Characterization of aroma compositions in different Chinese congou black teas using GC–MS and GC–O combined with partial least squares regression

To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas chromatography–mass spectrometry (GC–MS) and gas chromatography–olfactometry (GC–O). The aroma of Chinese congou black tea was described using six...

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Published inFlavour and fragrance journal Vol. 32; no. 4; pp. 265 - 276
Main Authors Xiao, Zuobing, Wang, Hongling, Niu, Yunwei, Liu, Qiang, Zhu, Jiancai, Chen, Hexing, Ma, Ning
Format Journal Article
LanguageEnglish
Published Chichester Wiley Subscription Services, Inc 01.07.2017
Subjects
Alcohols
Aldehydes
Aroma compounds
aroma‐active compounds
Black tea
Chinese congou black tea
Chromatography
Dilution
Esters
flavor
Flavors
Fruit juices
Gas chromatography
gas chromatography-mass spectrometry
GC‐O
GC–MS
geraniol
Ketones
Lactones
least squares
Least squares method
Linalool
Mass spectrometry
Mass spectroscopy
Nerolidol
odor compounds
odors
Olfactometers
PLSR
Pyrazines
Regression analysis
Sensory evaluation
Sensory properties
Tea
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Abstract To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas chromatography–mass spectrometry (GC–MS) and gas chromatography–olfactometry (GC–O). The aroma of Chinese congou black tea was described using six sensory terms: ‘Roasted’, ‘Sweet’, ‘Malty’, ‘Green grassy’, ‘Floral’ and ‘Woody’. A total of 64 compounds including alcohols (20), aldehydes (12), ketones (12), esters and lactones (9), pyrazines (7) and other compounds (4) were identified and quantified in four Chinese black tea samples. The highest amount of volatile aroma compounds was found in Tanyang congou black tea (TY) (29.8 mg/kg), followed by Dianhong congou black tea (DH) (29.4 mg/kg), Keemun congou black tea (KM) (24.1 mg/kg) and Yixing congou black tea (YH) (23.6 mg/kg). Through aroma extract dilution analysis (AEDA) on the black tea extract, the flavour dilution factor (FD factor) ranged from 41 to 46. Trans‐linalool oxide in DH, geraniol in TY, DH and KM were identified with the highest flavour dilution (FD = 4096) factors. The relationship between tea samples, sensory attributes and aroma‐active compounds was modelled by partial least squares regression (PLSR), and the PLSR analysis revealed that pentanal showed a significant and positive correlation with the ‘Malty’ attribute, (Z)‐3‐hexen‐1‐ol showed a significant and negative correlation with the ‘Green grassy’ attribute, 2‐methylpyrazine showed a significant and negative correlation with the ‘Floral’ attribute, cis‐linalool oxide, trans‐linalool oxide and nerolidol showed a significant and positive correlation with the ‘Woody’ attribute, cis‐6‐nonen‐1‐ol and 2‐methylpyrazine showed a significant and negative correlation with the ’Woody‘ attribute. The primary aim of the current research was (1) to apply descriptive sensory analysis to describe the aroma attributes of different black teas (2) to analyze the typical aroma compounds by GC‐MS and GC‐O; (3) to elucidate the relationship between tea samples, sensory attributes, and aroma‐active compounds by PLSR. A better understanding of this knowledge will be helpful for the improvement of characteristic aroma of different cultivars of congou black teas.
