Microsoft Word - 476hernandez.docx


CHEMICAL ENGINEERINGTRANSACTIONS 
 

VOL. 43, 2015 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Chief Editors:SauroPierucci, JiříJ. Klemeš 
Copyright © 2015, AIDIC ServiziS.r.l., 
ISBN 978-88-95608-34-1; ISSN 2283-9216                                                                               

 

Fermentable Sugar Production from Lignocellulosic Waste 

Linda Mezule*, Brigita Dalecka, Talis Juhna 

Riga Technical University, Faculty of Civil Engineering, Department of Water Science and Technology, Azenes 16/20-263, 
Riga, LV-1048, Latvia 
linda.mezule@rtu.lv 

Effective and economically supported conversion of lignocellulosic biomass is not only related to high sugar 
yields but also to simple, environmentally friendly and sustainable technological solutions. Commercialization 
of the biofuel and biogas production technologies from lignocellulose is of high interest in many countries, 
however, costs and various yield affecting factors are still not fully understood. The aim of this research was to 
evaluate and define a mild-hydrolysis technique, involving the combination of simple physical, thermal and 
enzymatic methods. Use of medium-fine biomass (< 0.5 cm) wetted in purified (nanofiltrated) water, boiled to 
remove indigenous biomass microorganisms and enzymatically hydrolysed for 24 h at 30 °C was enough to 
obtain similar sugar yields than with sulphuric acid hydrolysis.  

1. Introduction 

The potential of lignocellulosic biomass as a renewable energy resource has been evaluated worldwide over 
many decades. Effective conversion of biomass to electrical and heat energy has been shown in many 
countries as a considerable share in the total produced energy (Šturc, 2012). At the same time biomass 
resources, like grass, shrubs, straw, hay and agricultural waste could effectively replace energy crops as 
feedstock for biofuel and biogas production which take up considerable areas of agricultural land unavailable 
for food production. However, due to highly complex lignocellulosic matrix consisting of cellulose, 
hemicellulose and lignin, direct conversion of these biomass resources is not possible. To release fermentable 
sugars, various physical, thermal, physicochemical, chemical and biological techniques or their combinations 
have been offered over the years (Kumar et al., 2009). Sugar yields of up to 99 % have been obtained 
(Ballesteros et al., 2002), however, generally the yields vary from 12 to 98 % depending on the biomass 
source and treatment method used (Chaturvedi and Verma, 2013). Therefore there is a great interest in the 
optimization of laboratory techniques to increase fermentable sugar yields and decrease the production costs 
to subsequently introduce them into a commercial scale.  
On average 40% of the lignocellulosic biomass consists of cellulose which is the main source of fermentable 
sugars. The amount of cellulose varies from the biomass type assessed (Jorgensen et al., 2007), thus, 
affecting the product yields when a single pre-treatment/hydrolysis technique is used for various biomass 
sources. This in turn can strongly affect the availability and cost of the substrate, especially in the areas with a 
distinct seasonality and limited uniform feed material.  At the same time high productivity techniques, e.g., 
oxidative and physicochemical, producing more than 80 % sugar yields (Chaturvedi and Verma, 2013) and, 
thus, not so strongly affected by cellulose concentration, are mostly regarded as too energy and labor 
consuming, environmentally unfriendly (Brodeur et al., 2011) and fermentation inhibitor generating (Larsson et 
al., 1999), thus, limiting their application in small and medium scale biofuel production units. 
The aim of this study was to evaluate and define a mild-hydrolysis technique, involving combination of simple 
physical, thermal and enzymatic methods, for effective conversion of lignocellulose to fermentable sugars 
applicable in small-scale biofuel production. During the research various factors, like, biomass type, grinding 
(particle size), heat pre-treatment, solvent type and hydrolysis conditions were tested on the total outcome of 
fermentable sugar yields. To enhance the efficiency of enzymatic hydrolysis special laboratory made enzymes 
from the assessed substrates were used in the study. 

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1543104 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Mezule L., Dalecka B., Juhna T., 2015, Fermentable sugar production from lignocellulosic waste, Chemical 
Engineering Transactions, 43, 619-624  DOI: 10.3303/CET1543104

619



2. Materials and Methods 

2.1 Lignocellulosic biomass 

Hay mowed in late June from lowland hay meadows located in Latvia was used as a reference material. For 
biomass comparison studies wheat straw and fresh biomass from lowland hay meadows, dry grasslands 
(collected in July), cultivated grass (collected in July), Heracleum sosnowskyi (collected in early June) and 
freshwater green algae were used. 

