Thermal Generation of Aroma Compounds from Tea and Tea

The heat processing of tea leads to many complex chemical changes in tea. Tea's taste and aroma is affected by heat in at least three ways: by reducin...
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Thermal Generation of Aroma Compounds from Tea and Tea Constituents 1

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Tei Yamanishi , Michiko Kawakami , Akio Kobayashi , Tsuyoko Hamada , and Yulina Musalam 2

1

Ochanomizu University, Ohtsuka, Bunkyo-ku, Tokyo 112, Japan Research Institute for Tea and Cinchona, Gambung, Bandung 40001 Indonesia

2

The heat processing of tea leads to many complex chemical changes in tea. Tea's taste and aroma is affected by heat in at least three ways: by reducing the content of bitter soluble catechins, by the development of roast aromas and by the thermal degradation of β-carotene. Studies pertaining to the heat-induced changes in tea and appropriate model systems are reviewed. Additional investigations are required to more fully understand the thermal generation of aroma compounds from tea. Thermal processing i s a part of tea manufacture, whether for green, oolong, black or other types of tea. The aroma of tea i s greatly influenced by the type of heat treatment the tea receives. The chemical changes occuring i n tea during heat processing are very complex and not f u l l y understood. In addition, tea aroma may be formed through more than one route. This paper describes some of the chemical changes resulting from heating tea and two model systems that may be important i n the generation of tea aroma. Comparison of Chinese vs Japanese Tea Processing Tea i s made from the tender young leaves of Camellia sinensis. The young leaves are c a l l e d "tea flush" or "tea shoot tips". The production of tea from the tea flush i s outlined i n Figure 1. In the processing of green tea, the tea flush i s f i r s t steamed in the case of Japanese "sen-cha" or pan-fired to produce Chinese "kamairi-cha". This heat treatment inactivates enzymes i n the tea leaves. Steaming produces fewer chemical changes than pan-firing. The heating conditions i n the f i n a l drying and r e f i n i n g stages influence the flavor of the finished green tea product. As the moisture content of the tea leaves decrease, more s i g n i f i c a n t chemical changes, both q u a l i t a t i v e l y and quantitatively, occur. No pyrazines or pyrroles are found i n the aroma concentrate of 0097-6156/89/0409-0310$06.00/0 c 1989 American Chemical Society

Withered j—-^Panning Tea Leaves 150-160°C 8-10 min

Figure 1.

85°C 20 min

Crude Oolong Tea

J

Fermented Tea Leaves

BLACK TEA

Hot Wind Type o r Drum H e a t i n g Type

-->Ref i n i n g

Final Heating^Rolling

^ B l a c k Tea 80-90°C 15^20 min

-•^Drying

Refined Green Tea

Heat Treatment during Tea Manufacturing.

Rm. Temp.

-^Rolling—->Drying

Crude Geen Teal

Secondary Primary HeatingHeating->S t e a m i n g — ^ R o l l i n g — * R o l l i n g - • ^ R o l l i n g

Crude ^ D r y i n g — i j G r e e n Tea (Sen-cha) 150-100 70 Rm. Temp. 45-50 70-v75 Temp. (°C) 100 20^5 30^40 20^30 5-10 30-40 Time (min) 0.5-4.0 35 40 10 12 3 5 60 60 Moisture(%) 80 Crude >Pan F i r i n g — - ^ R o l l i n g — * P a n F i r i n g — * D r y i n g - - - ^ S e c o n d a r y — ^ F i n a l - i(Green Tea (Kamairi-cha)l Drying Drying (Parehing) 100 80 Temp.(°C) 230 Rm. Temp. 150 110 25-35 40-60 Time (min) 8-10 10 10-15 15 20 5-10 Moisture(%) 60 60 55 40

