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Continuous enzymatic synthesis of lactulose in packed-bed reactor with immobilized Aspergillus oryzae β-galactosidase
Accepted Manuscript Continuous enzymatic synthesis of lactulose in packed-bed reactor with immobilized Aspergillus oryzae β-galactosidase Cecilia Guerrero, Felipe Valdivia, Claudia Ubilla, Nicolás Ramírez, Matías Gómez, Carla Aburto, Carlos Vera, Andrés Illanes PII: DOI: Reference:
S0960-8524(18)31662-6 https://doi.org/10.1016/j.biortech.2018.12.018 BITE 20775
To appear in:
Bioresource Technology
Received Date: Revised Date: Accepted Date:
25 October 2018 3 December 2018 6 December 2018
Please cite this article as: Guerrero, C., Valdivia, F., Ubilla, C., Ramírez, N., Gómez, M., Aburto, C., Vera, C., Illanes, A., Continuous enzymatic synthesis of lactulose in packed-bed reactor with immobilized Aspergillus oryzae β-galactosidase, Bioresource Technology (2018), doi: https://doi.org/10.1016/j.biortech.2018.12.018
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1
Continuous enzymatic synthesis of lactulose in packed-bed reactor with
2
immobilized Aspergillus oryzae β-galactosidase.
3
Cecilia Guerrero1*, Felipe Valdivia1, Claudia Ubilla1, Nicolás Ramírez1, Matías Gómez1, Carla
4
Aburto1, Carlos Vera2, Andrés Illanes1.
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1. School of Biochemical Engineering, Pontificia Universidad Católica de Valparaíso (PUCV), Valparaíso, Chile. 2. Department of Biology, Faculty of Chemistry and Biology, Universidad de Santiago de Chile (USACH), Santiago, Chile. *: corresponding author. Tel. 56 32- 2272035; E-mail address: [email protected]
9 10
Abstract
11
Lactulose synthesis from fructose and lactose in continuous packed-bed reactor operation
12
with glyoxyl-agarose immobilized Aspergillus oryzae β-galactosidase is reported for the first
13
time. Alternative strategies to conventional batch synthesis have been scarcely explored for
14
lactulose synthesis. The effect of flow rate, substrates ratio and biocatalyst-inert packing
15
material mass ratio (MB/MIM) were studied on reactor performance. Increase in any of these
16
variables produced an increase in lactulose yield (YLu) being higher than obtained in batch
17
synthesis at comparable conditions. Maximum YLu of 0.6 g·g
18
4.5, 50 % w/w total sugars, 15 mL·min-1, fructose/lactose molar ratio of 12 and MB/MIM of
19
1/8 g·g-1; at such conditions yield of transgalactosylated oligosaccharides (YTOS) was 0.16
20
g·g-1, selectivity (lactulose/TOS molar ratio) was 5.4 and lactose conversion (XLactose) was
21
28 %. Reactor operation with recycle had no significant effect on yield, producing only some
22
decrease in productivity.
23
Keywords: β-galactosidase, lactulose, continuous operation, packed-bed reactor, glyoxyl agarose.
-1
was obtained at 50 °C, pH
24 25
1. Introduction
26
Lactulose (4-O-β-D-galactopyranosyl-D-fructose) is a synthetic non-digestible disaccharide
27
with interesting bioactive properties (Panesar & Kumari, 2011; Nooshkam et al., 2018) that
28
has received much attention in recent years due to its therapeutic and nutrition properties
29
(Wang et al., 2013; Wu et al., 2017; Nooshkam et al., 2018). Lactulose is produced
1
30
industrially by alkaline isomerization of lactose (Zokaee et al., 2002; Aider & de Halleux,
31
2007). However, chemical synthesis has several drawbacks: a high amount of inorganic
32
catalyst is required, yields are moderate (0.2 to 0.8 g lactulose/g lactose), significant lactulose
33
degradation and unwanted byproduct formation occur due to the harsh reaction conditions
34
making product purification complex and costly (Hicks & Parrish, 2002; Aider & de Halleux,
35
2007; Lima de Albuquerque et al., 2018). Therefore, developing an enzymatic process for
36
lactulose production aims to the purpose of increasing yield, reducing product degradation
37
and contamination with hard-to-remove byproducts, in compliance with the guidelines of
38
sustainable chemistry (Schumann, 2002; Panesar & Kumari, 2011; Guerrero et al., 2015a).
39
So, production of lactulose by enzyme biocatalysis is a promising alternative for outpacing
40
the inherent constraints of chemical synthesis (Schuster-Wolff-Bühring et al., 2010; Panesar
41
& Kumari, 2011; Guerrero et al., 2011). Biocatalysis offers also the advantage that high
42
purity lactose is not required as in the case of the less selective chemical synthesis (Guerrero
43
et al., 2017a). The most commonly used biocatalytic route for lactulose synthesis is the
44
transgalactosylation of lactose with fructose catalyzed by β-galactosidase; however, yields
45
are quite lower than in chemical synthesis (Panesar & Kumari, 2011; Guerrero et al., 2017a).
46
Several strategies have been proposed for increasing lactulose yield, including the screening
47
for β-galactosidases from different sources (Lee et al., 2004; Guerrero et al., 2015a; Cardoso
48
et al., 2017), the use of different immobilized enzymes (Albayrak & Yang, 2002a; Bernal et
49
al., 2013; Urrutia et al., 2013; Guerrero et al., 2018; Rehbein et al., 2019) and the use of
50
different reaction modes of operation (Foda & Lopez-Leiva, 2000; Chockchaisawasdee et
51
al., 2004; Mayer et al., 2010; Guerrero et al., 2015b; Sitanggang et al., 2015; Guerrero et al.,
52
2017b; Rehbein et al., 2019).
53 54
The use of continuously operated reactors with immobilized β- galactosidases has been
55
applied to the hydrolysis of lactose rather than to the synthesis of transgalactosylated
56
oligosaccharides (Rodriguez-Colinas et al., 2016).
57 58
Due to the kinetics of lactulose synthesis, continuous packed-bed reactors (CPBR) and batch
59
reactors are more adequate than continuous stirred tank reactors (CSTR) for the synthesis of
60
transgalactosylated oligosaccharides (TOS), namely galacto-oligosaccharides (GOS) and
2
61
fructosyl-galacto-oligosaccharides (fGOS), since the high conversion required implies a low
62
substrate concentration at reactor outlet. This means that in CSTR the enzyme will act at such
63
low substrate concentrations disfavoring transgalactosylation (Foda & Lopez-Leiva, 2000;
64
Albayrak & Yang, 2002a; Chockchaisawasdee et al., 2004; Vera et al., 2013). The synthesis
65
of transgalactosylated oligosaccharides in continuous mode of operation is quite useful since
66
higher efficiency can be obtained than in batch mode operation (Eskandarloo &
67
Abbaspourrad, 2018), which agrees with what was reported by Chockchaisawasdee et al.,
68
(2004) showing that, under the same operational conditions, a higher productivity of GOS
69
synthesis was obtained with Kluyveromyces lactis β- galactosidases in continuous than in
70
batch operation, while no significant difference was observed in product distribution.
71 72
Use of CPBR is a rather unexplored field for lactulose synthesis, even though this type of
73
reactor is usually employed for large-scale enzymatic processes because of its high
74
efficiency, easy operation and favorable kinetic pattern. Efficiency of CPBR relates mainly
75
to its high catalyst mass to reactor volume ratio (Nakkharat & Haltrich, 2007), easy retention
76
of catalyst within the reactor and reduced shear stress, being therefore the most used reactor
77
configuration (Hama et al., 2011; Illanes et al., 1992).
78 79
The purpose of this work is the evaluation of lactulose synthesis from fructose and lactose in
80
CPBR operation with glyoxyl-agarose immobilized Aspergillus oryzae β- galactosidase.
81
Reactor performance is evaluated in terms of lactulose yield, productivity, selectivity and
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lactose conversion, considering flow rate, feed substrates ratio and immobilized enzyme-inert
83
packing material mass ratio as variables, selecting the conditions at which lactulose
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concentration obtained is the highest. The effect of reactor geometry is assessed by working
85
with reactors of different diameters and bed heights. Effect of recirculation rate is also
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evaluated in terms of lactulose yield and selectivity.
87 88 89 90
2. Materials and Methods
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2.1. Materials
3
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Lactulose was supplied by Discovery Fine Chemicals (Wimborne, UK). Lactose
93
monohydrate, fructose, glucose, galactose, o-nitrophenol (o-NP), o-nitrophenyl-β-D-
94
galactopyranoside (o-NPG) and GOS standards were supplied by Sigma (St Louis, MO,
95
USA). Agarose Bead Standard (6 % cross-linked with epichlorohydrin) and packed-bed
96
reactor were purchased from Agarose Bead Technologies (Madrid, Spain). All other reagents
97
were of the highest purity attainable and provided by Sigma or Merck (Darmstadt, Germany).
