Biohydrogen production by Thermoanaerobacterium thermosaccharolyticum TERI S7 from oil reservoir flow pipeline

Thermophilic dark fermentative hydrogen producing bacterial strain, TERI S7, isolated from an oil reservoir flow pipeline located in Mumbai, India, showed 98% identity with Thermoanaerobacterium thermosaccharolyticum by 16S rRNA gene analysis. It produced 1450–1900 ml/L hydrogen under both acidic and alkaline conditions; at a temperature range of 45–60 °C. The maximum hydrogen yield was 2.5 ± 0.2 mol H₂/mol glucose, 2.2 ± 0.2 mol H₂/mol xylose and 5.2 ± 0.2 mol H₂/mol sucrose, when the respective sugars were used as carbon source. The cumulative hydrogen production, hydrogen production rate and specific hydrogen production rate by the strain TERI S7 with sucrose as carbon source was found to be 1704 ± 105 ml/L, 71 ± 6 ml/L/h and 142 ± 13 ml/g/h respectively. Major soluble metabolites produced during fermentation were acetic acid and butyric acid. The strain TERI S7 was also observed to produce hydrogen continuously up to 48 h at pH 3.9.     

Statistical optimization of fermentative hydrogen production from xylose by newly isolated Enterobacter sp. CN1

Statistical experimental designs were applied for the optimization of medium constituents for hydrogen production from xylose by newly isolated Enterobacter sp. CN1. Using Plackett–Burman design, xylose, FeSO₄ and peptone were identified as significant variables which highly influenced hydrogen production. The path of steepest ascent was undertaken to approach the optimal region of the three significant factors. These variables were subsequently optimized using Box–Behnken design of response surface methodology (RSM). The optimum conditions were found to be xylose 16.15 g/L, FeSO₄ 250.17 mg/L, peptone 2.54 g/L. Hydrogen production at these optimum conditions was 1149.9 ± 65 ml H₂/L medium. Under different carbon sources condition, the cumulative hydrogen volume were 1217 ml H₂/L xylose medium, 1102 ml H₂/L glucose medium and 977 ml H₂/L sucrose medium; the maximum hydrogen yield were 2.0 ± 0.05 mol H₂/mol xylose, 0.64 mol H₂/mol glucose. Fermentative hydrogen production from xylose by Enterobacter sp. CN1 was superior to glucose and sucrose.     

Biological hydrogen production by extremely thermophilic novel bacterium Thermoanaerobacter mathranii A3N isolated from oil producing well

Hydrogen producing novel bacterial strain was isolated from formation water from oil producing well. It was identified as Thermoanaerobacter mathranii A3N by 16S rRNA gene sequencing. Hydrogen production by novel strain was pH and substrate dependent and favored pH 8.0 for starch, pH 7.5 for xylose and sucrose, pH 8.0–9.0 for glucose fermentation at 70 °C. The highest H₂ yield was 2.64 ± 0.40 mol H₂ mol glucose at 10 g/L, 5.36 ± 0.41 mol H₂ mol – sucrose at 10 g/L, 17.91 ± 0.16 mmol H₂ g – starch at 5 g/L and 2.09 ± 0.21 mol H₂ mol xylose at 5 g/L. The maximum specific hydrogen production rates 6.29 (starch), 9.34 (sucrose), 5.76 (xylose) and 4.89 (glucose) mmol/g cell/h. Acetate-type fermentation pathway (approximately 97%) was found to be dominant in strain A3N, whereas butyrate formation was found in sucrose and xylose fermentation. Lactate production increased with high xylose concentrations above 10 g/L.     

Impact of regulated pH on proto scale hydrogen production from xylose by an alkaline tolerant novel bacterial strain, Enterobacter cloacae DT-1

