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Feb 13, 2019 - Agriculture, Cukurova University, 01330 Adana, Turkey. § ... Two hot teas and one cold tea were investigated and coded as 4MN (4 min/9...
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Chemistry and Biology of Aroma and Taste

Elucidation of Infusion Induced Changes in the Key Odorants and Aroma Profile of Iranian Endemic Borage (Echium amoenum) Herbal Tea Asghar Amanpour, Oscar Zannou, Hasim Kelebek, and Serkan Selli J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.9b00531 • Publication Date (Web): 13 Feb 2019 Downloaded from http://pubs.acs.org on February 14, 2019

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Journal of Agricultural and Food Chemistry

Elucidation of Infusion-Induced Changes in the Key Odorants and Aroma Profile of Iranian Endemic Borage (Echium amoenum) Herbal Tea Asghar Amanpoura,b, Oscar Zannoub, Hasim Kelebekc, Serkan Sellia,b*

a Department

of Biotechnology, Institute of Natural and Applied Sciences, Cukurova University, 01330 Adana, Turkey

b Department

of Food Engineering, Faculty of Agriculture, Cukurova University, 01330 Adana, Turkey

c Department

of Food Engineering, Faculty of Engineering, Adana Science and Technology University, 01110 Adana, Turkey

ORCID:

Asghar

Amanpour:

https://orcid.org/0000-0001-9783-691X,

Hasim

Kelebek:

https://orcid.org/0000-0002-8419-3019, Serkan Selli: https://orcid.org/0000-0003-0450-2668

*Corresponding author at: Department of Food Engineering, Faculty of Agriculture, Cukurova University, 01330 Adana, Turkey. Tel.: +90 322 3386173; fax: +90 322 3386614

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Abstract

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Infusion-induced changes in the aroma, key odorants, and their odor activity values of

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Iranian endemic herbal (Gol-Gavzaban) tea obtained from shade-dried violet-blue petals of

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borage (Echium amoenum) were studied for the first time. Two hot teas and one cold tea were

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investigated and coded as 4MN (4 minutes/98°C), 16MN (16 minutes/98°C) and 24HR (24

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hours/ambient temperature), respectively. Aromatic extracts of the tea samples were isolated

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by liquid-liquid extraction method and analyzed by gas chromatography-mass spectrometry-

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olfactometry (GC-MS-O) for the first time. According to the results of the aroma profiling, a

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total of 35 common aroma compounds comprising alcohols, acids, volatile phenols, lactones,

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aldehydes, ketone, pyrroles, and furans were identified and quantified in the tea samples.

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Indeed, it is worth noting that the aroma profiles of the borage teas were similar. However,

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the effects of the infusion techniques were clearly different as observed on the content of each

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individual and total compounds in the samples. The highest mean total concentration was

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detected in 24HR (266.0 mg/kg), followed by 16MN (247.1 mg/kg) and 4MN (216.1 mg/kg).

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1-Penten-3-ol was the principal volatile component in all borage teas. Based on the result of

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the flavor dilution (FD) factors, a combined total of 22 different key odorants were detected.

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The potential key odorants with regard to FD factors in all samples were prevailingly

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alcohols, acids and terpenes. The highest FD factors were observed in 2-hexanol (2048 in

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4MN and 24HR; 1024 in 16MN) and 1-penten-3-ol (2048 in 24HR; 1024 in 4MN and 16MN)

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in samples providing herbal and green notes. Principal component analysis (PCA) showed

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that the tea samples could clearly be discriminated in terms of their aroma profiles and key

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odorants. The findings of the current study demonstrate that the tea preparation conditions

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have a significant impact on the organoleptic quality of borage tea.

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Keywords: Borage, Echium amoenum, tea, key odorants, GC-MS-O, infusions

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Introduction

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The genus Echium (Boraginaceae) is composed of 95 species vernacular to Northern and

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Southern Africa, Europe, Iberian Peninsula, Macaronesian archipelagos and Eastern

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Mediterranean. In Iran, this genus is represented by four species. There has been an increased

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interest in Echium species, including E. amoenum, because of their medicinal and nutritional

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properties. Echium amoenum Fisch. and C. A. Mey. or borage is a biennial or perennial wild

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herbaceous plant cultivated mostly in the northern part of Iran and some regions of Europe.1

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E. amoenum is one of the oldest plants, which has been used to treat certain diseases

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throughout Iranian history. Dried violet-blue petals of E. amoenum which is known as “Gol

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Gavzaban” (ox-tongue) in the traditional medicine of Iran and consumed as a herbal tea have

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long been used as a tonic, tranquillizer, diaphoretic and as a remedy to prevent or treat several

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diseases including cough, stress, sore throat, pneumonia, benign prostate hyperplasia and

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depression.2 On the other hand, in western medicine, it has been used as antifebrile,

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antidepressant, anxiolytic, ameliorant of heart and pulmonary disturbances, poultice for

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inflammatory swellings, diuretic, laxative, emollient and demulcent and recently as a possible

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protective agent against cancer.3 Based on the estimation of the World Health Organization,

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herbal drugs are used for treating diseases by 80% of the world population because they are

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cheaper than chemical drugs. Additionally, around 30% of modern drugs are produced from

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plants and more than 66% of plant species have medical value. Iran’s ancient civilization has

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a long history in disease diagnosis and treatment by medicinal plants and Persian scientist

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Avicenna has tried to develop and subdivide this subject.4 In addition to the health benefits of

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aromatic herbal plants, they have also been used for centuries because of their aroma

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properties. Many studies have been carried out in some herbal plants and teas such as Borago

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officinalis,5 black teas,6 Chinese black fu-brick tea,7 rooibos tea,8 Longjing tea,9 Camellia

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sinensis black teas,10 tea flowers of Camellia sinensis,11 green teas,12 dill, savory,13 and

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saffron.14 A literature review revealed that the petals of E. amoenum contain anthocyanidin

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(13%), flavonoid aglycons (0.15%), and a small amount of alkaloids and volatile oils

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(0.05%).2

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Aroma of herbal teas is considered as a key attribute in consumer acceptance and product

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selection. Aroma is a perception of a large number of low molecular weight volatile

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compounds whose combination depends on species and often to the cultivar of plants.13 The

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majority of herbal plants are generally dried because high water content in the fresh plant

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causes drastic deterioration due to microbial activity and biochemical reactions. If freshly

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harvested herbal plants including E. amoenum are not dried immediately, their quality

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deteriorates in a rapid way. Water removal by dehydration stabilizes herbal plants