OOLONG TEA

Tea Flush

GREEN TEA

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I

S

ι

S3

ν©

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THERMAL GENERATION OF AROMAS

the steam processed sen-cha (1)· In pan-fired kamairi-cha, however, several of these roasty flavored compounds have been detected. Figure 2 compares gas chromatograms of the aroma concentrates from pan-fired Chinese green vs Japanese tea. The Japanese tea was from Kumamoto Prefecture i n southern Japan while the Chinese was a Longjing style tea. As seen from the chromatograms, more v o l a t i l e s are formed i n the Chinese Longjing tea. The Longjing tea was browner i n color indicating that more strenuous heating conditions are used for the Chinese tea compared to those used for Japanese kamairi-cha. As seen i n Table I, the concentration of pyrazines, pyrroles and ionone related compounds (from β-carotene) were greater in Longjing than i n Japanese kamairi-cha (2).

Figure 2. Gas Chromatograms of the Aroma Concentrates from Chinese Longjing Tea and Japanese Tea.

Green tea i s usually made from Camellia sinensis var. sinensis (small leaf type). In China, jasmine tea i s made from common kamairi-cha (from var. sinensis) while var. assamica (large leaf type) i s used for Indonesian jasmine tea. The Indonesian jasmine tea has a stronger roast aroma than Chinese jasmine tea (3). The var. assamica tea leaf also contains a much higher l e v e l of p o l y p h e n o l i c catechins than var. sinensis. Catechins are b i t t e r and astringent and thus a high content i s unacceptable. To reduce the concentration of soluble catechins, the pan-fired green tea i s subjected to a r e - f i r i n g p r i o r to scenting with jasmine flowers i.e. Jasminum sambac. As a result, the ref i r e d green tea has additional heat generated v o l a t i l e s . Table II shows some of the heat generated aroma compounds that have been i d e n t i f i e d (_3).

29. YAMANISHI ET AL.

Thermal Generation of Aroma Compounds from Tea

Table I. The Composition of Heat Generated Aroma Compounds from Chinese Longjing and Japanese Kamairi Tea

Peak Area %

Peak No.

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in F i g .2

Compound

Longjing

i n Aroma Japanese

11 16 18 23

Pyrazines 2,5-Dimethylpyrazine 2-Methyl-5-ethylpyrazine Trimethylpyrazine 2,5-Dimethyl-3-ethylpyrazine

0.3 0.1 0.1 0.3

-

37 40 76

Pyrroles l-Ethyl-2-formylpyrrole l-Ethyl-2-acetylpyrrole 2-Acetylpyrrole

1.8 0.5 3.0

1.8

Ionone Related Compounds 2,6,6-Trimethyl-2-OH-cyclohexanone β-Cyclocitral 2,6,6-Trimethylcyclohex-2-l,4-dione β-Ionone & (cis-jasmone) 5,6-Epoxy-fi-ionone Theaspirone D ihydroac t i n i d io1ide

1.9 1.1 0.2 3.5(1 .2) 2.2 0.5 1.7

0.8 0.5

36 38 47 74 77 92 106



-

1.1

-

2.2(3.8) 2.1

-

1.4

Adapted from Kawakami, M. and Yamanishi, T. (1983)

Table I I . Components of Indonesian Pan-fired Green Tea

Pyrazines 2-Methyl2-Ethyl-

2,5-Dimethyl2,3-Dimethy12,3,5-Trimethyl-

2,6-Dimethyl2-Methyl-5-ethyl2,3,5,6-Tetramethyl-

2-Acetyl-

l-Ethyl-2-formyl(isomer)

5-Methylfurfural

Furfuryl alcohol

2-Methyl-6-ethylPyrroles l-Ethyl-2-formylFurfural Furans Acids Hexanoic

Octanoic

Ionone related Compounds a-Ionone β-Ionone Dihydroactinidiolide 2,6,6-Trimethylcyclohex-2-enone trans-Geranic acid

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THERMAL GENERATION OF AROMAS