2.2 Preparation of cellulolytic enzymes  

Laboratory scale preparation of cellulolytic enzymes was performed according to the methodology described 
by Mezule et al. (2012). In brief, pre-homogenized liquid cultures of Irpex lacteus IBB 104 were transferred to 
liquid media (2.0 g/L NH4NO3; 0.8 g/L KH2PO4; 0.4 g/L K2HPO4; 0.5 g/L MgSO4⋅7H2O; 2.0 g/L yeast extract; 
pH = 5.5–5.8) containing hay as a carbohydrate source. After 10 days the biomass was removed and 
(NH4)2SO4 (0.5 kg/L) was added to the supernatant, dissolved and incubated at 4 °C for 24–48 h. After the 
incubation the enzyme was sedimented by centrifugation (8500 rcf; 10 min) and stored in 0.05 M sodium 
citrate buffer at 4 °C for further use. Enzyme activity (FPU) was estimated according to IUPAC 
recommendations (Ghose, 1987). 

2.3 Substrate pre-treatment and hydrolysis 

The dried biomass was grounded by grinder (Retsch GM200) and screened with a sieve to obtain various 
biomass fractions (powder, < 0.5 cm, 0.5 – 1 cm, 1 – 2 cm, > 2 cm). Fresh biomass was ground to a size < 0.5 
cm. Prior heat treatment the biomass was diluted in 0.05 M sodium citrate buffer (3 % w/v) and either boiled 
for 5 minutes or heat treated at 121 °C for 15 minutes. 
For enzymatic hydrolysis, the prepared enzyme (0.2 FPU/mL, 20 FPU/g) was added to the diluted substrates 
and incubated on an orbital shaker for 24 – 48 h at 30 – 50 °C depending on the experiment setup. For 
process optimization sterile distilled, nanofiltered or tap water was used as a solvent. 
As a reference acid hydrolysis was used for the same substrates. The grounded biomass samples were 
diluted in H2SO4 (5 % final concentration) and heat treated at 121 °C for 15 min. Prior sampling for the 
released sugars, adjustment to pH 5 with concentrated NaOH was performed.  
All tests were prepared in triplicates and at least 2 samples from each test were collected for produced sugar 
measurements. 

2.4 Measurements of sugar concentration 

Reducing sugar concentration was measured by dinitrosalicylic acid (DNS) method (Ghose, 1987). In brief, all 
samples were centrifuged (6,600 g, 10 min). Then 0.1 mL of the supernatant was mixed with 0.1 mL of 0.05 M 
sodium citrate buffer and 0.6 mL of DNS. For blank control, distilled water was used instead of the sample. 
Then all samples were boiled for 5 minutes and transferred to cold water. Then 4 mL of distilled water was 
added. Absorption was measured with spectrophotometer at 540 nm (Camspec M501, UK). To obtain 
absolute concentrations, a standard curve against glucose was constructed.  

2.5 Statistical analyses 

MS Excel 2007 ANOVA single parameter tool (significance level ≤ 0.05) was used for analysis of variance on 
data from various sample setup`s. To determine if the data sets are significantly different or not, t-test 
analyses (MS Excel 2007) were performed for two tailed distributions. Probabilities of ≤ 0.05 were considered 
as significant.  

3. Results and discussion 

3.1 Pre-treatment and solvent effect 

To make the handling of the biomass material easier, reduction of the particle size by mechanical treatment is 
often used. Increased surface/volume ratio increase the effectivity of the biomass hydrolysis (Kumar et al., 
2009). Research related to the effect of particle size has shown high inconsistencies among the reported 
results (Zhang et al., 2013), indicating on the need for the evaluation of this parameter within each biomass 
treatment technique. To analyze the effect of hay particle size on enzymatic hydrolysis, reducing sugar 
concentration in the biomass with the size range of powder, < 0.5 cm, 0.5 – 1 cm, 1 – 2 cm and > 2 cm was 
measured directly after grinding and after enzymatic hydrolysis. The results showed that the highest variations 
among the results of the size groups occurred with the size above 0.5 cm. Significantly different (p < 0.05) 