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microbiologically by lowering the water activity levels under the threshold for microbial

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growth (aw=0.6). During air-drying, some of the volatile compounds evaporate; whereas,

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others are partially retained and also some oxidation products emerge upon drying. Brewing

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herbal plants in water is the most common and oldest method which is often used for making

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herbal tea in Iran. Herbal tea from petals of E. amoenum which has attractive odor and taste is

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popular in Iran specifically in the northern part of the country. However, only one study was

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reported on the volatile constituents of E. amoenum petals15. In the study, aromatic extract of

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sun-dried petals was obtained by using steam-distillation extraction technique with pentane as

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the solvent and its volatile compounds were analyzed and identified by gas chromatography-

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mass spectrometry. Volatile compounds were dominated by sesquiterpenes comprising

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mainly α-cadinene, viridiflorol, α-muurolene, and ledene.15 It is worth noting that

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sesquiterpenes are terpenes or C15-terpenoids constituted by three molecules of isoprenes.

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They are found in plants, marine organisms, and fungi and are less volatile than other terpenes

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but have strong odors.

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There are several papers studying the extraction of volatile compounds directly from

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herbal plants. According to the European Pharmacopoeia,16 volatile oils are extracts isolated

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from aromatic plants only by distillation procedures such as hydrodistillation. The extracts

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separated from aromatic plants by other methods should not be considered as volatile oils

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even if they contain volatile compounds. Hydrodistillation (Clevenger and/or steam

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distillation apparatus) and organic solvent extraction (Soxhlet extractor) have both been

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extensively applied in the separation of volatile oils from herbal plants and considered as

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conventional methods. Nonetheless, these methods both tend to degrade the original plant

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flavor and change the volatile compounds because of the elevated applied temperatures and

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new flavors can be developed from non-volatile precursors by Maillard reaction, carotenoid

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degradation, and lipid oxidation. These limitations may be overcome by applying suitable

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extraction methods. Hence, a proper extraction method must be selected with the purpose of

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producing aromatic extracts with odor as close as possible to that of the studied sample.

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The volatile profile of most of the foods contains a vast number of compounds but

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very limited part of these actually gives characteristic aroma to the food. Therefore, the main

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duty in aroma investigations is to isolate the aroma-active compounds from the less odorous

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or odorless compounds existing in food.17 Screening techniques, like GC-O and aroma extract

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dilution analysis (AEDA), have provided main progress in discovering the key aroma

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compounds in a food extract.18,19 Aroma is one of the main quality factors for tea beverages;

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however, there is no study on the aroma profile and aroma-active compounds of Iranian

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herbal tea obtained from dried violet-blue petals of Borage (E. amoenum) in the literature

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except the one carried out by Ghassemi et al. (2003) which brings limited information only on

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its aroma compounds.15

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Despite the attractive flavor and health benefits of the herbal tea from the E. amoenum

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petals, no work has yet been found that investigates its aroma profile and key odorants. Thus,

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the goal of the present study was (i) to compare the volatile profile and key odorants of

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endemic Iranian herbal tea obtained from shade-dried violet-blue petals of borage (E.

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amoenum) by applying three different infusion processes; (ii) to characterize the most aroma-

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active compounds using aroma extract dilution analysis (AEDA) and finally to calculate the

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odor activity values (OAVs: ratio of concentration to odor threshold).

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Materials and methods

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Plant Material and Chemicals. Petals (approx. 4 kg) of borage used in this study were

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handpicked from a farming area of Mazandaran province in the northern part of Iran in 2017

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season. The collected petals were dried in the shade at about 30°C immediately after

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harvesting for 4–5 days. Besides, they were sorted out to remove undesirable particles or

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debris. In addition, each air-dried sample was mixed to obtain a homogeneous fine-grade

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sample. Afterwards, the shade-dried borage petals were packed into polyethylene bags and

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kept at 4°C until the analysis. Distilled water used during the analysis was purified through a

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Millipore-Q system (Milliport Billerica, Massachussets, USA). Dichloromethane was used as

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solvent after distilling. Dichloromethane and sodium sulfate were purchased from Merck

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(Darmstadt, Germany). Standard aroma compounds including acetic acid, hexanoic acid, 2-

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ethyl hexanoic acid, octanoic acid, nonanoic acid, capric acid, dodecanoic acid, 1-penten-3-ol,

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2-hexanol, 3-methyl-2-buten-1-ol, 1-octanol, benzyl alcohol, phenethyl alcohol, pentadecanol,

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phenol, 2,5-dimethylphenol, 3-ethylphenol, p-xylene, o-xylene, dl-limonene, styrene, p-

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cresol, thymol, carvacrol, γ-butyrolactone, 2-pyrrolidinone, nonanal, dodecanal, 2-

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acetylpyrrole, 5-methylene-2(5H)-furanone, and 2(5H)-furanone were acquired from

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Millipore-Sigma (St. Louis, Missouri, USA).

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Sample preparation. Three different tea samples coded as 4MN, 16MN and 24HR

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were prepared from borage petals. The sample preparation parameters were detailed as: 1)

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Borage petals (1g) were mixed with 150mL of 98°C distilled water for 4 min coded as 4MN.

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2) Borage petals (1g) were mixed with 150mL of 98°C distilled water for 16 min coded as

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16MN. 3) Borage petals (1g) were soaked in 150mL of distilled water for 24 hours at ambient

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temperature coded as 24HR. After preparing the hot tea samples (4MN and 16MN), they were

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left to cool at room temperature. The samples of 4MN and 24HR were prepared based on the

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traditional methods of Iran and the sample 16MN was prepared according to literature.20

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Liquid-Liquid Extraction (LLE) of Aroma Compounds. Aroma compounds of tea

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samples prepared from borage petals were extracted using dichloromethane as it was an

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efficient solvent for isolation of the volatile compounds in fruits and plants.21 The isolation

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technique was differed from our earlier survey.22 A 40-mL of a borage tea aqueous sample

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was mixed with a 100-mL of dichloromethane. The mixture was stirred under nitrogen gas at

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700 rpm for 45 min with a magnetic stirrer at 4°C. Afterwards, it was centrifuged at 4°C and

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4500 rpm for 15 min. Then, phases (insoluble and aromatic) were separated and the aromatic

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part was filtered and dehydrated with anhydrous sodium sulfate. Finally, the pooled aromatic

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part was concentrated to 5 mL in a Kuderna Danish concentrator (Sigma Aldrich St. Louis,

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Missouri, USA) fitted with a Snyder column at 40°C (Supelco, St. Quentin, France) and then

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to 200 µl under a flow of purified nitrogen. Extractions were carried out in triplicate.