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Products of Heated Tea In Japan, a lower grade of green tea, "ban-cha" i s roasted to make i t s flavor more acceptable. Roasted ban-cha i s c a l l e d h o j i cha. The optimum temperature for roasting i s about 180°C. The aroma concentrate from hoji-cha has a strong c h a r a c t e r i s t i c roast aroma. Hoji-chà produced about 3 times the aroma concentrate than the o r i g i n a l ban-cha. From the basic f r a c t i o n which comprised 29% of the aroma concentrate, 19 d i f f e r e n t pyrazines were i d e n t i f i e d . The neutral f r a c t i o n which was 47% of the aroma concentrate contained furans and pyrroles along with the o r i g i n a l tea aroma. In addition, ionone related compounds such as theaspirone, dihydroactinidiolide and a large amount of β-ionone were found i n the neutral fraction. Table III shows the increase of furan and pyrrole content due to roasting of the ban-cha (4 ). Pyrazines and pyrroles are generated from amino acids and sugars by heating. β-carotene, another important component of tea leaf i s the precursor of pleasant aromatic compounds. I t i s present the var. s i n e n s i s leaves at about 21.7 mg/100 g dry weight. To c l a r i f y the role of β-carotene to the aroma of roasted green tea, β-carotene was heated i n a pyrolyzer at 180°C for 6 minutes. The reaction was carried out under a i r with and without catechin gallates, a component of tea leaves. The v o l a t i l e products were trapped i n a precolumn cooled by dry ice/acetone. The precolumn was then connected to a GC c a p i l l a r y column and the v o l a t i l e s then analyzed by GC-MS.

Table I I I .

Increase of Furans and Pyrroles during Roasting of Ban-cha to Produce Hoji-cha

Area % i n Aroma Concentrate Ban-cha

Hoji-cha

Furans Furfuryl alcohol Furfural 2-Acetylfuran 5-Methylfurfural

0.5 0.2

13.7 9.3 4.7 2.9

Pyrroles 2-Acetylpyrrole 2-Formylpyrrole l-Ethyl-2-formylpyrrole a Pyrrole derivative

0.9 0.9 0.9

5.4 2.6 4.7 9.1

Ten v o l a t i l e compounds were produced from the pyrolysis of Bcarotene. Among them, toluene, xylene, β-cyclocitral, ionene, βionone, 5,6-epoxy-β-ionone and dihydroactinidiolide were i d e n t i f i e d . The addition of catechin gallates reduced the quantity of the ten

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29. YAMANISHI ET AL.

Thermal Generation ofAroma Compounds from Tea

v o l a t i l e s by about two thirds (5). Ionone related compounds such as β-ionone, 5,6-epoxy-ionone and dihydroactinidiolide were also i d e n t i f i e d i n the aroma concentrate from sen-cha (1) . In another study, β-carotene was heated i n aqueous medium at 90°C, 120°C and 150°C. More than 40 d i f f e r e n t compounds were found i n the ether extracts by GC-MS as shown i n Figure 3. Dihydroactini­ d i o l i d e (sweet peachy aroma) was found i n highest concentration at a l l temperatures studied. At 90°C, 5-6-epoxy-B-ionone (sweet, v i o l e t - l i k e ) was found i n second highest quantity, while at 150°C, 2,6,6-trimethyl-2-hydroxy-cyclohexanone (green, citrusy) and 2,6,6trimethyl-2-hydroxy-cyclohexan-l-aldehyde ( f l o r a l , geraniol-like) were found i n large quantity. At 120°C, these compounds were more evenly balanced than at 90°C or 150°C. A balance of ionone related compounds seem to contribute to an a t t r a c t i v e green tea flavor. This data i s outlined i n Table IV (6).

90 ° C

10

20

1

1

i

30

r

1

40 min

150 ° C

10

^

20

&

a

b

h

i

M

L

N

6 x 5f°

c

d

e

^

t^^^^y 9

40

30

j

k

ι OH

fie- » 4

0 ,

Figure 3. Products of the thermal degradation of ^-carotene in aqueous medium. (Data are from ref. 6.)

