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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 43, 2015 

A publication of 

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

Chief Editors: Sauro Pierucci, Jiří J. Klemeš 
Copyright © 2015, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-34-1; ISSN 2283-9216                                                                               

 

Determination of Enzyme (Cellulase from Trichoderma reesei) 
Kinetic Parameters in the Enzymatic Hydrolysis of H2SO4-

Catalyzed Hydrothermally Pretreated Sugarcane Bagasse at 
High-Solids Loading 

Laura Plazas Tovar, Emília Savioli Lopes, Maria Regina Wolf Maciel, Rubens 
Maciel Filho 

School of Chemical Engineering, University of Campinas, UNICAMP, Zipcode 13083–852, Campinas–SP, Brazil  
 
lplazast@feq.unicamp.br 
 
Enzymatic kinetic studies of celulignin material obtained from acid-catalyzed hydrothermally pretreated 
sugarcane bagasse at high-solids loading (S / 25%), acid concentration (A) equal to 1.0; 2.0 and 3.0% w/v and 
pretreatment time (tP) equal to 30; 90 and 150 min were carried out using the synergistic action of cellulase 
from T. reesei and cellobiase from Aspergillus niger. 
The kinetic experiments were carried out at 50 oC, 150 rpm and 3 h with substrate (water insoluble solids after 
pretreatment - WIS) loading range between 30 gsubstrate/Lsol and 100 gsubstrate/Lsol, and mixed with cellulase (at 
5.0; 15.0; 30.0 and 60.0 FPU cellulase/gsubstrate) and β-glucosidase (at 33.0 IU β-glucosidase/gsubstrate) 
enzymes. A Michaelis-Menten dependence on the cellulase from T. reesei concentration and substrate 
concentration plots were obtained based on experimental data. The rate constant, Km and maximum reaction 
rate attainable, Vmax were determined to characterize the cellulase-catalyzed reaction.  
Results showed that the cellulase from T. reesei behavior was highly specific for each WIS fraction obtained 
under a combination of [A-S-tP] where Vmax varies greatly as enzyme (cellulase) concentration rises. For 
example, Vmax values when considered a substrate obtained at [1.0% w/v - 25% - 30 min] and [3.0% w/v - 
25% - 30 min] using 5.0 FPU cellulase/gsubstrate(WIS) and [1.0% w/v - 25% - 90 min] and [3.0% w/v - 25% - 90 
min] using 60.0 FPU cellulase/gsubstrate(WIS) were 5.96±0.27 gGLC/LSOLh; 2.90±0.05 gGLC/LSOLh; 5.16±0.18 
gGLC/LSOLh; 7.48±0.81 gGLC/Lh, respectively. Dependence on the Km of enzyme-catalyzed reaction exhibited a 
considerably variation with the substrate nature and the enzymatic kinetic conditions establishing that Km for 
the cellulase from T. reesei –substrate complex was between 54.81 gGLC/LSOL and 209.99 gGLC/LSOL. 

1. Introduction 

The enzymatic hydrolysis is a heterogeneous reaction catalyzed by cellulases, distinguished by an insoluble 
substrate (cellulose) and a soluble catalyst (enzymes). The complete hydrolysis of the cellulose requires the 
combined action of multiple enzymes with different substrate specificities (Kumar et al., 2008), and offers the 
potential for a long term reduction in costs, since it is possible to attain high yields under less critical conditions 
of pressure, temperature and chemical attack (Canilha et al., 2011). 
 
Kinetic modeling of enzymatic saccharification results in a complex procedure comprising the kinetics of 
enzyme-catalyzed reactions: Michaelis-Menten kinetics, enzyme Inhibition and the enzyme-substrate 
interactions among others. Bansal et al. (2009) provides an overview of the models published in the open 
literature about enzymatic mechanism on cellulose hydrolysis. In their review are presented eighteen works 
about empirical models where the main predicted variables were: the glucose concentration, glucan to glucose 

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1543096 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Plazas Tovar L., Savioli Lopes E., Wolf Maciel M.R., Maciel Filho R., 2015, Determination of enzyme (cellulase from 
trichoderma reesei) kinetic parameters in the enzymatic hydrolysis of h2so4-catalyzed hydrothermally pretreated sugarcane bagasse at high-
solids loading, Chemical Engineering Transactions, 43, 571-576  DOI: 10.3303/CET1543096

571



conversion and hydrolysis yield. On the other hand, they presented Adsorption and Michaelis – Menten based 
models clustered in five groups: Michaelis – Menten, Product inhibition, Quasi Steady State assumption, 
Adsorption based approach, BG –β-glucosidase). 
 