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GC-MS-O Analyses of Aroma Compounds. The GC (Agilent 6890) equipped with a

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flame ionization detector (FID), a mass selective detector (Agilent 5973-MSD) and a Gerstel

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ODP-2 (Linthicum, MD, USA) sniffing port using a deactivated capillary column (30 cm ×

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0.3 mm) heated at 240°C and supplied with humidified air at 40°C was used to analyze the

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aroma and aroma-active compounds. Aroma compounds were separated by means of DB-

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Wax column (30 m length x 0.25 mm i.d. x 0.5 μm thickness, Agilent J&W, CA, USA).

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Helium was used at a flow rate of 1.5 mL/min as a carrier gas. The FID detector and injector

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were set at 280 and 270°C. The oven temperature was held at 40°C for 4 min, increased to

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90°C at 3°C/min, 130°C at 4°C/min and 240°C at 5°C/min and held at 240°C for 8 min. This

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same oven temperature programs were used for the MSD. Afterwards, GC effluent was split

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1:1:1 among the FID, MSD, and sniffing port via a Dean’s switch. A total volume of 3 μL

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from the aromatic extract was injected each time in pulsed splitless (40 psi; 0.5 min) mode.

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Mass spectra were obtained in electron impact mode with an energy voltage of 70 eV and

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quantification was performed in scan mode with a mass range of 30-300 amu. The

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temperature of GC-MS interface and ionization source were programmed to 250 and 180ºC.

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Identification of the aroma compounds was carried out by using mass spectral database (NIST

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98, Wiley 6), retention index and chemical standards.14,23 Retention indices of the compounds

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were calculated using the retention data of the linear n-alkane (C8-C32) series. The internal

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standard method was conducted to quantify the volatiles. The potential internal standards such

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as 2-octanol and (E)-2-butenoic acid were used as internal standards in the extractions

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because they fulfilled all necessary criteria as internal standards and behaved similarly with

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the main groups of analytes in studied samples. A quantitative method based on a

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combination of experimental calibration by internal standards and FID response factors was

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employed.24

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Aroma Extract Dilution Analysis (AEDA). The aroma-active compounds were

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evaluated using GC-MS-O by three experienced sniffers and the results were averaged.

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Sniffing of borage tea extract was divided into three parts (20 min each). Each panelist

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participated in the sniffing of the three parts interchangeably to remain alert. An AEDA was

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used to determine the flavor dilution (FD) factors of the key aroma compounds as it was

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successfully carried out in other previous studies.25,26 For this analysis, the condensed aroma

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extracts were diluted one by one in a rate of 1:1, 1:2, 1:4, 1:8, 1:16…, 1:2048 using

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dichloromethane. Sniffing of diluted extracts was sustained until no odor sense. Each

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perceived odor was expressed as FD factor such as 2, 4, 8, 16…, 2048 corresponding to the

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above ratios.

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Representativeness Test of the Aromatic Extract / Sensory Descriptive Analysis

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Panel. The panel composed of nine assessors (four females and five males between 23

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and 47 years of age) from the Biotechnology Laboratory at the Food Engineering Department

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of Cukurova University. The panelists were trained for the scent distinction and sensorial

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assessment and had experiences in the GC–MS–O analysis.

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Preparation and Presentation of the Samples. There are various techniques for the

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estimation of the representativeness of the aroma extracts. In this work, a cardboard sniffing

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strip (Granger-Veyron, Lyas, France) was used to investigate the representativeness of the

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aroma extracts. As a reference, 10 mL of tea was placed in a brown coded flask (25 mL) for

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these tests. The aroma extracts of the samples obtained by using the LLE technique were

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adsorbed on the cardboard. The details of the work were given in our previous study.14

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Similarity test. This test was carried out to estimate the closeness between the odors of

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aromatic extracts and the tea samples (reference). The panelists were instructed to sniff and

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memorize the aroma of the reference sample and to sniff the smelling strip for the extracts and

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determine the similarity of their odors. A 100-mm unstructured scale anchored with “very

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different from the reference” on the left and “similar to the reference” on the right was used.

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The position of the sample on the unstructured scale was measured as the distance in

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millimeters from the left anchor.

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Intensity test. The panelists were requested to evaluate the odor intensity of the extract.

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A 100-mm unstructured scale anchored with “no odor” on the left and “very powerful odor”

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on the right was utilized. The position of the sample on the unstructured scale was measured

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as the distance in millimeters from the left anchor.

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Descriptive analysis. Nine descriptors composed of herbal, green, citrusy, phenolic,

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tea, balsamic, sweet, fatty, and floral that designate the decisive aroma of the borage tea

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samples were assigned by the trained panelists. The reference sample and aromatic extract

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were offered to the panelists and they were requested to characterize the odor properties of the

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samples by judging the consistency of above-mentioned descriptors on a scale of 10 cm. The

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scale was scored towards the left end if there was no odor and was scored towards the right

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end if there was very strong odor. The scores given by each panelist were determined on the

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scale and then the average value of the odor intensity was calculated in centimeters.

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Odor Activity Value (OAV) determination. In order to determine the impact of

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aromatic compounds on overall borage tea aroma, the OAVs were calculated by dividing the

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concentrations of each aroma compound with its odor threshold obtained from the literature.21

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Statistical analysis. Three different preparation methods of the borage teas were

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compared by using analysis of variance in SPSS 22 software package (SPSS Inc., Chicago,

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Illinois, USA) at 95% confidence level (p≤0.05). Furthermore, XL Stat software (Addinsoft,

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New York City, NY, USA) was used for the principle component analysis (PCA).

212 213

Results and Discussions

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Sensory Analysis

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Odor Sensory Profiles. Three different borage tea samples were subjected to sensory

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analysis. The principal intensity groupings of the tea samples (4MN, 16MN, 24HR) were

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displayed on a spider graph with nine descriptors (Figure 1). Each rating was separately used

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by the panelists to describe the characteristic odor of the tea samples.

