Fermentative hydrogen production from agroindustrial lignocellulosic substrates

Reginatto, Valeria; Antônio, Regina Vasconcellos

doi:10.1590/S1517-838246220140111

Abstract

To achieve economically competitive biological hydrogen production, it is crucial to consider inexpensive materials such as lignocellulosic substrate residues derived from agroindustrial activities. It is possible to use (1) lignocellulosic materials without any type of pretreatment, (2) lignocellulosic materials after a pretreatment step, and (3) lignocellulosic materials hydrolysates originating from a pretreatment step followed by enzymatic hydrolysis. According to the current literature data on fermentative H₂ production presented in this review, thermophilic conditions produce H₂ in yields approximately 75% higher than those obtained in mesophilic conditions using untreated lignocellulosic substrates. The average H₂ production from pretreated material is 3.17 ± 1.79 mmol of H₂/g of substrate, which is approximately 50% higher compared with the average yield achieved using untreated materials (2.17 ± 1.84 mmol of H₂/g of substrate). Biological pretreatment affords the highest average yield 4.54 ± 1.78 mmol of H₂/g of substrate compared with the acid and basic pretreatment - average yields of 2.94 ± 1.85 and 2.41 ± 1.52 mmol of H₂/g of substrate, respectively. The average H₂ yield from hydrolysates, obtained from a pretreatment step and enzymatic hydrolysis (3.78 ± 1.92 mmol of H₂/g), was lower compared with the yield of substrates pretreated by biological methods only, demonstrating that it is important to avoid the formation of inhibitors generated by chemical pretreatments. Based on this review, exploring other microorganisms and optimizing the pretreatment and hydrolysis conditions can make the use of lignocellulosic substrates a sustainable way to produce H₂.

fermentation; hydrogen; lignocellulosic substrates; pretreatment; inhibitors

Introduction

H₂ is a promising fuel: it is carbon-free and its combustion produces only water (Wang and Wan, 2009Wang J, Wan W (2009) Factors influencing fermentative hydrogen production: A review. Int J Hydrogen Energy 34:799–811.). Although H₂ constitutes a clean fuel, currently available methods leading to its production, such as methane reforming and partial oil and coal oxidation, demand fossil fuels and a high amount of energy (Chaubey et al., 2013Chaubey R, Sahu S, James OO et al. (2013) A review on development of industrial processes and emerging techniques for production of hydrogen from renewable and sustainable sources. Renew Sust Energ Rev 23:443–462.). Biological approaches that produce H₂ offer several advantages over current physicochemical methods: they occur at ambient temperature and pressure, and they use renewable raw materials as substrates (Li and Fang, 2007Li C, Fang H (2007) Fermentative hydrogen production from wastewater and solid wastes by mixed cultures. Crit Rev Environ Sci Technol 37:1–39.; Li et al., 2012Li YC, Liu YF, Chu CY et al. (2012) Techno-economic evaluation of biohydrogen production from wastewater and agricultural waste. Int J Hydrogen Energy 37:15704–15710.).

A number of microbes belonging to a wide variety of bacterial groups can perform fermentative H₂ production, also called dark fermentation because it does not require light. The strict anaerobe Clostridium spp. and facultative anaerobes from the family Enterobacteriaceae are the most often cited H₂-producing bacteria (Seol et al., 2008Seol E, Kim S, Raj SM et al. (2008) Comparison of hydrogen-production capability of four different Enterobacteriaceae strains under growing and non-growing conditions. Int J Hydrogen Energy 33:5169–5175., Elsharnouby et al., 2013Elsharnouby O, Hafez H, Nakhla G et al. (2013) A critical literature review on biohydrogen production by pure cultures. Int J Hydrogen Energy 38:4945–4966.).

Mixed cultures that usually originate from an anaerobic environment, such as the sludge from anaerobic biodigestors, have also found application in H₂-producing processes. They resist the fluctuations typical of the fermentation process, consume a broader range of complex substrates, and can operate in a non-sterile environment (Valdez-Vazquez and Poggi-Varaldo, 2009Valdez-Vazquez I, Poggi-Varaldo HM (2009) Hydrogen production by fermentative consortia. Renew Sust Energ Rev 13:1000–1013., Kothari et al., 2012Kothari R, Singh DP, Tyagi VV et al. (2012) Fermentative hydrogen production - An alternative clean energy source. Renew Sust Energ Rev 16:2337–2346., Show et al., 2012Show KY, Lee DJ, Tay JH et al. (2012) Biohydrogen production: Current perspectives and the way forward. Int J Hydrogen Energy 37:15616–15631.; Rafrafi et al., 2013Rafrafi Y, Trably E, Hamelin J, et al. (2013) Sub-dominant bacteria as keystone species in microbial communities producing bio-hydrogen. Int J Hydrogen Energy 38:4881–5180.).

However, it is the choice of substrate for fermentative H₂ production that determines the feasibility of the process. The substrate should (1) be carbohydrate-rich, (2) originate from renewable resources, (3) suffice for fermentation, and (4) promote energetically favorable energy recovery. In addition, any necessary pretreatment should be inexpensive (Wang and Wan, 2009Wang J, Wan W (2009) Factors influencing fermentative hydrogen production: A review. Int J Hydrogen Energy 34:799–811.; Chaubey et al., 2013Chaubey R, Sahu S, James OO et al. (2013) A review on development of industrial processes and emerging techniques for production of hydrogen from renewable and sustainable sources. Renew Sust Energ Rev 23:443–462.). In this context, several investigators have turned to lignocellulosic materials to produce H₂ (Kapdan and Kargi, 2006Kapdan IK, Kargi F (2006) Bio-hydrogen production from waste materials Enz Microb Technol 38:569–582.; Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.; Lin et al., 2012Lin CY, Lay CH, Sen B et al. (2012) Fermentative hydrogen production from wastewaters: A review and prognosis. Int J Hydrogen Energy 37:15632–15642.). According to Kotay and Das (2008)Kotay SM, Das D (2008) Biohydrogen as a renewable energy resource - Prospects and potentials. Int J Hydrogen Energy 33:258–263., if the use of these resources is appropriately controlled, they will become a major source of energy in the future. Unfortunately, these residues have a complex chemical structure and often call for previous treatment and/or hydrolysis to serve as substrate for biological H₂ production. Such pretreatment and/or hydrolysis could not only alter the physicochemical features of the waste, making carbohydrates available for fermentation, but also afford byproducts that negatively interfere in fermentative H₂ production.

This review compares the yields of fermentative H₂ production from (1) different agroindustrial lignocellulosic substrates without any chemical or biological pretreatment (2) lignocellulosic materials after a pretreatment step and (3) hydrolysates of lignocellulosic materials originating from a pretreatment step followed by enzymatic hydrolysis. The comparison of these results will show how the pretreatment and hydrolysis of lignocellulosic substrates affect fermentative H₂ production. In addition, this review will present the microorganisms involved in H₂ production from those materials.

Lignocellulosic Materials as Substrate for Fermentative H₂ Production

Lignocellulosic materials are the most abundant residues derived from agroindustrial activities; therefore, they can potentially become a significant source of renewable H₂ (Saratale et al., 2008Saratale G, Chen SD, Lo YC et al. (2008) Outlook of biohydrogen production from lignocellulosic feedstock using dark fermentation - a review. J Sci Ind Res 67:962–979.; Levin et al., 2009Levin DB, Carere CR, Cicek N et al. (2009) Challenges for biohydrogen production via direct lignocellulose fermentation. Int J Hydrogen Energy 34:7390–7403.; Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.; Cheng et al., 2011Cheng CL, Lo YC, Lee KS et al. (2011) Biohydrogen production from lignocellulosic feedstock. Bioresour Technol 102:8514–8523.; Hay et al., 2013Hay JXW, Wu TY, Juan JC et al. (2013) Biohydrogen production through photo fermentation or dark fermentation using waste as a substrate: Overview, economics, and future prospects of hydrogen usage. Biofuels Bioprod Bioref 7:334–352.). Agricultural residues from harvested crops are the cheapest and the most abundant readily available lignocellulosic organic waste; they include straw, stover, peelings, cobs, stalks, and bagasse (Guo et al., 2010aGuo XM, Trably E, Latrille E et al. (2010a) Hydrogen production from agricultural waste by dark fermentation: A review. Int J Hydrogen Energy 35:10660–10673.; Cheng et al., 2011Cheng CL, Lo YC, Lee KS et al. (2011) Biohydrogen production from lignocellulosic feedstock. Bioresour Technol 102:8514–8523.; Li et al., 2012Li YC, Liu YF, Chu CY et al. (2012) Techno-economic evaluation of biohydrogen production from wastewater and agricultural waste. Int J Hydrogen Energy 37:15704–15710.). All these residues can undergo biological transformations to varying degrees, as well as conversion to hydrogen (Guo et al., 2010aGuo XM, Trably E, Latrille E et al. (2010a) Hydrogen production from agricultural waste by dark fermentation: A review. Int J Hydrogen Energy 35:10660–10673.).

Researchers have investigated several agroindustrial wastes for H₂ production. Cornstalk (Cao et al., 2009Cao G, Ren N, Wang A et al. (2009) Acid hydrolysis of corn stover for biohydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Int J Hydrogen Energy 34:7182–7188.; Cao et al., 2012Cao GL, Guo WQ, Wang AJ et al. (2012) Enhanced cellulosic hydrogen production from lime-treated cornstalk wastes using thermophilic anaerobic microflora. Int J Hydrogen Energy 37:13161–13166.; Cheng et al., 2012Cheng XY, Li Q, Liu CZ (2012) Coproduction of hydrogen and methane via anaerobic fermentation of cornstalk waste in continuous stirred tank reactor integrated with up-flow anaerobic sludge bed. Bioresour Technol 114:327–333.; Song et al., 2012Song ZX, Wang ZY, Wu LY et al. (2012) Effect of microwave irradiation pretreatment of cow dung compost on bio-hydrogen process from corn stalk by dark fermentation. Int J Hydrogen Energy 37:6554–6561.; Zhao et al., 2013Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.), wheat straw (Fan et al., 2006Fan YT, Zhang YH, Zhang SF et al. (2006) Efficient conversion of wheat straw wastes into biohydrogen gas by cow dung compost. Bioresour Technol 97:500–505.; Kaparaju et al., 2009Kaparaju P, Serrano M, Angelidaki I (2009) Effect of reactor configuration on biogas production from wheat straw hydrolysate. Bioresour Technol 100:6317–6323.; Kongjan and Angelidaki, 2010Kongjan P, Angelidaki I (2010) Extreme thermophilic biohydrogen production from wheat straw hydrolysate using mixed culture fermentation: Effect of reactor configuration. Bioresour Technol 101:7789–7796.; Nasirian et al., 2011Nasirian N, Almassi M, Minaei S et al. (2011) Development of a method for biohydrogen production from wheat straw by dark fermentation. Int J Hydrogen Energy 36:411–420., Quemeneur et al., 2012aQuemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647.) and sugarcane bagasse (Pattra et al., 2008Pattra S, Sangyoka S, Boonmee M et al. (2008) Bio-hydrogen production from the fermentation of sugarcane bagasse hydrolysate by Clostridium butyricum. Int J Hydrogen Energy 33:5256–5265.; Chairattanamanokorn et al., 2009Chairattanamanokorn P, Penthamkeerati P, Reungsang A et al. (2009) Production of biohydrogen from hydrolyzed bagasse with thermally preheated sludge. Int J Hydrogen Energy 34:7612–7617.; Fangkum and Reungsang, 2011Fangkum A, Reungsang A (2011) Biohydrogen production from sugarcane bagasse hydrolysate by elephant dung: Effects of initial pH and substrate concentration. Int J Hydrogen Energy 36:8687–8696.) are the most cited in the literature.

Lignocellulosic materials consist primarily of cellulose, hemicelluloses, and lignin. Thus, the main products of the enzymatic, chemical, or thermochemical hydrolysis of lignocellulosic materials are hexoses, mainly glucose, and pentose sugars, mainly xylose.

