Facilitatory effect of dissolved carbon dioxide in

Facilitatory effect of dissolved carbon dioxide in subcritical water for pectin hydrolysis Akiko Takahashi1), Takuya Suetsugu1), Masahiro Tanaka2), Munehiro Hoshino3), Mitsuru Sasaki1), Motonobu Goto4) 1)

Graduate School of Science and Technology, Kumamoto University, Kurokami 2-39-1, Kumamoto 860-8555 JAPAN

2)

Maruboshi Vinegar Co. Ltd., 2342 Tabara, Kawasaki-mati Tagawagun, Fukuoka, 827-0004, JAPAN 3)

4)

ASCII, Co Ltd, 2425 Tabara, Kawasaki-mati Tagawagun, Fukuoka, 827-0004, JAPAN

Bioelectorics Research Center, Kumamoto University, Kurokami 2-39-1, Kumamoto 860-8555 JAPAN

*Corresponding author, Phone: +81-96-342-3664, Fax: +81-96-342-3665, Email: [email protected]

ABSTRACT Pectin is composed of an acidic polysaccharide and several types of neutral sugars. The main chain consists of -1,4-linked D-galacturonic acid, which is partly methyl esterified. Most of pectin products are used for the production of jelly and jam because of having high viscosity, low-solubility, and gel forming properties. Recently, many properties of decomposed pectin products have been revealed. The hydrolysis of pectin and decomposition of galacturonic acid proceeds simultaneously at relatively moderate subcritical region of 140-180 oC due to easily hydrated structures. Water in contact with carbon dioxide becomes acidic due to the formation and dissociation of carbonic acid. Citrus pectin solution was used as a starting material. Pectin hydrolysis was carried out in the vessel type reactor under the hydrothermal condition with carbon dioxide below 150 oC. Under the adding of CO2 conditions, the degradation of pectin molecule proceeded slightly with increasing pressure. It was suggested that the CO2 dissolution in water exerted the catalytic effect. ATR-FTIR spectroscopy was used as an analytical tool to qualitatively determine the chemical change in the material. The ratio of methyl group in the pectin molecule was hardly changed.

Keywords: citrus pectin, galacturonic acid, ATR-FTIR

Facilitatory effect of dissolved carbon dioxide in subcritical water for pectin hydrolysis Akiko Takahashi1), Takuya Suetsugu1), Masahiro Tanaka2), Munehiro Hoshino3), Mitsuru Sasaki1), Motonobu Goto4) 1) Graduate School of Science and Technology, Kumamoto University, Kurokami 2-39-1, Kumamoto 860-8555 JAPAN 2) Maruboshi Vinegar Co. Ltd., 2342 Tabara, Kawasaki-mati Tagawagun, Fukuoka, 827-0004, JAPAN 3) ASCII, Co Ltd, 2425 Tabara, Kawasaki-mati Tagawagun, Fukuoka, 827-0004, JAPAN 4) Bioelectorics Research Center, Kumamoto University, Kurokami 2-39-1, Kumamoto 860-8555 JAPAN

Aug. 28. 2011 Kumamoto University

Contents  Introduction  Background  Purpose of this work  Experiment 1 Batch type reaction  Result  Experiment 2 Vessel type reaction  Result  Summary

Introduction -What is pectinPectin

COOH COOCH3 Ca2+ COO

COOCOO- -OOC Ca2+

Su P

COO- COOMg Ca2+ COO2+COO-

- OOC

Su

P

Ca2+ COO

P

COOH

COOH

P

Acid extraction

COOH COOCH

COOCH P

Cell walls

Commercial pectin product

Cellulose

P Phosphate group Pectin Su Neutral sugar Hydrogen bond

Industrially, pectin has been extracted from citrus peel and apple pomace using mild acid to separate from cellulose.

Introduction Relationship between Molecular Size and Use of Pectin High molecular weight pectin

Gelling agent Emulsifier Mw 200000~50000 Anti cancer effect

Enzyme

Low molecular weight pectin Mw 20000~5000

Hypolipidemic action

Enzyme

High value

Easy soluble dietary fiber

Pectic oligosaccharide 20mer~monomer Antiallergenic effect

Plant growth effect

Source of nutrient for bifidus

Pectic hydrolysis products have many properties and wide availabilities suited for various molecular sizes.

Background –Property of subcritical water※Ion product of water under ambient condition Kw= [H+][OH-]= 10-14 mol2 / L2 -5 -5 Kw=10-11 mol2 / L2

log KKWw log

-10 -10 100MPa 90MPa 80MPa 70MPa 60MPa

-15 -15

50MPa

-20 -20

40MPa 30MPa 22.1MPa 20MPa

-25 -25

15MPa 10MPa

-30 -30 0 0

100 100

200 200

300 300

400 400 [oC]

Temperature o Temperature [ C]

500 500

600 600

Figure 1 Ion product for water Subcritical water have been used as a reaction medium for hydrolysis of polysaccharide. Its reaction selectivity is given by changing the operation condition.

Purpose of this work Citrus pectin (raw material)

Subcritical water

Batch type reactor and Vessel type reactor

Subcritical water ＋ Carbon dioxide

Pectic oligosaccharide Hydrolysis of high molecular weight pectin to smaller size using subcritical water and carbon dioxide.