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Among all the descriptors of the 4MN tea sample obtained at high temperature and the

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shortest time, the highest score (7.9) was with herbal odor, followed by sweet (7.0), green

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(6.8) and citrusy (5.1) while the rest of the descriptors such as tea, phenolic, balsamic, fatty,

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and floral received the lowest scores (≤4). In the case of the 16MN tea sample that was

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processed at high temperature for a longer time, the highest score (7.7) was in sweet odor

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descriptor, followed by herbal (6.7), green (6.3) and citrusy (6.1) while the rest of the

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descriptors received the lowest scores (≤5). Finally, the 24HR tea sample obtained at ambient

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temperature with the longest time, a herbal odor had the greatest score (8.4) followed by

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green (7.9), sweet (5.6) and balsamic (5.2) while the rest of the descriptors demonstrated the

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lowest scores (≤4).

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By comparing the descriptors of the three different tea preparation methods, it can be

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seen that the scores of the herbal, green, balsamic, fatty, and floral descriptors were higher for

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the 24HR tea sample than the other two tea samples. In contrast, the sweet, citrusy, phenolic,

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and tea scores of the hot tea samples were higher than those of 24HR tea sample. According

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to the results of GC-MS-O analysis, the most dominant aroma-active compounds were 2-

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hexanol, 1-penten-3-ol, styrene, and nonanal which provide herbal, green, balsamic, and

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citrusy scents and these results were found to be in agreement with the sensory analysis. This

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result approved that the herbal and green odors caused by aroma-active compounds played a

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vital role in borage teas’ unique aroma.

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Similarity and Intensity Evaluation of Aromatic Extract. According to the results,

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both the similarity and intensity scores were satisfactory when compared to the previous

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studies.13,14,21 The mean similarity score of the aromatic extract on the smelling strips was

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found to be 71 mm on a 100 mm scale. The mean intensity score obtained from the same

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extract was found to be 74 mm.

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Aroma Profile of Borage Teas. Aroma composition identified and quantified from the

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borage tea samples and its linear retention index values on the DB-WAX column are given in

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Table 1 as mean and standard deviation of the concentrations (mg/kg).

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A total of 35 common aroma compounds belonging to volatile groups including acids

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(7), alcohols (8), hydrocarbons (3), volatile phenols (4), lactones (2), aldehydes (2),

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pyrroles-pyrrolidinone (3), terpenes (3), furans (2) and ketone (1) were successfully identified

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and quantified from each tea sample (Table 1). It was observed that the volatile profiles of all

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three tea samples were quite similar. However, three infusion methods had influence on the

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concentration of each compound in the samples. All these aroma compounds were

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characterized for the first time in borage (E. amoenum) teas. In addition, the majority of these

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compounds have been identified in previous studies in different herbal plants and teas such as

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Borago officinalis,5 Chinese black fu-brick tea,7 rooibos tea,8 Longjing tea,9 Camellia sinensis

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black tea,10 tea flowers of Camellia sinensis,11 green tea,12 dill, savory,13 and saffron.14 In the

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current study, the highest concentration of aroma compounds was observed in 24HR (266.0

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mg/kg), followed by 16MN (247.1 mg/kg) and 4MN (216.1 mg/kg) samples. Among the

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aroma groups, alcohols were the most important class of aroma compounds followed by

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acids, terpenes, volatile phenols, pyrroles, lactones and aldehydes, quantitatively. In the

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present study, 1-penten-3-ol was found in all tea samples as a dominant aroma compound.

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Apart from 1-penten-3-ol, the leading aroma compounds were 2-hexanol, p-xylene and

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dodecanoic acid in 4MN and 24HR tea samples and p-xylene, 2-hexanol, decanoic acid, and

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dodecanoic acid in 16MN tea samples. In contrast, volatile compounds of the dried petals of

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E. amoenum were dominated by sesquiterpenes comprising mainly α-cadinene, viridiflorol, α-

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muurolene, ledene, and α-calacorene and a small amount of aliphatic alkanes.15 The

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differences between the volatile compounds of dried petals and the borage tea samples may

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probably be caused by hydrophilic capacities of aroma groups in borage teas, which were

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released more efficiently with longer contact with water during infusion.

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Alcohols. Alcohols composed 52.1%, 40.9% and 49.6% of the total aroma compounds

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in 4MN, 16MN and 24HR tea samples, respectively. The total amounts of alcohols were

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found to be 112.6, 101.0 and 132.0 mg/kg in 4MN, 16MN and 24HR tea samples,

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respectively (Table 1). These compounds are synthesized from unsaturated fatty acids through

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the lipoxygenase action especially when cell structure is disrupted in the presence of oxygen.

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Volatile alcohols found in the hot tea samples decreased from 52% in 4MN to 41% in 16MN

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as a result of increasing the infusion time. The results suggested that longer heating process

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time reduced the total amount of alcohols from 112.6 to 101.0 mg/kg (Table 1). 1-Penten-3-

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ol, 2-hexanol, 3-methyl-2-buten-1-ol, 1-octanol, 2-(2-butoxyethoxy) ethanol, benzyl alcohol,

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phenethyl alcohol and pentadecanol were detected in the present study as volatile alcohol

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compounds in the borage tea samples for the first time. Nevertheless, the majority of them

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have formerly been detected in several herbal plants and teas.12,27,28 1-Penten-3-ol was the

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most abundant compound in the amounts of 71.0, 65.4 and 77.0 mg/kg in 4MN, 16MN and

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24HR tea samples, respectively (Table 1). It was also previously recorded in the aromatic

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extracts of other teas including white, green, oolong, black, and Puer teas.27,28 According to

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the previous literature, the amount of 1-penten-3-ol was detected twice more in the steam-

285

processed green teas than in the roast-processed green teas.29 In addition, its amount showed

286

increasing trend over the storage of green tea at ambient temperature.27 It is often created

287

from the degradation of lipids through production and other processes generating a greenish

288

aroma note which may be considered a quality defect.30 2-Hexanol was the second most

289

abundant aroma compound in the borage tea samples and its amount decreased in 4MN and

290

16MN samples (20.0 and 19.0 mg/kg) compared to the 24HR sample (23.0 mg/kg). This

291

compound was also previously determined in rooibos tea (Aspalathus linearis).6 3-Methyl-2-

292

buten-1-ol was in third place amongst the most abundant alcohol compounds (Table 1). This

293

compound was also detected in pickled tea (Miang).31

294

Acids. Acetic, hexanoic, 2-ethyl hexanoic, octanoic, nonanoic, decanoic and dodecanoic

295

acids were detected in borage tea samples (Table 1). Volatile carboxylic acids have rarely

296

been reported in teas probably due to their conversion into volatile alcohols, aldehydes, and

297

lactones during brewing. However, a considerable amount of volatile carboxylic acids was