For the adsorption based approach to approximate the kinetic equations governing the enzymatic hydrolysis 
and analyzing the enzyme-substrate reactions, Philippidis and Hatzis (1997) and Philippidis et al. (1992), 
defined a mathematical model based on quality and concentration of the cellulosic-substrate; quality and 
concentration of the cellulase and β-glucosidase enzyme system and the mode of interaction between 
substrate and enzyme (Figure 1). 
 

[ ] { }
[ ] [ ]

[ ]
[ ] [ ]

*

1 1
*
2

2

2

exp
1,3

1

1

i
i

B G

m
G

k C t
r i

B G
K K

k B
r

G
K B

K

λ−
= =

+ +

=
 

+ + 
 

   

Cellulose [C] Cellobiose [B]

Glucose [G]

r1

r2r3

where:
[C], [B] and [G]: are the concentrations (g/L) of cellulose, cellobiose, glucose
K1B, K1G and K2G: are inhibition constants (g/L)
k1 *, k2* and k3 * : are the lumped specific rate constants for cellulose (h-1) and 
cellobiose (g/L h) hydrolysis
λ: s the rate of decrease in the specific surface area of cellulose (h-1)

Rate constants of the heterogeneous cellulose hydrolysis

[ ]
[ ]

* i
i

eq

k enzyme
k

K enzyme
=

+

where:
ki: are the maximum specific cellulose hydrolysis rates (h-1)
[enzyme]: concentration of the cellulase and β-glucosidase 
enzyme complex (FPU/gsubstrate or IU /gsubstrate, respectively)
Keq: is the cellulase enzyme saturation constant (g/L)

Michaelis-Menten dependence on the cellulase concentration

[ ]( )*2 2 1 Lk k enzimeg K L= −
where:
k2: is the specific cellobiose hydrolysis rate (g/IU h)
[enzymeg]: concentration of the β-glucosidase enzyme complex 
(IU /gsubstrate)
KL: is the β-glucosidase adsorption constant to lignin (L/g)
L: is the lignin concentration (g/L)

Homogeneous cellobiose hydrolysis

 

Figure 1: Philippidis based kinetic model: adsorption of cellulose and β-glucosidase onto lignin 

 
Moreover, aiming to determine lumped specific rate constants for cellulose using the Philippidis and Hatzis 
(1997) and Philippidis et al. (1992) model associated to a Michaelis-Menten dependence on the cellulose, 
Kumar et al. (2008) described a methodology to ensure the validity of the steady state assumption for a 
standard enzyme-substrate reaction. In this sense, based on Philippidis and Hatzis (1997) and Philippidis et 
al. (1992) model to describe the enzymatic hydrolysis from lignocellulosic biomass, the present manuscript is 
an attempt to analyze the kinetic activator constant (Km) and maximum reaction rate attainable or theoretical 
maximal velocity, Vmax based on enzymatic kinetic investigation of celulignin material from H2SO4-catalyzed 
hydrothermally pretreated sugarcane bagasse at high-solids loading (S / 25%), acid concentration (A) equal to 
1.0; 2.0 and 3.0% w/v and pretreatment time (tP) equal to 30; 90 and 150 min. For such an enzymatic complex 
of cellulase from T. reesei and cellobiase from Aspergillus niger was used. 

2. Material and methods 

Sugarcane bagasse (SCB) was donated by a Brazilian sugar-alcohol-co-generation mill (Usina São João, 
Araras, São Paulo - Brazil) and its composition is presented in Figure 2. 

572



H2SO4-catalyzed hydrothermal pre-treatment and enzymatic digestibility experiments were carried out as 
exhibited in Figure 2. Water insoluble solids (WIS) and liquid streams were analyzed based on standard 
procedures (Canilha et al., 2011, Gouveia et al., 2009, Sluiter et al., 2008). 
 

