In gingko wine, about 58 volatile c

In gingko wine, about 58 volatile compounds were tentatively
identified and quantified using HS-SPME-GC–MS, shown in
Table 1 coupled with their calculated RI values. In Table 1, 58 volatile
compounds included esters (13), alcohols (10), acids (11), carbonyl
compounds (12), lactones (2), phenols (2), and hydrocarbons
(8), and the total volatile compounds concentration was 41.8 mg/L.
Moreover, the odor activity values (OAV) of volatile compounds are
also presented in Table 1. To some extent, OAV can reflect the contribution
of each aroma compound to the sample characteristic flavor.
While the threshold values for 18 compounds remained
unknown, 19 compounds with OAV > 1, and 21 compounds with
OAV < 1 are listed in Table 1. Generally, compounds with OAV > 1
contributed to the overall aroma significantly, while the compounds
with OAV < 1 may still affect wine aroma through an additive
effect of the compound with a similar structure or odor
(Francis & Newton, 2005; González Álvarez et al., 2011).
As the largest group of gingko wine volatile compounds
(18.2 mg/L), esters accounted for 43.7% of the total quantified compounds.
It has been suggested that esters are formed mainly
through the esterification of alcohols with organic acids during
the fermentation and storage processes (Erten, Tanguler, &
Cakiroz, 2007; Fan & Qian, 2005). In addition, the fermentation
procedure in the presence of yeast and other microorganism can
also lead to the generation of esters. The presence of esters contributed
to the fruity notes of wine samples. Ethyl hexanoate
(8.59 mg/L), ethyl acetate (2.90 mg/L), ethyl butyrate (2.50 mg/L),
ethyl pentanoate (1.16 mg/L), ethyl lactate (1.09 mg/L) presented
the highest concentration in this group. It was also found that ethyl
hexanoate has the highest concentration in many China liquors
(Xiao et al., 2014). There were 7 esters with OAV > 1, but not ethyl
acetate, ethyl lactate and ethyl decanoate. Ethyl hexanoate displayed
the biggest OAV (613) followed by ethyl pentanoate
(OAV = 233), ethyl butyrate (OAV = 125), ethyl heptanoate
(OAV = 66.4), isoamyl acetate (OAV = 11.2), diethyl succinate
(OAV = 8.7) and ethyl octanoate (OAV = 1.5). Ethyl butyrate has
strawberry and apple aroma notes; ethyl hexanoate is related to
a fruity, brandy and wine-like smell (Welke et al., 2014); and ethyl
pentanoate and ethyl heptanoate are associated with fruity, and
apple notes (Fan & Qian, 2006). The detection thresholds of ethyl
2-hexenoate, butyl butyryl lactate and cyclohexyl valerate are
unavailable, thereby their contribution to the gingko wine aroma
still needs to be determined in future. The rich ester compounds
in gingko wine suggests that it is a good flavor alcoholic beverage
and may have a promising market future.
Alcohols were produced by alcoholic fermentation and played
an important role in the gingko wine aroma profile. Research has
shown that alcohols facilitate the desirable complexity of liquor
when its concentration was below 300 mg/L (Noguerol-Pato,
González-Rodríguez, González-Barreiro, Cancho-Grande, & Simal-
Gándara, 2011). In the present studied gingko wine, 11 alcohols
(4.0 mg/L) accounted for 9.7% of the total aroma compounds.
Isoamyl alcohol was 1.82 mg/L approximately accounting for half
of the total alcohol content. Only isoamyl alcohol and 1-octanol
demonstrated OAVs > 1. Isoamyl alcohol is also an important compound
in some China liquors (Xiao et al., 2014) and grape wine
(Rebière, Clark, Schmidtke, Prenzler, & Scollary, 2010) which has a
whiskey, malt and burned aroma. Furthermore, phenethyl alcohol
and a-terpineol are widespread components in wine with a floral
odor.