In addition to H₂, the anaerobic digestion of glucose by strict anaerobes or facultative microorganisms yields different final products. Depending on the bacterial species, pH, and H₂ partial pressure, the fermentation of glucose can result in H₂, CO₂, acetate and/or butyrate (Eqs. 1 and 2). Theoretically, when the final product is acetate only, 4 mol of H₂/mol of glucose can emerge (Eq. 1). However, if the final product is butyrate, only 2 mol of H₂/mol of glucose arises (Eq. 2).

Xylose is the major pentose derived from the hydrolysis of hemicelluloses, which in turn constitutes approximately 20 to 30% of plant biomass. It can be used for the growth and energy production of numerous microorganisms. The use of xylose as a substrate for ethanol production has been extensively studied (Sun and Cheng, 2002Sun Y, Cheng JY (2002) Hydrolysis of lignocellulosic materials for ethanol production: a review. Bioresour Technol 83:1–11.; Lin and Tanaka 2006Lin Y, Tanaka S (2006) Ethanol fermentation from biomass resources: current state and prospects. Appl Microbiol Biotechnol 69:627–642.; Sarks et al., 2014Sarks C, Jin M, SatoTK et al. (2014) Studying the rapid bioconversion of lignocellulosic sugars into ethanol using high cell density fermentations with cell recycle. Biotechnol Biofuels 15:73–80.). However, only recently has attention been given to H₂ production from xylose fermentation. Theoretically, similarly to glucose fermentation, xylose fermentation can produce 3.33 mol H₂/mol xylose when acetate is the fermentation product (Eq. 3). When butyrate is the fermentation product, 1.66 mol of H₂/mol of xylose will emerge (Eq. 4) (Martin del Campo et al., 2013Martin del Campo JS, Rollin J, Myung S et al. (2013) High-yield production of dihydrogen from xylose by using a synthetic enzyme cascade in a cell-free system. Angew Chem Int Ed 52:1–5.).

(1)

C_{6} H_{12} O_{6} + 2 H_{2} O \to 2 {CH}_{3} {COO}^{-} + 2 {CO}_{2} + 4 H_{2}

(2)

C_{6} H_{12} O_{6} \to {CH}_{3} {CH}_{2} {CH}_{2} {COO}^{-} + 2 {CO}_{2} + 2 H_{2}

(3)

C_{5} H_{10} O_{5} + 1.66 H_{2} O \to 1.66 {CH}_{3} {COO}^{-} + 1.66 {CO}_{2} + 3.33 H_{2}

(4)

C_{5} H_{10} O_{5} + 1.66 H_{2} O \to 1.66 {CH}_{3} {CH}_{2} {CH}_{2} {COO}^{-} + 1.66 {CO}_{2} + 1.66 H_{2}

Figure 1 shows the main steps of the metabolic pathways and enzymes leading to H₂ production throughout glucose and xylose fermentation performed by anaerobic microorganisms. The figure shows that the enzyme xylose isomerase (XI) catalyzes the isomerization of xylose to xylulose. The latter is then phosphorylated by xylulokinase (XK), to afford xylulose-5-phosphate, one of the intermediates of the pentose phosphate (PP) pathway. Through the activities of epimerase, isomerase, transketolases, and transaldolases, enzymes of the PP pathway, xylulose-5-phosphate is converted to fructose-6-phosphate and glyceraldehyde-3-phosphate. Both of these compounds are intermediates of the EMP pathway, through which they undergo conversion to pyruvate. The supposed activities of pyruvate, ferredoxin oxyreductase (PFOR) and ferredoxin-dependent hydrogenase (Hyd) will produce H₂, CO₂, and acetate.

Figure 1
Schematic view of the major metabolic pathways that lead to the production of H₂, CO₂, and acetate from the carbohydrate components obtained from the hydrolysis of lignocellulosic materials. EMP, Embden-Meyerhoff-Parma; Fd, oxidized ferredoxin; FdH₂, reduced ferredoxin; Hyd, hydrogenase; PFOR, pyruvate: ferredoxin oxyreductase; PP, pentose phosphate; XI, xylose isomerase; XK, xylulokinase. The dashed arrows indicate multisteps of a metabolic pathway.

According to the Figure 1, glucose is converted to pyruvate, from which H₂, CO₂, and acetate are produced, as outlined above. It is noteworthy that for both carbohydrates, the consumption of reducing power to generate butyrate instead of acetate reduces the H₂ yield.

To produce H₂ by fermentation, it is possible to use (1) lignocellulosic materials without any chemical or biological pretreatment, (2) lignocellulosic materials after a pretreatment step, or (3) hydrolysates of lignocellulosic materials that normally originate after a pretreatment step followed by enzymatic hydrolysis. Another approach is to conduct simultaneous saccharification and fermentation (SSF), which consists in adding a hydrolytic enzyme(s) or microorganisms to a fermentation vessel (Quemeneur et al., 2012aQuemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647.).

Pretreatment of Lignocellulosic Materials for Fermentative H₂ Production

The complex nature of lignocellulosic substrates may adversely affect their biodegradability. Therefore, prehydrolysis, often referred to as pretreatment, is required to alter the structure of lignocellulosic biomass to make the sugars available for fermentation (Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060., Levin et al., 2009Levin DB, Carere CR, Cicek N et al. (2009) Challenges for biohydrogen production via direct lignocellulose fermentation. Int J Hydrogen Energy 34:7390–7403.). Carbohydrate polymers (cellulose and hemicellulose) and lignin are the main components of lignocellulosic materials (Rezende et al., 2011Rezende CA, de Lima MA, Maziero P et al. (2011) Chemical and morphological characterization of sugarcane bagasse submitted to a delignification process for enhanced enzymatic digestibility. Biotechnol Biofuels 4:1–18.; Mood et al., 2013Mood SH, Golfeshan AH, Tabatabaei M et al. (2013) Lignocellulosic biomass to bioethanol, a comprehensive review with a focus on pretreatment. Renew Sust Energy Rev 27:77–93.). Agricultural residues such as wheat straw, corn stalk, sugarcane bagasse, and rice straw contain approximately 32–47% cellulose, 19–27% hemicellulose, and 5–24% lignin (Sun and Cheng, 2002Sun Y, Cheng JY (2002) Hydrolysis of lignocellulosic materials for ethanol production: a review. Bioresour Technol 83:1–11.). Although hemicellulose and lignin are minor components, they protect cellulose. Hence, it is necessary to hydrolyze these components, to efficiently use the cellulose (Mosier et al., 2005Mosier N, Wyman C, Dale B et al. (2005) Features of promising technologies for pretreatment of lignocellulosic biomass. Bioresour Technol 96:673–686.; Rezende et al., 2011Rezende CA, de Lima MA, Maziero P et al. (2011) Chemical and morphological characterization of sugarcane bagasse submitted to a delignification process for enhanced enzymatic digestibility. Biotechnol Biofuels 4:1–18.). Thus, appropriate pretreatment steps reduce the cellulose crystallinity and/or polymerization degree and selectively remove hemicellulose and lignin to make carbohydrates from lignocellulosic materials accessible for enzymatic hydrolysis (Mood et al., 2013Mood SH, Golfeshan AH, Tabatabaei M et al. (2013) Lignocellulosic biomass to bioethanol, a comprehensive review with a focus on pretreatment. Renew Sust Energy Rev 27:77–93.; Monlau et al., 2013aMonlau F, Barakat A, Trably E et al. (2013a) Lignocellulosic Materials Into Biohydrogen and Biomethane: Impact of Structural Features and Pretreatment. Crit Rev Env Sci Technol 43:260–322.).

The main pretreatment methods rely on mechanical, physical, chemical, and biological techniques or a combination thereof (Alvira et al., 2010Alvira P, Tomás-Pejó E, Ballesteros M et al. (2010) Pretreatment technologies for an efficient bioethanol production process based on enzymatic hydrolysis: A review. Bioresour Technol 101:4851–4861.; Guo et al., 2010bGuo Y, Kim S, Sung S et al. (2010b) Effect of ultrasonic treatment of digestion sludge on bio-hydrogen production from sucrose by anaerobic fermentation. Int J Hydrogen Energy 35:3450–3455.; Ogeda and Petri, 2010Ogeda TL, Petri DFS (2010) Hidrólise Enzimática de Biomassa. Química Nova 36:1549–1558.). These methods serve to prepare lignocellulosic materials for bioethanol production mainly, but most of them also find application in fermentative H₂ production (Guo et al., 2010aGuo XM, Trably E, Latrille E et al. (2010a) Hydrogen production from agricultural waste by dark fermentation: A review. Int J Hydrogen Energy 35:10660–10673.; Mood et al., 2013Mood SH, Golfeshan AH, Tabatabaei M et al. (2013) Lignocellulosic biomass to bioethanol, a comprehensive review with a focus on pretreatment. Renew Sust Energy Rev 27:77–93.; Monlau et al., 2013aMonlau F, Barakat A, Trably E et al. (2013a) Lignocellulosic Materials Into Biohydrogen and Biomethane: Impact of Structural Features and Pretreatment. Crit Rev Env Sci Technol 43:260–322.).

Physicochemical pretreatment includes steam explosion, steam explosion with ammonium, use of organic solvents and supercritical fluids, and use of diluted acids and/or bases (Mosier et al., 2005Mosier N, Wyman C, Dale B et al. (2005) Features of promising technologies for pretreatment of lignocellulosic biomass. Bioresour Technol 96:673–686.; Vargas Betancur and Pereira Jr, 2010Vargas Betancur GJ, Pereira Jr N (2010) Sugar cane bagasse as feedstock for second generation ethanol production. Part I: Diluted acid pretreatment optimization. Elect J Biotechnol 13.; Monlau et al., 2013bMonlau F, Aemig Q, Trably E et al. (2013b) Specific inhibition of biohydrogen-producing Clostridium sp after dilute-acid pretreatment of sunflower stalks. Int J Hydrogen Energy 38:12273–12282.). Biological pretreatment relies on the ability of fungi and bacteria to produce enzymes such as lignin peroxidase and laccase, and hemicellulase, which help to remove lignin and hemicellulose from the lignocellulosic matrix, respectively (Ogeda and Petri, 2010Ogeda TL, Petri DFS (2010) Hidrólise Enzimática de Biomassa. Química Nova 36:1549–1558.).

Various methods for pretreating lignocellulosic material exist; however, it is essential to select a method that minimizes carbohydrate degradation and avoids the formation of inhibitory compounds that are toxic to fermentative microorganisms (Alriksson et al., 2011Alriksson B, Cavka A, Jonsson L (2011) Improving the fermentability of enzymatic hydrolysates of lignocellulose through chemical in-situ detoxification with reducing agents. Bioresour Technol 102:1254–1263.; Rezende et al., 2011Rezende CA, de Lima MA, Maziero P et al. (2011) Chemical and morphological characterization of sugarcane bagasse submitted to a delignification process for enhanced enzymatic digestibility. Biotechnol Biofuels 4:1–18.; Jonsson et al., 2013Jonsson L, Alriksson B, Nilvebrant N-O (2013) Bioconversion of lignocellulose: inhibitors and detoxification. Biotechnol Biofuels 6:16.). Pretreatment at high temperatures rapidly degrades hemicellulose pentoses and to a lesser extent hexoses, producing acetic acid and furfurals, which constitute potential fermentation inhibitors (Alriksson et al., 2011Alriksson B, Cavka A, Jonsson L (2011) Improving the fermentability of enzymatic hydrolysates of lignocellulose through chemical in-situ detoxification with reducing agents. Bioresour Technol 102:1254–1263.; Jonsson et al., 2013Jonsson L, Alriksson B, Nilvebrant N-O (2013) Bioconversion of lignocellulose: inhibitors and detoxification. Biotechnol Biofuels 6:16.).