98
The enzyme used was Enzeco™ Fungal Lactase Concentrate, a commercial preparation of
99
Aspergillus oryzae β-galactosidase kindly donated by Enzyme Development Corporation,
100
New York, USA.
101
2.2. HPLC analysis of the reaction products
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Substrates and products of the reaction of lactulose synthesis were analyzed in a Jasco RI
103
2031 HPLC equipment, provided with refractive index detector, isocratic pump (Jasco
104
PU2080) and autosampler (Jasco AS 2055). BP-100 Ca++ columns (300 mm x 7.8 mm) for
105
carbohydrate analysis (Benson Polymeric, Reno, USA) were used. Samples were eluted with
106
milli-Q water at a flow rate of 0.5 mLmin-1. Column and detector temperatures were 80 and
107
40 °C respectively. ChromPass software was used for integrating the chromatograms.
108
Composition of samples was determined assuming that the area of each peak is proportional
109
to the weight percentage of the respective sugar (Boon et al., 1999). Standards of galactose,
110
fructose, lactulose, 4β-galactobiose and 3α-4β-3α galactotetraose were used to determine
111
their retention times checking that measurements were in the linear range.
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2.3. Immobilization of Aspergillus oryzae β-galactosidase
113
Immobilization of A. oryzae β-galactosidase in monofunctional glyoxyl-agarose supports
114
was done following the procedure described by Guisán (1988) and Guerrero et al. (2017a).
115
In order to determine the maximum hydrolytic potential of the biocatalyst, one international
116
unit of hydrolytic activity (IUH) was defined as the amount of β-galactosidase that hydrolyzes
117
1 μmol of o-NPG per minute at 45 mM o-NPG, 40 ºC and pH of 4.5 (Vera et al., 2011). The
118
glyoxyl-agarose derivatives had a specific activity of 32,000 IUHg-1 at the above assay
119
conditions.
120
4
121
2.4. Continuous synthesis of lactulose in packed-bed reactor.
122
Figure 1 shows a schematic representation of the experimental system used for the synthesis
123
of lactulose in CPBR. The reactor had an effective volume (VE) of 45 mL, temperature was
124
kept at 50°C and pH at 4.5. A chromatographic furnace was used for temperature control
125
(Figure 1) at 50 ºC in all experiments. To avoid catalyst bed compaction during operation,
126
the reactor was packed with a mixture of immobilized enzymes and 0.75 mm glass beads as
127
inert material, in different proportions
128 129
Lactulose synthesis was performed in 45 mL packed-bed reactor at 50 °C, pH 4.5, 50% (w/w)
130
total initial sugars concentration and different flow rates (1, 3, 5, 7, 9, 12 and 15 mL·min-1),
131
fructose/lactose molar ratios (2, 4, 6, 8, 12, 16 and 20) and biocatalyst/inert packing material
132
mass ratios (1/2, 1/5, 1/8, 1/11, 1/14 and 1/17). Reactor operations at different recirculation
133
rates (0.25, 0.67, 1.5 and mLrecirculation·mLfeed -1) were also tested. Recirculation rate was
134
defined as the ratio between recirculation flow and influent flow. Sugar substrates were
135
dissolved in 100 mM citrate-phosphate buffer pH 4.5 previously heated at 95 °C and then
136
cooled down to the reaction temperature. Different fructose/lactose molar ratios (F/L) were
137
fed to the reactor using a Masterflex L/S 7525 (USA) pump and Masterflex 96400-14 silicone
138
tubing cured in peroxide. 0.5 mL samples were taken every hour. Product distribution was
139
determined by analyzing the amounts of lactulose, disaccharides, trisaccharides and
140
tetrasaccharides produced. The assays were carried out in duplicate, with standard deviations
141
always below 5%. Quantification of carbohydrates was carried out as described in section
142
2.2.
143
Figure 1
144
The reactions of synthesis were evaluated in terms of the following parameters:
145
-Lactulose yield (YLu), which represents the average of the mass fraction of lactose entering
146
the reactor, which is converted into lactulose during the reactor operation: t
YLu =
∫0 F ∙ Cout Lu ∙ dt t
(Eq. 1)
out
∫0 F ∙ (Cin Lactose - CLactose ) ∙ dt
147
-TOS yield (YTOS), which represents the average of the mass fraction of lactose that enters
148
the reactor, which is converted into TOS during the reactor operation: 5
t
YTOS =
∫0 F ∙ Cout TOS ∙ dt
(Eq. 2)
out
t
∫0 F ∙ (Cin Lactose - CLactose ) ∙ dt
149 150
- Selectivity (SLu/TOS), which represents the average of the ratio between the moles of
151
lactulose and moles of TOS produced during the reactor operation: t
SLu/TOS =
∫0 F ∙ Nout Lu ∙ dt t
∫0 F ∙ Nout TOS ∙ dt
(Eq.3)
152
- Specific productivity of lactulose (πLu), which represents the amount of lactulose produced
153
(MLu) per unit mass of biocatalyst (MB) and unit reaction time (t) at the maximum lactulose
154
concentration attained: t
πLu =
∫0 Cout Lu ∙ dt
(Eq.4)
t
MB ∙ ∫0 dt
155
- Conversion of lactose (XLac), which represents the average of the mass fraction of lactose
156
that enters the reactor, which is reacted during reactor operation out
t
XLac =
in ∫0 F ∙ (CLactose - CLactose ) ∙ dt t ∫0 F∙Cin Lactose
∙dt
157
Where:
158
C
159
respectively (g·L-1).
160
C
ou t Lu
161
C
ou t TO S
162
F is the feed flow rate (mL·min-1).
163
NLouu tis the moles of lactulose at the reactor outlet (M).
164
ou t NTos is the moles of TOS at reactor outlet (M).
in L actose and
C
ou t L actose are
(Eq.5)
the lactose concentrations at the inlet and outlet of the reactor
is the lactulose concentration at the reactor outlet (g·L-1). is the TOS concentration at the reactor outlet (g·L-1).
6
165
MB is the total mass of biocatalyst in the reactor (g).
166
t is the reactor operation time (min).
167 168
3. Results and Discussion
169
3.1. Effect of the feed flow rate in the synthesis of lactulose in packed- bed reactor.
170
Table 1 shows the effect of feed flow rate on YLu, πLu, SLu/TOS and lactose conversion in the
171
synthesis of lactulose in CPBR. The feed flow rates used corresponded to hydraulic residence
172
times (VE/F) between 3 and 45 mins.
173
YLu and YTOS increased with the increase in feed flow rate (Table 1). At 12 mL·min-1, YLu
174
and YTOS obtained were 0.65 and 0.19 respectively, corresponding to a total
175
transgalactosylation yield of 0.94, which means that 94 % of the reacted lactose was
176
converted into transgalactosylated products and that synthesis prevailed over hydrolysis at
177
such operation conditions. YLu and YTOS obtained are higher than the corresponding values
178
reported for the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-
179
galactosidase in batch under similar reaction conditions, where YLu and YTOS reported were
180
0.35 and 0.1 respectively, with total transgalactosylation yield of 0.45 (Guerrero et al. 2017a).
181
This means that 55 % of the lactose was hydrolyzed and that in batch mode of operation
182
hydrolysis strongly competes with transgalactosylation. However, in CPBR at 1 mL·min-1,
183
YLu and YTOS were 0.34 and 0.04 respectively, which are similar than obtained in batch;
184
therefore, at lower flow rates hydrolysis is favored over transgalactosylation very much as it
185
occurs in batch. In agreement with these results, Song et al., (2013) reported that CPBR
186
allowed obtaining higher YLu than in batch reactor, when the former is operated at high flow
187
rates.
188
Table 1
189
As seen in Table 1, πLu increased with feed flow rate, which is consistent with the results
190
reported for the synthesis of GOS with glutaraldehyde-activated chitosan immobilized K.
191
lactis β- galactosidase in CPBR (Klein et al., 2013). Table 1 also shows that SLu/TOS and
192
XLactose decreased with feed flow rate, which agrees with the results reported by Mayer et al.
7
193
(2010) for the synthesis of lactulose in CPBR with Pyrococcus furiosus β-galactosidase
194
immobilized onto an anion-exchange resin and onto Eupergit C, and also to those reported
195
by Kang (2013) for the hydrolysis of lactose with K. lactis immobilized in Duolite A568
196
where XLactose was significantly reduced by increasing the feed flow rate, which is due to the
197
reducing residence times, so that a substantial fraction of lactose remained unreacted.