298

detected in the present study. This compound have already been reported in Hibiscus

299

sabdariffa teas,20 spices such as saffron, dill and savory.13,14 It was found that the total amount

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300

of acids was the highest in the tea samples obtained at high temperature and long infusion

301

time (16MN; 44.1 mg/kg). The larger amount of acid compounds in 24HR tea sample (38.0

302

mg/kg) than in 4MN tea (26.7 mg/kg) could be related to their hydrophilic capacities as it was

303

soaked in water for a long time (24 hours). Dodecanoic acid was the prevailing compound in

304

4MN and 24HR teas while in the case of 16MN tea, decanoic acid was the predominant

305

compound. Dodecanoic and decanoic acids in green, green purple, black and black purple

306

teas were also reported as aroma compounds.32,33

307

Hydrocarbons. Three hydrocarbons comprising p-xylene, ο-xylene and styrene were

308

identified in all borage tea samples (Table 1). 21.1, 37.6 and 28.0 mg/kg of total hydrocarbons

309

were found in 4MN, 16MN and 24HR tea samples, respectively. The high amount of

310

hydrocarbons in 16MN tea sample may be due to the higher temperature and time. The same

311

hydrocarbons were reported in several kinds of teas such as Chinese black fu-brick tea7 and

312

rooibos tea.8 p-Xylene was the most dominant hydrocarbon (Table 1) and its amount was

313

increased in higher temperature and heating time (24HR: 5.0%, 4MN: 6.0%, 16MN: 11.1%).

314

Volatile phenols. Low amounts of volatile phenols ranging from 14.1 to 19.2 mg/kg

315

were observed in borage tea samples (Table 1). Phenol, 2,5-dimethylphenol, p-cresol and 3-

316

ethylphenol were volatile phenolic compounds detected in all borage teas. The variations in

317

the contents of these compounds may result from not only the biochemical composition of the

318

raw materials but also the tea infusion conditions. The highest concentration found in the 4

319

MN samples as 19.2 mg/kg (Table 1). Volatile phenols have also been detected in essential

320

oils of leaves (8.3%) and petals (13.2%) of Borago officinalis, which belong to the

321

Boraginaceae family same as E. amoenum5 and other different tea samples.34-36

322

Pyrroles and pyrrolidinone. 2-Formylpyrrole (1H-pyrrol-2-carboxaldehyde), 2-

323

acetylpyrrole, and 2-pyrrolidinone were detected in all borage teas. 2-Formylpyrrole and 2-

324

acetylpyrrole were largely found in various herbal teas as they were accounted among major

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325

odor contributors of green teas.12 The total amount of pyrroles was 4.8, 10.7 and 10.4 mg/kg

326

in 4MN, 16MN and 24HR tea samples, respectively (Table 1). Pyrroles belong to heterocyclic

327

compounds are created by the Maillard reaction during tea processing. The Maillard reaction

328

between reducing carbohydrates and amino acids is an important reaction leading to the

329

development of the unique aroma and taste as well as the typical browning, which contribute

330

to the sensory quality of thermally processed foods.37–39 Interestingly, higher amounts of

331

pyrroles quantified in 24HR and 16MN suggested that both tea preparation time and

332

temperature might affect pyrroles content.

333

Lactones. γ-Butyrolactone and pantolactone were identified as lactones in all borage tea

334

samples (Table 1). Both of them have been previously reported in different teas.9 The total

335

concentrations of lactones quantified in 4MN, 16MN and 24HR tea samples were 1.7, 5.4 and

336

8.6 mg/kg, respectively. In respect to this finding, it may be affirmed that longer infusion time

337

had more significant effect than temperature on the lactone. Among lactones, γ-butyrolactone

338

was found as the prevailing compound in all samples followed by pantolactone.

339

Aldehydes. Two volatile aldehydes including nonanal and dodecanal were quantified

340

(Table 1). It is worth mentioning that aldehydes are widespread in herbal teas as one of the

341

major aroma group which affect their overall aroma profile. For instance, Hibiscus sadariffa

342

teas,20 Camellia sinensis black teas,10 tea flowers of Camellia sinensis,11 green teas,12 and

343

rooibos teas8 contained significant amounts of aldehydes in their aroma profiles.

344

Terpenes. dl-Limonene, thymol and carvacrol were terpene compounds in the borage

345

tea samples. dl-Limonene was the most dominant terpene and its percentage decreased in

346

higher temperature (24HR: 4.5%, 4MN: 4.3%, 16MN: 3.0%). It has also been reported in

347

green, green purple, black and black purple teas.32

348

Other compounds. Two furans encompassing 5-methylene-2(5H)-furanone and 2(5H)-

349

furanone were detected in all borage tea samples (Table 1). These aroma compounds are sugar

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350

derivatives produced during tea infusion through Maillard reaction. Piperitenone was the only

351

ketone in the tea samples and its amount in 24HR and 4MN tea samples was higher than

352

16MN tea sample (Table 1). Piperitenone was reported in the essential oil of pennyroyal

353

(Mentha longifolia) as one of the antimicrobial and antioxidant agents.40

354

PCA Results of aroma compounds. Principle component analysis (PCA) was applied

355

to evaluate the possibility of distinguishing the samples based on their aroma properties as

356

influenced by different infusion processes (4MN, 16MN and 24HR tea samples). A total of 35

357

variables (aroma compounds) were used for the PCA and the elucidated variance was

358

100.00% (Factor 1: 63.18%; Factor 2: 36.82%) (Figure 2). The tea samples based on the

359

preparation methods were clearly discriminated into three separate classes in the PCA biplot.

360

24HR tea samples were characterized by 2-hexanol, benzyl alcohol, 3-methyl-2-buten-1-ol, 2-

361

pyrrolidinone, thymol, dodecanal, styrene, 2-ethyl hexanoic acid, acetic acid, dodecanoic acid,

362

γ-butyrolactone, pantolactone, 1-octanol, and o-xylene variables. The second class was the

363

16MN tea sample, which was characterized via 2-formylpyrrole, 2-acetylpyrrole, decanoic

364

acid, carvacrol, p-xylene, and 5-methylene-2(5H)-furanone variables. Finally, the third class

365

was 4MN tea sample and differentiated by nonanal, 3-ethyl phenol, nonanoic acid, p-cresol,

366

2,5-dimethylphenol, and piperitenone variables.