Figure 2 shows the main carbohydrate degradation products from hemicelluloses and cellulose hydrolysis, i.e., xylose and glucose, as well as furfural, hydroxymethylfurfural (HMF), and organic acids, such as formic and acetic acid (Palmqvist and Hahn-Hagerdal, 2000Palmqvist E, Hahn-Hagerdal B (2000) Fermentation of lignocellulosic hydrolysates. II: inhibitors and mechanisms of inhibition. Bioresour Technol 74:25–33.; Jonsson et al., 2013Jonsson L, Alriksson B, Nilvebrant N-O (2013) Bioconversion of lignocellulose: inhibitors and detoxification. Biotechnol Biofuels 6:16.).

Figure 2
Products and subproducts from the pretreatment of lignocellulosic materials (modified from Jonsson et al., 2013Jonsson L, Alriksson B, Nilvebrant N-O (2013) Bioconversion of lignocellulose: inhibitors and detoxification. Biotechnol Biofuels 6:16.).

Furfural originates from pentose dehydration; its concentration in the liquid phase increases with rising pretreatment temperature, acid concentration, or pretreatment time (Chen et al., 2013Chen R, Wang YZ, Liao Q et al. (2013) Hydrolysates of lignocellulosic materials for biohydrogen production. Bmb Reports 46:244–251.). Furfural may react further, to yield formic acid, or it may polymerize. Hydroxymethylfurfural (HMF) stems from the dehydration of hexoses such as glucose; it can further react to yield levulinic and formic acid (Palmqvist and Hahn-Hagerdal, 2000Palmqvist E, Hahn-Hagerdal B (2000) Fermentation of lignocellulosic hydrolysates. II: inhibitors and mechanisms of inhibition. Bioresour Technol 74:25–33.; Chen et al., 2013Chen R, Wang YZ, Liao Q et al. (2013) Hydrolysates of lignocellulosic materials for biohydrogen production. Bmb Reports 46:244–251.; Jonsson et al., 2013Jonsson L, Alriksson B, Nilvebrant N-O (2013) Bioconversion of lignocellulose: inhibitors and detoxification. Biotechnol Biofuels 6:16.). These inhibitors may interfere with cell functions and osmotic pressure; they can even directly inhibit the acid fermentation pathway (Palmqvist and Hahn-Hagerdal, 2000Palmqvist E, Hahn-Hagerdal B (2000) Fermentation of lignocellulosic hydrolysates. II: inhibitors and mechanisms of inhibition. Bioresour Technol 74:25–33.).

Acetic acid is an inhibitory substance that also exists in hydrolysates. It is formed by the hydrolysis of acetyl groups in hemicellulose and, to some extent, lignin (Klinke et al., 2004Klinke HB, Thomsen AB, Ahring BK (2004) Inhibition of ethanol-producing yeast and bacteria by degradation products produced during pre-treatment of biomass. Appl Microbiol Biotechnol 66:10–26.). In the undissociated form, acetic acid can penetrate the cell membrane and inhibit product formation, disrupting the pH balance at high concentration, inhibiting cell growth or even killing cells (Klinke et al., 2002Klinke H, Ahring B, Schmidt A et al. (2002) Characterization of degradation products from alkaline wet oxidation of wheat straw. Bioresour Technol 82:15–26.). However, some strains can use acetic acid as a substrate to produce H₂ (Matsumoto and Nishimura, 2007Matsumoto M, Nishimura Y (2007) Hydrogen production by fermentation using acetic acid and lactic acid. J Biosc Bioeng 103:236–241.; Xu et al., 2010Xu JF, Ren N, Su DX et al. (2010) Bio-hydrogen production from acetic acid steam-exploded corn straws by simultaneous saccharification and fermentation with Ethanoligenens harbinense B49. Int J Hydrogen Energy 34:381–386.).

Aromatics may arise in hydrolysates depending on the type of pretreatment applied and on the ratio of p-coumaryl alcohol, coniferyl, and sinapyl alcohol, the main lignin monomers. Pretreatment can transform lignin into a complex mixture of low-molecular-weight or "monomeric" phenolic compounds, especially by acid impregnation (Klinke et al., 2004Klinke HB, Thomsen AB, Ahring BK (2004) Inhibition of ethanol-producing yeast and bacteria by degradation products produced during pre-treatment of biomass. Appl Microbiol Biotechnol 66:10–26.; Chen et al., 2013Chen R, Wang YZ, Liao Q et al. (2013) Hydrolysates of lignocellulosic materials for biohydrogen production. Bmb Reports 46:244–251.). Phenolic compounds are well known for being toxic to microbial cells. They bear carboxyl, formyl, and hydroxyl groups, which increase the fluidity of the membrane and affect its permeability (Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.).

In summary, the pretreatment of lignocellulosic material to use it as a substrate for producing H₂ may generate fermentation inhibitors as well as other unusual substrates, such as pentose (xylose) and/or oligosaccharides (Maintinguer et al., 2011Maintinguer SI, Fernandes BS, Duarte ICS (2011) Fermentative hydrogen production with xylose by Clostridium and Klebsiella species in anaerobic batch reactors. Int J Hydrogen Energy 36:13508–13517.; Quemeneur et al., 2012bQuemeneur M, Hamelin J, Barakat A et al. (2012b) Inhibition of fermentative hydrogen production by lignocellulose-derived compounds in mixed cultures. Int J Hydrogen Energy 37:3150–3159.), which is a major drawback.

The use of xylose as a substrate appears to be less problematic than the presence of inhibitory compounds because xylose can be metabolized as illustrated in Figure 1. Indeed a series of H₂-producing microorganisms, such as Clostridium spp. (Maintinguer et al., 2011Maintinguer SI, Fernandes BS, Duarte ICS (2011) Fermentative hydrogen production with xylose by Clostridium and Klebsiella species in anaerobic batch reactors. Int J Hydrogen Energy 36:13508–13517.); Enterobacter spp. CN1 (Long et al., 2010Long C, Cui J, Liu Z et al. (2010) Statistical optimization of fermentative hydrogen production from xylose by newly isolated Enterobacter sp CN1. Int J Hydrogen Energy 35:6657–6664.); and the thermophiles Thermoanaerobacterium saccharolyticum (Ren et al., 2008Ren N, Wang A, Gao L et al. (2008) Bioaugmented hydrogen production from carboxymethyl cellulose and partially delignified corn stalks using isolated cultures. Int J Hydrogen Energy 33:5250–5255.; Shaw et al., 2008Shaw AJ, Jenney FE Jr, Adams MWW et al. (2008) End-product pathways in the xylose fermenting bacterium Thermoanaerobacterium saccharolyticum. Enzyme Microb Technol 42:453–458.), Thermotoga neapolitana DSM 4359 (Ngo et al., 2012Ngo TA, Nguyen TH, Bui BTV (2012) Thermophilic fermentative hydrogen production from xylose by Thermotoga neapolitana DSM 4359. Renew Energy 37:174–179.), Caldicellulosiruptor saccharolyticus (de Vrije et al., 2009de Vrije T, Bakker RR, Budde MAW et al. (2009) Efficient hydrogen production from the lignocellulosic energy crop Miscanthus by the extreme thermophilic bacteria Caldicellulosiruptor saccharolyticus and Thermotoga neapolitana. Biotechnol Biofuels 2,12. http://www.biotechnologyforbiofuels.com/content/2/1/12
http://www.biotechnologyforbiofuels.com/... ) and Thermoanaerobacterium thermosaccharolyticum (Khamtib and Reungsang, 2012Khamtib S, Reungsang A (2012) Biohydrogen production from xylose by Thermoanaerobacterium thermosaccharolyticum KKU19 isolated from hot spring sediment. Int J Hydrogen Energy 37:12219–12228.), can consume and produce hydrogen from xylose. Ren et al. (2008)Ren N, Wang A, Gao L et al. (2008) Bioaugmented hydrogen production from carboxymethyl cellulose and partially delignified corn stalks using isolated cultures. Int J Hydrogen Energy 33:5250–5255. reported that T. saccharolyticum W16 can ferment a mixture of glucose and xylose with a H₂ yield of up to 2.37 mol of H₂/mol of substrate.

However, inhibitors such as furan derivatives and phenolic compounds negatively affect H₂ production by mixed cultures. According to Quéméneur et al. (2012)Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647., furans exert a more negative effect than that induced by phenolic compounds. These authors found that Clostridium beijerinckii strains resisted these inhibitors better than other clostridial and non-clostridial bacteria did; therefore, C. beijerinckii is a promising microorganism for H₂ production from lignocellulosic hydrolysates. Tai et al. (2010)Tai J, Adav SS, Su A et al. (2010) Biological hydrogen production from phenol-containing wastewater using Clostridium butyricum. Int J Hydrogen Energy 35:13345–13349. observed that higher phenol concentrations (1 g/L) significantly inhibited C. butyricum metabolism. Nevertheless, no metabolic inhibition or co-degradation occurred at concentrations of approximately 0.6 g/L. Veeravalli et al. (2013)Veeravalli SS, Chaganti SR, Lalman JA et al. (2013) Effect of furans and linoleic acid on hydrogen production. Int J Hydrogen Energy 38:12283–12293. observed that furans affected fermentative H₂ production by a mixed anaerobic culture. Furan levels of up to 1 g/L favored propionate and ethanol generation, decreasing H₂ production.

In conclusion, the main limitation of using pretreated lignocellulosic materials in fermentative H₂ production is the presence of these inhibitors.

H₂ Production From Non-Pretreated Lignocellulosic Materials

Because pretreatment processes are expensive and can produce inhibitory compounds, it would be beneficial to avoid pretreatment and directly convert lignocellulosic materials to H₂ (Levin et al., 2009Levin DB, Carere CR, Cicek N et al. (2009) Challenges for biohydrogen production via direct lignocellulose fermentation. Int J Hydrogen Energy 34:7390–7403.; Raj et al., 2012Raj SM, Talluri S, Christopher LP (2012) Thermophilic Hydrogen Production from Renewable Resources: Current Status and Future Perspectives. Bioenergy Res 5:515–531.).

Only a few reports concerning the production of H₂ from untreated lignocellulosic feedstocks exist in the literature (Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.), and most of them involve thermophilic microorganisms. For example, Clostridium thermocellum ATCC 27405 and C. saccharolyticus DSM 8903 can hydrolyze cellulose and hemicellulose to produce H₂ (Raj et al., 2012Raj SM, Talluri S, Christopher LP (2012) Thermophilic Hydrogen Production from Renewable Resources: Current Status and Future Perspectives. Bioenergy Res 5:515–531.).

C. saccharolyticus can produce H₂ directly from mechanically comminuted switchgrass without any chemical or biological pretreatment (Talluri et al., 2013Talluri S, Raj SM, Christopher LP (2013) Consolidated bioprocessing of untreated switchgrass to hydrogen by the extreme thermophile Caldicellulosiruptor saccharolyticus DSM 8903. Bioresour Technol 139:272–279.).

Some authors have resorted to co-cultures that allow for the use of lignocellulosic materials as substrates. Wang et al. (2008)Wang A, Ren N, Shi Y et al. (2008) Bioaugmented hydrogen production from microcrystalline cellulose using co-culture - Clostridium acetobutylicum X-9 and Ethanoligenens harbinense B-49. Int J Hydrogen Energy 33:912–917. reported that a co-culture consisting of Clostridium acetobutylicum and Ethanoigenens harbinense effectively hydrolyzed cellulose and produced H₂ from microcrystalline cellulose. Li and Liu (2012)Li Q, Liu CZ (2012) Co-culture of Clostridium thermocellum and Clostridium thermosaccharolyticum for enhancing hydrogen production via thermophilic fermentation of cornstalk waste. Int J Hydrogen Energy 37:10648–10654. developed a co-culture of C. thermocellum and C. thermosaccharolyticum, to improve hydrogen production via the thermophilic fermentation of cornstalk waste. The authors achieved a hydrogen yield of 68.2 mL of H₂/g of cornstalk, 94.1% higher than the yield obtained using a monoculture of C. thermocellum.

