Vol. 14(6), pp. 519-524, 11 February, 2015  

DOI: 10.5897/AJB2014.14330 

Article Number: 2AA965850411 

ISSN 1684-5315  

Copyright © 2015 

Author(s) retain the copyright of this article 

http://www.academicjournals.org/AJB 

African Journal of Biotechnology 

 
 
 
 
 

Full Length Research Paper 
 

Ethanol production using hemicellulosic hydrolyzate 
and sugarcane juice with yeasts that converts pentoses 

and hexoses 
 

Juliana Pelegrini Roviero1, Priscila Vaz de Arruda2, Maria das Graças de Almeida Felipe2 and 
Márcia Justino Rossini Mutton1* 

 
1
Faculdade de Ciências Agrárias e Veterinárias, UNESP – Univ Estadual Paulista. Via de Acesso Prof. Paulo Donato 

Castellane s/n 14884-900 - Jaboticabal, SP, Brasil. 
2
Escola de Engenharia de Lorena, USP - Universidade de São Paulo. Estrada Municipal do Campinho s/n, CEP 12602-

810, Lorena, SP, Brasil. 
 

Received 21 November, 2014; Accepted 2 February, 2015 
 

The use of vegetable biomass as substrate for ethanol production could reduce the existing usage of 
fossil fuels, thereby minimizing negative environmental impacts. Due to mechanical harvesting of 
sugarcane, the amount of pointer and straw has increased in sugarcane fields, becoming inputs of great 
energy potential. This study aimed to analyze the use of hemicellulosic hydrolyzate produced by 
sugarcane pointers and leaves compared with that of sugarcane juice fermented by yeasts that unfold 
hexoses and pentoses in the production of second generation biofuel, ethanol. The substrates used for 
ethanol production composed of either sugarcane juice (hexoses) or hemicellulosic hydrolyzate from 
sugarcane leaves and pointers (pentoses and hexoses), and the mixture of these two musts. 
Fermentation was performed in a laboratory scale using the J10 and FT858 yeast strains using 500 ml 
Erlenmeyer flasks with 180 ml of must prepared by adjusting the Brix to 16 ± 0.3°; pH 4.5 ± 0.5; 30°C; 10

7
 

CFU/ml with constant stirring for 72 h, with four replications. Cell viability, budding, buds viability, and 
ethanol production were evaluated. Among the yeasts, the cell viability was greater for J10. The use of 
FT858 + J10 was effective in producing ethanol. The hemicellulosic hydrolyzate had low efficiency in 
ethanol production compared with sugarcane juice. 
 
Key words: Hydrolysis of sugarcane straw and pointers, sugarcane juice, xylose, cell viability, ethanol. 

 
  
INTRODUCTION  
 
With the decline in world oil reserves, along with price 
instability and the appeal for the sustainable use of 
natural resources, the search for alternative such as 

biofuel production has intensified (Oderich and Filippi, 
2013). Brazil stands out as the world's largest producer of 
sugarcane, with an estimated production of 25.77 billion

  
*Corresponding author. E-mail: marcia.mutton@gmail.com. Tel: +55 16 3209-2675. 
 
Author(s) agree that this article remains permanently open access under the terms of the Creative Commons Attribution License 
4.0 International License 

 

 

 

http://creativecommons.org/licenses/by/4.0/deed.en_US
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520         Afr. J. Biotechnol. 
 
 
 
gallons of ethanol in the 2013/2014 harvest (Conab, 
2013). In order to increase ethanol production, the 
technology of converting lignocellulosic biomass into 
fermentable sugars for ethanol production is an 
alternative to meet the global demand for fuels (Santos et 
al., 2012). 

Due to the expansion of energy crops in conjunction 
with environmental responsibility measures, an agro-
environmental protocol on the cooperation between the 
government and the sugar-energy sector was established 
with the purpose of ending sugarcane burning and 
expanding mechanized harvesting. Without previous 

burning of sugarcane trash, mechanized harvesting results 
in large amounts of straw and pointers in the field, 
reaching 5-20 tons per hectare (Foloni et al., 2010). 