Experiment 1 - Batch type reaction-

Mixing heater

Reactor 5.5mL

Experimental Conditions Material ： 3 mL of 1wt % of citrus pectin solution Reaction time ： 3, 15, 30, 60 min Reaction temperature ：120, 140, 160, 180, 200oC

Result -Analysis of decomposition productsRI response

Pectin molecule Pectic oligosaccharide Galacturonic acid

160 oC, 60min

Neutral sugars Decomposition products Dyhydroxy acetone

Column: Sugar SH1011 Detector：RI, UV-Vis 430nm

Abs. 430 nm

Pectin molecule Galacturonic acid Lactic acid Formic acid Acetic acid

Void volume 0

10

20

30

40

50

60

Retention time [min]

Figure 2 HPLC chromatograms of SH1011 column obtained from 60 min of batch

reaction at 160 oC.

Result -Decomposition behavior of pectinPectin (Mw >1000) 140oC

160oC

Galacturonic acid (monomer)

180oC

200oC

100 90 80 70 60 50 40 30 20 10 0

120oC

140oC

160oC

180oC

200oC

5

Yield [%]

Residual [%]

120oC

4 3 2

1 0 0

10

20

30

40

50

60

70

0

10

Reaction time [min]

20

30

40

50

60

70

Reaction time [min]

Figure 3 Effect of reaction temperature and time on residual pectin molecule for a batch reactor

Figure 4 Effect of reaction temperature and time on yield of galacturonic acid for a batch reactor

Result -Further decomposition productsFormic acid 120 oC

140 oC

160 oC

2-furfral

180 oC

120

200 oC

3.5

oC

140

oC

160 oC

180 oC

200 oC

4

3 3 Yield [%]

Yield [%]

2.5 2 1.5 1

2

1

0.5

0

0

10

20

30

40

50

60

70

Reaction time [min]

Figure 5 Effect of reaction temperature and time on yield of formic acid for a batch reactor

0

0

10

20 30 40 50 60 Reaction time [min]

70

Figure 6 Effect of reaction temperature and time on yield of 2-furfural for a batch reactor

Result -Oligomerization behavior of pectinBatch reaction at 160 oC Pectin molecule (>Mw 10000) DP=8

Control 3 min 15 min 30 min 60 min

Galacturonic acid

RI response

DP=7 DP=6 DP=5

Column: Sugar SH1821 Detector：RI

DP=4 DP=3 DP=2

3

4

5

6

7

8

9

10

11

12

Retention time [min]

Figure 7 Oligosaccharide distribution chromatogram of hydrothermal reactive solutions at 160 oC using batch reactor.

Result Citrus pectin Hydrolysis ~120 oC

Pectic oligosaccharides Hydrolysis ~120 oC

Hydrolysis and further decomposition proceed simultaneously with ・Progress of reaction time and ・Rise of reaction temperature

Galacturonic acid Dehydration ~160 oC

2-furfural

Decomposition ~120 oC

Organic acids

Shorter reaction time and Lower reaction temperature

Experiment 2 -Vessel type reactorBPR

P Gas meter

Feed pump Chiller

1% Pectin solution T

CO2 pump Heater

Metering valve

Sample

Stirrer

N2

CO2

Vessel:30mL

Experimental Conditions Feed material： 25 mL of 1wt % of citrus pectin solution Reaction time ： 30 min Reaction pressure：30 MPa Reaction temperature ：100, 120, 140, 150 oC

Result -Effect of adding CO2Add CO2

N2

[MPa]

30

10

20

Pectin molecule

Acetic acid

30

(b) UV

(a) RI 100 oC

120

oC

Intensity

CO2 10MPa CO2 10MPa

CO2 20MPa

CO2 20MPa CO2 30MPa

CO2 30MPa N2 30MPa

140 oC 4

5

6

7

8

9

10 11 4

Retention time [min]

Figure 8 Appearance of samples

N2 30MPa

5

6

7

8

9

10 11

Retention time [min]

Figure 9 Effect of adding CO2 on the HPLC chromatograms of reaction solutions

Conclusions  Pectic oligosaccharide was obtained under hydrothermal condition without using catalyst.  Hydrolysis and further decomposition of pectic substances proceed simultaneously with progress of reaction time and rise of reaction temperature.  Slight catalysis effect has been confirmed by adding carbon dioxide in pectin hydrolysis.

ACKNOWLEDGEMENT This research was supported by Kumamoto University Global COE Program “Global Initiative Center for Pulsed Power Engineering”.

Thank you very much for your kind attention!

-Complex structure of pectin moleculeH H

Homogalacturonan

O

COOH

OH

O OH

H

H O COOCH3

H

H

O H

H

OH H

O

H

H

OH

OH

H

COOH O

H

H

O COOCH3

OH

H

O H

OH

H

H

OH

O n

a-1,4-linked D-galacturonic acid

Rhamnogalacturonan I

Rhamnogalacturonan II Glucronic acid

Glacturonic acid

Arabinose Xylose

Galactose Fucose

Apiose

4-O-cetyl-2-O-methylfucose

Aceric acid

Rhamunose

2-methylxylose

Kdo

M Methyl group

Dha

Figure 1 The canonical primary structure of pectin

-Solubility of carbon dioxide in subcritical water0.045

Solubility of CO2 (mol fraction)

60MPa Wiebe et.al, (1939) Wiebe et.al, (1940) A. N. Sabirzyanov, (2003)

0.04 0.035

40MPa

0.03 0.025

30MPa

0.02

15MPa

30MPa 15MPa

7.5MPa

0.015

20MPa

10MPa

10MPa

7.5MPa

0.01 0.005 0

0

20

40

60

80

100

Temperature [oC]

120

140

160