Table 1 lists results for fermentative H₂ production from lignocellulosic materials without any chemical pretreatment, the employed inocula, and the H₂ yield obtained from these substrates. The results are presented as maximum assessed production yield, as indicated by the authors; when possible, we converted the data and expressed them as maximum calculated production yield (mmol of H₂/g of substrate) for comparison. All the wastes included in Table 1 were milled before being assayed.

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Table 1
Fermentative H₂ production from lignocellulosic residues without pretreatment: employed inoculum and H₂ yield obtained from these substrates.

The temperature clearly affected the fermentative H₂ production yield from lignocellulosic residues. Most of the studies that used untreated lignocellulosic materials employed thermophilic conditions (10, n = 14) to provide yields approximately 75% higher than those obtained under mesophilic conditions. Although most studies employed a mixed culture as an inoculum, C. thermocellum and T. thermosaccharolyticum, previously known as C. thermosaccharolyticum were the thermophilic microorganisms most frequently employed to produce H₂ from untreated feedstock.

The untreated raw materials presented in Table 1 afforded an average maximum calculated H₂ production yield of 2.17 (± 1.84) mmol of H₂/g of substrate; yields ranged from 0.12 to 11.2 mmol of H₂/g of substrate. The only study on switchgrass furnished the highest yield − 11.2 mmol of H₂/g of substrate (Talluri et al., 2013Talluri S, Raj SM, Christopher LP (2013) Consolidated bioprocessing of untreated switchgrass to hydrogen by the extreme thermophile Caldicellulosiruptor saccharolyticus DSM 8903. Bioresour Technol 139:272–279.). When we excluded this study from the calculations, the average H₂ production yield from untreated lignocellulosic substrates decreased to 1.41 (± 1.02) mmol of H₂/g, where the highest average yield observed was that obtained for cornstalk − 2.16 (± 1.17) mmol of H₂/g.

H₂ Production From Pretreated Lignocellulosic Materials

Although some studies on the direct conversion of lignocellulosic materials to H₂ exist, most microorganisms require pretreated lignocellulosic material as a substrate to produce biohydrogen. The degree of pretreatment depends on the nature of the raw material and on the inoculated organism(s) (Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.).

Most pretreatment steps generate undesirable inhibitors, but they significantly enhance H₂ production. Zhang et al. (2007)Zhang M-L, Fan Y-T, Xing Y et al. (2007) Enhanced biohydrogen production from cornstalk wastes with acidification pretreatment by mixed anaerobic cultures. Biomass Bioenergy 31:250–254. improved biohydrogen production from cornstalk after acidification and heat pretreatment. The authors achieved maximum cumulative H₂ production of 150 mL of H₂/g of VS after treating the substrate with 0.2% HCl; this production was 50 times higher than the value obtained without pretreatment. Cornstalks treated with NaOH (0.5%) furnished 57 mL of H₂/g of VS, i.e., 19-fold the initial value obtained for the raw material (3 mL of H₂/g of VS) (Zhang et al., 2007Zhang M-L, Fan Y-T, Xing Y et al. (2007) Enhanced biohydrogen production from cornstalk wastes with acidification pretreatment by mixed anaerobic cultures. Biomass Bioenergy 31:250–254.).

Table 2 summarizes literature results concerning the use of pretreated lignocellulosic wastes, the pretreatment type, the inoculum, and the H₂ yield obtained from these substrates. The results shown in Table 2 refer to the maximum assessed production yield, as indicated by the authors; when possible, we converted the data and expressed them as maximum calculated production yield (mmol H₂/g of substrate) for comparison.

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Table 2
Fermentative H₂ production from pretreated lignocellulosic residues, pretreatment type, inoculum, and H₂ yield obtained from these substrates.

Acid and base pretreatment have been the pretreatments most frequently employed to prepare lignocellulosic materials for biohydrogen production − 11 and 6 studies, respectively, from the 21 publications presented in Table 2 have been reported. Enzymatic and/or biological pretreatment represent 3 of the 21 studies shown in Table 2. Only one study involved the use of temperature alone.

As indicated by the maximum calculated production yield data presented in Table 2, the biological pretreatment afforded the highest average yield 4.54 (± 1.78) mmol of H₂/g of substrate compared with the acid and basic pretreatment (2.94 ± 1.85 and 2.41 ± 1.52 mmol of H₂/g of substrate, respectively). Therefore, pretreatment effectiveness depended on the feedstock and pretreatment conditions, such as acid or base concentration, exposure time, and temperature.

According to Table 2, the average H₂ production yield from pretreated material was 3.17 (± 1.79), ranging from 0.68 to 8.11 mmol of H₂/g of substrate for corn stover and cornstalk, respectively. Pretreated cornstalk furnished the highest average yield 4.74 (± 1.80) mmol of H₂/g of substrate, which was approximately 2.2 times higher that yielded by untreated cornstalk (2.17 ± 1.84 mmol of H₂/g of substrate, Table 1). Therefore, the pretreatment step enhances H₂ production.

Most studies used a mixed culture of microorganisms previously enriched with H₂-producing bacteria as an inoculum. The thermophilic T. thermosaccharolyticum was the pure culture most frequently employed in the studies using pretreated lignocellulosic wastes as substrates.

H₂ Production From Lignocellulosic Materials Hydrolysates

The structural changes that prehydrolysis (pretreatment) promotes in a lignocellulosic matrix positively affect the subsequent enzymatic hydrolysis of lignocellulosic materials, increasing the saccharification yield (Ren et al., 2009Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.). Several authors have used this strategy to increase the concentration of sugars in hydrolysates for H₂ production (de Vrije et al., 2009de Vrije T, Bakker RR, Budde MAW et al. (2009) Efficient hydrogen production from the lignocellulosic energy crop Miscanthus by the extreme thermophilic bacteria Caldicellulosiruptor saccharolyticus and Thermotoga neapolitana. Biotechnol Biofuels 2,12. http://www.biotechnologyforbiofuels.com/content/2/1/12
http://www.biotechnologyforbiofuels.com/... ; Cui et al., 2010Cui M, Yuan Z, Zhi X et al. (2010) Biohydrogen production from poplar leaves pretreated by different methods using anaerobic mixed bacteria. Int J Hydrogen Energy 35:4041–4047.; Luo et al., 2011Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.; Pan et al., 2011Pan CM, Ma HC, Fan YT et al. (2011) Bioaugmented cellulosic hydrogen production from cornstalk by integrating dilute acid-enzyme hydrolysis and dark fermentation. Int J Hydrogen Energy 36:4852–4862.; Monlau et al., 2013bMonlau F, Aemig Q, Trably E et al. (2013b) Specific inhibition of biohydrogen-producing Clostridium sp after dilute-acid pretreatment of sunflower stalks. Int J Hydrogen Energy 38:12273–12282.). Pan et al. (2011)Pan CM, Ma HC, Fan YT et al. (2011) Bioaugmented cellulosic hydrogen production from cornstalk by integrating dilute acid-enzyme hydrolysis and dark fermentation. Int J Hydrogen Energy 36:4852–4862. pretreated cornstalk containing 81.7% TVS with dilute acid, i.e., 1.5% H₂SO₄, at 121 °C for 60 min, followed by enzymatic hydrolysis at 52 °C, pH 4.8, with an enzyme loading of 9.4 IU/g, to obtain a total soluble sugar content of 562.1 ± 6.9 mg/g of TVS during the stages of hydrolysis. The maximum hydrogen yield from this hydrolysate using an anaerobic mixed culture was calculated in terms of grams of cornstalk (TVS) as 209.8 mL of H₂/g of TVS.

Pretreatment followed by enzymatic hydrolysis is a very efficient method for saccharifying lignocellulosic substrates. However, depending on the type of substrate and pretreatment conditions employed, the hydrolysates could inhibit fermentative H₂ production. Monlau et al. (2013b)Monlau F, Aemig Q, Trably E et al. (2013b) Specific inhibition of biohydrogen-producing Clostridium sp after dilute-acid pretreatment of sunflower stalks. Int J Hydrogen Energy 38:12273–12282. verified that hydrolysates from sunflower stalks pretreated with dilute acid negatively affected H₂-producing microflora. The dilute acid pretreatment condition that these authors employed (170 °C, 1 h, 4 g of HCl/100 g of TS) was highly efficient in hydrolyzing hemicellulosic material because approximately 3.14 g/L of xylose and only 0.28 g/L of glucose emerged in the slurry. In addition to the amount of xylose, other byproducts arose - formate (0.6 g/L) and acetate (0.81 g/L), and furan derivatives such as furfural (1.15 g/L) and HMF (0.13 g/L). In a batch system inoculated with mixed microflora, 15% of this hydrolysate completely inhibited H₂ production.

In a long-term experiment, Arreola-Vargas et al. (2013)Arreola-Vargas J, Celis LB, Buitrón G et al. (2013) Hydrogen production from acid and enzymatic oat straw hydrolysates in an anaerobic sequencing batch reactor: Performance and microbial population analysis. Int J Hydrogen Energy 38:13884–13894. observed that partial replacement of a synthetic medium containing glucose and xylose with an acid and with an enzymatic hydrolysate of oat straw, in a continuous reactor, diminished H₂ production. The acid hydrolysate consisted mainly of glucose 1.5 g/L and xylose 3.7 g/L as well as phenolic compounds, such as HMF (133.2 mg/L), furfural (0.6 mg/L), and vanillin (3.59 mg/L). The enzymatic hydrolysate contained 3.8 g/L of glucose and 1.3 g/L of xylose, but no HMF, furfural, or vanillin. Both hydrolysates were used to feed an anaerobic sequencing batch reactor by gradually substituting the glucose/xylose medium with the hydrolysates. The substitution of glucose/xylose by the acid hydrolysate disaggregated the granules and interrupted the process. On the other hand, the replacement of the glucose/xylose medium with the enzymatic hydrolysate without fermentation inhibitors elicited H₂ production. However, the H₂ yield and production rate decreased from 2 mol of H₂/mol of sugar and 278 mL of H₂/L.h to 0.81 mol of H₂/mol of sugar and 29.6 mL H₂/L.h, respectively, in going from the synthetic medium to the enzymatic hydrolysate (Arreola-Vargas et al., 2013Arreola-Vargas J, Celis LB, Buitrón G et al. (2013) Hydrogen production from acid and enzymatic oat straw hydrolysates in an anaerobic sequencing batch reactor: Performance and microbial population analysis. Int J Hydrogen Energy 38:13884–13894.).

Simultaneous saccharification and fermentation (SSF) has been successfully conducted to produce H₂ from pretreated or even untreated lignocellulosic substrates by adding hydrolytic enzyme(s) or by seeding hydrolytic enzymes produced in the same fermentation vessel. Thus, in this approach, no pretreatments or only mild conditions for pretreating substrates are necessary, diminishing the formation of fermentation inhibitors (see Figure 2) because most saccharification occurs simultaneously with the fermentation (Lakshmidevi and Muthukumar, 2010; Quemeneur et al., 2012aQuemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647.; Zhao et al., 2013Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.). For example, Quemeneur et al. (2012a)Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647. used a mixed culture of microorganisms and evaluated the efficiency of exogenous enzyme addition during fermentative H₂ production from wheat straw. The authors used two experimental designs: a one-stage system (direct enzyme addition) and a two-stage system (enzymatic hydrolysis prior to fermentation). H₂ production from untreated wheat straw ranged from 5.18 to 10.52 mL of H₂/g of vs. H₂ production yields increased two-fold and ranged from 11.06 to 19.63 mL of H₂/g of VS after the enzymatic treatment of the wheat straw. Direct addition of exogenous enzymes during one-stage dark fermentation was the best way to improve H₂ production from lignocellulosic biomass.