A hydrogen producing facultative anaerobic alkaline tolerant novel bacterial strain was isolated from crude oil contaminated soil and identified as Enterobacter cloacae DT-1 based on 16S rRNA gene sequence analysis. DT-1 strain could utilize various carbon sources; glycerol, CMCellulose, glucose and xylose, which demonstrates that DT-1 has potential for hydrogen generation from renewable wastes. Batch fermentative studies were carried out for optimization of pH and Fe²⁺ concentration. DT-1 could generate hydrogen at wide range of pH (5–10) at 37 °C. Optimum pH was; 8, at which maximum hydrogen was obtained from glucose (32 mmol/L), when used as substrate in BSH medium containing 5 mg/L Fe²⁺ ion. Decrease in hydrogen partial pressure by lowering the total pressure in the fermenter head space, enhanced the hydrogen production performance of DT-1 from 32 mmol H₂/L to 42 mmol H₂/L from glucose and from 19 mmol H₂/L to 33 mmol H₂/L from xylose. Hydrogen yield efficiency (HY) of DT-1 from glucose and xylose was 1.4 mol H₂/mol glucose and 2.2 mol H₂/mol xylose, respectively. Scale up of batch fermentative hydrogen production in proto scale (20 L working volume) at regulated pH, enhanced the HY efficiency of DT-1 from 2.2 to 2.8 mol H₂/mol xylose (1.27 fold increase in HY from laboratory scale). 84% of maximum theoretical possible HY efficiency from xylose was achieved by DT-1. Acetate and ethanol were the major metabolites generated during hydrogen production.     

Dark fermentative hydrogen production with crude glycerol from biodiesel industry using indigenous hydrogen-producing bacteria

Glycerol is an inevitable by-product from biodiesel synthesis process and could be a promising feedstock for fermentative hydrogen production. In this study, the feasibility of using crude glycerol from biodiesel industry for biohydrogen production was evaluated using seven isolated hydrogen-producing bacterial strains (Clostridium butyricum, Clostridium pasteurianum, and Klebsiella sp.). Among the strains examined, C. pasteurianum CH4 exhibited the best biohydrogen-producing performance under the optimal conditions of: temperature, 35 °C; initial pH, 7.0; agitation rate, 200 rpm; glycerol concentration, 10 g/l. When using pure glycerol as carbon source for continuous hydrogen fermentation, the average H₂ production rate and H₂ yield were 103.1 ± 8.1 ml/h/l and 0.50 ± 0.02 mol H₂/mol glycerol, respectively. In contrast, when using crude glycerol as the carbon source, the H₂ production rate and H₂ yield was improved to 166.0 ± 8.7 ml/h/l and 0.77 ± 0.05 mol H₂/mol glycerol, respectively. This work demonstrated the high potential of using biodiesel by-product, glycerol, for cost-effective biohydrogen production.     

Dark fermentative hydrogen production from xylose by a hot spring enrichment culture

Dark fermentative hydrogen production by a hot spring culture was studied from different sugars in batch assays and from xylose in continuous stirred tank reactor (CSTR) with on-line pH control. Batch assays yielded hydrogen in following order: xylose > arabinose > ribose > glucose. The highest hydrogen yield in batch assays was 0.71 mol H₂/mol xylose. In CSTR the highest H₂ yield and production rate at 45 °C were 1.97 mol H₂/mol xylose and 7.3 mmol H₂/h/L, respectively, and at 37 °C, 1.18 mol H₂/mol xylose and 1.7 mmol H₂/h/L, respectively. At 45 °C, microbial community consisted of only two bacterial strains affiliated to Clostridium acetobutulyticum and Citrobacter freundii, whereas at 37 °C six Clostridial species were detected. In summary hydrogen yield by hot spring culture was higher with pentoses than hexoses. The highest H₂ production rate and yield and thus, the most efficient hydrogen producing bacteria were obtained at suboptimal temperature of 45 °C for both mesophiles and thermophiles.     

Fermentative hydrogen production by new marine Clostridium amygdalinum strain C9 isolated from offshore crude oil pipeline

The present study investigated hydrogen production potential of novel marine Clostridium amygdalinum strain C9 isolated from oil water mixtures. Batch fermentations were carried out to determine the optimal conditions for the maximum hydrogen production on xylan, xylose, arabinose and starch. Maximum hydrogen production was pH and substrate dependant. The strain C9 favored optimum pH 7.5 (40 mmol H₂/g xylan) from xylan, pH 7.5–8.5 from xylose (2.2–2.5 mol H₂/mol xylose), pH 8.5 from arabinose (1.78 mol H₂/mol arabinose) and pH 7.5 from starch (390 ml H₂/g starch). But the strain C9 exhibited mixed type fermentation was exhibited during xylose fermentation. NaCl is required for the growth and hydrogen production. Distribution of volatile fatty acids was initial pH dependant and substrate dependant. Optimum NaCl requirement for maximum hydrogen production is substrate dependant (10 g NaCl/L for xylose and arabinose, and 7.5 g NaCl/L for xylan and starch).     