The dry bagasse (which has now been used in 
cogeneration) and sugarcane trash account for two-thirds 
of the planted area, that is, only one third of the biomass 
in plants is used in the production of ethanol or sugar, but 
they have great potential to produce second generation 
ethanol (Fugita, 2010). For straw and sugarcane bagasse 
cellulose content with an average of 39 and 43% 
respectively, there is a potential ethanol production of 
about 88/101 billion liters (Nunes et al., 2013). 

The ethanol production from lignocellulosic hydrolysates 
in an economically feasible process, requires micro-
organisms that produce ethanol with a high yield from all 
sugars present (hexoses and pentoses), have high ethanol 
productivity and can withstand potential inhibitors; 
furthermore, an integration of fermentation with the rest of 
the process should be investigated (Olsson and Hahn-
Hägerdal, 1996). 

Several studies have been conducted focusing on viable 
and low cost alternatives for the production of biofuel 
from biomass (Canilha et al. 2012; Cheng et al., 2008). In 
order to allow the release of sugars present in the 
hemicellulosic fraction of the mechanized harvesting 
residues and to make it available for fermentation using 
microorganisms, prior hydrolysis of biomass is required. 

Amongst the available processes, acid hydrolysis 
provides recovery of up to 90% of fermentable sugars 
present in the hemicellulosic fraction (Rodrigues, 2007). 
However, this process may generate inhibitors, such as 
the phenolic compounds which are mainly formed during 
partial degradation of lignin (Martin et al., 2007), thereby 
inhibiting the fermentation process and resulting in low 
efficiency and low industrial production (Ravaneli et al., 
2006). 

The objective of this study was to evaluate the produc-
tion of second generation biofuel, the ethanol from a 
hemicellulosic hydrolyzate obtained from sugarcane 
leaves and pointers, sugarcane juice and their mixture, 
fermented by two different yeasts. 
 
 

MATERIALS AND METHODS  
 

Raw material  
 

The raw material obtained from sugarcane variety RB867515 

 
 
 
 
(straw, pointers and juice) was collected from a production unit in 
the region of Jaboticabal, SP. The straw and pointers were 
subjected to hydrolysis process. Before and after this process, 
these fractions were characterized as cellulose, hemicellulose and 
lignin (Van Soest and Robertson, 1985). The sugarcane juice was 
adjusted and available to fermentative process. 
 
 

Hydrolysis  
 

In order to obtain the hemicellulosic hydrolyzate, 2 kg of leaves and 
pointers previously dried in an aerated-oven at 60°C to constant 
weight were used. Acid hydrolysis of the hemicellulosic fraction was 
performed in a 40 L reactor under the following conditions: 
temperature of 121°C, residence time of 20 min, and 105 ml of 
sulfuric acid in 20 L of water. 
 
 

Musts 
 

To obtain the hemicellulosic hydrolyzate must (HHM), the hydrolysis 
fraction were initially detoxified for the removal of the fermentation 
inhibitors. The solution pH was adjusted to 7.0 by the addition of 
calcium oxide (CaO), followed by an adjustment to pH 4.0 using 
phosphoric acid (H3PO4). Furthermore, the hydrolyzate underwent 
adsorption using activated carbon (1%) in an incubator at 50°C 
(B.O.D) for 30 min. At the end of each pH adjustment step, the 
hydrolyzate was centrifuged and filtered (Marton, 2002), resulting in 
the must to be fermented.  

To obtain the sugarcane juice must (SJM), the original juice was 
subjected to clarification process for the removal of impurities. This 
process consisted of 300 mg/L of phosphoric acid and pH adjusted 
to (6.0 ± 0.1) with calcium hydroxide (0.76 mol/L) of analytical 
reagent grade (a.r.). The lime juice was then heated to 100 to 
105°C and was transferred to beakers, and allowed to rest for 20 
min for all impurities settling. To promote high settling rate, the 
beakers contained a polymer (Flomex 9074 – 2 mg/L) that group 
the small amount of impurities in high molecular weight flocs. After 
that, the juice was filtered through a 14 µm filter paper in order to 
separate the precipitated impurities, thereby resulting in a clarified 
juice. The clarified juice was standardized with distilled water to 16° 
Brix (soluble solids), and its pH was adjusted to 4.5 with sulfuric 

acid ( 0.3) at a temperature of 30°C, resulting in the must. 
The third must (HSJM) was obtained by mixing the sugarcane 

juice must and hemicellulosic hydrolysate must in the ratio 1:1 (v/v). 
 