198
As seen in Table 1, SLu/TOS in CPBR was 14 at 1 mL·min-1, which is higher than the value of
199
11 obtained in batch under similar conditions. But SLu/TOS decreased with feed flow rate being
200
only 5.5 at 12 mL·min-1 (Guerrero et al., 2017a) which reflects that at high feed flow rate a
201
higher fraction of the lactose fed remains unreacted due to the low residence time (45 mins
202
at 1 mL·min-1 and 3.8 mins at 12 mL·min-1. XLactose in batch (66 %) was significantly higher
203
than in CPBR at 12 mL·min-1 (26%); lactulose yield in CPBR, despite the low XLactose, is
204
higher than in batch which allows obtaining a higher lactulose concentration. At the low flow
205
rate of 1 mL·min-1, where XLactose obtained is high, lactulose yield is low and a lower lactulose
206
concentration is obtained than in batch.
207 208
3.2. Effect of the fructose/lactose molar ratio (F/L) on the synthesis of lactulose in packed-
209
bed reactor.
210
Figure 2 shows the effect of F/L on the synthesis of lactulose in CPBR at different feed flow
211
rates (1, 3 and 5 mL·min-1).
212
Figure 2
213
As seen, at higher F/L higher YLu, SLu/TOS and πLu were obtained at all the feed flow rates
214
evaluated, while YTOS decreased. The effect of F/L is similar than reported for batch synthesis
215
where this was the variable most influencing such parameters, being the one allowing to
216
control product distribution (Guerrero et al., 2011; Guerrero et al., 2017a). So, synthesis of
217
lactulose is favored over TOS at high F/L both for batch and CSTR operation, as shown in
218
Table 2. When operating CPBR at a feed flow rate of 1 mL·min-1, YLu was lower than in
219
batch, but XLactose was similar at all substrates ratios evaluated. When increasing the feed
220
flow rate to 5 mL·min-1 YLu sharply increased being higher than in batch; however XLactose
8
221
decreased considerably due to the lower residence time. Similar results were reported by
222
Mayer et al. (2010) for the synthesis of lactulose in CPBR with Pyrococcus furiosus β-
223
galactosidase immobilized onto an anion-exchange resin and onto Eupergit C, and also to
224
those reported by Kang (2013) for the hydrolysis of lactose with K. lactis immobilized in
225
Duolite A568. In such cases, an increase in feed lactose concentration produced a decrease
226
in conversion at a given feed flow rate.
227
Table 2
228
As shown in Figures 2a and 2b, the higher the value of F/L the milder the effect of feed flow
229
rate on YLu and YTOS, being only severe in the F/L range from 2 to 6 at all feed flow rates
230
evaluated. XLactose (Figure 2e) was not affected significantly by variations in F/L at flow rates
231
under 3 mL·min-1, but at 5 mL·min-1 XLactose increased with the increase in F/L. A similar
232
pattern was observed in the batch synthesis of lactulose with soluble and glyoxyl-agarose
233
immobilized β-galactosidase (Guerrero et al., 2011; Guerrero et al., 2017a). Also, no
234
significant effect of F/L on XLactose was observed in the hydrolysis of lactose in CPBR with
235
immobilized K. marxianus cells (Panesar et al., 2010).
236
The biocatalyst remained fully active during the whole operation at the different substrates
237
ratios tested, which precluded an estimate of operation time for catalyst replacement.
238
However, Guerrero et al. (2017a) reported for the synthesis of lactulose in repeated batch
239
operation with the same biocatalyst here used that making an estimate of catalyst replacement
240
at one half-life, a total of 507 batches could be performed with a total operation time of 2823
241
h when operating the reactor at a F/L of 4, and 100 batches could be performed with a total
242
operation time of 940 h when operating the reactor at a F/L of 12. Similar total operating
243
times are to be expected in CPBR operation, allowing to produce a high mass of lactulose
244
per unit mass of biocatalyst so that a specific productivity much higher than in batch is
245
achievable with the consequent reduction in operating cost.
246
3.3. Effect of the biocatalyst/inert packing material mass ratio (MB/MIM) on the synthesis of
247
lactulose in packed- bed reactor.
248
Catalyst bed compaction during operation is one of the critical problems in CPBR, so in order
249
to reduce this effect the biocatalyst particles were mixed with particles of inert non-
9
250
compressible material (glass beads) in different proportions assessing the effect of MB/MIM
251
on reactor performance. Table 3 shows the effect of such ratio on YLu, YTOS, SLu/TOS, πLu and
252
XLactose.
253
Table 3
254
As seen in Table 3, the lower the MB/MIM the higher the values of YLu, YTOS and πLu obtained
255
in the synthesis of lactulose in CPBR. These results can be explained by the following
256
considerations: firstly, lower MB/MIM implies lower biocatalyst mass inside the reactor, since
257
the reactor volume was kept constant; secondly, the yield of transgalactosylation reactions
258
decreased at higher XLactose, because the transgalactosylation activity of β-galactosidases
259
declines at lower lactose concentrations and the presence of glucose and galactose also
260
reduces this activity (Albayrak & Yang, 2002b; Vera et al., 2002). Thus, at lower MB/MIM
261
lower XLactose conversions are reached in the reactor because there is less biocatalyst, then
262
higher YLu, YTOS and πLu are obtained because the transgalactosylation reactions prevail over
263
hydrolysis at lower XLactose- In agreement with these results, Neri et al. (2009) reported that
264
the reaction yield strongly decreased with the increase in XLactose in the case of GOS synthesis
265
with A. oryzae β-galactosidase.
266 267
3.4. Synthesis of lactulose in packed- bed reactor with recirculation.
268
The effect of recirculation on CPBR performance was evaluated in the synthesis of lactulose
269
at recirculation rates of 0.25, 0.67, 1.5 and 4 mLrecirculation·mLfeed -1 (Table 4).
270
Table 4
271
As shown in Table 4, YLu, YTOS and πLu decreased, while XLactose increased with the increase
272
in recirculation rate. This effect can be explained by considering that an increase in
273
recirculation rate will promote mixing, moving the flow pattern inside the reactor away from
274
ideal plug-flow regime (Fogler, 2017), which is the most favorable flow pattern for
275
transgalactosylation reactions according to its reaction kinetics (Splechtna et al., 2007)
276
Besides, increase in the recirculation rate implies higher concentrations of galactose and
277
glucose, which are inhibitors of the transgalactosylation activity of β-galactosidase inside the
10
278
reactor, with the consequent decrease in YLu, YTOS and πLu (Albayrak & Yang, 2002b; Vera
279
et al., 2011). It is worth noting that SLu/TOS increased at higher recirculation rates, which
280
reflects that the adverse effect on yields is stronger for the synthesis of TOS (GOS and fGOS)
281
than for lactulose. Recirculation rate is then a variable that these results suggest to be worthy
282
of optimization since it allows increasing SLu/TOS and XLactose at the expense of YLu and πLu.
283 284
4. Conclusions
285
Lactulose synthesis in CPBR is an interesting alternative to conventional batch synthesis
286
since it allows increasing lactulose and TOS yields. The effect of feed flow rate,
287
fructose/lactose molar ratio and biocatalyst to inert packing material mass ratio was evaluated
288
on reactor performance. Increase in any of these variables produced an increase in lactulose
289
and TOS yields, being them higher than reported for lactulose batch synthesis with the same
290
biocatalyst and at similar reaction conditions. The effect of reactor recirculation was also
291
assessed, but despite the increase in selectivity, no further increase in lactulose yield was
292
obtained and productivity decreased.
293 294
Acknowledgements
295
Work financed by Chilean Fondecyt Grant 1160216. We acknowledge generous donation of
296
β-galactosidase from Enzyme Development Corporation.
297 298
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299
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11. Guerrero, C., Vera, C., Plou, F., Illanes, A. 2011. Influence of reaction conditions on the
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12
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12. Guerrero, C., Vera, C., Illanes, A. 2015a. Transgalactosylation and hydrolytic activities
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13. Guerrero, C., Vera, C., Conejeros, R., Illanes, A. 2015b. Repeated-batch operation for
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14. Guerrero, C., Vera, C., Illanes, A. 2017a. Immobilization of Aspergillus oryzae β-
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galactosidase in an agarose matrix functionalized by four different methods and application
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to the synthesis of lactulose. Bioresour. Technol. 232: 53-63.
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15. Guerrero, C., Vera, C., Illanes, A. 2017b. Fed-batch operation for the synthesis of
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lactulose with β-galactosidase of Aspergillus oryzae. Bioresour. Technol. 237: 126-134.