Table 3 summarizes the lignocellulosic material hydrolysates used as substrates for fermentative H₂ production, the pretreatment and enzymatic hydrolysis methods used, the source of inoculum or the microorganisms involved in the fermentation, and the process yields and/or rates. Results regarding H₂ yields from hydrolysates are expressed in terms of mmol of H₂/mmol of sugar or mmol of H₂/g of substrate because it was not always possible to convert these units. In the last case, it was possible to compare data with the results of untreated and pretreated substrates (Table 1 and 2).

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Table 3
Fermentative H₂ production from hydrolysates of lignocellulosic substrates according to pretreatment type and enzymatic hydrolysis, inocula, yields, and maximum production rate obtained from these substrates.

According to Table 3 the H₂ production yields from hydrolysates ranged from 0.45 to 13.39 mmol of H₂/g of substrate, for wheat straw and sugarcane bagasse, respectively.

Cornstalk is the most often studied lignocellulosic substrate for H₂ production. The average yield using a cornstalk hydrolysate for biohydrogen production is 5.93 mmol of H₂/g of substrate, which is approximately 270% and 25% higher than that afforded by the untreated (2.17 mmol of H₂/g of substrate) and pretreated cornstalk (4.74 mmol of H₂/g of substrate), respectively. The results demonstrated that after pretreatment and/or hydrolysis, this substrate is potentially applicable in biohydrogen production.

Although sugarcane bagasse afforded the highest yield − 13.39 mmol of H₂/g of TVS; this figure represents the results obtained in only one study (Chairattanamanokorn et al., 2009Chairattanamanokorn P, Penthamkeerati P, Reungsang A et al. (2009) Production of biohydrogen from hydrolyzed bagasse with thermally preheated sludge. Int J Hydrogen Energy 34:7612–7617.). The average H₂ production yield per mol of sugar of pretreated bagasse was 1.23 mol of H₂/mol of glucose (Table 2); for the hydrolysates, this yield dropped to 1.12 (Table 3), demonstrating that H₂ production from hydrolysates of this substrate was slightly lower.

Excluding the work of Chairattanamanokorn et al. (2009)Chairattanamanokorn P, Penthamkeerati P, Reungsang A et al. (2009) Production of biohydrogen from hydrolyzed bagasse with thermally preheated sludge. Int J Hydrogen Energy 34:7612–7617. with sugarcane bagasse, the average H₂ production yield with sugarcane bagasse hydrolysates (Table 3) was 3.78 ± 1.92 mmol of H₂/g, 20% higher compared with the average yields of pretreated substrates. However, this average H₂ production yield was lower than that of biologically pretreated substrates, 4.54 ± 1.78 mmol of H₂/g. These results demonstrate the importance of avoiding the presence of inhibitors originating from chemical pretreatment methods.

Conclusions and Perspectives

Based on this review, converting agroindustrial lignocellulosic substrates to H₂ by fermentative microorganisms is a feasible solution for producing H₂ sustainably. However, additional research into the pretreatment of lignocellulosic wastes for biohydrogen production is desirable to improve the yield and make the process economically viable. Efforts to control the formation (or removal) of toxic compounds (such as furan derivatives, phenolics, and organic acids, formed during the chemical pretreatment) are necessary because these could clearly inhibit H₂ fermentation. Biological pretreatment methods afford higher H₂ yields from lignocellulosic materials because they do not produce inhibitors.

The development of microbial strains or consortia resistant to inhibitors remains an important research area. Moreover, the discovery of novel H₂-producing microorganisms able to use lignocellulosic derivatives is associated with different environmental conditions, particularly high temperatures.

Currently, results have shown that corn stalk submitted to a pretreatment step and/or hydrolysis furnishes a higher average yield of biohydrogen production than that afforded by other agroindustrial lignocellulosic substrates. Exploring other microorganisms and optimizing the pretreatment and hydrolysis conditions can make the use of this substrate and other agroindustrial residues a sustainable way to produce clean H₂.

Acknowledgments

FAPESP (2010-2010/11901-0), CNPq.

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Lakaniemi AM, Koskinen PEP, Nevatalo LM et al. (2011) Biogenic hydrogen and methane production from reed canary grass. Biomass Bioenergy 35:773–780.
Lay CH, Sung IY, Kumar G et al. (2012) Optimizing biohydrogen production from mushroom cultivation waste using anaerobic mixed cultures. Int J Hydrogen Energy 37:16473–16478.
Levin DB, Carere CR, Cicek N et al. (2009) Challenges for biohydrogen production via direct lignocellulose fermentation. Int J Hydrogen Energy 34:7390–7403.
Levin DB, Pitt L, Love M (2004) Biohydrogen production: prospects and limitations to practical application. Int J Hydrogen Energy 29:173–185.
Li C, Fang H (2007) Fermentative hydrogen production from wastewater and solid wastes by mixed cultures. Crit Rev Environ Sci Technol 37:1–39.
Li Q, Liu CZ (2012) Co-culture of Clostridium thermocellum and Clostridium thermosaccharolyticum for enhancing hydrogen production via thermophilic fermentation of cornstalk waste. Int J Hydrogen Energy 37:10648–10654.
Li YC, Liu YF, Chu CY et al. (2012) Techno-economic evaluation of biohydrogen production from wastewater and agricultural waste. Int J Hydrogen Energy 37:15704–15710.
Lin CY, Lay CH, Sen B et al. (2012) Fermentative hydrogen production from wastewaters: A review and prognosis. Int J Hydrogen Energy 37:15632–15642.
Lin Y, Tanaka S (2006) Ethanol fermentation from biomass resources: current state and prospects. Appl Microbiol Biotechnol 69:627–642.
Liu CZ, Cheng XY (2010) Improved hydrogen production via thermophilic fermentation of corn stover by microwave-assisted acid pretreatment. Int J Hydrogen Energy 35:8945–8952.
Lo YC, Lu WC, Chen CY et al. (2010) Dark fermentative hydrogen production from enzymatic hydrolysate of xylan and pretreated rice straw by Clostridium butyricum CGS5. Bioresour Technol 101:5885–5891.
Lo YC, Su YC, Cheng CL et al. (2011) Biohydrogen production from pure and natural lignocellulosic feedstock with chemical pretreatment and bacterial hydrolysis. Int J Hydrogen Energy 36:13955–13963.
Long C, Cui J, Liu Z et al. (2010) Statistical optimization of fermentative hydrogen production from xylose by newly isolated Enterobacter sp CN1. Int J Hydrogen Energy 35:6657–6664.
Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.
Maintinguer SI, Fernandes BS, Duarte ICS (2011) Fermentative hydrogen production with xylose by Clostridium and Klebsiella species in anaerobic batch reactors. Int J Hydrogen Energy 36:13508–13517.
Martin del Campo JS, Rollin J, Myung S et al. (2013) High-yield production of dihydrogen from xylose by using a synthetic enzyme cascade in a cell-free system. Angew Chem Int Ed 52:1–5.
Matsumoto M, Nishimura Y (2007) Hydrogen production by fermentation using acetic acid and lactic acid. J Biosc Bioeng 103:236–241.
Monlau F, Barakat A, Trably E et al. (2013a) Lignocellulosic Materials Into Biohydrogen and Biomethane: Impact of Structural Features and Pretreatment. Crit Rev Env Sci Technol 43:260–322.
Monlau F, Aemig Q, Trably E et al. (2013b) Specific inhibition of biohydrogen-producing Clostridium sp after dilute-acid pretreatment of sunflower stalks. Int J Hydrogen Energy 38:12273–12282.
Mood SH, Golfeshan AH, Tabatabaei M et al. (2013) Lignocellulosic biomass to bioethanol, a comprehensive review with a focus on pretreatment. Renew Sust Energy Rev 27:77–93.
Mosier N, Wyman C, Dale B et al. (2005) Features of promising technologies for pretreatment of lignocellulosic biomass. Bioresour Technol 96:673–686.
Nasirian N, Almassi M, Minaei S et al. (2011) Development of a method for biohydrogen production from wheat straw by dark fermentation. Int J Hydrogen Energy 36:411–420.
Ngo TA, Nguyen TH, Bui BTV (2012) Thermophilic fermentative hydrogen production from xylose by Thermotoga neapolitana DSM 4359. Renew Energy 37:174–179.
Nguyen T-AD, Kim K-R, Kim MS et al. (2010) Thermophilic hydrogen fermentation from Korean rice straw by Thermotoga neapolitana Int J Hydrogen Energy 35:13392–13398.
Nissila ME, Li YC, Wu SY et al. (2012) Dark Fermentative Hydrogen Production from Neutralized Acid Hydrolysates of Conifer Pulp. Appl Biochem Biotechnol 168:2160–2169.
Ogeda TL, Petri DFS (2010) Hidrólise Enzimática de Biomassa. Química Nova 36:1549–1558.
Ozkan L, Erguder TH, Demirer GN (2011) Effects of pretreatment methods on solubilization of beet-pulp and biohydrogen production yield. Int J Hydrogen Energy 36:382–389.
Palmqvist E, Hahn-Hagerdal B (2000) Fermentation of lignocellulosic hydrolysates. II: inhibitors and mechanisms of inhibition. Bioresour Technol 74:25–33.
Pan CM, Ma HC, Fan YT et al. (2011) Bioaugmented cellulosic hydrogen production from cornstalk by integrating dilute acid-enzyme hydrolysis and dark fermentation. Int J Hydrogen Energy 36:4852–4862.
Panagiotopoulos IA, Bakker RR, de Vrije T et al. (2010) Pretreatment of sweet sorghum bagasse for hydrogen production by Caldicellulosiruptor saccharolyticus Int J Hydrogen Energy 35:7738–7747.
Pattra S, Sangyoka S, Boonmee M et al. (2008) Bio-hydrogen production from the fermentation of sugarcane bagasse hydrolysate by Clostridium butyricum Int J Hydrogen Energy 33:5256–5265.
Pawar SS, Nkemka VN, Zeidan AA et al. (2013) Biohydrogen production from wheat straw hydrolysate using Caldicellulosiruptor saccharolyticus followed by biogas production in a two-step uncoupled process. Int J Hydrogen Energy 38:9121–9130.
Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647.
Quemeneur M, Hamelin J, Barakat A et al. (2012b) Inhibition of fermentative hydrogen production by lignocellulose-derived compounds in mixed cultures. Int J Hydrogen Energy 37:3150–3159.
Rafrafi Y, Trably E, Hamelin J, et al. (2013) Sub-dominant bacteria as keystone species in microbial communities producing bio-hydrogen. Int J Hydrogen Energy 38:4881–5180.
Raj SM, Talluri S, Christopher LP (2012) Thermophilic Hydrogen Production from Renewable Resources: Current Status and Future Perspectives. Bioenergy Res 5:515–531.
Ren N, Wang A, Gao L et al. (2008) Bioaugmented hydrogen production from carboxymethyl cellulose and partially delignified corn stalks using isolated cultures. Int J Hydrogen Energy 33:5250–5255.
Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.
Ren NQ, Cao GL, Guo WQ et al. (2010) Biological hydrogen production from corn stover by moderately thermophile Thermoanaerobacterium thermosaccharolyticum W16. Int J Hydrogen Energy 35:2708–2712.
Rezende CA, de Lima MA, Maziero P et al. (2011) Chemical and morphological characterization of sugarcane bagasse submitted to a delignification process for enhanced enzymatic digestibility. Biotechnol Biofuels 4:1–18.
Sagnak R, Kargi F, Kapdan IK (2011) Bio-hydrogen production from acid hydrolyzed waste ground wheat by dark fermentation. Int J Hydrogen Energy 36:12803–12809.
Saratale G, Chen SD, Lo YC et al. (2008) Outlook of biohydrogen production from lignocellulosic feedstock using dark fermentation - a review. J Sci Ind Res 67:962–979.
Saripan AF, Reungsang A (2013) Biohydrogen production by Thermoanaerobacterium thermosaccharolyticum KKU-ED1: Culture conditions optimization using xylan as the substrate. Int J Hydrogen Energy 38:6167–6173.
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Shaw AJ, Jenney FE Jr, Adams MWW et al. (2008) End-product pathways in the xylose fermenting bacterium Thermoanaerobacterium saccharolyticum Enzyme Microb Technol 42:453–458.
Show KY, Lee DJ, Tay JH et al. (2012) Biohydrogen production: Current perspectives and the way forward. Int J Hydrogen Energy 37:15616–15631.
Song ZX, Wang ZY, Wu LY et al. (2012) Effect of microwave irradiation pretreatment of cow dung compost on bio-hydrogen process from corn stalk by dark fermentation. Int J Hydrogen Energy 37:6554–6561.
Sun Y, Cheng JY (2002) Hydrolysis of lignocellulosic materials for ethanol production: a review. Bioresour Technol 83:1–11.
Tai J, Adav SS, Su A et al. (2010) Biological hydrogen production from phenol-containing wastewater using Clostridium butyricum Int J Hydrogen Energy 35:13345–13349.
Talluri S, Raj SM, Christopher LP (2013) Consolidated bioprocessing of untreated switchgrass to hydrogen by the extreme thermophile Caldicellulosiruptor saccharolyticus DSM 8903. Bioresour Technol 139:272–279.
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Publication Dates

Publication in this collection
Apr-Jun 2015

History

Received
05 Feb 2014
Accepted
09 Oct 2014

All the content of the journal, except where otherwise noted, is licensed under a Creative Commons License CC BY-NC.