367

Key Odorants and Odor Activity Values (OAVs) in Borage Teas. In order to decode

368

the characteristic key odorants in the tea samples, GC-MS-O with AEDA was used in the

369

study. The GC-MS-O results of the tea samples are summarized in Table 2. The OAV data

370

were used for confirming the contribution of the key odorants to the overall aroma of the tea

371

samples. The flavor dilution (FD) values of the key odorants in the tea samples ranged from 4

372

to 2048. The OAV of these compounds ranged from 1 to 276. A total of 22 different key

373

odorants in all tea samples including alcohols (5), terpenes (3), aldehydes (2), ketone (1),

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374

acids (4), volatile phenols (2) hydrocarbon (1) and unknown compounds (4) were found.

375

Unknown compounds were detected by GC-MS-O but could not be identified by GC–MS.

376

To the best of our knowledge, there is no study on the key odorants of this endemic

377

Iranian herbal tea; however, most of these key odorants are prevalent as they have been

378

detected in many other herbal plants and teas such as Dong-Ding oolong tea,41 diverse brewed

379

green tea,12 rooibos tea,6 Longjing tea,9,42 and chrysanthemum flower tea.43 A total of 18, 21

380

and 20 different key odorants were identified in 4MN, 16MN, and 24 HR tea samples,

381

respectively. These variations indicated that the type, number, and power (FD factors) of the

382

key odorants were altered as a result of different tea preparation processes (time and

383

temperature). The powerful key odorants were decoded as 2-hexanol and 1-penten-3-ol in all

384

three the samples with varying FDs and OAVs (Table 2).

385

Alcohols were the principle key odorants in all three tea samples. A total of five

386

different aroma-active alcohols were identified: 1-penten-3-ol (green), 2-hexanol (herbal,

387

fruity), 3-methyl-2-buten-1-ol (fruity), 1-octanol (citrusy), and phenethyl alcohol. Their FD

388

values and OAV levels changed from 8 to 2048 and from 1 to 276, respectively. They can be

389

considered as common compounds since they have been detected as key odorants in other

390

herbal plants and teas such as Dong-Ding oolong tea

391

tea,28 rooibos tea,6 and Longjing tea.42 Among the aroma-active alcohols, 1-penten-3-ol in

392

24HR tea sample and 2-hexanol in 4MN and 24HR tea samples with an FD factor of 2048

393

were the potential key odorants, followed by 1-penten-3-ol in 4MN and 16MN samples and 2-

394

hexanol in 16MN sample with an FD factor of 1024. These powerful aroma-active alcohols

395

provided the distinct green, herbal, and fruity odor notes to these herbal teas. These two main

396

alcohols have been previously identified and quantified as the potential key odorants for the

397

overall aroma of other herbal teas such as Dong-Ding oolong tea,41 diverse brewed green

398

tea,12 oolong tea,28 and rooibos tea.6 3-Methyl-2-buten-1-ol with fruity odor note was another

41,

diverse brewed green tea,12 oolong

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399

potential key aroma alcohol in the borage tea samples and its FD value was lower in 4MN and

400

16MN (32) as compared to 24HR (64). Octanol and phenethyl alcohol were other potential

401

key aroma alcohols which were observed together or separately in several teas such as oolong

402

tea28 and Longjing tea.42

403

Terpenes were the other important key odorants in tea samples. A total of three

404

different aroma-active terpenes were detected comprising dl-limonene (citrusy), thymol

405

(spicy) and carvacrol (phenolic). Their FD values and OAV levels changed from 4 to 32 and

406

from 1 to 10, respectively. Among the terpenes, dl-limonene, which gives a citrusy odor to the

407

teas, was perceived with the highest FD value in 24HR (32) and 4MN (16) tea samples. The

408

identified aroma-active terpenes are widespread as they have been detected in other black and

409

green teas.8,44

410

Other potential key odorants identified in the tea samples were carboxylic acids.

411

Hexanoic acid (cheesy), octanoic acid (sweet), nonanoic acid (green), and decanoic acid

412

(sweet) were found as aroma-active carboxylic acids in the all samples. Octanoic acid was the

413

main aroma-active acid among this group and its FD value was 8 in 16MN and 4 in 4MN and

414

24HR tea samples.

415

Two important aroma-active aldehydes including nonanal (citrusy) and dodecanal

416

(fatty) were present in all tea samples. Their FD factors and OAV levels varied from 32 to

417

512 and from 25 to 125, respectively. The odor thresholds of the aldehydes are prevalently

418

lower than those of volatile compounds; hence, they have considerable potential impacts on

419

the overall aroma of food products. Nonanal had higher FD values in all samples as compared

420

to the dodecanal (Table 2). The FD values of nonanal were increased by the increase in

421

heating time (128 in 24HR; 256 in 4MN; 512 in 16MN). Nonanal has been reported as

422

responsible for green, citrus and floral odors in Longjing tea9 and chrysanthemum flower tea43

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423

while dodecanal was indicated as a major aroma-active compound in essential oil of

424

Polygonum minus providing pungent oily odor.45

425

p-Cresol and 3-ethylphenol were detected as aroma-active volatile phenol compounds in

426

the samples. The FD value of p-cresol with phenolic odor note rose in the shorter heating time

427

(FD=128 for 4MN). Whereas, 3-ethylphenol (soapy) had higher FD factor in hot teas (FD=16

428

for 4MN and 16MN) than the tea sample prepared in ambient condition (FD=8 for 24HR).

429

γ-Butyrolactone, which is the only aroma-active ketone and gives a sweet odor note

430

showed higher FD factor in both 16MN and 24HR tea samples (16) as compared to 4MN (8)

431

tea sample. Similarly, γ-butyrolactone has been reported to display caramel odor note in

432

Longjing tea.9 Styrene, which gives a balsamic odor to the teas, was perceived with the

433

highest FD value in 24HR (512) and 16MN (128) tea samples. The FD factor of the styrene

434

was increased by the longer infusion time in 24HR and 16MN tea samples. Moreover, four

435

unknown aroma-active compounds were determined contributing to the overall aroma of the

436

tea samples. Table 2 shows the FD factors of these unknown compounds changing between 8

437

and 64 providing tea, sweet, green, and floral odor attributes to the tea samples.

438

PCA results of key odorants. 22 variables were selected for the PCA with two

439

principal components elucidating 100% of the total variance (PC1: 65.65%; PC2: 34.35%)

440

(Figure 3). The application of the PCA exposed three distinctive groups. The ellipses indicate

441

the confidence region of the odor descriptions which can contribute to the characterization of

442

the tea samples obtained from three different preparation methods (4MN, 16MN, 24HR). The

443

odor descriptions inside the ellipse contribute more to identify the tea samples based on their

444

aroma-active compounds than those outside. In Figure 3, quadrant Q4 cluster is composed by

445

16MN tea sample and characterized by the citrusy, phenolic, sweet, and metallic attributes.