AbstractList To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas chromatography-mass spectrometry (GC-MS) and gas chromatography-olfactometry (GC-O). The aroma of Chinese congou black tea was described using six sensory terms: 'Roasted', 'Sweet', 'Malty', 'Green grassy', 'Floral' and 'Woody'. A total of 64 compounds including alcohols (20), aldehydes (12), ketones (12), esters and lactones (9), pyrazines (7) and other compounds (4) were identified and quantified in four Chinese black tea samples. The highest amount of volatile aroma compounds was found in Tanyang congou black tea (TY) (29.8 mg/kg), followed by Dianhong congou black tea (DH) (29.4 mg/kg), Keemun congou black tea (KM) (24.1 mg/kg) and Yixing congou black tea (YH) (23.6 mg/kg). Through aroma extract dilution analysis (AEDA) on the black tea extract, the flavour dilution factor (FD factor) ranged from 41 to 46. Trans-linalool oxide in DH, geraniol in TY, DH and KM were identified with the highest flavour dilution (FD = 4096) factors. The relationship between tea samples, sensory attributes and aroma-active compounds was modelled by partial least squares regression (PLSR), and the PLSR analysis revealed that pentanal showed a significant and positive correlation with the 'Malty' attribute, (Z)-3-hexen-1-ol showed a significant and negative correlation with the 'Green grassy' attribute, 2-methylpyrazine showed a significant and negative correlation with the 'Floral' attribute, cis-linalool oxide, trans-linalool oxide and nerolidol showed a significant and positive correlation with the 'Woody' attribute, cis-6-nonen-1-ol and 2-methylpyrazine showed a significant and negative correlation with the 'Woody' attribute.
To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas chromatography–mass spectrometry (GC–MS) and gas chromatography–olfactometry (GC–O). The aroma of Chinese congou black tea was described using six sensory terms: ‘Roasted’, ‘Sweet’, ‘Malty’, ‘Green grassy’, ‘Floral’ and ‘Woody’. A total of 64 compounds including alcohols (20), aldehydes (12), ketones (12), esters and lactones (9), pyrazines (7) and other compounds (4) were identified and quantified in four Chinese black tea samples. The highest amount of volatile aroma compounds was found in Tanyang congou black tea (TY) (29.8 mg/kg), followed by Dianhong congou black tea (DH) (29.4 mg/kg), Keemun congou black tea (KM) (24.1 mg/kg) and Yixing congou black tea (YH) (23.6 mg/kg). Through aroma extract dilution analysis (AEDA) on the black tea extract, the flavour dilution factor (FD factor) ranged from 4 1 to 4 6 . Trans‐linalool oxide in DH, geraniol in TY, DH and KM were identified with the highest flavour dilution (FD = 4096) factors. The relationship between tea samples, sensory attributes and aroma‐active compounds was modelled by partial least squares regression (PLSR), and the PLSR analysis revealed that pentanal showed a significant and positive correlation with the ‘Malty’ attribute, (Z)‐3‐hexen‐1‐ol showed a significant and negative correlation with the ‘Green grassy’ attribute, 2‐methylpyrazine showed a significant and negative correlation with the ‘Floral’ attribute, cis‐linalool oxide, trans‐linalool oxide and nerolidol showed a significant and positive correlation with the ‘Woody’ attribute, cis‐6‐nonen‐1‐ol and 2‐methylpyrazine showed a significant and negative correlation with the ’Woody‘ attribute.
To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas chromatography–mass spectrometry (GC–MS) and gas chromatography–olfactometry (GC–O). The aroma of Chinese congou black tea was described using six sensory terms: ‘Roasted’, ‘Sweet’, ‘Malty’, ‘Green grassy’, ‘Floral’ and ‘Woody’. A total of 64 compounds including alcohols (20), aldehydes (12), ketones (12), esters and lactones (9), pyrazines (7) and other compounds (4) were identified and quantified in four Chinese black tea samples. The highest amount of volatile aroma compounds was found in Tanyang congou black tea (TY) (29.8 mg/kg), followed by Dianhong congou black tea (DH) (29.4 mg/kg), Keemun congou black tea (KM) (24.1 mg/kg) and Yixing congou black tea (YH) (23.6 mg/kg). Through aroma extract dilution analysis (AEDA) on the black tea extract, the flavour dilution factor (FD factor) ranged from 4¹ to 4⁶. Trans‐linalool oxide in DH, geraniol in TY, DH and KM were identified with the highest flavour dilution (FD = 4096) factors. The relationship between tea samples, sensory attributes and aroma‐active compounds was modelled by partial least squares regression (PLSR), and the PLSR analysis revealed that pentanal showed a significant and positive correlation with the ‘Malty’ attribute, (Z)‐3‐hexen‐1‐ol showed a significant and negative correlation with the ‘Green grassy’ attribute, 2‐methylpyrazine showed a significant and negative correlation with the ‘Floral’ attribute, cis‐linalool oxide, trans‐linalool oxide and nerolidol showed a significant and positive correlation with the ‘Woody’ attribute, cis‐6‐nonen‐1‐ol and 2‐methylpyrazine showed a significant and negative correlation with the ’Woody‘ attribute.