 

Yeast strains 
 

The following yeasts were isolated and mixed at the ratio of (1:1) 
(four replications): 1. J10 (Rhodotorula glutinis -xylose metabolizing) 
obtained from a stock-culture maintained at 4°C provided by the 
yeast bank of the Laboratory of Sugar and Ethanol Technology of 
the Department of Technology - School of Agrarian and Veterinary 
Sciences, UNESP, SP, Jaboticabal, (Guidi, 2000); 2. FT858 
(Saccharomyces cerevisiae - used for industrial ethanol production) 
with the following characteristics: high-yield fermentation; resistant 
at low pH; tolerance to higher levels of alcohol; high viability during 
cell recycling fermentation; low foam formation; non-
flocculent yeast strain; good fermentation speed (8 h when used in 
sugarcane industry), and low residual sugar levels in the must 
(Amorim, 2011). 

The initial cell viability was determined for 72 h using a Neubauer 
cell-counter chamber (Lee et al., 1981), and a cell mass of both 
strains, containing a sufficient amount of cells to start fermentation  
(107 CFU/ml), was used.  
 
 

Fermentation and ethanol production 
 

Fermentation was performed in laboratory scale using 500 ml



Roviero et al.         521 
 
 
 

Table 1. Cellulose, hemicellulose and lignin from the straw and sugarcane tip 
before and after hydrolysis of the hemicellulose fraction. 
 

Percentage Cellulose Hemicellulose  Lignin 

Composition before acid hydrolysis 37.32 35.98 5.52 

Composition after acid hydrolysis 22.44 28.71 11.80 
 

Values are represented as means.  

 
 
 

Table 2. Analytical of pretreated substrates used for ethanol production. 
 

Evaluated parameters SJM HHM HSJM 

Brix 16.1 16 16.3 

pH 4.51 4.24 4.31 

Sulfuric Acid Concentration (g/L) 0.73 5.72 2.69 

Phenolic Compounds (g/L) 0.17 2.85 1.82 

Total Monosaccharides (g/L) 111.7 81 97.5 
 

Values are represented as means. SJM, Sugarcane juice; HHM, hemicellulosic hydrolyzate sugarcane 
leaves and pointers; HSJM, the mixture of these two substrates. 

 
 
 
Erlenmeyer flasks containing the substrate used for ethanol 
production (180 mL): SJM, HHM and HSJM.  A total cell concen-
tration of 107 CFU/mL of the following strains J10, FT858, and J10 + 
FT858 was used. The flasks after inoculation with respective 
cultures at desired cell concentration were incubated at 30± 1°C 
with continuous stirring for 72 h. Cell viability, budding and buds 
viability were determined at 0, 6, 12, 24, 36, 48, and 72 hof 
fermentation (Lee et al., 1981).  

The concentrations of sugars and ethanol were determined by 
HPLC (Waters, Milford, MA) with a Bio Rad Aminex HPX-87H 
column under the following conditions: column temperature 45°C, 
eluent: H2SO4, 0.005 mol/L, flow rate of 0.6 ml/min, and an injection 
volume of 20 μL. 

The aliquots collected at 0, 6, 12, 24, 36, 48, and 72 h of fermen-
tation, for analysis of sugar consumption and ethanol production, 
were properly diluted and filtered through a “Sep Pack” C18 filter 
(Millipore). The eluent was prepared by subjecting it to vacuum 
filtration using Millipore membrane filter (0.45 pm, Hawp) and was 
degassed in an ultrasound bath (Microsonic SX-50) for 15 min 
which was subsequently analyzed by HPLC. 
 