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[33] Khamtib S, Reungsang A (2012) Biohydrogen production from xylose by Thermoanaerobacterium thermosaccharolyticum KKU19 isolated from hot spring sediment. Int J Hydrogen Energy 37:12219–12228.

[34] Kim M, Liu C, Noh JW et al. (2013) Hydrogen and methane production from untreated rice straw and raw sewage sludge under thermophilic anaerobic conditions. Int J Hydrogen Energy 38:8648–8656.

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[38] Kongjan P, O-Thong S, Kotay M et al. (2010) Biohydrogen Production From Wheat Straw Hydrolysate by Dark Fermentation Using Extreme Thermophilic Mixed Culture. Biotechnol Bioeng 105:899–908.

[39] Kotay SM, Das D (2008) Biohydrogen as a renewable energy resource - Prospects and potentials. Int J Hydrogen Energy 33:258–263.

[40] Kothari R, Singh DP, Tyagi VV et al. (2012) Fermentative hydrogen production - An alternative clean energy source. Renew Sust Energ Rev 16:2337–2346.

[41] Lakaniemi AM, Koskinen PEP, Nevatalo LM et al. (2011) Biogenic hydrogen and methane production from reed canary grass. Biomass Bioenergy 35:773–780.

[42] Lay CH, Sung IY, Kumar G et al. (2012) Optimizing biohydrogen production from mushroom cultivation waste using anaerobic mixed cultures. Int J Hydrogen Energy 37:16473–16478.

[43] Levin DB, Carere CR, Cicek N et al. (2009) Challenges for biohydrogen production via direct lignocellulose fermentation. Int J Hydrogen Energy 34:7390–7403.

[44] Levin DB, Pitt L, Love M (2004) Biohydrogen production: prospects and limitations to practical application. Int J Hydrogen Energy 29:173–185.

[45] Li C, Fang H (2007) Fermentative hydrogen production from wastewater and solid wastes by mixed cultures. Crit Rev Environ Sci Technol 37:1–39.

[46] Li Q, Liu CZ (2012) Co-culture of Clostridium thermocellum and Clostridium thermosaccharolyticum for enhancing hydrogen production via thermophilic fermentation of cornstalk waste. Int J Hydrogen Energy 37:10648–10654.

[47] Li YC, Liu YF, Chu CY et al. (2012) Techno-economic evaluation of biohydrogen production from wastewater and agricultural waste. Int J Hydrogen Energy 37:15704–15710.

[48] Lin CY, Lay CH, Sen B et al. (2012) Fermentative hydrogen production from wastewaters: A review and prognosis. Int J Hydrogen Energy 37:15632–15642.

[49] Lin Y, Tanaka S (2006) Ethanol fermentation from biomass resources: current state and prospects. Appl Microbiol Biotechnol 69:627–642.

[50] Liu CZ, Cheng XY (2010) Improved hydrogen production via thermophilic fermentation of corn stover by microwave-assisted acid pretreatment. Int J Hydrogen Energy 35:8945–8952.

[51] Lo YC, Lu WC, Chen CY et al. (2010) Dark fermentative hydrogen production from enzymatic hydrolysate of xylan and pretreated rice straw by Clostridium butyricum CGS5. Bioresour Technol 101:5885–5891.

[52] Lo YC, Su YC, Cheng CL et al. (2011) Biohydrogen production from pure and natural lignocellulosic feedstock with chemical pretreatment and bacterial hydrolysis. Int J Hydrogen Energy 36:13955–13963.

[53] Long C, Cui J, Liu Z et al. (2010) Statistical optimization of fermentative hydrogen production from xylose by newly isolated Enterobacter sp CN1. Int J Hydrogen Energy 35:6657–6664.

[54] Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.

[55] Maintinguer SI, Fernandes BS, Duarte ICS (2011) Fermentative hydrogen production with xylose by Clostridium and Klebsiella species in anaerobic batch reactors. Int J Hydrogen Energy 36:13508–13517.

[56] Martin del Campo JS, Rollin J, Myung S et al. (2013) High-yield production of dihydrogen from xylose by using a synthetic enzyme cascade in a cell-free system. Angew Chem Int Ed 52:1–5.

[57] Matsumoto M, Nishimura Y (2007) Hydrogen production by fermentation using acetic acid and lactic acid. J Biosc Bioeng 103:236–241.

[58] Monlau F, Barakat A, Trably E et al. (2013a) Lignocellulosic Materials Into Biohydrogen and Biomethane: Impact of Structural Features and Pretreatment. Crit Rev Env Sci Technol 43:260–322.

[59] Monlau F, Aemig Q, Trably E et al. (2013b) Specific inhibition of biohydrogen-producing Clostridium sp after dilute-acid pretreatment of sunflower stalks. Int J Hydrogen Energy 38:12273–12282.

[60] Mood SH, Golfeshan AH, Tabatabaei M et al. (2013) Lignocellulosic biomass to bioethanol, a comprehensive review with a focus on pretreatment. Renew Sust Energy Rev 27:77–93.

[61] Mosier N, Wyman C, Dale B et al. (2005) Features of promising technologies for pretreatment of lignocellulosic biomass. Bioresour Technol 96:673–686.

[62] Nasirian N, Almassi M, Minaei S et al. (2011) Development of a method for biohydrogen production from wheat straw by dark fermentation. Int J Hydrogen Energy 36:411–420.

[63] Ngo TA, Nguyen TH, Bui BTV (2012) Thermophilic fermentative hydrogen production from xylose by Thermotoga neapolitana DSM 4359. Renew Energy 37:174–179.

[64] Nguyen T-AD, Kim K-R, Kim MS et al. (2010) Thermophilic hydrogen fermentation from Korean rice straw by Thermotoga neapolitana Int J Hydrogen Energy 35:13392–13398.

[65] Nissila ME, Li YC, Wu SY et al. (2012) Dark Fermentative Hydrogen Production from Neutralized Acid Hydrolysates of Conifer Pulp. Appl Biochem Biotechnol 168:2160–2169.

[66] Ogeda TL, Petri DFS (2010) Hidrólise Enzimática de Biomassa. Química Nova 36:1549–1558.

[67] Ozkan L, Erguder TH, Demirer GN (2011) Effects of pretreatment methods on solubilization of beet-pulp and biohydrogen production yield. Int J Hydrogen Energy 36:382–389.

[68] Palmqvist E, Hahn-Hagerdal B (2000) Fermentation of lignocellulosic hydrolysates. II: inhibitors and mechanisms of inhibition. Bioresour Technol 74:25–33.

[69] Pan CM, Ma HC, Fan YT et al. (2011) Bioaugmented cellulosic hydrogen production from cornstalk by integrating dilute acid-enzyme hydrolysis and dark fermentation. Int J Hydrogen Energy 36:4852–4862.

[70] Panagiotopoulos IA, Bakker RR, de Vrije T et al. (2010) Pretreatment of sweet sorghum bagasse for hydrogen production by Caldicellulosiruptor saccharolyticus Int J Hydrogen Energy 35:7738–7747.

[71] Pattra S, Sangyoka S, Boonmee M et al. (2008) Bio-hydrogen production from the fermentation of sugarcane bagasse hydrolysate by Clostridium butyricum Int J Hydrogen Energy 33:5256–5265.

[72] Pawar SS, Nkemka VN, Zeidan AA et al. (2013) Biohydrogen production from wheat straw hydrolysate using Caldicellulosiruptor saccharolyticus followed by biogas production in a two-step uncoupled process. Int J Hydrogen Energy 38:9121–9130.

[73] Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647.

[74] Quemeneur M, Hamelin J, Barakat A et al. (2012b) Inhibition of fermentative hydrogen production by lignocellulose-derived compounds in mixed cultures. Int J Hydrogen Energy 37:3150–3159.

[75] Rafrafi Y, Trably E, Hamelin J, et al. (2013) Sub-dominant bacteria as keystone species in microbial communities producing bio-hydrogen. Int J Hydrogen Energy 38:4881–5180.

[76] Raj SM, Talluri S, Christopher LP (2012) Thermophilic Hydrogen Production from Renewable Resources: Current Status and Future Perspectives. Bioenergy Res 5:515–531.

[77] Ren N, Wang A, Gao L et al. (2008) Bioaugmented hydrogen production from carboxymethyl cellulose and partially delignified corn stalks using isolated cultures. Int J Hydrogen Energy 33:5250–5255.

[78] Ren N, Wang A, Cao GL et al. (2009) Bioconversion of lignocellulosic biomass to hydrogen: Potential and challenges. Biotechnol Adv 27:1051–1060.

[79] Ren NQ, Cao GL, Guo WQ et al. (2010) Biological hydrogen production from corn stover by moderately thermophile Thermoanaerobacterium thermosaccharolyticum W16. Int J Hydrogen Energy 35:2708–2712.

[80] Rezende CA, de Lima MA, Maziero P et al. (2011) Chemical and morphological characterization of sugarcane bagasse submitted to a delignification process for enhanced enzymatic digestibility. Biotechnol Biofuels 4:1–18.

[81] Sagnak R, Kargi F, Kapdan IK (2011) Bio-hydrogen production from acid hydrolyzed waste ground wheat by dark fermentation. Int J Hydrogen Energy 36:12803–12809.

[82] Saratale G, Chen SD, Lo YC et al. (2008) Outlook of biohydrogen production from lignocellulosic feedstock using dark fermentation - a review. J Sci Ind Res 67:962–979.

[83] Saripan AF, Reungsang A (2013) Biohydrogen production by Thermoanaerobacterium thermosaccharolyticum KKU-ED1: Culture conditions optimization using xylan as the substrate. Int J Hydrogen Energy 38:6167–6173.

[84] Sarks C, Jin M, SatoTK et al. (2014) Studying the rapid bioconversion of lignocellulosic sugars into ethanol using high cell density fermentations with cell recycle. Biotechnol Biofuels 15:73–80.

[85] Seol E, Kim S, Raj SM et al. (2008) Comparison of hydrogen-production capability of four different Enterobacteriaceae strains under growing and non-growing conditions. Int J Hydrogen Energy 33:5169–5175.

[86] Shaw AJ, Jenney FE Jr, Adams MWW et al. (2008) End-product pathways in the xylose fermenting bacterium Thermoanaerobacterium saccharolyticum Enzyme Microb Technol 42:453–458.

[87] Show KY, Lee DJ, Tay JH et al. (2012) Biohydrogen production: Current perspectives and the way forward. Int J Hydrogen Energy 37:15616–15631.