620



sugar yields were observed in-between samples of > 2 cm and those below 0.5 cm. No difference (p > 0.05) 
between > 2 cm and 1-2 cm was observed in samples both after grinding and after hydrolysis (Figure 1). The 
same observation was also for the samples of powder and < 0.5 cm with only difference that samples of < 0.5 
cm gave the highest standard deviation values. This could be explained by variations among the produced 
grinded biomass size – from powder to 0.5 cm phase in a single sample; creating a real situation – no detailed 
size checkup during the production process. Other samples showed variable yields in between the 
experiments or treatments (wetting and hydrolysis), giving raise to the constant inconsistencies of the reported 
results. Nevertheless, the analysis of the reducing sugar concentrations after the hydrolysis showed 24-35 % 
higher sugar yields in samples with lower particle size (< 0.5 cm). Due to the observations particle size of < 
0.5 cm was used in all further tests. The use of powder type biomass was omitted due to almost double 
energy consumption when compared to <0.5 cm and the observed yields were only 13 % higher for powder (p 
>0.05). Subsequent fractionation in particle size was omitted due to the fact that commercial availability of 
such grinding technologies is either limited or highly expensive.  
 

 

Figure 1: The amount of reducing sugars produced from various biomass sizes directly after wetting (dark) 
and after enzymatic hydrolysis (light). The bars represent average values from 6 replicates. 

Another feature assessed within the research was the type of solvent used for biomass wetting prior mild 
thermal treatment (5 min boiling as reported by Mezule et al. (2012)) and subsequent enzymatic hydrolysis. 
Generally this issue is not addressed during the technology evaluation by limiting to laboratory pure 
(deionised) (Chen et al., 2012) or unidentified water (Diaz et al., 2013). No matter as insignificant it seems the 
production of distilled or ultra pure water has an effect on the overall production costs. During the study three 
water types were evaluated: laboratory pure deionised water, tap water complying all regulations (European 
Comission, 1998) and nanofiltered tap water. The latter was used due to the wide availability of such devices 
intended for commercial scale, thus, increasing the competitiveness and minimizing production costs. The 
results of the research showed that the highest sugar yields from hay were obtained when pure deionised 
water was used for biomass wetting. A 6% decrease was observed for nanofiltered and 14 % for tap water. 
Thus, giving no significant difference (p > 0.05) in between pure deionised and nanofiltered water, however, 
for pure deionised and tap water sugar yields differed significantly (p < 0.05). Slightly different results were 
obtained for fresh biomass obtained from dry grasslands where almost no difference was observed for pure 
deionised and nanofiltered water and a 3.4 % decrease for tap water (p > 0.05). Despite the relatively low 
variations it was concluded that tap water due to its changing nature and quality (regionally and in time) can 
affect the produced sugar yields.  

3.2 Hydrolysis conditions 

Enzymatic hydrolysis is generally linked to very slow processes with often low yields (Chaturvedi and Verma, 
2013), however, the method does not require high temperatures and is regarded as environmentally friendly 
(Brodeur et al., 2011). Enzyme producing fungi are incubated with the lignocellulosic biomass for 2 to 23 days 

0

20

40

60

80

100

120

140

160

>2 cm 1-2 cm 0,5-1cm < 0,5 cm powder

m
g

 s
u

g
a
r 

/ 
g

 h
a
y

Biomass size

621



(Chaturvedi and Verma, 2013). Shorter incubations are achieved with commercially available or pre-prepared 
enzymes at temperatures around 48 – 50 °C when fungal cellulases are regarded as the most effective 
(Brodeur et al., 2011). At the same time white-rot fungus Irpex lacteus is cultured at 28 – 30 °C (Novotný et al., 
2000). Thus, to estimate the necessity of increased temperature (50 °C) hydrolysis, a comparative study was 
performed. The results (Table 1) showed that higher reduced sugar yields from hay biomass were obtained at 
the temperatures closer to the natural growth and enzyme production temperature of I. lacteus. 30 % higher 
reducing sugar yields were obtained in samples incubated at 30 °C than at 50 °C. A reduction in 9 % of sugar 
yield was observed when the temperature was increased from 30 °C to 37 °C (p < 0.05). It is regarded that 
mesophilic bacteria found in the biomass are not effective at 50 °C temperatures, thus, non-sterile 
saccharification of lignocellulose has been proposed (Song et al., 2013). The results of this study showed that 
there is a significant difference (p < 0.05) in between the sugar yields of heat pre-treated and untreated 
samples.  