 
Statistical analysis 
 
The results of cell viability and ethanol production were subjected to 
analysis of variance by the F test, and the comparison of the means 
was performed by the Tukey test (Barbosa and Maldonado, 2011). 
 
 
RESULTS AND DISCUSSION 
 
The composition of the cellulose and hemicellulose was 
reduced when considering the results reported by Santos 
et al. (2012) (Table 1). After hydrolysis there was a 
reduction in the percentage of cellulose and hemi-
cellulose, and an increase in lignin concentration. 

The cellulose and hemicellulose have a low calorific 
value and after the hydrolysis process, the sugar were 

released and used as a substrate for ethanol production. 
Lignin has a high calorific value and can be used in 
cogeneration. The values obtained from cellulose, hemi-
cellulose and lignin, for the sugar cane bagasse are 
around 48, 7.8 and 34.5%, respectively. These differences 
are explained by the straw characteristics and tips of 
sugarcane used in the study, which are structurally less 
rigid than the bagasse from sugarcane stalks. 

The average values of Brix, pH, sulfuric acid concen-
tration, total monosaccharides and phenolic compounds 
of the musts are shown in Table 2. It can be seen that the 
three musts (SJM, HHM and HSJM) had similar 
characteristics in terms of pH and Brix. Regarding to total 
acidity, highest values were found in the hemicellulosic 
hydrolyzate probably because sulfuric acid (0.5%) was 
added in the hydrolysis process.  

The concentration process means an increase in the 
content of sugar and phenolic compounds, which were 
higher than the values reported in the literature. Phenolic 
compounds and other compounds that remain after 
detoxification can inhibit fermentation (Polakovic et al., 
1992) directly affecting cell viability and ethanol produc-
tion (Ravaneli et al., 2006; Garcia et al., 2010). 

The presence of toxic compounds may influence fermen-
tative organisms to an inefficient use of reducing sugar 
and formation of the product (Mussatto and Roberto, 
2004). Martinez et al. (2000) observed a synergistic effect 
when inhibitors compounds combined; including a variety 
of phenolic, aromatic compounds and several types of 
acids, derived from lignin degradation, that ethanol 
production by E. coli was affected. 

On the other hand, the results of yeast cell viability in 
the three substrates are given in Table 3, which clearly 
show that  the yeast cell viability in the sugarcane juice 



522         Afr. J. Biotechnol. 
 
 
 

Table 3. Variance analysis and comparison of means by the Tukey test (5% 
probability) of the microbiological analysis results using the musts composed of 
sugarcane juice (SJM), hemicellulosic hydrolyzate (HHM), and sugarcane juice 
+ hemicellulosic hydrolyzate (HSJM), with the strains J10, FT858, and J10  + 
FT858. 
 

Musts and yeats Cell viability (%) Budding (%) Buds viability (%) 

Musts    

SJM 88.69
A
* 7.57

A
 87.46

A
 

HHM 68.89
C
 3.67

B
 63.54

C
 

HSJM 78.59
B
 5.77

A
 77.71

B
 

    

Yeasts    

J10 83.77
A
 6.14

A
 80.27

A
 

FT858 73.84
C
 5.45

A
 69.85

B
 

J10 + TF858 78.55
B
 5.42

A
 78.58

A
 

Must X Yeasts 4.66** 15.04** 2.80
ns

 
 

**Significant at 1% (P<0.01); ns, non-significant (P≥0.05); *Means followed by the 
same uppercase in letters in a column are not significantly different according to the 
Tukey Test. 

 
 
 
must was 22.33% higher than that in the hemicellulosic 
hydrolyzate must. It was found that J10 had the best cell 
viability, while the worst viability was found for FT858; the 
mixture of these two yeasts showed intermediate viability 
values.  

There was a continuous decrease in cell viability after 
72 h of fermentation for all strains. This behavior is due to 
the natural metabolism of yeast strains since they trans-
form sugar into fermentation products such as ethanol, 
acids, glycerol and other compounds that accumulate in 
the culture medium inhibiting their metabolic process, 
negatively affecting cell viability (Amorim et al., 1996). 