[88] Song ZX, Wang ZY, Wu LY et al. (2012) Effect of microwave irradiation pretreatment of cow dung compost on bio-hydrogen process from corn stalk by dark fermentation. Int J Hydrogen Energy 37:6554–6561.

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[90] Tai J, Adav SS, Su A et al. (2010) Biological hydrogen production from phenol-containing wastewater using Clostridium butyricum Int J Hydrogen Energy 35:13345–13349.

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Feedstock	Inoculum	T (°C)	Maximum assessed production yield^a a Maximum assessed production yields are the results presented by the authors.	Maximum calculated production yield (mmol H₂/g of substrate)^b b Maximum calculated production yields are results converted from authors' data determined according to the ideal gas equation considering a pressure of 1 atm and the absolute temperature used during H2 fermentation.	Reference
Cornstalk	C. thermocellum	55	61.4 mL of H₂/g	2.28	Cheng and Liu, 2012Cheng XY, Li Q, Liu CZ (2012) Coproduction of hydrogen and methane via anaerobic fermentation of cornstalk waste in continuous stirred tank reactor integrated with up-flow anaerobic sludge bed. Bioresour Technol 114:327–333.
Cornstalk	anaerobic digester sludge	55	37.6 mL of H₂/g	1.40	Cheng and Liu, 2012Cheng XY, Li Q, Liu CZ (2012) Coproduction of hydrogen and methane via anaerobic fermentation of cornstalk waste in continuous stirred tank reactor integrated with up-flow anaerobic sludge bed. Bioresour Technol 114:327–333.
Cornstalk	mixed microflora from rotted wood crumb	60	115.3 mL of H₂/g	4.22	*Cao et al., 2012*Cao GL, Guo WQ, Wang AJ et al. (2012) Enhanced cellulosic hydrogen production from lime-treated cornstalk wastes using thermophilic anaerobic microflora. Int J Hydrogen Energy 37:13161–13166.
Cornstalk	C. thermocellum, C. thermosaccharolyticum	55	74.9 mL of H₂/g	2.78	Li and Liu, 2012Li Q, Liu CZ (2012) Co-culture of Clostridium thermocellum and Clostridium thermosaccharolyticum for enhancing hydrogen production via thermophilic fermentation of cornstalk waste. Int J Hydrogen Energy 37:10648–10654.
Cornstalk	cow dung compost	36	3 mL of H₂/g	0.12	*Zhang et al., 2007*Zhang M-L, Fan Y-T, Xing Y et al. (2007) Enhanced biohydrogen production from cornstalk wastes with acidification pretreatment by mixed anaerobic cultures. Biomass Bioenergy 31:250–254.
Mushroom cultivation waste	heated mixed cultures	55	0.73 mmol of H₂/g	0.73	*Lay et al., 2012*Lay CH, Sung IY, Kumar G et al. (2012) Optimizing biohydrogen production from mushroom cultivation waste using anaerobic mixed cultures. Int J Hydrogen Energy 37:16473–16478.
Grass (Reed canary)	H₂-microbial enrichment culture	35	0.19 mmol of H₂/g	0.19	*Lakaniemi et al., 2011*Lakaniemi AM, Koskinen PEP, Nevatalo LM et al. (2011) Biogenic hydrogen and methane production from reed canary grass. Biomass Bioenergy 35:773–780.
Grass	mixed cultures enriched with C. pasteurianum	35	4.39 mL of H₂/g	0.17	Cui and Shen, 2012Cui M, Shen J (2012) Effects of acid and alkaline pretreatments on the biohydrogen production from grass by anaerobic dark fermentation. Int J Hydrogen Energy 37:1120–1124.
Grass (switchgrass)	C. saccharolyticus DSM 8903	65	11.2 mmol of H₂/g	11.2	*Talluri et al., 2013*Talluri S, Raj SM, Christopher LP (2013) Consolidated bioprocessing of untreated switchgrass to hydrogen by the extreme thermophile Caldicellulosiruptor saccharolyticus DSM 8903. Bioresour Technol 139:272–279.
Rice straw	T. neapolitana	75	2.3 mmol of H₂/g	2.3	*Nguyen et al., 2010*Nguyen T-AD, Kim K-R, Kim MS et al. (2010) Thermophilic hydrogen fermentation from Korean rice straw by Thermotoga neapolitana. Int J Hydrogen Energy 35:13392–13398.
Rice straw	sewage sludge	55	21 mL of H₂/g	0.78	*Kim et al, 2013*Kim M, Liu C, Noh JW et al. (2013) Hydrogen and methane production from untreated rice straw and raw sewage sludge under thermophilic anaerobic conditions. Int J Hydrogen Energy 38:8648–8656.
Wheat straw	preheated anaerobic sludge	37	10.52 mL of H₂/g VS^c c VS: Volatile solids contained in the substrate.	0.41	*Quemeneur et al., 2012*Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647. ^(a) a Maximum assessed production yields are the results presented by the authors.
Wheat straw	C. saccharolyticus	70	44.7 mL of H₂/g	1.59	*Ivanova et al., 2009*Ivanova G, Rakhely G, Kovacs KL (2009) Thermophilic biohydrogen production from energy plants by Caldicellulosiruptor saccharolyticus and comparison with related studies. Int J Hydrogen Energy 34:3659–3670.

Feedstock	Pretreatment	Inoculum	T (°C)	Maximum assessed production yield^a a Maximum assessed production yields are the results as presented by the authors.	Maximum calculated production yield (mmol H₂/g of substrate)^b b Maximum calculated production yields results converted from authors' data calculated according to the ideal gas equation considering a pressure of 1 atm and the absolute temperature used during H2 fermentation.	Reference
Beet pulp	pH 12 with NaOH for 30 min	anaerobic sludge	35	115.6 mL of H₂/g of COD	-	*Ozkan et al., 2011*Ozkan L, Erguder TH, Demirer GN (2011) Effects of pretreatment methods on solubilization of beet-pulp and biohydrogen production yield. Int J Hydrogen Energy 36:382–389.
Corn stalk	Lime loading of 0.10 g/g of biomass for 96 h	mixed microflora from rotted wood crumb	60	155.4 mL of H₂/g of TVS	5.69	*Cao et al., 2012*Cao GL, Guo WQ, Wang AJ et al. (2012) Enhanced cellulosic hydrogen production from lime-treated cornstalk wastes using thermophilic anaerobic microflora. Int J Hydrogen Energy 37:13161–13166.
Cornstalk	Phanerochaete chrysosporium	T. thermosaccharolyticum	50	89.3 mL of H₂/g	3.99	*Zhao et al., 2013*Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.
	Trichoderma viride	T. thermosaccharolyticum	50	90.6 mL of H₂/g	4.04	*Zhao et al., 2013*Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.
Cornstalk	solid state enzymolysis	panda manure	36	205.5 mL of H₂/g of TVS	8.11^* * Maximum calculated production yield/g of substrate calculated as mmol H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	*Xing et al., 2011*Xing Y, Fan SQ, Zhang JN (2011) Enhanced bio-hydrogen production from corn stalk by anaerobic fermentation using response surface methodology. Int J Hydrogen Energy 36:12770–12779.
Cornstalk	H₂SO₄ 0.5% at 121°C for 60 min	microwave irradiated cow dung compost	36	144.3 mL of H₂/g	6.44	*Song et al., 2012*Song ZX, Wang ZY, Wu LY et al. (2012) Effect of microwave irradiation pretreatment of cow dung compost on bio-hydrogen process from corn stalk by dark fermentation. Int J Hydrogen Energy 37:6554–6561.
Cornstalk	NaOH at 120 °C for 20 min	anaerobic sludge	55	45.7 mL of H₂/g	1.70	Cheng and Liu, 2012Cheng XY, Liu CZ (2012a) Enhanced coproduction of hydrogen and methane from cornstalks by a three-stage anaerobic fermentation process integrated with alkaline hydrolysis. Bioresour Technol 104:373–379. ^(a) a Maximum assessed production yields are the results as presented by the authors.
Cornstalk	Fungal pretreatment	anaerobic sludge	55	54.1 mL of H₂/g of VS	2.01^* * Maximum calculated production yield/g of substrate calculated as mmol H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	Cheng and Liu, 2012Cheng XY, Liu CZ (2012a) Enhanced coproduction of hydrogen and methane from cornstalks by a three-stage anaerobic fermentation process integrated with alkaline hydrolysis. Bioresour Technol 104:373–379. ^(b) b Maximum calculated production yields results converted from authors' data calculated according to the ideal gas equation considering a pressure of 1 atm and the absolute temperature used during H2 fermentation.
Cornstalk	Acidification 0.2% HCl	cow dung compost	36	149.69 mL of H₂/g of TVS	5.90^* * Maximum calculated production yield/g of substrate calculated as mmol H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	*Zhang et al., 2007*Zhang M-L, Fan Y-T, Xing Y et al. (2007) Enhanced biohydrogen production from cornstalk wastes with acidification pretreatment by mixed anaerobic cultures. Biomass Bioenergy 31:250–254.
Corn stover	1.2% H₂SO₄/2 h and steam explosion 200 °C for 1 min	dried sludge	35	184.71 mL of H₂/10 g (18.47 mL/g)	0.73	*Datar et al., 2007*Datar R, Huang J, Maness P-C et al. (2007) Hydrogen production from the fermentation of corn stover biomass pretreated with a steam-explosion process Int J Hydrogen Energy 32:932–939.
Corn stover	Microwave assisted acid pretreatment (H₂SO₄ 0.3 N for 45 min)	anaerobic sludge	55	18.22 mL of H₂/g	0.68	Liu and Cheng, 2010Liu CZ, Cheng XY (2010) Improved hydrogen production via thermophilic fermentation of corn stover by microwave-assisted acid pretreatment. Int J Hydrogen Energy 35:8945–8952.
Grass	4% HCl	anaerobic	35	72.21 mL of H₂/g	2.86	Cui and Shen 2012Cui M, Shen J (2012) Effects of acid and alkaline pretreatments on the biohydrogen production from grass by anaerobic dark fermentation. Int J Hydrogen Energy 37:1120–1124.
	0.5% NaOH	mixed bacteria	35	19.25 mL of H₂/g	0.86	Cui and Shen 2012Cui M, Shen J (2012) Effects of acid and alkaline pretreatments on the biohydrogen production from grass by anaerobic dark fermentation. Int J Hydrogen Energy 37:1120–1124.
Grass (Reed canary)	3% HCl solution for 90 min at 121 °C	H₂-fermenting microbial enrichment culture	35	1.25 mmol of H₂/g	1.25	*Lakaniemi et al., 2011*Lakaniemi AM, Koskinen PEP, Nevatalo LM et al. (2011) Biogenic hydrogen and methane production from reed canary grass. Biomass Bioenergy 35:773–780.
Rapeseed stillage	Alkaline peroxide with steam treatment	digested manure	55	79 mL of H₂/gVS	2.94^* * Maximum calculated production yield/g of substrate calculated as mmol H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	*Luo et al., 2011*Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.
Rapeseed cake	Alkaline peroxide with steam treatment	digested manure	55	24 mL of H₂/gVS	0.89^* * Maximum calculated production yield/g of substrate calculated as mmol H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	*Luo et al., 2011*Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.
Rice straw	10% ammonia and 1.0% H₂SO₄	T. neapolitana	75	2.7 mmol of H₂/g	2.70	*Nguyen et al., 2010*Nguyen T-AD, Kim K-R, Kim MS et al. (2010) Thermophilic hydrogen fermentation from Korean rice straw by Thermotoga neapolitana. Int J Hydrogen Energy 35:13392–13398.
Sugarcane bagasse	0.5% H₂SO₄ for 60 min at 121 °C	C. butyricum	37	1.73 mol of H₂/mol sugar	-	*Pattra et al., 2008*Pattra S, Sangyoka S, Boonmee M et al. (2008) Bio-hydrogen production from the fermentation of sugarcane bagasse hydrolysate by Clostridium butyricum. Int J Hydrogen Energy 33:5256–5265.
Sugarcane bagasse	H₂SO₄ at 1% for 60 min at 121 °C	preheated elephant dung	37	0.84 mol of H₂/mol sugar	-	Fangkum and Reunsang, 2011Fangkum A, Reungsang A (2011) Biohydrogen production from sugarcane bagasse hydrolysate by elephant dung: Effects of initial pH and substrate concentration. Int J Hydrogen Energy 36:8687–8696.
Sugarcane bagasse	H₂SO₄ at 1% for 60 min at 121 °C	T. thermosaccharolyticum	55	1.12 mol of H₂/mol sugar	-	Saripan and Reungsang, 2013Saripan AF, Reungsang A (2013) Biohydrogen production by Thermoanaerobacterium thermosaccharolyticum KKU-ED1: Culture conditions optimization using xylan as the substrate. Int J Hydrogen Energy 38:6167–6173.
Waste ground wheat	H₂SO₄, pH 3.0, 90 °C for 15 min	preheated anaerobic sludge	37	946.2 mL	-	*Sagnak et al., 2011*Sagnak R, Kargi F, Kapdan IK (2011) Bio-hydrogen production from acid hydrolyzed waste ground wheat by dark fermentation. Int J Hydrogen Energy 36:12803–12809.
Wheat straw	HCl pretreated	cow dung compost	36	68.1 mL of H₂/g TVS	3.04^* * Maximum calculated production yield/g of substrate calculated as mmol H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	*Fan et al., 2006*Fan YT, Zhang YH, Zhang SF et al. (2006) Efficient conversion of wheat straw wastes into biohydrogen gas by cow dung compost. Bioresour Technol 97:500–505.
Wheat straw	Hydrothermic 180 °C for 15 min	preheated anaerobic sludge	70	7.36 mmol of H₂/g sugars	-	*Kongjan et al., 2010*Kongjan P, O-Thong S, Kotay M et al. (2010) Biohydrogen Production From Wheat Straw Hydrolysate by Dark Fermentation Using Extreme Thermophilic Mixed Culture. Biotechnol Bioeng 105:899–908.