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THERMAL GENERATION OF AROMAS Table IV.

Ionone Related Compounds Identified i n the Thermal Degradation of β-Carotene

Peak

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90°C Dihydroactinidiolide* 5,6-Epoxy-B-ionone 2,6,6-Trimethyl-2-hydroxycyclohexane-1-aldehyde (tentative) 2,6,6-Trimethyl-2-hydroxycyclohexanone B-Ionone 2,6,6-Trimethyl-2 3-epoxycyclohexliden-l-acetaldehyde 4-0χο-β-ionone β-Cyclocitral Ionene β-Damascone 2,6,6-Trimethyl-cyclohex-2-enone 2,6,6-Trimethyl-cyclohexanone f

*

Area 120°C

% 150°C

35.5 24.3 4.6

42.2 17.1 2.2

45.4 9.0 14.9

3.8

3.5

9.2

2.5 2.5

7.9 2.0

1.5 2.0

1.4 0.8 0.2 0.2 0.4 0.2

1.5 2.9

0.2 1.0 0.5 0.5 0.5 0.5

-0.1 0.1

Found i n pyrolized β-Carotene (_5) Data are from ref. 6.

SOURCE

The Role of Catechins Catechins are the most abundant components i n tea flush. As previously mentioned, catechins have a b i t t e r , astringent taste. The concentration of individual catechins i n tea flush are shown i n Table V. The most abundant catechin i s (-)-epigallocatechin gallate.

Table V.

(-)-Epigallocatechin gallate (-)-Epicatechin gallate (-)-Epigallocatechin (-)-Epicatechin

Catechins i n Tea Flush

(i) (ii) (iii) (iv)

10.7 3.3 3.2 1.2

14.4 4.3 2.9 1.0

% Dry Wt.

Table VI shows the decrease of catechin by heating as reported by Anan and Kato 1984 (7). The loss of catechins at 70°C i s greatly influenced by the addition of amino acids.

29.

YAMANISHI ET AL. Table VI.

Sample

Changes i n Catechin Content During Heating of Catechin-Amino Acid Blend and Catechin Alone

Time (min) at 150°C

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Thermal Generation ofAroma Compounds from Tea

30 70 30 70

Β

Loss of Catechin (%) (iii) (ii)

(i) 11.8 61.2 4.6 6.5

36.5 90.4 19.2 26.9

11.7 52.4 3.8 2.8

(iv) 28.3 80.0 14.5 38.4

Sample A:

Mixture of crude catechin, theanine, glutamic acid, arginine and serine (20:3:1:1:1) Sample B: Crude catechin alone Adapted from Anan, T. and Kato, H. (1984) (7)

L-Theanine i s the most abundant amino acid i n tea flush. V o l a t i l e s produced by pyrolysis at 180°C of (A) L-theanine, (B) (-)-epigallocatechin gallate and (C) a mixture of (A) and (B) were examined. The procedure was the same as that reported e a r l i e r for the pyrolysis of β-carotene. The results of the GC-MS analysis are shown i n Figure 4. From L-theanine alone, a large amount of Nethyl-formamide was formed, along with ethyl amine, propyl amine, 2pyrrolidone, N-ethyl-succinimide and l-ethyl-3,4-dehydropyrrolidone.

Peak a E t h y l amine b P r o p y l amine c 2-Pyrrolidone d Water e N - E t h y l formamide f N-Ethyl succinimide & l-Ethyl-3,4-dehydropyrrolidone g Unknown

0

10

20

30

40

50

60

70

80

min

Figure 4. Gas Chromatograms of Thermal Degradation Products from (A) Theanine, (B) Theanine and Epigallocatechin Gallate, and (C) E p i g a l l o c a t e c h i n Gallate. GC C o n d i t i o n s ; Column SE 30 SCOT, 15 m X 0.5 mm i.d., Column Temp., 30°C(10 min hold) 170°C(3°C/min), Carrier Gas, Helium 3.8 ml/min