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16. Guerrero, C., Aburto, C., Suárez, S., Vera, C., Illanes, A. 2018. Effect of the type of
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immobilization of β-galactosidase on the yield and selectivity of synthesis of
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17. Guisán, J.M. 1988. Aldehyde-agarose gels as activated supports for immobilization
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18. Hama, S., Tamalampudi, S., Yoshida, A., Tamadani, N., Kuratani, N., Noda, H., Fukuda,
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19. Hicks, K.B., Parrish F.W. 1980. A new method for the preparation of lactulose from
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20. Illanes, A., Zuñiga, M. E., Contreras, S., Guerrero, A. 1992. Reactor design for the
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enzymatic isomerization of glucose to fructose. Bioproc. Biosyst. Eng. 7: 199-204.
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21. Kang, B.C. 2013. Analysis of an immobilized β-galactosidase reactor with competitive
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product inhibition kinetics. J. Life Sci. 23: 1471-1476.
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22. Klein, M. P., Fallavena, L.P., Schöffer, J.N., Ayub, M.A.Z., Rodrigues, R.C., Ninow,
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J.L., Hertz, P.F. 2013. High stability of immobilized β-D-galactosidase for lactose hydrolysis
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and galactooligosaccharides synthesis. Carbohyd. Res. 95: 465-470.
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23. Lee, Y.J., Kim, D., Oh, D.K. 2004. Lactulose production by β-galactosidase in
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permeabilized cells of Kuyveromyces lactis. Appl. Microbiol. Biotechnol. 64: 787-793.
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24. Lima de Albuquerquer, T., Lucindo, S., Portal, A., Fernandez-Lafuente, R., Rocha, L.,
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Valderez, M. 2018. Immobilization of β-galactosidase in glutaraldehyde-chitosan and its
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application to the synthesis of lactulose using cheese whey as feedstock. Process Biochem.
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73: 65-73.
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25. Mayer, J., Kranz, B., Fischer, L. 2010. Continuous production of lactulose by
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immobilized thermostable β-glucosidasa de Pyrococcus furiosus. J. Biotechnol. 145: 387-
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393.
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26. Nakkharat, P., Haltrich, D. 2007. β-Galactosidase from Talaromyces thermophilus
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immobilized on to Eupergit C for production of galacto-oligosaccharides during lactose
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hydrolysis in batch and packed-bed reactor. World J. Microbiol. Biotechnol. 23: 759-764.
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27. Neri, D., Balcão, V., Costa, R., Rocha, I., Ferreira, E., Torres, D., Teixeira, J., 2009.
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Galacto-oligosaccharides production during lactose hydrolysis by free Aspergillus oryzae β-
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galactosidase and immobilized on magnetic polysiloxane-polyvinyl alcohol. Food Chem.,
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115: 92-99.
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28. Nooshkam, M., Babazadeh, A., Jooyandeh, H. 2018. Lactulose: Properties, techno-
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functional food applications, and food grade delivery system. Trends Food Sci. Technol. 80:
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23-24.
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29. Panesar, P.S., Kumari, S. 2011. Lactulose: Production, purification and potential
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applications. Biotechnol. Adv. 29: 940-948.
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30. Rehbein, P., Raguz, N., Schwalbe, H. 2019. Evaluating mechanical properties of silica-
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coated alginate beads for immobilized biocatalysis. Biochem. Eng. J. 141: 225-231.
14
380
31. Rodriguez-Colinas, B., Fernandez-Arrojo, L., Santos-Moriano, P., Ballesteros, A., Plou,
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F. 2016. Continuous packed bed reactor with immobilized β-galactosidase for production of
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galactooligosaccharides (GOS). Catal. 6: 189.
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32. Schumann, C., 2002. Medical, nutritional and technological properties of lactulose. An
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update. Eur. J. Nutr. 41: 17-25.
385
33. Schuster-Wolff-Bühring, R., Fischer, L., Hinrichs, J. 2010. Production and physiological
386
action of the disaccharide lactulose. Int. Dairy J. 20: 731-741.
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34. Sitanggang, A.B., Drews, A., Kraume, M. 2015. Influences of operating conditions on
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continuous lactulose synthesis in an enzymatic membrane reactor system: A basis prior to
389
long-term operation. J. Biotechnol. 203: 89-96.
390
35. Song, Y.S., Lee, H.U., Park, C., Kim, S.W. 2013. Batch and continuous synthesis of
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lactulose from whey lactose by immobilized β-galactosidase. Food Chem. 136: 689-694.
392
36. Splechtna, B., Nguyen, T. H., Haltrich, D., 2007. Comparison between discontinuous and
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continuous lactose conversion processes for the production of prebiotic galacto-
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oligosaccharides using β-galactosidase from Lactobacilius reuteri. J. Agr. Food Chem. 55,
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6772-6777.
396
37. Urrutia, P., Mateo, C., Guisan, J.M., Wilson, L., Illanes, A. 2013. Immobilization of
397
Bacillus circulans β-galactosidase and its application in the synthesis of galacto-
398
oligosaccharides under repeated-batch operation. Biochem. Eng. J. 77: 41-48.
399
38. Vera, C., Guerrero, C., Illanes, A. 2011. Determination of the transgalactosylation
400
activity of Aspergillus oryzae β-galactosidase: effect of pH, temperature, and galactose and
401
glucose concentrations. Carbohydr. Res. 346: 745-752.
402
39. Vera, C., Guerrero, C., Illanes, A., Conejeros R. 2013. Fed-batch synthesis of galacto-
403
oligosaccharides with Aspergillus oryzae β-galactosidase using optimal control strategy.
404
Biotechnol. Progr. 30: 59-67.
405
40. Wang, H., Yang, R., Hua, X., Zhao, W., Zhang W. 2013. Enzymatic production of
406
lactulose and 1-lactulose: current state and perspectives. Appl. Microbiol. Biotechnol. 97:
407
6167-6180. 15
408
41. Wu L, Xu Cen, Li S, Liang J, Xu H, Xu Z. 2017. Efficient production of lactulose from
409
whey powder by cellobiose 2-epimerase in an enzymatic membrane reactor. Bioresour.
410
Technol. 232: 305-312.
411
42. Zokaee, F., Kaghazchi, T., Zare, A., Soleimani, M., 2002. Isomerization of lactose to
412
lactulose. Study and comparison of three catalytic systems. Process Biochem. 37: 629-635.
413 414 415 416 417 418 419 420 421 422 423
Table 1: Effect of feed flow rate on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, feed fructose/lactose molar ratio of 12 and biocatalyst/inert packing material mass ratio of 1/8.
Feed Flow Rate (mL·min-1)
Y Lu
Y TOS
SLu/TOS
π Lu (g·min-1·g-1)
X Lactose
1 3 5 7 9 12 15
0.34 0.42 0.45 0.51 0.52 0.56 0.60
0.04 0.07 0.10 0.13 0.14 0.15 0.16
13.97 9.18 6.99 5.92 5.55 5.45 5.38
0.59 1.21 2.32 2.81 3.28 4.94 5.76
0.76 0.55 0.44 0.34 0.31 0.30 0.28
424 425 426 427 428 429 430 431 432
16
433 434 435 436 437 438 439 440 441 442 443 444 445 446
Table 2: Lactulose and transgalactosylated oligosaccharide yields (YLu and YTOS), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose wit glyoxyl-agarose immobilized A. oryzae βgalactosidase in continuous packed-bed reactor (CPBR) and in batch reactor operation at 50 °C, pH 4.5, 50 % w/w total carbohydrates concentration. Reactions in CPBR were conducted at different fructose/lactose molar rations and feed flow rates at a biocatalyst/inert packing material mass ratio of 1/8.
Fructose/Lactose Molar Ratio
Type of Reactor Batch Reactor*
4
1 Packed-Bed Reactor Batch Reactor*
8
Feed Flow Rate (mL·min-1) -
Packed-Bed Reactor
5 1 5
Batch Reactor* 12
Packed-Bed Reactor
1 5
Batch Reactor* 16
Packed-Bed Reactor
1 5
Batch Reactor* 20
Packed-Bed Reactor
1 5
447
Y Lu
Y TOS
SLu/TOS
X Lactose
0.29
0.15
3
0.69
0.15
0.05
4.1
0.82
0.32
0.27
1.7
0.34
0.35
0.09
6
0.69
0.33
0.04
6.7
0.71
0.42
0.16
3.9
0.40
0.36
0.07
7.9
0.72
0.33
0.04
14
0.76
0.45
0.10
7
0.44
0.37
0.051
10.7
0.76
0.34
0.02
21.5
0.80
0.43
0.07
9.8
0.50
0.37
0.04
13.5
0.80
0.33
0.02
26.1
0.78
0.04
13.6
0.56
0.41 *Data reprocessed from Guerrero et al., 2017a.