The fermentation process was evaluated for 72 h, 
which in an industrial scale is considered a process too 
long for ethanol production. In the present study, the 
fermentation process occurred within the first 10 h, with 
cell viability of approximately 90, 86, and 78% for the 
sugarcane juice must, mixture (broth and hydrolyzate), 
and for the hydrolyzate must , respectively. Very low 
values around 40% were found for the hydrolyzate must 
at the end of the process due to the combination of 
inhibitory compounds which accumulate over time.  

During sugarcane juice must fermentation, cell viability 
was statistically the highest, followed by the mixture of 
the fermented hemicellulosic hydrolyzate and sugarcane 
juice. Among the yeasts, the best performance was found 
for J10 and the mixture of J10 and FT858. The strain 
FT858 had shown lowest cell viability.  

The bud was the highest in sugarcane juice broth and 
was found to be lowest in the hemicellulosic hydrolyzate. 
When strains used in the present study was compared, 
no statistical significant differences was obtained in terms 
of budding. The optimum budding index of a fermentation 
process should generally range between 5 and 15% 
(Amorim et al., 1996); while, in the present report, the 

hemicellulosic hydrolyzate was the one with values lower 
than the optimal ones reported in literature (3.67%. on 
average), probably affected by the presence of inhibitor 
compounds. 

The buds viability yeast cells in the fermentation of the 
sugarcane juice was also statistically higher, followed by 
that in the fermentation of the must composed of the 
mixture of hemicellulosic hydrolyzate and sugarcane juice. 
Among the yeasts, the best performance was found for 
J10; FT858 produced the lowest performance, and the 

mixture of J10 and FT858 produced intermediate 

performance. 
Literature reports suggest that hexoses and pentoses 

were completely consumed in the first few of fermentation 
as glucose is the universal carbon source (Schirmer-
Michel et al. 2008). Similar results has been reported by 
Cheng and coworkers (2008) in sugarcane bagasse 
hydrolyzates. Xylose consumption in this study (the main 
sugar in the hemicellulosic hydrolyzate), however, was 
not complete (Table 4).  

Our results are in accordance with the report of Toivari 
et al. (2001) wherein a higher concentration of phenolic 
compounds and acids could be responsible for lower 
production of ethanol. Evaluating the effect of the 
fermentation time (Figure 1) on the musts, it was 
observed that in 24 h of fermentation, the highest 
concentration of ethanol with the clarified broth of 
sugarcane juice yield was 70% higher than that of the 
hemicellulosic hydrolyzate (around 9 g/L) in same time 
period. The sugarcane juice must produced the highest 
level of ethanol (33 g/L), followed by the must composed 
of the mixture of hemicellulosic hydrolyzate and 
sugarcane juice (22 g/L).  

The variation in the ethanol production, cell viability, 
budding and buds viability was mainly attributed to the



Roviero et al.         523 
 
 
 

Table 4. Variance analysis and comparison of means by the Tukey test 
(5% probability) of the use of xylose by yeasts J10, FT858, and J10 + 
FT858. 
 

Time of fermentation (h) 
Use of xylose by yeasts 

J10 FT858 J10 + FT858 

0 49.80
A
 56.55

A
 52.51

A
 

6 37.51
B
 45.91

B
 42.96

B
 

12 34.49
B
 35.76

C
 35.67

C
 

24 24.15
C
 25.80

D
 27.03

D
 

36 23.40
C
 21.49

DE
 22.24

DE
 

48 22.55
C
 20.45

DE
 19.03

EF
 

72 18.09
C
 18.59

E
 14.74

F
 

Teste F 53.92** 92.26** 81.69** 
 

**Significant at 1% (P<0.01); *Means followed by the same uppercase in 
letters in a column are not significantly different according to the Tukey Test. 

 
 
 

 
 

Figure 1. Graphical representation of the unfolding of the musts and yeasts (J10. FT858 and J10 + 
FT858) over a 72 h period for ethanol production. 