446

Attributes of tea, soapy, green, and phenolic were placed inside the quadrant Q1 and Q2

447

which characterize the 4MN tea sample. The last group was in the quadrant Q3 containing

19 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

448

24HR tea sample with citrusy, floral, spicy, green, fruity, balsamic, fatty, cheesy, sweet, and

449

metallic attributes. The sweet and herbal attributes were between 4MN and 24HR samples

450

with the same FD factor. From the PCA results, it can be concluded that the desirable odors

451

such as green, herbal, fruity, tea and floral attributes were found to be related to both 4MN

452

and 24HR tea samples more than 16MN tea sample.

453

In conclusion, the aroma-active compounds of the endemic Iranian herbal “Gol-

454

Gavzaban” tea obtained from shade-dried violet-blue petals of borage (Echium amoenum) by

455

three different infusion methods were detected for the first time with the application of aroma

456

extract dilution analysis. Regarding the influence of the infusion method on the total volatile

457

compounds of the borage tea samples, the highest amount was detected in 24HR sample

458

(prepared at ambient temperature) followed by 16MN and 4MN (prepared with water at

459

98°C); hence, it is recommended that the borage tea should be prepared at ambient

460

temperature. Terpenes, alcohols, and acids were responsible for the majority of the aroma

461

compounds in all tea samples. Of these groups, 1-penten-3-ol was found in all tea samples as

462

a dominant aroma compound. The main group of the key odorants in all samples was terpenes

463

followed by alcohols and acids. 2-Hexanol (herbal) and 1-penten-3-ol (green) were found as

464

the most potential key odorants containing the highest FD factors and OAV levels in all

465

samples. In addition, the aroma compounds and the key odorants of 24HR were dominated by

466

the highest total aroma concentration, FD factors and OAV levels and the differences could

467

come from the various infusion temperatures and duration. Thus, the outcomes from the

468

present study might be considered as supplying useful knowledge concerning the presence of

469

organoleptic properties (e.g. volatile profile, key odorants, sensory analysis) of borage tea.

470

Acknowledgments

471

We would like to thank Dr. Muharrem Keskin from Hatay Mustafa Kemal University, Turkey

472

and Pei Zhu from Cornell University, USA for their outstanding editing.

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Chem. 1995, 43 (8), 2187–2194.

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quality control of Chinese chrysanthemum flower teas using gas chromatography–mass

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analysis. Int. J. Food Sci. Technol. 2017, 52 (3), 714–723.

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characteristics of various instant teas produced from black tea. Food Chem. 2016, 194,

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aroma extraction dilution analysis of aroma active compounds in’Polygonum minus’

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essential oil. Plant Omics 2016, 9 (4), 289.

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odour. Water 1971, 4, 367–371.

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24.

619 620 621

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Journal of Agricultural and Food Chemistry

622

FIGURE CAPTIONS

623

Figure 1. Odor sensory features of borage (E. amoenum) tea samples.

624

Figure 2. PCA biplot of aroma compounds in borage (E. amoenum) tea samples.

625 626 627 628 629 630 631 632 633 634 635 636 637 638 639 640 641

26 ACS Paragon Plus Environment

Page 26 of 34

Page 27 of 34

Journal of Agricultural and Food Chemistry

Herbal 9 8 7

Floral

Green

6 5 4 3 2

Fatty

Citrusy

1 0

Sweet

Phenolic

Balsamic

4MN

Tea

16MN

Figure 1.

27 ACS Paragon Plus Environment

24HR

Journal of Agricultural and Food Chemistry

Biplot (axes F1 and F2: 100.00 %) 1

Page 28 of 34

. 16MN

Hexanoic acid Octanoic acid o-Xylene 1-Octanol Pantolactone 24HR γ-Butyrolactone Dodecanoic acid Acetic acid 2-Ethyl hexanoic acid Styrene Dodecanal Thymol 2-Pyrrolidinone

.

1

F2 (36.82 %)

2-Formylpyrrole 2-Acetylpyrrole Decanoic acid Carvacrol p-Xylene 5-Methylene-2(5H)furanone

3-Methyl-2-buten-1-ol Benzyl alcohol 2-Hexanol dl-Limonene Phenethyl alcohol 2(5H)-Furanone 2-(2-Butoxyethoxy)ethanol Phenol 1-Penten-3-ol Pentadecanol

0

Nonanal 3-Ethylphenol Nonanoic acid

Piperitenone

-1

2,5-Dimethylphenol p-Cresol

.

4MN -1 -2

-2

-1

-1

0

F1 (63.18 %) Figure 2.

28 ACS Paragon Plus Environment

1

1

2

2

Page 29 of 34

Journal of Agricultural and Food Chemistry

Biplot (axes F1 and F2: 100.00 %) 1

Q1

.

1

Q2 4MN 17-Phenolic 5-Sweet 6-Herbal

18-Green 19-Soapy 3-Tea

F2 (34.35 %)

0

2-Citrusy

0

15-Floral 20-Spicy 1-Green 7-Fruity 14-Floral 4-Balsamic 12-Fatty

8-Citrusy 11-Sweet

0

16-Sweet 21-Phenolic -1

22-Metallic

.

.

13-Cheesy 10-Sweet 9-Citrusy, metal

24MN

16MN

Q4

Q3

-1 -1

-1

-1

-1

0

0

0

1

1

1

1

F1 (65.65 %) Figure 3. PCA biplot of the potent key odorants and their related odor descriptions; 1-Green [1-Penten-3-ol], 2-Citrusy [dl-Limonene], 3-Tea [Unknown I], 4-Balsamic [Styrene], 5-Sweet [Unknown II], 6-Herbal [2-Hexanol], 7-Fruity [3-Methyl-2-buten-1-ol], 8-Citrusy [Nonanal], 9-Citrusy, metal [1-Octanol], 10-Sweet [γ-Butyrolactone], 11-Sweet [Unknown III], 12-Fatty [Dodecanal], 13-Cheesy [Hexanoic acid], 14-Floral [Phenethyl alcohol], 15Floral [Unknown IV], 16-Sweet [Octanoic acid], 17-Phenolic [ρ-Cresol], 18-Green [Nonanoic acid], 19-Soapy [3-Ethylphenol], 20-Spicy [Thymol], 21-Phenolic [Carvacrol], and 22Metallic [Decanoic acid].