448 449 450 451
17
452 453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468
Table 3: Effect of biocatalyst/inert packing material mass ratio (MB/MIM) on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, feed flow rate of 5 mL·min -1, fructose/lactose molar ratio of 12 and 45 mL of reactor.
Biocatalyst/inert packing material mass ratio (MB/MIM)
Y Lu
Y TOS
SLu/TOS
π Lu (g·min-1·g-1)
X Lactose
1/2 1/5 1/8 1/11 1/14 1/17
0.34 0.44 0.45 0.55 0.59 0.63
0.03 0.08 0.10 0.13 0.13 0.14
14.9 8.00 6.99 6.95 6.92 6.54
0.73 1.72 2.32 3.51 3.90 4.67
0.78 0.54 0.44 0.40 0.35 0.30
469 470 471 472 473 474 475 476 477
18
478 479 480 481 482 483 484 485 486 487 488 489 490 491 492 493 494 495
Table 4: Effect of recirculation rate on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, feed flow rate of 5 mL·min -1, fructose/lactose molar ratio of 12, and biocatalyst/inert packing material mass ratio (MB/MIM) of 1/8 g·g -1.
Recirculation rate
Y Lu
Y TOS
SLu/TOS
π Lu (g·min-1·g-1)
X Lactose
0 0.25 0.67 1.5 4
0.45 0.45 0.44 0.44 0.40
0.10 0.09 0.09 0.08 0.06
6.99 7.05 7.16 8.20 9,83
2.32 1.87 1.30 0.96 0.51
0.44 0.47 0.45 0.51 0.58
496 497 498 499 500 501 502 503
19
504 505 506 507
508 509 510 511 512 513 514 515 516 517 518 519
Figure 1: Experimental set-up for packed-bed reactor operation in the synthesis of lactulose with glyoxylagarose immobilized Aspergillus oryzae β-galactosidase. 1: Heating immersion circulator, 2: Magnetic stirring plate, 3: Substrates (fructose/lactose) mixture reservoir with 50 % w/w total sugars, 4: Feeding pump, 5: Product collecting reservoir, 6: Packed-bed reactor, 7: Chromatographic oven for temperature control. 8: Recirculation pump.
6
520 521 522 523 524
20
525 526 527 0.5
0.5
a)
0.4
b)
0.4
Y Lu
Y TOS
0.3
0.3
0.2
0.2
0.1
0.1
0.0
0.0 2
4
6
8
12
16
20
2
4
8
12
16
20
Fructose/Lactose Molar Ratio
Fructose/Lactose Molar Ratio 30
4
d)
c) π Lu (g·min-1·g-1)
25 20
SLu/TOS
6
15 10
3
2
1
5 0
0 2
4
6
8
12
16
20
2
4
Fructose/Lactose Molar Ratio 1.0
6
8
12
16
20
Fructose/Lactose Molar Ratio
e)
X Lactose
0.8 0.6 0.4
0.2 0.0 2
4
6
8
12
16
20
Fructose/Lactose Molar Ratio
528 529 530 531 532
Figure 2: Effect of feed fructose/lactose molar ratio on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, biocatalyst/inert packing material mass ratio of 1/8, and feed flowrates of 1 (), 3 () and 5 mL·min-1 ().
533 534
21
535 536 537 538 539
- A. oryzae β-gal immobilized on glyoxyl agarose was tested in CPBR for the first time
540 541
- Highest YLu obtained was 0.6 g·g -1 for continuous operation in a packed bed reactor
542 543
- Flow, substrate molar ratio and enzyme/inert support affected CPBR performance
544 545
- Lactulose synthesis in CPBR is a sound alternative to conventional batch synthesis
546 547 548
22
549 550
23
S0960-8524(18)31662-6 https://doi.org/10.1016/j.biortech.2018.12.018 BITE 20775
To appear in:
Bioresource Technology
Received Date: Revised Date: Accepted Date:
25 October 2018 3 December 2018 6 December 2018
Please cite this article as: Guerrero, C., Valdivia, F., Ubilla, C., Ramírez, N., Gómez, M., Aburto, C., Vera, C., Illanes, A., Continuous enzymatic synthesis of lactulose in packed-bed reactor with immobilized Aspergillus oryzae β-galactosidase, Bioresource Technology (2018), doi: https://doi.org/10.1016/j.biortech.2018.12.018
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1
Continuous enzymatic synthesis of lactulose in packed-bed reactor with
2
immobilized Aspergillus oryzae β-galactosidase.
3
Cecilia Guerrero1*, Felipe Valdivia1, Claudia Ubilla1, Nicolás Ramírez1, Matías Gómez1, Carla
4
Aburto1, Carlos Vera2, Andrés Illanes1.
5 6 7 8
1. School of Biochemical Engineering, Pontificia Universidad Católica de Valparaíso (PUCV), Valparaíso, Chile. 2. Department of Biology, Faculty of Chemistry and Biology, Universidad de Santiago de Chile (USACH), Santiago, Chile. *: corresponding author. Tel. 56 32- 2272035; E-mail address: [email protected]
9 10
Abstract
11
Lactulose synthesis from fructose and lactose in continuous packed-bed reactor operation
12
with glyoxyl-agarose immobilized Aspergillus oryzae β-galactosidase is reported for the first
13
time. Alternative strategies to conventional batch synthesis have been scarcely explored for
14
lactulose synthesis. The effect of flow rate, substrates ratio and biocatalyst-inert packing
15
material mass ratio (MB/MIM) were studied on reactor performance. Increase in any of these
16
variables produced an increase in lactulose yield (YLu) being higher than obtained in batch
17
synthesis at comparable conditions. Maximum YLu of 0.6 g·g
18
4.5, 50 % w/w total sugars, 15 mL·min-1, fructose/lactose molar ratio of 12 and MB/MIM of
19
1/8 g·g-1; at such conditions yield of transgalactosylated oligosaccharides (YTOS) was 0.16
20
g·g-1, selectivity (lactulose/TOS molar ratio) was 5.4 and lactose conversion (XLactose) was
21
28 %. Reactor operation with recycle had no significant effect on yield, producing only some
22
decrease in productivity.
23
Keywords: β-galactosidase, lactulose, continuous operation, packed-bed reactor, glyoxyl agarose.
-1
was obtained at 50 °C, pH
24 25
1. Introduction
26
Lactulose (4-O-β-D-galactopyranosyl-D-fructose) is a synthetic non-digestible disaccharide
27
with interesting bioactive properties (Panesar & Kumari, 2011; Nooshkam et al., 2018) that
28
has received much attention in recent years due to its therapeutic and nutrition properties
29
(Wang et al., 2013; Wu et al., 2017; Nooshkam et al., 2018). Lactulose is produced
1
30
industrially by alkaline isomerization of lactose (Zokaee et al., 2002; Aider & de Halleux,
31
2007). However, chemical synthesis has several drawbacks: a high amount of inorganic
32
catalyst is required, yields are moderate (0.2 to 0.8 g lactulose/g lactose), significant lactulose
33
degradation and unwanted byproduct formation occur due to the harsh reaction conditions
34
making product purification complex and costly (Hicks & Parrish, 2002; Aider & de Halleux,
35
2007; Lima de Albuquerque et al., 2018). Therefore, developing an enzymatic process for
36
lactulose production aims to the purpose of increasing yield, reducing product degradation
37
and contamination with hard-to-remove byproducts, in compliance with the guidelines of
38
sustainable chemistry (Schumann, 2002; Panesar & Kumari, 2011; Guerrero et al., 2015a).
39
So, production of lactulose by enzyme biocatalysis is a promising alternative for outpacing
40
the inherent constraints of chemical synthesis (Schuster-Wolff-Bühring et al., 2010; Panesar
41
& Kumari, 2011; Guerrero et al., 2011). Biocatalysis offers also the advantage that high
42
purity lactose is not required as in the case of the less selective chemical synthesis (Guerrero
43
et al., 2017a). The most commonly used biocatalytic route for lactulose synthesis is the
44
transgalactosylation of lactose with fructose catalyzed by β-galactosidase; however, yields
45
are quite lower than in chemical synthesis (Panesar & Kumari, 2011; Guerrero et al., 2017a).
46
Several strategies have been proposed for increasing lactulose yield, including the screening
47
for β-galactosidases from different sources (Lee et al., 2004; Guerrero et al., 2015a; Cardoso
48
et al., 2017), the use of different immobilized enzymes (Albayrak & Yang, 2002a; Bernal et
49
al., 2013; Urrutia et al., 2013; Guerrero et al., 2018; Rehbein et al., 2019) and the use of
50
different reaction modes of operation (Foda & Lopez-Leiva, 2000; Chockchaisawasdee et
51
al., 2004; Mayer et al., 2010; Guerrero et al., 2015b; Sitanggang et al., 2015; Guerrero et al.,
52
2017b; Rehbein et al., 2019).