Feedstock	Pretreatment/ hydrolysis	Inoculum	T (°C)	Maximum production yield (^a a Maximum production yield in terms of mmol of H2/mmol of sugar. , ^b b Maximum production yield in terms of mmol of H2/g of substrate. , ^b* b* Maximum production yield in terms of mmol of H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate. )	Maximum production rate (mmol of H₂/L.h)	Reference
Conifer pulp	55%H₂SO₄ at 45 °C for 2 h, neutralized with Ca(OH)₂	preheated anaerobic sludge	37	2.26^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	nd	*Nissilä et al., 2012*Nissila ME, Li YC, Wu SY et al. (2012) Dark Fermentative Hydrogen Production from Neutralized Acid Hydrolysates of Conifer Pulp. Appl Biochem Biotechnol 168:2160–2169.
Corn stover	Delignification with 2% NaOH+hydrolysis with cellulase and xylanase	T. thermosaccharolyticum	60	nd	11.2	*Ren et al., 2010*Ren NQ, Cao GL, Guo WQ et al. (2010) Biological hydrogen production from corn stover by moderately thermophile Thermoanaerobacterium thermosaccharolyticum W16. Int J Hydrogen Energy 35:2708–2712.
Cornstalk	Dilute acid+enzymatic hydrolysis	anaerobic mixed microflora	36	8.58^b b Maximum production yield in terms of mmol of H2/g of substrate.	nd	*Pan et al., 2011*Pan CM, Ma HC, Fan YT et al. (2011) Bioaugmented cellulosic hydrogen production from cornstalk by integrating dilute acid-enzyme hydrolysis and dark fermentation. Int J Hydrogen Energy 36:4852–4862.
Cornstalk	Fungal hydrolysis by Trichoderma viride	T. thermosaccharolyticum W16	60	3.28^b b Maximum production yield in terms of mmol of H2/g of substrate.	nd	*Zhao et al., 2013*Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.
Miscanthus crop	Alkaline pretreatment at 75 °C+enzymatic hydrolysis	C. saccharolyticus	70	2.9^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	12.6	*de Vrije et al., 2009*de Vrije T, Bakker RR, Budde MAW et al. (2009) Efficient hydrogen production from the lignocellulosic energy crop Miscanthus by the extreme thermophilic bacteria Caldicellulosiruptor saccharolyticus and Thermotoga neapolitana. Biotechnol Biofuels 2,12. http://www.biotechnologyforbiofuels.com/content/2/1/12 http://www.biotechnologyforbiofuels.com/...
		T. neapolitana	70	3.4^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	13.1	*de Vrije et al., 2009*de Vrije T, Bakker RR, Budde MAW et al. (2009) Efficient hydrogen production from the lignocellulosic energy crop Miscanthus by the extreme thermophilic bacteria Caldicellulosiruptor saccharolyticus and Thermotoga neapolitana. Biotechnol Biofuels 2,12. http://www.biotechnologyforbiofuels.com/content/2/1/12 http://www.biotechnologyforbiofuels.com/...
Oat straw	HCl at 2%+90 °C for 2 h	two anaerobic sludges, heated at 100 °C for 30 min.	30	2.9^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	3.3	*Arriaga et al., 2011*Arriaga S, Rosas I, Alatriste-Mondragón F et al. (2011) Continuous production of hydrogen from oat straw hydrolysate in a biotrickling filter. Int J Hydrogen Energy 36:3442–3449.
Poplar leaves	HCl at 4%+2% Viscozyme	anaerobic mixed bacteria	35	1.78^b b Maximum production yield in terms of mmol of H2/g of substrate.	nd	*Cui et al., 2010*Cui M, Yuan Z, Zhi X et al. (2010) Biohydrogen production from poplar leaves pretreated by different methods using anaerobic mixed bacteria. Int J Hydrogen Energy 35:4041–4047.
Rapeseed	Alkaline peroxide with steam treatment+celluclast and β-glucosidase	digested manure	55	3.38^b* b* Maximum production yield in terms of mmol of H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	nd	Luo et al.
Rice straw	Alkaline pretreatment+Acinetobacter junii F6-02 enzymes	C. butyricum CGS5	37	0.76^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	1.05	*Lo et al., 2010*Lo YC, Lu WC, Chen CY et al. (2010) Dark fermentative hydrogen production from enzymatic hydrolysate of xylan and pretreated rice straw by Clostridium butyricum CGS5. Bioresour Technol 101:5885–5891.
Sugarcane bagasse	Pretreated with H₃PO₄+Cellulomonas uda enzymes	C. butyricum CGS5	37	1.08^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	nd	*Lo et al., 2011*Lo YC, Su YC, Cheng CL et al. (2011) Biohydrogen production from pure and natural lignocellulosic feedstock with chemical pretreatment and bacterial hydrolysis. Int J Hydrogen Energy 36:13955–13963.
Sugarcane bagasse	Alkaline and enzymatic hydrolysis with cellulase from Pseudomonas sp.	C. pasteurianum	37	0.96^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	1.38	Cheng and Chang, 2011Cheng CL, Chang JS (2011) Hydrolysis of lignocellulosic feedstock by novel cellulases originating from Pseudomonas sp. CL3 for fermentative hydrogen production. Bioresour Technol 102:8628–8634.
Sugarcane bagasse	NaOH 0.1 mol/L at 100 °C for 2 h and hydrolysis with cellulase	preheated anaerobic sludge	35	13.4^b* b* Maximum production yield in terms of mmol of H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	0.28^c c Maximum production rate in terms of mmol of H2/h.g TVS.	*Chairattanamanokorn et al., 2009*Chairattanamanokorn P, Penthamkeerati P, Reungsang A et al. (2009) Production of biohydrogen from hydrolyzed bagasse with thermally preheated sludge. Int J Hydrogen Energy 34:7612–7617.
Sunflower stalks	HCl 4 g at 170 °C for 1 h/100 gTS	preheated anaerobic sludge	35	2.04^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	nd	*Monlau et al., 2013*Monlau F, Barakat A, Trably E et al. (2013a) Lignocellulosic Materials Into Biohydrogen and Biomethane: Impact of Structural Features and Pretreatment. Crit Rev Env Sci Technol 43:260–322. ^(b) b Maximum production yield in terms of mmol of H2/g of substrate.
Sweet sorghum bagasse	Pretreatment with NaOH+cellulase	C. saccharolyticus	72	2.6^a a Maximum production yield in terms of mmol of H2/mmol of sugar.	10.2 – 10.6	*Panagiotopoulos et al, 2010*Panagiotopoulos IA, Bakker RR, de Vrije T et al. (2010) Pretreatment of sweet sorghum bagasse for hydrogen production by Caldicellulosiruptor saccharolyticus. Int J Hydrogen Energy 35:7738–7747.
Wheat straw	SSF (acid+enzymatic)	anaerobic sludge	36	5.56^b* b* Maximum production yield in terms of mmol of H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	nd	*Nasirian et al., 2011*Nasirian N, Almassi M, Minaei S et al. (2011) Development of a method for biohydrogen production from wheat straw by dark fermentation. Int J Hydrogen Energy 36:411–420.
Wheat straw	Ozone and simultaneous enzymatic hydrolysis	preheated cow manure and pond sediment preheated	35	3.2^b b Maximum production yield in terms of mmol of H2/g of substrate.	nd	*Wu et al., 2013*Wu J, Upreti S, Mozaffari FE (2013) Ozone pretreatment of wheat straw for enhanced biohydrogen production. Int J Hydrogen Energy 38:10270–10276.
Wheat straw	SSF (Trichoderma+fermentation)		37	0.80^b* b* Maximum production yield in terms of mmol of H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	nd	*Quemeneur et al., 2012*Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647. ^(a) a Maximum production yield in terms of mmol of H2/mmol of sugar.
	SSF (acid+enzymatic saccharification prior to fermentation)	preheated anaerobic sludge	37	0.45^b* b* Maximum production yield in terms of mmol of H2/g of total volatile solids (TVS) or volatile solids (VS) contained in the substrate.	nd	*Quemeneur et al., 2012*Quemeneur M, Bittel M, Trably E et al. (2012a) Effect of enzyme addition on fermentative hydrogen production from wheat straw. Int J Hydrogen Energy 37:10639–10647. ^(a) a Maximum production yield in terms of mmol of H2/mmol of sugar.

Brasil

Brasil

Fermentative hydrogen production from agroindustrial lignocellulosic substrates

Abstract

Introduction

Lignocellulosic Materials as Substrate for Fermentative H₂ Production

Pretreatment of Lignocellulosic Materials for Fermentative H₂ Production

H₂ Production From Non-Pretreated Lignocellulosic Materials

H₂ Production From Pretreated Lignocellulosic Materials

H₂ Production From Lignocellulosic Materials Hydrolysates

Conclusions and Perspectives

Acknowledgments

References

Publication Dates

History

Brasil

Brasil

Fermentative hydrogen production from agroindustrial lignocellulosic substrates

Abstract

Introduction

Lignocellulosic Materials as Substrate for Fermentative H2 Production

Pretreatment of Lignocellulosic Materials for Fermentative H2 Production

H2 Production From Non-Pretreated Lignocellulosic Materials

H2 Production From Pretreated Lignocellulosic Materials

H2 Production From Lignocellulosic Materials Hydrolysates

Conclusions and Perspectives

Acknowledgments

References

Publication Dates

History

Lignocellulosic Materials as Substrate for Fermentative H₂ Production

Pretreatment of Lignocellulosic Materials for Fermentative H₂ Production

H₂ Production From Non-Pretreated Lignocellulosic Materials

H₂ Production From Pretreated Lignocellulosic Materials

H₂ Production From Lignocellulosic Materials Hydrolysates