---------------------------
41.81 ± 3.31 g

Cellulose

31.00 ± 2.54 g
Hemicellulose

17.08 ± 2.19 g 
Total Lignin

 8.93 ± 1.16 g
Extractives

 2.53 ± 0.13 g
Ash

---------------------------

Enzymatic
hydrolysate

Acid
hydrolysate

WIS(EH)

Cellulase, from Trichoderma reesei ATCC 26921
Cellobiase from Aspergillus niger Novozyme 188

(50 
o
C); (0 - 3 h)

5.0; 15.0; 30.0; 60.0 FPU/g
substrate (WIS)

; 33.0 IU/g
substrate (WIS)

Hydrolysis

WIS

Pretreatment

Biomass: SCB
H

2
SO

4
 solution: 

1.0% w/v - 3.0% w/v
S=25%

(121 
o
C)

(30, 90 and 150 min)

H
2
SO

4
 pretreatment Enzymatic hydrolysis

The solid fraction was washed over 
a 400 mesh wire sieve with warm water at 60 °C 

to raise the pH to ~6 and prepared to enzymatic digestibility

loading range between 30 g/L and 100 g/L

 

Figure 2: Enzymatic kinetic studies of celulignin material obtained from acid-catalyzed hydrothermally 
pretreated sugarcane bagasse 

 

2.1 Method of modelling: Michaelis-Menten kinetics  

The Michaelis-Menten (MM) equation is the model of enzyme kinetics for a one-substrate (S) enzyme-
catalyzed (E) reaction to product (P) which quantitatively relates the initial rate, the maximum rate, and the 
initial substrate concentration to the Michaelis constant Km (Figure 3). Furthermore, enzyme-catalyzed 
reaction is characterized by the formation of a complex between the enzyme and its substrate (ES) (Berg et 
al., 2002). 

1 2

1 2

k k

k k
S E ES E P

− −

⎯⎯→ ⎯⎯→+ +←⎯⎯ ←⎯⎯The MM equation

Consideration 1 Consideration 2

Only consider initial time:
 [P] is neglected
 Formation products reaction is 
irreversible

1 2

1

k k

k
S E ES E P

−

⎯⎯→+ ⎯⎯→ +←⎯⎯

Then:
oInitial rate v0=k2[ES]
o[Etotal]=[E]+[ES]
oRate formation of ES=k1[S]([E]total-[ES])
oRate of breakdown of ES=k-1[ES]+k2[ES]

Rate of ES formation = Rate of ES breakdown
Where:

k1[S]([E]total-[ES])=k-1[ES]+k2[ES]

[ ] [ ][ ]

[ ] 1 2
1

total
S E

ES
k k

s
k

−

=
 +

+  
 

oInitial rate v0=k2[ES]

[ ][ ]

[ ]
0 2

1 2

1

total
S E

v k
k k

s
k

−

=
 +

+  
 

Consideration 3

 [S] >> [E] total
[ES] = [E] total
As the concentration of substrate 
increases, the enzyme becomes saturated 
with substrate.

[ ]max 2 totalV k E=

[ ]
[ ]

max
0

1 2

1

S V
v

k k
s

k
−

=
 +

+  
 

[ ]
[ ]

max
0

m

S V
v

s K
=

+

 

Figure 3: Considerations to use the Michaelis-Menten equation to estimate Philippidis and Hatzis (1997) and 
Philippidis et al. (1992) model parameters 

Based on Michaelis-Menten equation, it is possible to estimate k1*, k2* and k3* (Figure 1) and described the 
kinetic behavior of enzyme by Eq(1) considering a variation in solid substrate at different soluble enzyme 
concentration (Carvalho et al., 2013, Magalhães et al., 2010). 

[ ]
[ ]

max
0

m

V S
v

K S
=

+
 (1) 

where: Vmax is the maximal velocity for the initial concentration of adsorption sites on the substrate 
(gGLC/LSOLh); Km is the corresponding half-saturation constant (gGLC/LSOL), and [S] is the substrate 
concentration (gsubstrate/L).  

573



3. Results and discussion 

3.1 Estimation of kinetic parameters for cellulase 

The initial rate of the glucose released from cellulose presented in the H2SO4-catalyzed hydrothermally 
pretreated sugarcane bagasse (under a combination of [A-S-tP] equal to [1.0% w/v - 25% - 90 min]; [2.0% w/v 
- 25% - 90 min] and [3.0% w/v - 25% - 90 min]) by the synergistic action of cellulase from T. reesei and 
cellobiase from Aspergillus niger as a function of substrate concentration is shown in Figure 4. 
 
Experimental data showed the effect of the H2SO4-catalyzed hydrothermal pretreatment of sugarcane 
bagasse, the substrate concentration and the enzyme concentration on the initial enzymatic hydrolysis during 
3 h (Figure 4). Due to polymeric nature, it is observed that it is not a linear behavior and it rises as the 
substrate concentration and enzyme concentration increase up to substrate become limiting (about 80 
gsubstrate/LSOL).  
 