53 54
The use of continuously operated reactors with immobilized β- galactosidases has been
55
applied to the hydrolysis of lactose rather than to the synthesis of transgalactosylated
56
oligosaccharides (Rodriguez-Colinas et al., 2016).
57 58
Due to the kinetics of lactulose synthesis, continuous packed-bed reactors (CPBR) and batch
59
reactors are more adequate than continuous stirred tank reactors (CSTR) for the synthesis of
60
transgalactosylated oligosaccharides (TOS), namely galacto-oligosaccharides (GOS) and
2
61
fructosyl-galacto-oligosaccharides (fGOS), since the high conversion required implies a low
62
substrate concentration at reactor outlet. This means that in CSTR the enzyme will act at such
63
low substrate concentrations disfavoring transgalactosylation (Foda & Lopez-Leiva, 2000;
64
Albayrak & Yang, 2002a; Chockchaisawasdee et al., 2004; Vera et al., 2013). The synthesis
65
of transgalactosylated oligosaccharides in continuous mode of operation is quite useful since
66
higher efficiency can be obtained than in batch mode operation (Eskandarloo &
67
Abbaspourrad, 2018), which agrees with what was reported by Chockchaisawasdee et al.,
68
(2004) showing that, under the same operational conditions, a higher productivity of GOS
69
synthesis was obtained with Kluyveromyces lactis β- galactosidases in continuous than in
70
batch operation, while no significant difference was observed in product distribution.
71 72
Use of CPBR is a rather unexplored field for lactulose synthesis, even though this type of
73
reactor is usually employed for large-scale enzymatic processes because of its high
74
efficiency, easy operation and favorable kinetic pattern. Efficiency of CPBR relates mainly
75
to its high catalyst mass to reactor volume ratio (Nakkharat & Haltrich, 2007), easy retention
76
of catalyst within the reactor and reduced shear stress, being therefore the most used reactor
77
configuration (Hama et al., 2011; Illanes et al., 1992).
78 79
The purpose of this work is the evaluation of lactulose synthesis from fructose and lactose in
80
CPBR operation with glyoxyl-agarose immobilized Aspergillus oryzae β- galactosidase.
81
Reactor performance is evaluated in terms of lactulose yield, productivity, selectivity and
82
lactose conversion, considering flow rate, feed substrates ratio and immobilized enzyme-inert
83
packing material mass ratio as variables, selecting the conditions at which lactulose
84
concentration obtained is the highest. The effect of reactor geometry is assessed by working
85
with reactors of different diameters and bed heights. Effect of recirculation rate is also
86
evaluated in terms of lactulose yield and selectivity.
87 88 89 90
2. Materials and Methods
91
2.1. Materials
3
92
Lactulose was supplied by Discovery Fine Chemicals (Wimborne, UK). Lactose
93
monohydrate, fructose, glucose, galactose, o-nitrophenol (o-NP), o-nitrophenyl-β-D-
94
galactopyranoside (o-NPG) and GOS standards were supplied by Sigma (St Louis, MO,
95
USA). Agarose Bead Standard (6 % cross-linked with epichlorohydrin) and packed-bed
96
reactor were purchased from Agarose Bead Technologies (Madrid, Spain). All other reagents
97
were of the highest purity attainable and provided by Sigma or Merck (Darmstadt, Germany).
98
The enzyme used was Enzeco™ Fungal Lactase Concentrate, a commercial preparation of
99
Aspergillus oryzae β-galactosidase kindly donated by Enzyme Development Corporation,
100
New York, USA.
101
2.2. HPLC analysis of the reaction products
102
Substrates and products of the reaction of lactulose synthesis were analyzed in a Jasco RI
103
2031 HPLC equipment, provided with refractive index detector, isocratic pump (Jasco
104
PU2080) and autosampler (Jasco AS 2055). BP-100 Ca++ columns (300 mm x 7.8 mm) for
105
carbohydrate analysis (Benson Polymeric, Reno, USA) were used. Samples were eluted with
106
milli-Q water at a flow rate of 0.5 mLmin-1. Column and detector temperatures were 80 and
107
40 °C respectively. ChromPass software was used for integrating the chromatograms.
108
Composition of samples was determined assuming that the area of each peak is proportional
109
to the weight percentage of the respective sugar (Boon et al., 1999). Standards of galactose,
110
fructose, lactulose, 4β-galactobiose and 3α-4β-3α galactotetraose were used to determine
111
their retention times checking that measurements were in the linear range.
112
2.3. Immobilization of Aspergillus oryzae β-galactosidase
113
Immobilization of A. oryzae β-galactosidase in monofunctional glyoxyl-agarose supports
114
was done following the procedure described by Guisán (1988) and Guerrero et al. (2017a).
115
In order to determine the maximum hydrolytic potential of the biocatalyst, one international
116
unit of hydrolytic activity (IUH) was defined as the amount of β-galactosidase that hydrolyzes
117
1 μmol of o-NPG per minute at 45 mM o-NPG, 40 ºC and pH of 4.5 (Vera et al., 2011). The
118
glyoxyl-agarose derivatives had a specific activity of 32,000 IUHg-1 at the above assay
119
conditions.
120
4
121
2.4. Continuous synthesis of lactulose in packed-bed reactor.
122
Figure 1 shows a schematic representation of the experimental system used for the synthesis
123
of lactulose in CPBR. The reactor had an effective volume (VE) of 45 mL, temperature was
124
kept at 50°C and pH at 4.5. A chromatographic furnace was used for temperature control
125
(Figure 1) at 50 ºC in all experiments. To avoid catalyst bed compaction during operation,
126
the reactor was packed with a mixture of immobilized enzymes and 0.75 mm glass beads as
127
inert material, in different proportions
128 129
Lactulose synthesis was performed in 45 mL packed-bed reactor at 50 °C, pH 4.5, 50% (w/w)
130
total initial sugars concentration and different flow rates (1, 3, 5, 7, 9, 12 and 15 mL·min-1),
131
fructose/lactose molar ratios (2, 4, 6, 8, 12, 16 and 20) and biocatalyst/inert packing material
132
mass ratios (1/2, 1/5, 1/8, 1/11, 1/14 and 1/17). Reactor operations at different recirculation
133
rates (0.25, 0.67, 1.5 and mLrecirculation·mLfeed -1) were also tested. Recirculation rate was
134
defined as the ratio between recirculation flow and influent flow. Sugar substrates were
135
dissolved in 100 mM citrate-phosphate buffer pH 4.5 previously heated at 95 °C and then
136
cooled down to the reaction temperature. Different fructose/lactose molar ratios (F/L) were
137
fed to the reactor using a Masterflex L/S 7525 (USA) pump and Masterflex 96400-14 silicone
138
tubing cured in peroxide. 0.5 mL samples were taken every hour. Product distribution was
139
determined by analyzing the amounts of lactulose, disaccharides, trisaccharides and
140
tetrasaccharides produced. The assays were carried out in duplicate, with standard deviations
141
always below 5%. Quantification of carbohydrates was carried out as described in section
142
2.2.
143
Figure 1
144
The reactions of synthesis were evaluated in terms of the following parameters:
145
-Lactulose yield (YLu), which represents the average of the mass fraction of lactose entering
146
the reactor, which is converted into lactulose during the reactor operation: t
YLu =
∫0 F ∙ Cout Lu ∙ dt t
(Eq. 1)
out
∫0 F ∙ (Cin Lactose - CLactose ) ∙ dt
147
-TOS yield (YTOS), which represents the average of the mass fraction of lactose that enters
148
the reactor, which is converted into TOS during the reactor operation: 5
t
YTOS =
∫0 F ∙ Cout TOS ∙ dt
(Eq. 2)
out
t
∫0 F ∙ (Cin Lactose - CLactose ) ∙ dt
149 150
- Selectivity (SLu/TOS), which represents the average of the ratio between the moles of
151
lactulose and moles of TOS produced during the reactor operation: t
SLu/TOS =
∫0 F ∙ Nout Lu ∙ dt t
∫0 F ∙ Nout TOS ∙ dt
(Eq.3)
152
- Specific productivity of lactulose (πLu), which represents the amount of lactulose produced
153
(MLu) per unit mass of biocatalyst (MB) and unit reaction time (t) at the maximum lactulose
154
concentration attained: t
πLu =
∫0 Cout Lu ∙ dt
(Eq.4)
t
MB ∙ ∫0 dt
155
- Conversion of lactose (XLac), which represents the average of the mass fraction of lactose
156
that enters the reactor, which is reacted during reactor operation out
t
XLac =
in ∫0 F ∙ (CLactose - CLactose ) ∙ dt t ∫0 F∙Cin Lactose
∙dt
157
Where:
158
C
159
respectively (g·L-1).