Wine acids was identified as the second most abundant volatile
compounds in gingko wine with the concentration of 14.2 mg/L,
which was equivalent to 34.0% of the total volatile compounds.
Because short-chain acids present sour notes and can mask other
aromas in wine (Xiao et al., 2014), the short-chain acids within
an appropriate concentration range in gingko wine are required
for optimum flavor. Hexanoic acid was considered as the dominant
compound in the acid group with the content of 10.83 mg/L. Only
hexanoic acid and butyric acid from the 11 acids were present
above their thresholds (OAVs > 1). The other 7 acids may contribute
less to the flavor of gingko wine due to their moderate concentrations
and high olfactory thresholds (Table 1). The
contribution of undecanoic acid and tridecanoic acid was undetermined
as their olfactory detection thresholds were not available.
Carbonyl compounds (aldehydes and ketones) were another
key aroma group in gingko wine. The total content of this group
was 3.6 mg/L (8.7% of the total volatile compounds) including 9
aldehydes and 3 ketones. Carbonyl compounds could be formed
from two pathways: the reduction of unsaturated fatty acids and
the partial degradation of amino acids in the presence of oxygen
(Xiao et al., 2014). Six carbonyl compounds were determined with
OAVs > 1, and they were nonanal (OAV = 218), 2-undecanone
(OAV = 4.1), 2-nonanone (OAV = 3.2), octanal (OAV = 2.9), benzaldehyde
(OAV = 1.5) and palmitaldehyde (OAV = 1.5). Nonanal
exhibited a strong fatty-floral odor at a moderate level. 2-
Undecanone was characterized by fruity and cheese notes, related
to the lingering aroma after tasting.
Only c-hexalactone and c-octanoic lactone were identified in
the lactone group. The total content of lactones with a fruity aroma
in gingko wine was merely 0.1 mg/L (0.3% of the total volatile compounds).
Lactones were generated by the corresponding hydroxyl
acids (Belitz, Grosch, & Schieberle, 2004). The olfactory detection
threshold of c-hexalactone was far more than its content in gingko
wine. Therefore, its contribution to the wine flavor was negligible.
Since an odor threshold was not available for c-lactone, its contribution
cannot be determined.
Two volatile phenolic compounds were detected in the gingko
wine: thymol and carvacrol. The total content of volatile phenolic
compounds was 0.4 mg/L, accounting for 1.0% of the total volatile
compounds. Phenols in wines can be generated from p-coumaric
acid and ferulic acid (Rapp & Mandery, 1986). The concentration
of thymol was higher than its detection threshold (OAV = 1.6),
while carvacrol displayed a reversed trend. It has been indicated
that phenols often have spicy and smoky aroma.
Eight hydrocarbons were listed in Table 1: limonene, tridecane,
styrene, 1-isopropyl-2-methylbenzene, octadecane, eicosane,
heneicosane and 1-octadecene. The total content was 1.1 mg/L
(2.6% of the total volatile compounds). Limonene was a kind of terpene
compound with sweet, citrus- and lemon-like notes, and its
OAV = 13.1. Because the odor detection thresholds of the other 7
hydrocarbons are not available, their contributions to gingko wine
are still undetermined. However, it is likely that the contribution of
the 7 hydrocarbons would be minor, as their odor thresholds are
expected to be fairly high.
For ROC analysis, ethyl hexanoate possessed the highest contribution
to gingko wine aroma (ROC = 46.5%), followed by ethyl pentanoate
(ROC = 17.6%), nonanal (ROC = 16.5%), ethyl butyrate
(ROC = 9.5%) and ethyl heptanoate (ROC = 5.0%). Interestingly,
ethyl hexanoate was identified as the second highest ROC in
Chardonnay wine (Welke et al., 2014). The total ROC of esters as
accounted for 80.2% followed by carbonyl compounds (17.5%).
Those results illustrated the key role of esters in wine aroma.