Table 1: The amount of reduced sugars produced from hay at various enzymatic hydrolysis conditions. 
Standard deviation represents the average values from 6 replicates 

Time, h Temperature, °C mg/g reducing sugar  
24 30 176.1 ± 7.4 
 37 160.3 ± 10.4 
 50 122.6 ± 7.9 
 50 (no heat pre-treatment) 99.7 ± 4.6 
48 30 172.6 ± 11.6 
 37 172.6 ± 7.7 

 
An additional release of sugars during the heat pre-treatment and reduced effect of sugar consuming 
microorganisms are the reasons for the choice of the selected thermal treatment. As it was shown previously 
(Mezule et al., 2012) there is no need for energy intense sterilization – simple 5 min boiling is sufficient. Within 
the study it was observed that irrespective of the generally low sugar concentration, the released sugars, vary 
(p < 0.05) before and after thermal treatment. Thus, 10 minutes of boiling were compared to the previously 
used 5 minutes. The results showed that the yields increased (p < 0.05) from 13 % (straw) to 18 % (hay), 
however, due to the double energy consumption; this was not regarded as essential improvement in the 
overall technology. 
To increase the sugar yields longer hydrolysis was introduced. No significant (p > 0.05) improvement in the 
sugar yields was observed when the samples are incubated at 30 °C for 24 or 48 h (Table 1). Additionally 
there was no difference in sugar yields hydrolysed at 30 °C or 37 °C after 48 h.   

3.3 Technology effectivity and substrate evaluation 

To assess the efficiency of the technology, sugar production yields were compared with acid hydrolysis 
(Figure 2). Mechanical grinding released low amount of reducing sugars in wetted biomass of all samples (p < 
0.05). No significant increase (p > 0.05) in reducing sugar concentration after thermal treatment was observed 
for samples containing only wetting buffer. At the same time reducing sugar concentration in samples 
undergoing acid hydrolysis increased significantly (p < 0.05). The results showed that boiling is not as efficient 
(24% lower sugar yields, p < 0.05) than heating at 121 °C. This corresponds to the data available for efficient 
acid hydrolysis where the temperatures are closely linked to the acid concentrations (Janga et al., 2012). 
Subsequent 24 h enzymatic hydrolysis (pH 5 adjusted for all samples) increased reducing sugar concentration 
in non-acid treated samples to an average level of 216 mg/g substrate which was only slightly lower than 220 
mg/g substrate obtained with acid hydrolysis (p > 0.6). The results supported the described advantages and 
disadvantages of both techniques where long treatment time comes up against the use of chemicals (Brodeur 
et al., 2011). Nevertheless, enzymatic hydrolysis was regarded as superior due to the fact that final liquid was 
directly available for fermentation and no presence of elevated salt concentration generated during pH 
adjustment was affecting the growth of fermenting microorganisms. 
Assessment of the described technique was evaluated on various biomass resources available in temperate 
climate zones (Figure 3). Due to limited seasonal availability of various biomass both dried and fresh biomass 
was tested. The results showed low differences between hay and fresh grass from cultivated and lowland hay 
meadows (163-194 mg/g dry mass). Higher yields from hay could be affected by the earlier biomass collection 
period, which also supported the more than 300 mg sugar/g dry mass from H. sosnowskyi collected in early 
June. The lowest reducing sugar yields (below 50 mg/g) were obtained from straw showing the potential 
drawback of this material.  

622



 

Figure 2: The amount of reducing sugars produced from hay with enzymatic and acid hydrolysis with 5 min of 
boiling or 30 min at 121 °C thermal treatment. Standard deviation represents the average values from 3 
replicates. 

 

Figure 3: Comparison of sugar yields obtained from various biomass sources with mild-enzymatic hydrolysis 
technique. Standard deviation represents the average values from 3 replicates. 

Despite the observed outcomes, the results showed that in none of the cases increased sugar productivity 
was observed when compared to the available yields of other techniques (Chaturvedi and Verma, 2013). 
Variability within the substrates, pre-treatment conditions and enzymes used can affect the outcome. To apply 
the technology in a commercial scale such issues should be minor. One of the potential solutions could be 
enzyme recovery and sugar concentration by membrane technologies (Knutsen and Davis, 2004), thus, 
excluding any potential shifts in productivity of fermentation feed.  However, the potential application and 
introduction of this technology is still not fully described.  

4. Conclusions 

Effective conversion of lignocellulosic biomass to fermenting sugars is not only limited to selection of most 
efficient pre-treatment/hydrolysis technique. Factors like, biomass type and collection period, size, preparatory 
reagents and treatment conditions affect the outcome.  
This study showed that enzymatic hydrolysis can be as efficient as acid hydrolysis and the overall enzymatic 
treatment time can be reduced to 24 h at 30 °C which is more energy efficient than described before.  