160
C
ou t Lu
161
C
ou t TO S
162
F is the feed flow rate (mL·min-1).
163
NLouu tis the moles of lactulose at the reactor outlet (M).
164
ou t NTos is the moles of TOS at reactor outlet (M).
in L actose and
C
ou t L actose are
(Eq.5)
the lactose concentrations at the inlet and outlet of the reactor
is the lactulose concentration at the reactor outlet (g·L-1). is the TOS concentration at the reactor outlet (g·L-1).
6
165
MB is the total mass of biocatalyst in the reactor (g).
166
t is the reactor operation time (min).
167 168
3. Results and Discussion
169
3.1. Effect of the feed flow rate in the synthesis of lactulose in packed- bed reactor.
170
Table 1 shows the effect of feed flow rate on YLu, πLu, SLu/TOS and lactose conversion in the
171
synthesis of lactulose in CPBR. The feed flow rates used corresponded to hydraulic residence
172
times (VE/F) between 3 and 45 mins.
173
YLu and YTOS increased with the increase in feed flow rate (Table 1). At 12 mL·min-1, YLu
174
and YTOS obtained were 0.65 and 0.19 respectively, corresponding to a total
175
transgalactosylation yield of 0.94, which means that 94 % of the reacted lactose was
176
converted into transgalactosylated products and that synthesis prevailed over hydrolysis at
177
such operation conditions. YLu and YTOS obtained are higher than the corresponding values
178
reported for the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-
179
galactosidase in batch under similar reaction conditions, where YLu and YTOS reported were
180
0.35 and 0.1 respectively, with total transgalactosylation yield of 0.45 (Guerrero et al. 2017a).
181
This means that 55 % of the lactose was hydrolyzed and that in batch mode of operation
182
hydrolysis strongly competes with transgalactosylation. However, in CPBR at 1 mL·min-1,
183
YLu and YTOS were 0.34 and 0.04 respectively, which are similar than obtained in batch;
184
therefore, at lower flow rates hydrolysis is favored over transgalactosylation very much as it
185
occurs in batch. In agreement with these results, Song et al., (2013) reported that CPBR
186
allowed obtaining higher YLu than in batch reactor, when the former is operated at high flow
187
rates.
188
Table 1
189
As seen in Table 1, πLu increased with feed flow rate, which is consistent with the results
190
reported for the synthesis of GOS with glutaraldehyde-activated chitosan immobilized K.
191
lactis β- galactosidase in CPBR (Klein et al., 2013). Table 1 also shows that SLu/TOS and
192
XLactose decreased with feed flow rate, which agrees with the results reported by Mayer et al.
7
193
(2010) for the synthesis of lactulose in CPBR with Pyrococcus furiosus β-galactosidase
194
immobilized onto an anion-exchange resin and onto Eupergit C, and also to those reported
195
by Kang (2013) for the hydrolysis of lactose with K. lactis immobilized in Duolite A568
196
where XLactose was significantly reduced by increasing the feed flow rate, which is due to the
197
reducing residence times, so that a substantial fraction of lactose remained unreacted.
198
As seen in Table 1, SLu/TOS in CPBR was 14 at 1 mL·min-1, which is higher than the value of
199
11 obtained in batch under similar conditions. But SLu/TOS decreased with feed flow rate being
200
only 5.5 at 12 mL·min-1 (Guerrero et al., 2017a) which reflects that at high feed flow rate a
201
higher fraction of the lactose fed remains unreacted due to the low residence time (45 mins
202
at 1 mL·min-1 and 3.8 mins at 12 mL·min-1. XLactose in batch (66 %) was significantly higher
203
than in CPBR at 12 mL·min-1 (26%); lactulose yield in CPBR, despite the low XLactose, is
204
higher than in batch which allows obtaining a higher lactulose concentration. At the low flow
205
rate of 1 mL·min-1, where XLactose obtained is high, lactulose yield is low and a lower lactulose
206
concentration is obtained than in batch.
207 208
3.2. Effect of the fructose/lactose molar ratio (F/L) on the synthesis of lactulose in packed-
209
bed reactor.
210
Figure 2 shows the effect of F/L on the synthesis of lactulose in CPBR at different feed flow
211
rates (1, 3 and 5 mL·min-1).
212
Figure 2
213
As seen, at higher F/L higher YLu, SLu/TOS and πLu were obtained at all the feed flow rates
214
evaluated, while YTOS decreased. The effect of F/L is similar than reported for batch synthesis
215
where this was the variable most influencing such parameters, being the one allowing to
216
control product distribution (Guerrero et al., 2011; Guerrero et al., 2017a). So, synthesis of
217
lactulose is favored over TOS at high F/L both for batch and CSTR operation, as shown in
218
Table 2. When operating CPBR at a feed flow rate of 1 mL·min-1, YLu was lower than in
219
batch, but XLactose was similar at all substrates ratios evaluated. When increasing the feed
220
flow rate to 5 mL·min-1 YLu sharply increased being higher than in batch; however XLactose
8
221
decreased considerably due to the lower residence time. Similar results were reported by
222
Mayer et al. (2010) for the synthesis of lactulose in CPBR with Pyrococcus furiosus β-
223
galactosidase immobilized onto an anion-exchange resin and onto Eupergit C, and also to
224
those reported by Kang (2013) for the hydrolysis of lactose with K. lactis immobilized in
225
Duolite A568. In such cases, an increase in feed lactose concentration produced a decrease
226
in conversion at a given feed flow rate.
227
Table 2
228
As shown in Figures 2a and 2b, the higher the value of F/L the milder the effect of feed flow
229
rate on YLu and YTOS, being only severe in the F/L range from 2 to 6 at all feed flow rates
230
evaluated. XLactose (Figure 2e) was not affected significantly by variations in F/L at flow rates
231
under 3 mL·min-1, but at 5 mL·min-1 XLactose increased with the increase in F/L. A similar
232
pattern was observed in the batch synthesis of lactulose with soluble and glyoxyl-agarose
233
immobilized β-galactosidase (Guerrero et al., 2011; Guerrero et al., 2017a). Also, no
234
significant effect of F/L on XLactose was observed in the hydrolysis of lactose in CPBR with
235
immobilized K. marxianus cells (Panesar et al., 2010).
236
The biocatalyst remained fully active during the whole operation at the different substrates
237
ratios tested, which precluded an estimate of operation time for catalyst replacement.
238
However, Guerrero et al. (2017a) reported for the synthesis of lactulose in repeated batch
239
operation with the same biocatalyst here used that making an estimate of catalyst replacement
240
at one half-life, a total of 507 batches could be performed with a total operation time of 2823
241
h when operating the reactor at a F/L of 4, and 100 batches could be performed with a total
242
operation time of 940 h when operating the reactor at a F/L of 12. Similar total operating
243
times are to be expected in CPBR operation, allowing to produce a high mass of lactulose
244
per unit mass of biocatalyst so that a specific productivity much higher than in batch is
245
achievable with the consequent reduction in operating cost.
246
3.3. Effect of the biocatalyst/inert packing material mass ratio (MB/MIM) on the synthesis of
247
lactulose in packed- bed reactor.
248
Catalyst bed compaction during operation is one of the critical problems in CPBR, so in order
249
to reduce this effect the biocatalyst particles were mixed with particles of inert non-
9
250
compressible material (glass beads) in different proportions assessing the effect of MB/MIM
251
on reactor performance. Table 3 shows the effect of such ratio on YLu, YTOS, SLu/TOS, πLu and
252
XLactose.
253
Table 3
254
As seen in Table 3, the lower the MB/MIM the higher the values of YLu, YTOS and πLu obtained
255
in the synthesis of lactulose in CPBR. These results can be explained by the following
256
considerations: firstly, lower MB/MIM implies lower biocatalyst mass inside the reactor, since
257
the reactor volume was kept constant; secondly, the yield of transgalactosylation reactions
258
decreased at higher XLactose, because the transgalactosylation activity of β-galactosidases
259
declines at lower lactose concentrations and the presence of glucose and galactose also
260
reduces this activity (Albayrak & Yang, 2002b; Vera et al., 2002). Thus, at lower MB/MIM
261
lower XLactose conversions are reached in the reactor because there is less biocatalyst, then
262
higher YLu, YTOS and πLu are obtained because the transgalactosylation reactions prevail over
263
hydrolysis at lower XLactose- In agreement with these results, Neri et al. (2009) reported that
264
the reaction yield strongly decreased with the increase in XLactose in the case of GOS synthesis
265
with A. oryzae β-galactosidase.