Co-digestion of oil palm trunk hydrolysate with slaughterhouse wastewater for thermophilic bio-hydrogen production by Thermoanaerobacterium thermosaccharolyticm KKU19

The key factors influencing a co-digestion of the oil palm trunk (OPT) hydrolysate with a slaughterhouse wastewater (SHW) to produce hydrogen by Thermoanaerobacterium thermosaccharolyticum KKU19 were investigated. The OPT hydrolysate was obtained by the hydrolysis of OPT by microwave-H₂SO₄ method using 1.56% (w/v) H₂SO₄ and 7.50 min reaction time at 450 W. The Plackett–Burman method was used to screen the key factors that influenced the hydrogen production potential (P_s). Results indicated that initial cell concentration, tCOD/TN (total COD/total nitrogen) ratio and CuSO₄ concentration influenced the P_s. These factors were further optimized using response surface methodology (RSM) with central composite design (CCD). A maximum P_s of 2604 ± 86 mL H₂/L substrate was achieved at an initial cell concentration of 224 mg dry cell/L, tCOD/TN ratio of 49.87 and CuSO₄ concentration of 13.33 mg/L. The main soluble metabolite products were butyric and acetic acids. The P_s obtained when the hydrolysate was supplemented with SHW (2604mL ± 86 mL H₂/L substrate) was comparable to the P_s obtained when it was supplemented with yeast extract at the same tCOD/TN (2802 ± 87 mL H₂/L substrate). This result suggests that SHW can be used to replace the costly nitrogen source.     

Characterization on hydrogen production performance of a newly isolated Clostridium beijerinckii YA001 using xylose

A mesophilic bacterium was isolated from cow manure, and identified as Clostridium beijerinckii YA001 based on 16S rRNA gene sequence calculation using MEGA 5.0 and biochemical tests. This strain showed the ability to digest a wide range of carbon and nitrogen sources for hydrogen production, and it showed high hydrogen production performance using xylose as substrate. The optimum parameters for bio-hydrogen production in batch tests were pH 8.0, 1% substrate concentration, 40 °C and yeast extract as nitrogen source. The maximum hydrogen yield and the hydrogen production rate were obtained at 2.31 mol/mol xylose and 311.3 mL H₂/(Lh), respectively. These results indicate that C. beijerinckii YA001 is an ideal candidate for fermentative hydrogen production.     

Phytosynthesized iron oxide nanoparticles and ferrous iron on fermentative hydrogen production using Enterobacter cloacae: Evaluation and comparison of the effects

The effects of FeSO₄ and synthesized iron oxide nanoparticles (0–250 mg/L) on fermentative hydrogen production from glucose and sucrose, using Enterobacter cloacae were investigated, to find out the enhancement of efficiency. The maximum hydrogen yields of 1.7 ± 0.017 mol H₂/mol glucose and 5.19 ± 0.12 mol H₂/mol sucrose were obtained with 25 mg/L of ferrous iron supplementation. In comparison, the maximum hydrogen yields of 2.07 ± 0.07 mol H₂/mol glucose and 5.44 ± 0.27 mol H₂/mol sucrose were achieved with 125 mg/L and 200 mg/L of iron oxide nanoparticles, respectively. These results indicate that the enhancement of hydrogen production on the supplementation of iron oxide nanoparticles was found to be considerably higher than that of ferrous iron supplementation. The activity of E. cloacae in a glucose and sucrose fed systems was increased by the addition of iron oxide nanoparticles, but the metabolic pathway was not changed. The results revealed that the glucose and sucrose fed systems conformed to the acetate/butyrate fermentation type.     

