Feasibility of ABE fermentation from Rhizoclonium spp. hydrolysate with low nutrient supplementation

Salaeh, Suhaila; Kongjan, Prawit; Panphon, Somrak; Hemmanee, Sukallaya; Reungsang, Alissara; Jariyaboon, Rattana

doi:10.1016/j.biombioe.2019.105269

Cited by 19 publications

(9 citation statements)

References 18 publications

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“…On the other hand, Potts et al [29] produce biobutanol concentration from U. lactuca (green macroalgae) in the fermentation broth reached about 4 g/L. Moreover, our results agreed with Salaeha et al [33], who also studied the biobutanol production from Rhizoclonium macroalgae (red macroalgae), the maximum biobutanol produced was 2.43 g/L and the total ABE were 4.57 g/L. finally, the results recorded in tables 4 and 5 illustrated that, the native isolate HG1 produced the maximum acetone-butanol-ethanol from the fermentation of T6 medium and also from algal hydrolysate.…”

Section: Abe Production From Fermentation Of Algal Hydrolysate By Closupporting

confidence: 91%

“…Finally, the three bacterial isolates (HB3, HC5 and HP1) were the lowest total solvent producing bacterial isolates (1.145, 0.392 and 0.353 g/L) respectively. Salaeh et al [33] reported that, the maximum biobutanol produced was (2.55 g/L) and the total ABE were (3.65 g/L) on TYA medium which its composition similar to T6 medium by using Clostridium beijerinckii TISTR 1461. On the other hand, Montoya et al [16] mentioned that, the biobutanol produced on T6 medium from different clostridium isolates from different crops ranged from 1.1 to 11.4 g/L.…”

Section: Table 1 the Chemical Composition Of Collected Brown Macroalmentioning

confidence: 98%

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Isolation of Different Clostridium Isolates for Acetone-Butanol-Ethanol (ABE) Production from Sargassum sp.

Ali

2020

Egypt. J. Chem.

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Macroalgae with several species are an abundant, carbon-neutral renewable resource and rich in carbohydrates which make it suitable for biobutanol production. Recently, due to advantages of biobutanol as a liquid biofuel, it can be used as a substitute for gasoline and diesel. Many researches mentioned that, different Clostridium species are able to use fermentable sugars for production of biobutanol from different biomasses through ABE (Acetone-Butanol-Ethanol) fermentation process. In this study the (Sargassum sp.) was used as carbon source for biobutanol production. Thirty-three anaerobic mesophilic isolates were isolated on RCM medium from five soil cultivated with different crops. Only thirteen spore forming, mesophilic, anaerobic Clostridium isolates used for the fermentation process. 100 g/L from Sargassum sp. were hydrolyzed by sulfuric acid (6 % (v/v)) followed by thermal pretreatment at 121°C for 20 minutes to produce total reducing sugars (24.151 ± 0.273 g/L), which were fermented by Clostridium isolates. The most promising isolate (HG1) which produce the highest butanol level, acetone and ethanol (3.743, 1.401 and 1.031 g/l) respectively was identified according to Butanol dehydrogenases (bdhA) gene analysis as Clostridium acetobutylicum. This paper emphasizes the importance of (Sargassum sp.) as a renewable feedstock for the biobutanol production.

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Section: Abe Production From Fermentation Of Algal Hydrolysate By Closupporting

confidence: 91%

Section: Table 1 the Chemical Composition Of Collected Brown Macroalmentioning

confidence: 98%

Isolation of Different Clostridium Isolates for Acetone-Butanol-Ethanol (ABE) Production from Sargassum sp.

Ali

2020

Egypt. J. Chem.