20 40 60 80 100

 

At A=2.0% w/v
 [E]=5 FPU/g

substrate
   

 [E]=15 FPU/g
substrate

 [E]=30 FPU/g
substrate

 

 [E]=60 FPU/g
substrate

 

S/ g
substrate

/L
sol

20 40 60 80 100

 

At A=3.0% w/v

S/ g
substrate

/L
sol

20 40 60 80 100

0.8

1.6

2.4

3.2

4.0

4.8

 
At A=1.0% w/v

V
 /
  

g
G

L
C
 /

 L
s
o
l h

S/ g
substrate

/L
sol

 

Figure 4: Initial rate of the glucose released from cellulose presented in the H2SO4-catalyzed hydrothermally 
pretreated sugarcane bagasse 

Initial rates were based on the quantification of glucose after 3 h of hydrolysis guarantying a linear region of 
the time curve. Table 1 lists the calculated Vmax and Km from the enzymatic hydrolysis data by nonlinear 
regression following the Eq(1). For high values of enzyme concentration (60.0 FPU/gsubstrate), the ratio 
substrate and solution (SOL) became limited and the initial rate asymptotically approaches to a maximum as 
being: 2.81±0.25 gGLC/LSOL h, 2.62± - gGLC/LSOL h and 4.51±0.59 gGLC/LSOL h, respectively. Similar trends were 
observed for the others substrates obtained from different pretreatment conditions. 
 
Comparing the hydrolysis of substrate pretreated at acid concentration equal to 1.0, 2.0 and 3.0% w/v at the 
same cellulase enzyme concentration, it is observed that acid concentration in the pretreatment increases the 
total sugar (glucose) yield on the saccharification process about two times when acid concentration rises from 
1.0 to 3.0% w/v. Moreover, results evidenced that increasing enzyme (from 5.0 to 60.0 FPU/gsubstrate), it is 
produced higher amount of soluble reducing sugars, although for enzyme concentration between 15.0 and 
30.0 FPU/gsubstrate, for H2SO4-catalyzed hydrothermally pretreated sugarcane bagasse at 1.0% w/v, small 
differences were observed because of the substrate saturation. 
 
Kinetics parameters were determined using Eq(1). A maximum rate, Vmax values, when considered a substrate 
obtained at [1.0% w/v - 25% - 30 min] and [3.0% w/v - 25% - 30 min] using 5.0 FPU cellulase/gsubstrate(WIS) and 
[1.0% w/v - 25% - 90 min] and [3.0% w/v - 25% - 90 min] using 60.0 FPU cellulase/gsubstrate(WIS) were 5.96±0.27 
gGLC/LSOLh; 2.90±0.05 gGLC/LSOLh; 5.16±0.18 gGLC/LSOLh; 7.48±0.81 gGLC/LSOLh, respectively. Initial rate of 
enzymatic hydrolysis were calculated from the MM model and compared with the experimental results (Figure 
4) and the MM model fits well with the experimental results reporting a adjustable-R2 higher than 0.93.

574



 

   

575



Carvalho et al. (2013) studied the influence of substrate concentration for the exploded sugarcane bagasse 
treated with 4% NaOH during the enzymatic hydrolysis. Analyses during enzymatic hydrolysis were carried out 
for substrate loads ranges between 11.11 gsubstrate/LSOL and 111.11 gsubstrate/LSOL. Results reported a Vmax = 6.3 
gGLC/LSOLh and Km = 8.78 gGLC/LSOL. Thus, the dependence on the Km of enzyme-catalyzed reaction exhibited 
a considerably variation with the substrate nature and the enzymatic kinetic conditions establishing that Km for 
the cellulase from T. reesei – substrate complex was between 54.81 gGLC/LSOL and 209.99 gGLC/LSOL. Higher 
Km values indicate that the cellulase from T. reesei binds the substrate weakly and due to wide variation in Km, 
it could be an indication of the presence of an inhibitor and/or loss of enzyme activity through adsorption to the 
lignin present in the substrate. 

4. Conclusions 

The influence of enzyme concentration (between 5.0 and 60.0 FPU/gsubstrate) and substrate concentration 
(between 30 and 100 gsubstrate/LSOL) on the production of glucose was studied by the Michaelis–Menten model 
showing good correlation with experimental data. The parameters Vmax and Km have been determined with 
high accuracy. 
 
Acknowledgements 

The authors gratefully acknowledge the financial support provided by São Paulo Research Foundation-
FAPESP (Grant N°. 2012/10857-3 and 2008/57873-8). 
 
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