Enhanced hydrogen production from xylose and bamboo stalk hydrolysate by overexpression of xylulokinase and xylose isomerase in Klebsiella oxytoca HP1

Biofuels production from lignocellulose hydrolysates by microbe fermentation has merited attention because of the mild reaction conditions involved and the clean nature of the process. In this work, xylulokinase (XK) and xylose isomerase (XI) were overexpressed in Klebsiella oxytoca HP1 to enhance hydrogen production by the fermentation of xylose. The recombinant strains exhibited higher enzyme activity of XI or XK compared with the wild strain. Hydrogen production from pure xylose, xylose/glucose mixtures and bamboo stalk hydrolysate was significantly enhanced with the overexpression of XI and XK in K. oxytoca HP1 in terms of total hydrogen yield (THY), hydrogen yield per mole substrate (HYPM) and hydrogen production rate (HPR). The HYPM of K. oxytoca HP1/xylB and K. oxytoca HP1/xylA reached 1.93 ± 0.05 and 2.46 ± 0.05 mol H₂/mol xylose, respectively in pure xylose, while the value for the wild strain was 1.68 ± 0.04 mol H₂/mol xylose. The xylose consumption rate (XCR) for the recombinant strain was significantly higher than that for the wild strain, particularly in the early stage of fermentation. Relative to the wild type, hydrogen yield (HY) from 1 g of preprocessed bamboo powder of HP1/xylB and HP1/xylA increased by 33.04 and 41.31%, respectively. It was concluded that overexpression of XK or XI was able to promote hydrogen production from xylose and xylose/glucose mixtures by simultaneously increasing the utilization efficiency of xylose and weakening the inhibitory effect of glucose on xylose use. In addition, the results indicated that overexpression technology was an effective way to further increase hydrogen production from lignocellulosic hydrolysates.     

Fermentative hydrogen production from different sugars by Citrobacter sp. CMC-1 in batch culture

In this study, production of hydrogen (H₂) from glucose, xylose, galactose, mannose, arabinose and rhamnose by a strain isolated from activated sludge was investigated. The strain, named as Citrobacter sp. CMC-1, was enriched in cellobiose amended minimal media. Based on 16S rRNA sequence, the CMC-1 strain is a close relative of Citrobacter amalonaticus strain SA01 (99%). Optimal cultivation parameters for H₂ production and growth such as pH and temperature were investigated. H₂ yields from glucose at optimal conditions (pH 6.0 and 34 °C) were 1.82 ± 0.02 mol-H₂/mol-glucose. Strain CMC-1 fermented galactose, mannose, xylose, arabinose and rhamnose. After 48 h incubation, the strain CMC-1 completely fermented all sugars tested, except arabinose. Increase in fermentation period lowered residual formate level in the media and improved H₂ production for galactose, mannose and xylose (1.68 ± 0.24, 1.93 ± 0.14 and 1.63 ± 0.07 mol-H₂/mol-substrate respectively).     

Biohydrogen production from various feedstocks by Bacillus firmus NMBL-03

In present work our objective was to find out the potential substrates for fermentative hydrogen production using microbial culture of Bacillus firmus NMBL-03 isolated from municipal sludge. A wide variety of substrates (glucose, xylose, arabinose, lactose, sucrose, and starch) and carbohydrate rich waste products (bagasse hydrolysate, molasses, potato peel and cyanobacterial mass) have been used for dark fermentative hydrogen production. All studies were done at optimized physico-chemical conditions. Among all substrates glucose, arabinose, lactose, starch, molasses and bagasse hydrolysate were found to be the favorable substrates for hydrogen production. The highest VHPR i.e. 177.5 ± 7.07 ml/L.h (7.95 ± 0.29 mmol H₂/L.h) and maximum H₂ production (22.58 ± 2.65 mmol H₂/L) was achieved using starch as the substrate. The maximum yield 1.29 ± 0.11 mol H₂/mol reducing sugar was obtained from bagasse hydrolysate as substrate. Butyrate and acetate were detected as the end product in all the cases while lactate was also detected from glucose and cyanobacterial hydrolysate. Since considerable amount of H₂ also evolved when cyanobacterial mass was used, therefore this microbe can be exploited for hydrogen production through a three stage integrated system. Residual carbohydrate containing biomass left after cyanobacterial H₂ production can be utilized in dark fermentative H₂ production. Spent media obtained after dark fermentative H₂ production contain considerable amount of volatile fatty acids that can be potential substrate for photo fermentative H₂ production.     