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“…The prepared inoculum was used at approximately 10% of the active volume for triplicate ABE fermentation in a serum bottle with a 200‐mL working volume, incubating it at a temperature of 37°C for 48 h with shaking at 120 rpm until reaching an OD 600 value of ≈1.5. [ 15 ] The performance of C. beijerinckii ATCC 10132 was determined using glucose concentrations of 40 and 60 g L −1 with the same medium and conditions as described above, and samples were collected at 0, 4, 8, 12, 16, 20, and 24 h for further analysis.…”

Section: Methodsmentioning

confidence: 99%

Potential of butanol production from Thailand marine macroalgae using Clostridium beijerinckii ATCC 10132‐based ABE fermentation

Khaonuan

Jariyaboon

Usmanbaha

et al. 2023

Biotechnology Journal

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The economical bio‐butanol‐based fermentation process is mainly limited by the high price of first‐generation biomass, which is an intensive cost for the pretreatment of second‐generation biomass. As third‐generation biomass, marine macroalgae could be potentially advantageous for conversion to clean and renewable bio‐butanol through acetone‐butanol‐ethanol (ABE) fermentation. In this study, butanol production from three macroalgae species (Gracilaria tenuistipitata, Ulva intestinalis, and Rhizoclonium sp.) by Clostridium beijerinckii ATCC 10132 was assessed comparatively. The enriched C beijerinckii ATCC 10132 inoculum produced a high butanol concentration of 14.07 g L−1 using 60 g L−1 of glucose. Among the three marine seaweed species, G. tenuistipitata exhibited the highest potential for butanol production (1.38 g L−1). Under the 16 conditions designed using the Taguchi method for low‐temperature hydrothermal pretreatment (HTP) of G. tenuistipitata, the maximum reducing sugar yield rate of 57.6% and ABE yield of 19.87% were achieved at a solid to liquid (S/L) ratio of 120, temperature of 110°C, and holding time of 10 min (Severity factor, R0 1.29). In addition, pretreated G. tenuistipitata could be converted to 3.1 g L−1 of butanol using low‐HTP at an S/L ratio of 50 g L−1, temperature of 80°C (R0 0.11), and holding time of 5 min.

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“…Pre-treatment methods can further improve the fermentation process [196]. Low-cost biological pre-treatment options such as a fungal pre-treatment provide fermentation efficiencies up to 92% from Kappaphycus alvarezii [220]. Chemical pre-treatments can also be used [220].…”

Section: Algae Biomass and Biofuel Productionmentioning

confidence: 99%

“…Low-cost biological pre-treatment options such as a fungal pre-treatment provide fermentation efficiencies up to 92% from Kappaphycus alvarezii [220]. Chemical pre-treatments can also be used [220]. Additionally, physical pre-treatments such as ultrasound and microwave are useful [221].…”

Section: Algae Biomass and Biofuel Productionmentioning

confidence: 99%

Biological-Based Produced Water Treatment Using Microalgae: Challenges and Efficiency

et al. 2022

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Produced water (PW) is the most significant waste stream generated in the oil and gas industries. The generated PW has the potential to be a useful water source rather than waste. While a variety of technologies can be used for the treatment of PW for reuse, biological-based technologies are an effective and sustainable remediation method. Specifically, microalgae, which are a cost-effective and sustainable process that use nutrients to eliminate organic pollutants from PW during the bioremediation process. In these treatment processes, microalgae grow in PW free of charge, eliminate pollutants, and generate clean water that can be recycled and reused. This helps to reduce CO2 levels in the atmosphere while simultaneously producing biofuels, other useful chemicals, and added-value products. As such, this review focuses on PW generation in the oil and gas industry, PW characteristics, and examines the available technologies that can be used for PW remediation, with specific attention to algal-based technologies. In addition, the various aspects of algae growth and cultivation in PW, the effect of growth conditions, water quality parameters, and the corresponding treatment performance are presented. Lastly, this review emphasizes the bioremediation of PW using algae and highlights how to harvest algae that can be processed to generate biofuels for added-value products as a sustainable approach.

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Feasibility of ABE fermentation from Rhizoclonium spp. hydrolysate with low nutrient supplementation

Cited by 19 publications

References 18 publications

Isolation of Different Clostridium Isolates for Acetone-Butanol-Ethanol (ABE) Production from Sargassum sp.

Isolation of Different Clostridium Isolates for Acetone-Butanol-Ethanol (ABE) Production from Sargassum sp.

Potential of butanol production from Thailand marine macroalgae using Clostridium beijerinckii ATCC 10132‐based ABE fermentation

Biological-Based Produced Water Treatment Using Microalgae: Challenges and Efficiency

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