 
 
 
composition of the pretreated substrates, which contain 
large concentration of inhibitory compounds; which were 
not efficiently removed during the detoxification process 
and this might have negatively influenced the final result. 
Some toxic compounds can stress fermentative organisms 
to an inefficient utilization of sugar resulting in product 
formation decreases (Silva, 2004). 

The final ethanol concentration varies according to the 
concentration of sugar, nutrients, contaminants, and inhibi-
tors presents in the substrate. Accordingly, it was found 
that only one single detoxification process was not sufficient 

for the removal of acids and phenolic compounds, which 
negatively influenced the production of ethanol from the 
hemicellulosic hydrolyzate. The detoxification method has 
to be based on concentrations and the degree of microbial 
inhibition caused by the compounds. To a certain types of 
compounds, better results can be obtained by combining 
two or more different detoxification method (Silva, 2004). 

In the present investigation, the level of ethanol produced 
using clarified broth of sugarcane juice, although lower 
than most of the literature reports using sugarcane juice, 
in the present investigation, the level of ethanol produced 

 



524         Afr. J. Biotechnol. 
 
 
 
using clarified broth of sugarcane juice was the higher 
(about 9 g/L) compared with 1.5 g/L reported by Fugita 
(2010) that used sugarcane bagasse as raw material and 
J10 yeasts.  

In conclusion, we observed highest cell viability and 
ethanol production in the clarified broth of sugarcane juice 
using the strain J10. The detoxification process used 
promoted a partial removal of acids and phenolic 

compounds. The use of a yeast co-culture produced the 
best performance in ethanol production. The pointer and 
straw cane are an important raw material to be 
considered for the ethanol production. 
 
 
Conflict of interests 
 
The authors did not declare any conflict of interest. 
 
 
ACKNOWLEDGMENTS 
 
CAPES is acknowledged for the master scholarship 
granted to the first author. 
 
 
REFERENCES 
 
Amorim HV (2011). How much does select an industrial yeast? V Week 

of Alcoholic Fermentation “Jayme Rocha de Almeida”. Piracicaba: 
ESALQ / USP. 

Amorim HV, Basso LC, Alves DG (1996). Alcohol production processes: 
monitoring and control. Fermentec/Fealq/ESALQ - Univ. of São Paulo 
93p. 

Barbosa JC, Maldonado Júnior W (2011). AgroEstat: System statistical 
analysis of agronomic trials. Univ. Estadual Paulista.  

Cheng KK, Cai BY, Zhang JA, Ling HZ, Zhou YJ, Ge JP, Xu JM (2008). 
Sugarcane bagasse hemicellulose hydrolysate for ethanol production 
by acid recovery process. Biochem. Eng. J. 38(1):105–109. 

Conab - National Supply Company (2013). Monitoring of the Brazilian 
harvest: sugarcane. 2013/2014 harvest. Available in: 
http://www.conab.gov.br/OlalaCMS/uploads/arquivos/13_08_08_09_
39_29_boletim_cana_portugues_-_abril_2013_1o_lev.pdf. Accessed 
on: 25 April 2013. 

Canilha L, Chandel AK, Milessi TSS, Antunes FAF, Freitas WLC, Felipe 
MGA,  Silva SS (2012). Bioconversion of Sugarcane Biomass into 
Ethanol: An Overview about Composition, Pretreatment Methods, 
Detoxification of Hydrolysates, Enzymatic Saccharification, and 
Ethanol Fermentation. J. Biomed. Biotechnol. 

Foloni LL, Velini ED, Souza ELC, Carbonari C (2010). Dynamics of s-
metolachlor herbicides diuron and using humic acids. Fulvic and fish 
hydrolyzate as adjuvants. applied on straw sugarcane sugar. 
Brazilian Congress of weed science. 

Fugita TPL (2010). Performance yeasts metabolize xylose to produce 
ethanol hydrolyzed hemicellulosic sugarcane bagasse. 
Dissertation.Univ. Estadual Paulista.  