266 267
3.4. Synthesis of lactulose in packed- bed reactor with recirculation.
268
The effect of recirculation on CPBR performance was evaluated in the synthesis of lactulose
269
at recirculation rates of 0.25, 0.67, 1.5 and 4 mLrecirculation·mLfeed -1 (Table 4).
270
Table 4
271
As shown in Table 4, YLu, YTOS and πLu decreased, while XLactose increased with the increase
272
in recirculation rate. This effect can be explained by considering that an increase in
273
recirculation rate will promote mixing, moving the flow pattern inside the reactor away from
274
ideal plug-flow regime (Fogler, 2017), which is the most favorable flow pattern for
275
transgalactosylation reactions according to its reaction kinetics (Splechtna et al., 2007)
276
Besides, increase in the recirculation rate implies higher concentrations of galactose and
277
glucose, which are inhibitors of the transgalactosylation activity of β-galactosidase inside the
10
278
reactor, with the consequent decrease in YLu, YTOS and πLu (Albayrak & Yang, 2002b; Vera
279
et al., 2011). It is worth noting that SLu/TOS increased at higher recirculation rates, which
280
reflects that the adverse effect on yields is stronger for the synthesis of TOS (GOS and fGOS)
281
than for lactulose. Recirculation rate is then a variable that these results suggest to be worthy
282
of optimization since it allows increasing SLu/TOS and XLactose at the expense of YLu and πLu.
283 284
4. Conclusions
285
Lactulose synthesis in CPBR is an interesting alternative to conventional batch synthesis
286
since it allows increasing lactulose and TOS yields. The effect of feed flow rate,
287
fructose/lactose molar ratio and biocatalyst to inert packing material mass ratio was evaluated
288
on reactor performance. Increase in any of these variables produced an increase in lactulose
289
and TOS yields, being them higher than reported for lactulose batch synthesis with the same
290
biocatalyst and at similar reaction conditions. The effect of reactor recirculation was also
291
assessed, but despite the increase in selectivity, no further increase in lactulose yield was
292
obtained and productivity decreased.
293 294
Acknowledgements
295
Work financed by Chilean Fondecyt Grant 1160216. We acknowledge generous donation of
296
β-galactosidase from Enzyme Development Corporation.
297 298
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299
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413 414 415 416 417 418 419 420 421 422 423
Table 1: Effect of feed flow rate on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, feed fructose/lactose molar ratio of 12 and biocatalyst/inert packing material mass ratio of 1/8.
Feed Flow Rate (mL·min-1)
Y Lu
Y TOS
SLu/TOS
π Lu (g·min-1·g-1)
X Lactose
1 3 5 7 9 12 15
0.34 0.42 0.45 0.51 0.52 0.56 0.60
0.04 0.07 0.10 0.13 0.14 0.15 0.16
13.97 9.18 6.99 5.92 5.55 5.45 5.38
0.59 1.21 2.32 2.81 3.28 4.94 5.76
0.76 0.55 0.44 0.34 0.31 0.30 0.28
424 425 426 427 428 429 430 431 432
16
433 434 435 436 437 438 439 440 441 442 443 444 445 446
Table 2: Lactulose and transgalactosylated oligosaccharide yields (YLu and YTOS), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose wit glyoxyl-agarose immobilized A. oryzae βgalactosidase in continuous packed-bed reactor (CPBR) and in batch reactor operation at 50 °C, pH 4.5, 50 % w/w total carbohydrates concentration. Reactions in CPBR were conducted at different fructose/lactose molar rations and feed flow rates at a biocatalyst/inert packing material mass ratio of 1/8.
Fructose/Lactose Molar Ratio
Type of Reactor Batch Reactor*
4
1 Packed-Bed Reactor Batch Reactor*
8
Feed Flow Rate (mL·min-1) -
Packed-Bed Reactor
5 1 5
Batch Reactor* 12
Packed-Bed Reactor
1 5
Batch Reactor* 16
Packed-Bed Reactor
1 5
Batch Reactor* 20
Packed-Bed Reactor
1 5
447
Y Lu
Y TOS
SLu/TOS
X Lactose
0.29
0.15
3
0.69
0.15
0.05
4.1
0.82
0.32
0.27
1.7
0.34
0.35
0.09
6
0.69
0.33
0.04
6.7
0.71
0.42
0.16
3.9
0.40
0.36
0.07
7.9
0.72
0.33
0.04
14
0.76
0.45
0.10
7
0.44
0.37
0.051
10.7
0.76
0.34
0.02
21.5
0.80
0.43
0.07
9.8
0.50
0.37
0.04
13.5
0.80
0.33
0.02
26.1
0.78
0.04
13.6
0.56
0.41 *Data reprocessed from Guerrero et al., 2017a.
448 449 450 451
17
452 453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468
Table 3: Effect of biocatalyst/inert packing material mass ratio (MB/MIM) on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, feed flow rate of 5 mL·min -1, fructose/lactose molar ratio of 12 and 45 mL of reactor.
Biocatalyst/inert packing material mass ratio (MB/MIM)
Y Lu
Y TOS
SLu/TOS
π Lu (g·min-1·g-1)
X Lactose
1/2 1/5 1/8 1/11 1/14 1/17
0.34 0.44 0.45 0.55 0.59 0.63
0.03 0.08 0.10 0.13 0.13 0.14
14.9 8.00 6.99 6.95 6.92 6.54
0.73 1.72 2.32 3.51 3.90 4.67
0.78 0.54 0.44 0.40 0.35 0.30
469 470 471 472 473 474 475 476 477
18
478 479 480 481 482 483 484 485 486 487 488 489 490 491 492 493 494 495
Table 4: Effect of recirculation rate on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, feed flow rate of 5 mL·min -1, fructose/lactose molar ratio of 12, and biocatalyst/inert packing material mass ratio (MB/MIM) of 1/8 g·g -1.
Recirculation rate
Y Lu
Y TOS
SLu/TOS
π Lu (g·min-1·g-1)
X Lactose
0 0.25 0.67 1.5 4
0.45 0.45 0.44 0.44 0.40
0.10 0.09 0.09 0.08 0.06
6.99 7.05 7.16 8.20 9,83
2.32 1.87 1.30 0.96 0.51
0.44 0.47 0.45 0.51 0.58
496 497 498 499 500 501 502 503
19
504 505 506 507
508 509 510 511 512 513 514 515 516 517 518 519
Figure 1: Experimental set-up for packed-bed reactor operation in the synthesis of lactulose with glyoxylagarose immobilized Aspergillus oryzae β-galactosidase. 1: Heating immersion circulator, 2: Magnetic stirring plate, 3: Substrates (fructose/lactose) mixture reservoir with 50 % w/w total sugars, 4: Feeding pump, 5: Product collecting reservoir, 6: Packed-bed reactor, 7: Chromatographic oven for temperature control. 8: Recirculation pump.
6
520 521 522 523 524
20
525 526 527 0.5
0.5
a)
0.4
b)
0.4
Y Lu
Y TOS
0.3
0.3
0.2
0.2
0.1
0.1
0.0
0.0 2
4
6
8
12
16
20
2
4
8
12
16
20
Fructose/Lactose Molar Ratio
Fructose/Lactose Molar Ratio 30
4
d)
c) π Lu (g·min-1·g-1)
25 20
SLu/TOS
6
15 10
3
2
1
5 0
0 2
4
6
8
12
16
20
2
4
Fructose/Lactose Molar Ratio 1.0
6
8
12
16
20
Fructose/Lactose Molar Ratio
e)
X Lactose
0.8 0.6 0.4
0.2 0.0 2
4
6
8
12
16
20
Fructose/Lactose Molar Ratio
528 529 530 531 532
Figure 2: Effect of feed fructose/lactose molar ratio on lactulose and TOS yields (YLu and YTOS), lactulose productivity (πLu), selectivity (SLu/TOS) and lactose conversion (XLactose) in the synthesis of lactulose with glyoxyl-agarose immobilized A. oryzae β-galactosidase in CPBR. Operating conditions: 50 °C, pH 4.5, 50 % w/w total carbohydrates, biocatalyst/inert packing material mass ratio of 1/8, and feed flowrates of 1 (), 3 () and 5 mL·min-1 ().
533 534
21
535 536 537 538 539
- A. oryzae β-gal immobilized on glyoxyl agarose was tested in CPBR for the first time
540 541
- Highest YLu obtained was 0.6 g·g -1 for continuous operation in a packed bed reactor
542 543
- Flow, substrate molar ratio and enzyme/inert support affected CPBR performance
544 545
- Lactulose synthesis in CPBR is a sound alternative to conventional batch synthesis
546 547 548
22
549 550
23