Dark fermentative biohydrogen production by mesophilic bacterial consortia isolated from riverbed sediments

Dark fermentative bacterial strains were isolated from riverbed sediments and investigated for hydrogen production. A series of batch experiments were conducted to study the effect of pH, substrate concentration and temperature on hydrogen production from a selected bacterial consortium, TERI BH05. Batch experiments for fermentative conversion of sucrose, starch, glucose, fructose, and xylose indicated that TERI BH05 effectively utilized all the five sugars to produce fermentative hydrogen. Glucose was the most preferred carbon source indicating highest hydrogen yields of 22.3 mmol/L. Acetic and butyric acid were the major soluble metabolites detected. Investigation on optimization of pH, temperature, and substrate concentration revealed that TERI BH05 produced maximum hydrogen at 37 °C, pH 6 with 8 g/L of glucose supplementation and maximum yield of hydrogen production observed was 2.0–2.3 mol H₂/mol glucose. Characterization of TERI BH05 revealed the presence of two different bacterial strains showing maximum homology to Clostridium butyricum and Clostridium bifermentans.     

Enrichment of activated sludge for enhanced hydrogen production from crude glycerol

Enriched activated sludge that can effectively convert crude glycerol into bio-hydrogen was selected by an eco-biotechnological approach, in very strict conditions, using biodiesel-derived glycerol as the only carbon source. The thus obtained functional consortium was characterized by the genera Klebsiella, Escherichia/Shigella and Cupriavidus. During enrichment, the dominant metabolic end-product shifted from a 1,3 propanediol to ethanol, with a concomitant increase of the hydrogen yield from 0.18 ± 0.003 to 0.66 ± 0.06 mol/mol and an almost five-fold increase of the hydrogen production. Glycerol degradation efficiency showed an increase of around 50%. In optimized and upscaled conditions it was possible to obtain a hydrogen production rate of 2960 mL H₂/L/day ± 185 at a near stoichiometric yield (of 0.90 mol/mol ± 0.01), with a carbon recovery of almost 90%, both in sterile and non-sterile conditions. Glycerol was almost totally degraded (degradation efficiency of 97.42% ± 0.98), independently of the glycerol type used.     

Biohydrogen production from pentose-rich oil palm empty fruit bunch molasses: A first trial

Oil palm empty fruit bunch (OPEFB) was pretreated by local plantation industry to increase the accessibility towards its fermentable sugars. This pretreatment process led to the formation of a dark sugar-rich molasses byproduct. The total carbohydrate content of the molasses was 9.7 g/L with 4.3 g/L xylose (C₅H₁₀O₅). This pentose-rich molasses was fed as substrate for biohydrogen production using locally isolated Clostridium butyricum KBH1. The effect of initial pH and substrate concentration on the yield and productivity of hydrogen production were investigated in this study. The best result for the fermentation performed in 70 mL working volume was obtained at the initial reaction condition of pH 9, 150 rpm, 37 °C and 5.9 g/L total carbohydrate. The maximum hydrogen yield was 1.24 mol H₂/mol pentose and the highest productivity rate achieved was 0.91 mmol H₂/L/h. The optimal pH at pH 9 was slightly unusual due to the presence of inhibitors, mainly furfural. The furfural content decreased proportionally as pH was increased. The optimal experiment condition was repeated and continued in fermentation volume of 200 mL. The maximum hydrogen yield found for this run was 1.21 mol H₂/mol pentose while the maximum productivity was 1.1 mmol H₂/L/h. The major soluble metabolites in the fermentation were n-butyric acid and acetic acid.     

Yeast extract as an effective nitrogen source stimulating cell growth and enhancing hydrogen photoproduction by Rhodobacter sphaeroides strains from mineral springs