29 ACS Paragon Plus Environment

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Page 30 of 34

Table 1. Aroma compounds in borage (Echium amoenum L.) tea samples No.

Aroma compounds

LRI 1

Concentration (mean ± SD) 2

Identification 3

4MN

16MN

24HR

1400

1.6 ± 0.0c

2.6 ± 0.1b

4.1 ± 0.2a

LRI, MS, Std

1807

1.0 ±

0.0c

4.2 ±

0.1a

3.5 ±

0.2b

LRI, MS, Std

2.0 ±

0.1c

3.6 ±

0.1b

5.9 ±

0.2a

LRI, MS, Std

0.0c

2.7 ±

0.1a

2.4 ±

0.2b

LRI, MS, Std

Acids 1 2 3

Acetic acid Hexanoic acid 2-Ethyl hexanoic acid

1911

4

Octanoic acid

2041

1.4 ±

5

Nonanoic acid

2124

5.8 ± 0.1b

6.0 ± 0.2a

4.4 ± 0.0c

LRI, MS, Std

6

Decanoic acid

2313

3.9 ± 0.0c

13.0 ± 0.2a

4.7 ± 0.1b

LRI, MS, Std

7

Dodecanoic acid

2517

11.0 ± 0.5c

12.0 ± 0.4b

13.0 ± 0.6a

LRI, MS, Std

26.7

44.1

38.0

1158

71.0 ± 1.9b

65.4 ± 2.1c

77.0 ± 2.3a

LRI, MS, Std

1254

0.9b

1.0c

23.0 ±

1.2a

LRI, MS, Std

11.0 ±

0.3a

LRI, MS, Std

2.7 ±

0.1a

LRI, MS, Std

1.9 ±

0.1a

LRI, MS, Tent

4.7 ±

0.2a

LRI, MS, Std

5.3 ±

0.2a

LRI, MS, Std

6.4 ±

0.2a

LRI, MS, Std

Total Alcohols 8 9 10 11 12 13 14 15

1-Penten-3-ol 2-Hexanol 3-Methyl-2-buten-1-ol 1-Octanol 2-(2-Butoxyethoxy)ethanol Benzyl alcohol Phenethyl alcohol Pentadecanol

1325 1546 1749 1823 1859 2241

Total

20.0 ± 8.1 ±

0.3b

1.1 ±

0.0c

1.0 ±

0.0b

1.9 ±

0.0b

3.8 ±

0.2b

5.7 ±

0.3b

19.0 ± 7.1 ±

0.2c

2.2 ±

0.0b

0.3 ±

0.0c

0.6 ±

0.0c

2.6 ±

0.3c

3.8 ±

0.1c

112.6

101.0

132.0

Volatile phenols 16

Phenol

1958

2.6 ± 0.0b

1.9 ± 0.0c

3.6 ± 0.1a

LRI, MS, Std

17

2,5-Dimethylphenol

2068

5.3 ± 0.2a

2.8 ± 0.0c

4.6 ± 0.2b

LRI, MS, Std

18

p-Cresol

2074

5.2 ± 0.1a

2.3 ± 0.0c

3.4 ± 0.0b

LRI, MS, Std

2150

0.3b

0.2a

0.2c

LRI, MS, Std

19

3-Ethylphenol Total

6.1 ±

7.1 ±

3.1 ±

19.2

14.1

14.7

1130

13.0 ± 0.6c

27.0 ± 0.8a

13.0 ± 0.3b

LRI, MS, Std

1169

5.2 ±

0.3c

6.4 ±

0.3b

6.8 ±

0.3a

LRI, MS, Std

2.9 ±

0.0c

4.2 ±

0.0b

8.2 ±

0.1a

LRI, MS, Std

Hydrocarbons 20 21 22

p-Xylene o-Xylene Styrene

1245

Total

21.1

37.6

28.0

1943

2.5 ± 0.0c

5.2 ± 0.1a

4.1 ± 0.2b

LRI, MS, Std

0.0c

0.1a

0.1b

LRI, MS, Tent LRI, MS, Std

Pyrroles 23

2-Acetylpyrrole

24

2-Formylpyrrole

2010

0.8 ±

25

2-Pyrrolidinone

2032

1.5 ± 0.0b

1.5 ± 0.0b

3.4 ± 0.1a

4.8

10.7

10.4

Total

4.0 ±

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2.9 ±

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Journal of Agricultural and Food Chemistry

Lactones 26 27

γ-Butyrolactone Pantolactone

1647

1.1 ± 0.0c

3.1 ± 0.0b

5.0 ± 0.0a

LRI, MS, Std

2024

0.0c

0.1b

0.0a

LRI, MS, Tent

Total

0.6 ±

2.3 ±

3.6 ±

1.7

5.4

8.6

1391

5.0 ± 0.1b

6.1 ± 0.1a

2.0 ± 0.0c

LRI, MS, Std

1682

0.0c

0.0b

0.0a

LRI, MS, Std

Aldehydes 28 29

Nonanal Dodecanal Total

1.4 ±

1.9 ±

4.3 ±

6.4

8.0

6.2

Furans 30

5-Methylene-2(5H)-furanone

1635

3.5 ± 0.1b

4.3 ± 0.1a

2.8 ± 0.0c

LRI, MS, Std

31

2(5H)-Furanone

1702

2.5 ± 0.0b

2.1 ± 0.0c

3.1 ± 0.0a

LRI, MS, Std

6.0

6.4

5.9

1199

9.2 ± 0.2b

7.5 ± 0.1c

12.0 ± 0.2a

LRI, MS, Std

2167

1.8 ±

0.0b

2.0 ±

0.0b

3.2 ±

0.0a

LRI, MS, Std

4.0 ±

0.1b

8.4 ±

0.1a

4.2 ±

0.0b

LRI, MS, Std

Total Terpenes 32 33 34

dl-limonene Thymol Carvacrol

2246

Total

15.0

17.9

19.4

2.6 ± 0.1a

1.9 ± 0.0b

2.7 ± 0.1a

2.6

1.9

2.7

216.1

247.1

266.0

Ketone 35

Piperitenone Total General total

1905

1

LRI, MS, Tent

LRI: Linear retention index calculated on DB-Wax capillary column. 2 Concentration: results are the means of three repetitions as mg/kg. Different lower-case letters (a,b,c) within the same line indicate significant differences (p