317

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THERMAL GENERATION OF AROMAS

The addition of catechins (sample B) greatly reduced these products. Thus catechins show a s i m i l a r e f f e c t on the pyrolysis of β-carotene and L-theanine. (Yamanishi, T. & Hamada, T. unpublished.) Hara i n 1981 (8) reported on v o l a t i l e s produced by roasting Ltheanine and glucose at about 150°C for one hour. l-Ethyl-3,4dehydropyrrolidone was the main product. Five pyrroles, three a l k y l pyrazines and four furans which were i d e n t i f i e d by GC-MS and NMR are shown i n Table VII. With the exception of l-ethyl-3,4-dehydropyrrolidone these products are quite d i f f e r e n t than found from Lthreonine alone. Surprisingly, l-ethyl-3,4-dehydropyrrolidone has never been found i n tea aroma.

Table VII.

V o l a t i l e Compounds Identified from Roasting L-Theanine and D-Glucose

Compounds

Peak Area

l-Ethyl-3,4-dehydropyrrolidone 1-Εthy1-5-methylpyrrο1e-2-a1dehyde 5-Methyl-2-furfuryl alcohol 2,3-Dihydro-3,5-dihydroxy-6-methyl4H-pyran-4-one a Pyrrole derivative 1-Ethylpyrrole a Pyrrole derivative a Pyrrolidone derivative a Pyrrole derivative Methylpyrrole 1- Ethyl-2-acetylpyrrole 2- Acetylfuran 5-Methyl-2-furaldehyde 2,5- (or 2,6)-Dimethylpyrazine Trimethylpyrazine 2-Acetylpyrrole 2-Furaldehyde 2-Methylpyrazine Adapted from Hara, T.

(1981)

%

41.1 9.8 9.0 8.7 5.1 4.0 3.6 3.4 2.1 1·5 1.1 1.0 1.0 0.8 0.4 0.3 0.3 0.2

(8)

CONCLUSIONS It has been shown that the aroma of tea i s affected by the heat treatment received. Tea aroma and flavor are greatly influenced by catechins and proceeds by more than one pathway. The catechins influence tea aroma and flavor i n three ways. F i r s t , catechins have a b i t t e r , astringent taste. Second i n order to reduce the l e v e l of soluble catechins (i.e. i n var. assamica), a second heat treatment i s required. This r e f i r i n g produces a stronger roast aroma. Third catechins strongly influence the pyrolysis of β-carotene and Ltheanine. A tea of good quality possesses a balance of tea aroma compounds. This requires control of the heating process. Because

29. YAMANISHI ET A L

Thermal Generation ofAroma Compounds from Tea

of i t s complicated nature, further detailed research on the thermally generated aroma of tea i s necessary.

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Literature Cited 1. Takei, Y.; Ishiwata, K.; Yamanishi, T. Agric. Biol. Chem. 1976, 40, 2151-2157. 2. Kawakami, M.; Yamanishi, T. Agric. Biol. Chem. 1983, 47, 2077-2083. 3. Mussalam, Y.; Kobayshi, Α.; Yamanishi, T. Proceesings of the 10th International Congress of Essential Oils, Fragrances and Flavors, Washington, DC U.S.A., 1986, 659-668. 4. Yamanishi, T.; Shimojo, S.; Ukita, M.; Kawashima, K.; Nakatani, Y. Agric. Biol. Chem. 1973, 37, 2147-2153. 5. Kawashima, K.; Yamanishi, T. Nippon Nogeikagaku Kaishi 1973, 47, 79-81. 6. Kawakami, M. Nippon Nogeikagaku Kaishi 1982, 56, 917-921. 7. Anan, T.; Kato, H. Nippon Shokuhin Kogyo Gakkaishi 1984, 31, 321-326. 8. Hara, T. Nippon Nogeikagaku Kaishi 1981, 55, 1069-1072. RECEIVED May 11, 1989

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