Garcia DB, Ravaneli GC, Madaleno LL, Mutton MA, Mutton MJR 
(2010). Damages of spittlebug onsugarcane quality and fermentation 
process. Sci. Agric. 67:555-561.  

 
 
 
 
 

 
 

 
 
 
 
Guidi RH (2000). Characterization, classification and determination of 

molecular genetic markers strains and contaminants yeast in the 
fermentation process. Dissertation. Univ. Estadual Paulista. 

Lee SS, Robinson FM, Wong HY (1981). Rapid determination of yeast 
viability. Biotechnology Bioengineering Symposium.  

Martin C, Almazán O, Marcet M, Jonsson LJ (2007). A study of three 
strategies for improving the fermentability of sugarcane bagasse 
hydrolysates for fuel ethanol production. Int. Sugar J. 109(1297):33-
35, 37-39. 

Martinez A, Rodriguez ME, York SW, Preston J, Ingram LO (2000). 
Effects of Ca (OH) 2 treatments (“overliming”) on the composition and 
toxicity of bagasse hemicellulose hydrolysates. Biotechnol. 
Bioeng. 69(5):526-536. 

Marton JM (2002). Evaluation of various activated carbons and 
adsorption conditions for treating the hydrolyzate hemicellulosic 
sugar cane bagasse for the biotechnological obtain xylitol. 
Dissertation. Universidade de São Paulo. 

 Mussatto SI, Roberto IC (2004). Alternatives for detoxification of 
diluted-acid lignocellulosic hydrolyzates for use in fermentative 
processes: a review. Bioresour. Technol. 93(1):1-10. 

Nunes MR., Guarda EA, Serra JC V, Martins ÁA (2013). Agroindustrial 
residues ethanol production potential of second generation in Brazil. 
Revista Liberato 14(22):135-150. 

Oderich EH, Filippi EE (2013). The different speeches in the debate 
about biofuels and the options of the Brazilian state. J. Economic 
Universidade Estadual de Goiás.  

Olsson L, Hahn-Hägerdal B (1996). Fermentation of lignocellulosic 
hydrolysates for ethanol production. Enzyme Microb. Technol. 18(5): 
312-331. 

Polakovic M, Handriková G, Kosik M (1992). Inhibitory effects of some 
phenolic compounds on enzymatic hydrolysis of sucrose. Biomass 
Bioenergy. 3:369-371. 

Ravaneli GC, Madaleno LL, Presotti LE, Mutton MA, Mutton MJR 
(2006). Spittlebug infestation in sugarcane affects ethanolic 
fermentation. Sci. Agric. 63:6 

Rodrigues FA (2007). Evaluation of sugarcane bagasse Acid Hydrolysis 
technology. Dissertation. Univ. Estadual de Campinas.  

Santos FA, De Queiróz JH, Colodette JL, Fernandes AS, Guimarães 
VM, Rezende ST (2012). Potential of straw sugarcane for ethanol 
production.  Quim. Nova 35:5.  

Schirmer-Michel AC, Flôres SH, Hertz F, Matos GS, Ayub MA (2008). 
Production of ethanol from soybean hull hydrolysate by osmotolerant 
Candida guilliermondii NRRL Y-2075. Bioresour. Technol. 
99(8):2898-2904. 

Silva DDV, Felipe MGA, Mancilha IM, Luchese R H, SILVA S S (2004). 
Inhibitory effect of acetic acid in bioconversion of xylose in xylitol by 
Candida guilliermondii in sugarcane bagasse hydrolysate. Brazilian J. 
of Microbiol. 35(3). 

Toivari MH, Aristidou A, Ruohonen L, Penttilla M (2001). Conversion of 
xylose to ethanol by recombinant Saccharomyces cerevisiae: 
Importance of xylulokinase (XKS1) and oxygen availability. Metab. 
Eng. 3(3):236-249.  

Van Soest PJ, Robertson JR (1985). Analysis of forages and fibrous 
foods: a laboratory manual for animal science. Illaca: Coronell 
University, 202pp.