuterated d₅-amphetamine was used as an internal standard. After extraction, phenethylamine and d₅-amphetamine were derivatized using MBHFBA. Ions monitored for d₅-amphetamine were m/z 337 and 338; and for phenethylamine were m/z 318 and 319. Precision and accuracy were studied using control solutions prepared in naive dog plasma (80 and 300 ng/ml). Intra-day variability was determined using six replicates of each control solution analyzed on a single day. The relative standard deviation for the 80 ng/ml control was 12.9% and for the 300 ng/ml it was 12.1%. Relative accuracy was 10.9% for the low control and −4.1% for the high control. Inter-day variability was determined over a 6-day period. For the 80 and 300 ng/ml control solutions, the relative standard deviations were 15.8 and 9.1%, respectively, and relative accuracy values were 10.1 and −5.2%, respectively. Standard curves were prepared in naive dog plasma and were linear over the range of phenethylamine assayed (10–500 ng/ml). The results of this study indicate that the proposed method is simple, precise, accurate and sensitive enough for analysis of large numbers of plasma samples.     

A continuous fluorimetric assay for glycosidase activity: Human N-acetyl-β-d-hexosaminidase

The fluorescence intensity of 4-methylumbelliferone (λ_excitation = 320 nm, λ_emission = 450 nm) is approximately 120-fold greater than those of 4-methylumbelliferyl glycosides over a pH range from 3 to 7. Therefore, continuous fluorimetric monitoring of the enzymatic release of 4-methylumbelliferone from its corresponding glycoside can be performed. The technique we developed is suitable for kinetic studies of various glycosidases operating within the indicated pH range. This procedure was found to be accurate, sensitive, and rapid, as shown using N-acetyl-β-d-hexosaminidases A and B isolated from human placenta.     

The microbiological basis of process control in methanogenic fermentation of soluble wastes

The essential requirement for anaerobic digestion of industrial wastes is that the process should operate reliably at high performance. In the digestion of dilute, soluble wastes it is necessary to retain the active biomass within the digester at short liquid retention times for the process to be economically feasible and this is reflected in digester design. Performance of digesters can only be assessed by interpretation of measurable parameters such as pH₂, E_h, pH, volatile fatty acid concentrations, temperature, gas production, biomass content and feed rate and composition. The effects of changes in these parameters on the microbiology of methanogenic digestion and the application of this knowledge in control of the process is discussed.     

Chlorobium limicola forma thiosulfatophilum: Biocatalyst in the Production of Sulfur and Organic Carbon from a Gas Stream Containing H2S and CO2

Chlorobium limicola forma thiosulfatophilum (ATCC 17092) was grown in a 1-liter continuously stirred tank reactor (800-ml liquid volume) at pH 6.8, 30°C, saturated light intensity, and a gas flow rate of 23.6 ml/min from a gas cylinder blend consisting of 3.9 mol% H₂S, 9.2 mol% CO₂, 86.4 mol% N₂, and 0.5 mol% H₂. This is the first demonstration of photoautotrophic growth of a Chlorobium sp. on a continuous inorganic gas feed. A significant potential exists for applying this photoautotrophic process to desulfurization and CO₂ fixation of gases containing acidic components (H₂S and CO₂).     

Effect of pH on phase separated anaerobic digestion

A pilot scale experiment was performed for a year to develop a two-phase anaerobic process for piggery wastewater treatment (COD: 6,000 mg/L, BOD: 4,000 mg/L, SS: 500 gm/L, pH 8.4, alkalinity 6,000 mg/L). The acidogenic reactor had a total volume of 3 m³, and the methanogenic reactor, an, anaerobic up-flow sludge filter, combining a filter and a sludge bed, was also of total volume 3 m³ (1.5 m³ of upper packing material). Temperatures of the acidogenic and methanogenic reactors kept at 20°C and 35°C., respectively. When the pH of the acidogenic reactor was controlled at 6.0–7.0 with HCl, the COD removal efficiency increased from 50 to 80% over a period of six months, and as a result, the COD of the final effluent fell in the range of 1,000–1,500 mg/L. BOD removal efficiency over the same period was above 90%, and 300 to 400 mg/L was maintained in the final effluent. The average SS in the final effluent was 270 mg/L. The methane production was 0.32 m³ CH₄/kg COD_removed and methane content of the methanogenic reactor was high value at 80–90%., When the pH of the acidogenic reactor was not controlled over the final two months, the pH reached 8.2 and acid conversion decreased compared with that of pH controlled, while COD removal was similar to the pH controlled operation. Without pH control, the methane content in the gas from methanogenic reactor improved to 90%, compared to 80% with pH control.