To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas chromatography–mass spectrometry (GC–MS) and gas chromatography–olfactometry (GC–O). The aroma of Chinese congou black tea was described using six sensory terms: ‘Roasted’, ‘Sweet’, ‘Malty’, ‘Green grassy’, ‘Floral’ and ‘Woody’. A total of 64 compounds including alcohols (20), aldehydes (12), ketones (12), esters and lactones (9), pyrazines (7) and other compounds (4) were identified and quantified in four Chinese black tea samples. The highest amount of volatile aroma compounds was found in Tanyang congou black tea (TY) (29.8 mg/kg), followed by Dianhong congou black tea (DH) (29.4 mg/kg), Keemun congou black tea (KM) (24.1 mg/kg) and Yixing congou black tea (YH) (23.6 mg/kg). Through aroma extract dilution analysis (AEDA) on the black tea extract, the flavour dilution factor (FD factor) ranged from 41 to 46. Trans‐linalool oxide in DH, geraniol in TY, DH and KM were identified with the highest flavour dilution (FD = 4096) factors. The relationship between tea samples, sensory attributes and aroma‐active compounds was modelled by partial least squares regression (PLSR), and the PLSR analysis revealed that pentanal showed a significant and positive correlation with the ‘Malty’ attribute, (Z)‐3‐hexen‐1‐ol showed a significant and negative correlation with the ‘Green grassy’ attribute, 2‐methylpyrazine showed a significant and negative correlation with the ‘Floral’ attribute, cis‐linalool oxide, trans‐linalool oxide and nerolidol showed a significant and positive correlation with the ‘Woody’ attribute, cis‐6‐nonen‐1‐ol and 2‐methylpyrazine showed a significant and negative correlation with the ’Woody‘ attribute. The primary aim of the current research was (1) to apply descriptive sensory analysis to describe the aroma attributes of different black teas (2) to analyze the typical aroma compounds by GC‐MS and GC‐O; (3) to elucidate the relationship between tea samples, sensory attributes, and aroma‐active compounds by PLSR. A better understanding of this knowledge will be helpful for the improvement of characteristic aroma of different cultivars of congou black teas.
Author Xiao, Zuobing
Niu, Yunwei
Ma, Ning
Liu, Qiang
Wang, Hongling
Zhu, Jiancai
Chen, Hexing
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  surname: Xiao
  fullname: Xiao, Zuobing
  organization: Shanghai Research Institute of Fragrance and Flavor Industry
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  givenname: Hongling
  surname: Wang
  fullname: Wang, Hongling
  organization: Shanghai Institute of Technology
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  givenname: Yunwei
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  givenname: Qiang
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  fullname: Liu, Qiang
  organization: China Tobacco Yunnan Industrial Co., Ltd
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  fullname: Zhu, Jiancai
  organization: Shanghai Institute of Technology
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  fullname: Chen, Hexing
  organization: Shanghai Institute of Technology
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  organization: Shanghai Institute of Technology
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Snippet To characterise the volatile aroma compositions of Chinese congou black teas, four types were analysed by quantitative descriptive sensory analysis, gas...
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SubjectTerms Alcohols
Aldehydes
Aroma compounds
aroma‐active compounds
Black tea
Chinese congou black tea
Chromatography
Dilution
Esters
flavor
Flavors
Fruit juices
Gas chromatography
gas chromatography-mass spectrometry
GC‐O
GC–MS
geraniol
Ketones
Lactones
least squares
Least squares method
Linalool
Mass spectrometry
Mass spectroscopy
Nerolidol
odor compounds
odors
Olfactometers
PLSR
Pyrazines
Regression analysis
Sensory evaluation
Sensory properties
Tea
Title Characterization of aroma compositions in different Chinese congou black teas using GC–MS and GC–O combined with partial least squares regression
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Volume 32
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