The suitability and limitation of yeast extract as nitrogen source to support cell growth and to enhance hydrogen photoproduction by Rhodobacter sphaeroides strains MDC6521 and MDC6522 isolated from mineral springs in Armenia was investigated during the anaerobic growth. Yeast extract (2 g L⁻¹) was indicated to be an effective nitrogen source for bacterial cell growth stimulation and enhanced H₂ production (compared to glutamate). Both strains followed similar growth patterns in medium with yeast extract as nitrogen source and succinate or malate as carbon source. The highest growth rate was obtained for bacterial cells with yeast extract: the latter added gave a stimulated (2–3.5 fold) growth rate than using glutamate. R. sphaeroides suspension oxidation–reduction potential (ORP), which was measured with a platinum electrode, decreased down to low negative values with nitrogen source for both strains. ORP decreased down to more negative values (−610 ± 25 mV) in the presence of yeast extract than when adding glutamate (−405 ± 15 mV) compared to the control (without nitrogen source addition): the significant decrease of ORP indicated enhanced (∼6 fold) H₂ yield. The noticeable ORP decrease measured with the titanium-silicate electrode and simultaneously the increase of extracellular pH ([pH]_out) were observed; ORP was more negative at alkaline [pH]_out. Thus, the optimal culture conditions with nitrogen and carbon sources for bacterial growth stimulation and enhanced H₂ production were established. The ORP decrease together with the increase of [pH]_out point out a significant role of reduction processes in cell growth and ability of bacteria to live.     

Thermophilic fermentative hydrogen production from various carbon sources by anaerobic mixed cultures

In the present work, various carbon sources, xylose, glucose, galactose, sucrose, cellobiose, and starch were tested for thermophilic (60 °C) fermentative hydrogen production (FHP) by using the anaerobic mixed culture. An inoculum was obtained from a continuously-stirred tank reactor (CSTR) operated at pH 5.5 and HRT 12 h, and fed with tofu processing waste. The dominant species in the CSTR were found to be Thermoanaerobacterium thermosaccharolyticum and Clostridium thermosaccharolyticum, which are well known thermophilic H₂-producers in anaerobic-state, and have the ability to utilize a wide range of carbohydrates. When initial pH was adjusted to 6.8 ± 0.1 but not controlled during fermentation, vigorous pH drop began within 5 h, and finally reached 4.0–4.5 in all carbon sources. Although over 90% of substrate removal was achieved for all carbon sources except cellobiose (71.7%), the fermentation performances were profoundly different with each other. Glucose, galactose, and sucrose exhibited relatively higher H₂ yields whereas lower H₂ yields were observed for xylose, cellobiose, and starch. On the other hand, when pH was controlled (pH ≥ 5.5), the fermentation performance was enhanced in all carbon sources but to a different extent. A substantial increase in H₂ production was observed for cellobiose, a 1.9-fold increase of H₂ yield along with a substrate removal increase to 93.8%, but a negligible increase for xylose. H₂ production capabilities of all carbon sources tested were as follows: sucrose > galactose > glucose > cellobiose > starch > xylose. The maximum H₂ yield of 3.17 mol H₂/mol hexose_added achieved from sucrose is equivalent to a 26.5% conversion of energy content in sucrose to H₂. Acetic and butyric acids were the main liquid-state metabolites of all carbon sources while lactic acid was detected only in cellobiose, starch and xylose exhibiting relatively lower H₂ yields.     

Improvement of hydrogen production under decreased partial pressure by newly isolated alkaline tolerant anaerobe, Clostridium butyricum TM-9A: Optimization of process parameters

A mesophilic alkaline tolerant fermentative microbe was isolated from estuarine sediment samples and designated as Clostridium butyricum TM-9A, based on 16S rRNA gene sequence. Batch experiments were conducted for investigation of TM-9A strain for its growth and hydrogen productivity from glucose, in an iron containing basal solution supplemented with yeast extract as organic nitrogen source. Hydrogen production started to evolve when cell growth entered exponential phase and reached maximum production rate at late exponential phase. Maximum hydrogen production was observed at 37 °C, initial pH of 8.0 in the presence of 1% glucose. Optimization of process parameters resulted in increase in hydrogen yield from 1.64 to 2.67 mol of H₂/mol glucose. Molar yield of H₂ increased further from 2.67 to 3.1 mol of H₂/mol of glucose with the decrease in hydrogen partial pressure, obtained by lowering the total pressure in the head space of the batch reactor. Acetate and butyrate were the measure volatile fatty acids generated during hydrogen fermentation. TM-9A strain produced hydrogen efficiently from a range of pentose and hexose sugars including di-, tri and poly-saccharides like; xylose, ribose, glucose, rhamnose, galactose, fructose, mannose, sucrose, arabinose, raffinose, cellulose, cellobiose and starch.