623



The study allowed to come up with a simple technique for lignocellulose hydrolysis which can be applied at a 
small-scale and do not require extensive resource and technological involvement.  

Acknowledgements 

This work has been supported by Latvian National Research Programme „LATENERGI”. The authors thank 
Ms Alina Nescerecka for technical support and Ms Baiba Strazdina for providing fresh biomass samples used 
in the study. 

References  

Brodeur G., Yau E., Badal K., Collier J., Ramachandran K.B., Ramakrishnan S., 2011, Chemical and 
physicochemical pretreatment of lignocellulosic biomass: A review, Enzyme Res., 2011, 1-17. 

Ballesteros I., Oliva J.M., Negro M.J., Manzanares P., Ballesteros M., 2002, Enzymic hydrolysis of steam 
exploded herbaceous agricultural waste (Brassica carinata) at different particule sizes, Process Biochem., 
38, 187-192. 

Chaturvedi V., Verma P., 2013, An overview of key pretreatment processes employed for bioconversion of 
lignocellulosic biomass into biofuels and value added products, 3 Biotech., 3, 415-431. 

Chen R., Yue Z., Deitz L., Liu Y., Mulbry W., Liao W., 2012, Use of an algal hydrolysate to improve enzymatic 
hydrolysis of lignocellulose, Bioresource Technol., 108, 149-154. 

Diaz A., Le Toullec J., Blandino A., De Ory I., Caro I., 2013, Pretreatment of Rice Hulls with Alkaline Peroxide 
to Enhance Enzyme Hydrolysis for Ethanol Production, Chemical Engineering Transactions, 32, 949-954. 

European Commission., 1998, Council Directive 98/83/EC, The quality of water intended for human 
consumption, Official Journal, 41, 32-51. 

Ghose T.K., 1987, Measurement of cellulose activities, Pure& Appl. Chem., 59, 257-268. 
Janga K.K., Hägg M.B., Moe S.T., 2012, Influence of acid concentration, temperature, and time on the 

concentrated sulfuric acid hydrolysis of pinewood and aspenwood: A statistical approach, BioResources, 
7, 391-411. 

Jørgensen H., Kristensen J.B., Felby C., 2007, Enzymatic conversion of lignocellulose into fermentable 
sugars: challenges and opportunities, Biofuel Bioprod. Bioref., 1, 119-134.  

Knutsen J.S., Davis R.H., 2004, Cellulase retention and sugar removal by membrane ultrafiltration during 
lignocellulosic biomass hydrolysis, Appl Biochem Biotechnol., 113-116, 585-599. 

Kumar P., Barrett D.M., Delwiche M.J., Stroeve P., 2009, Methods for Pretreatment of Lignocellulosic Biomass 
for Efficient Hydrolysis and Biofuel Production, Ind. Eng. Chem. Res., 48, 3713–3729. 

Larsson S., Palmqvist E., Hahn-Hägerdal B., Tengborg C., Stenberg K., Zacchi G., Nilvebrant N.O., 1999, The 
generation of fermentation inhibitors during dilute acid hydrolysis of softwood, Enzyme Microb. Tech, 24, 
151-159,  

Mezule L., Tihomirova K., Nescerecka A., Juhna T., 2012, Biobutanol production from agricultural waste: A 
simple approach for pre-treatment and hydrolysis, Latv. J. Chem., 4, 407-414. 

Novotný Č., Erbanová P., Cajthaml T., Rothschild N., Dosoretz C., Šašek V., 2000, Irpex lacteus, a white rot 
fungus applicable to water and soil bioremediation, Appl. Microbiol. Biot., 54, 850-853. 

Song L., Yu H., Ma F., Zhang X., 2013, Biological pretreatment under non-sterile conditions for enzymatic 
hydrolysis if corn stover, BioResources, 8, 3802-3816. 

Šturc A., 2012, Renewable energy. Analysis of the latest data on energy from renewable sources, Statistics in 
focus 44/2012, Environment and Energy, Eurostat, 1-7. 

Zhang Q., Zhang P., Pei Z.J., Wang D., 2013, Relationships between cellulosic biomass particle size and 
enzymatic hydrolysis sugar yield: Analysis of inconsistent reports in the literature, Renew. Energ., 60, 127-
136. 

624