Furanoid linalool oxide

The interdigital secretion of the red hartebeest, A. b. caama, consists of fewer compound classes. It contains a few alkanes and short-chain, branched alcohols, fatty acids, including a few of the higher fatty acids up to octadecanoic acid, an epoxide and the cyclic ethers, rans-(2 ,5.R)-furanoid linalool oxide 23, as-(2JR,5S)-furanoid linalool oxide 24 and ds-(2S,5i )-furanoid linalool oxide 25 (Fig. 5) in a ratio of 2.5 1 1.5 respectively [138]. From the point of view that many of the constituents of the interdigital secretion of this animal are probably of microbial origin, it is interesting that cis- and trans- furanoid linalool oxides have also been found in castoreum [77]. 

The biotransformation of (/f,5)-Iinalool by fungi is a useful method for the preparation of natural linalool oxides. The stereospecific conversion of (J ,5)-linalool by Corynespora cassiicola DSM 62475 led to 5/f-configured furanoid linalool oxides and 55-configured pyranoid linalool oxides, both via bS -configured epoxylinalool as postulated intermediate (Figure 12.6). The biotransformation protocol affords an almost total conversion of the substrate with high enantioselectivities and a molar conversion yield close to 100% (Table 12.4). Pure linalool oxides are of interest for lavender notes in perfumery. ... 

Table 17.1 Elution order of the furanoid linalool oxides using different modified cyclodextrins (CD) as chiral stationary phases [11, 13]...

Kreis P, Dietrich A, Mosandl A (1996) Elution order of the furanoid linalool oxides on common gas chromatographic phases and modified cyclodextrin phases. J Essent Oil Res 8 339 Weinert B, Wiist M, Mosandl A Hanssum H (1998) Stereoisomeric flavour compounds LXX-Vlff. Separation and structure elucidation of the pyranoid linalool oxide stereoisomers using common gas chromatographic phases, modified cyclodextrin phases and nuclear magnetic resonance spectroscopy. Phytochem Anal 9.T0... 

The biotransformation of linalool by Botrytis cinerea has also been described [60]. After addition of linalool to botrytised must, a series of transformation products was identified (E)- (49) and (Z)-2,6-dimethyl-2,7-octadiene-l,6-diol (48), trans- (76) and cw-furanoid linalool oxide (77), trans- (78) and c/s-pyranoid linalool oxide (79) and their acetates (80, 81), 3,9-epoxy-p-menth-1 -ene (75) and 2-methyl-2-vinyltetrahydrofuran-5-one (66) (unsaturated lactone), Fig. (11). Quantitative analysis however, showed that linalool was predominantly (> 90%) metabolised to ( )-2,6-dimethyl-2,7-octadiene-l,6-diol (49) by B. cinerea. The other compounds were only found as by-products in minor concentrations. 

Figure 9. Structures of additional glycoconjugates isolated from Riesling wine during this study B-D-glucopyranosides of 3-methylbutanol 21, 2-methyl-butanol 22, benzyl alcohol 23, 2-phenylethanol 24, furanoid linalool oxides (two diastereoisomers) 25, pyranoid linalool oxides (two diastereoisomers) 27, 3-oxo-7,8-dihydrc>-a-ionol 28, 3-oxo-a-ionol 29, 4,5-dihydro-vomifoliol 30, vomifoliol 31, and 7,8-dihydro-vomifoliol as well as the 6-O-B-D-apiofurano-syl-fi-D-glucopyranosides of furanoid linalool oxides (two diastereoisomers).

Figure 8. Chemical formation of furanoid linalool oxides (14) and (15) from triol (21) and biogenetic formation of the four linalool oxides (14), (15), (22) and (23) from 6,7-epoxy-linalool (18).

Finally, the lactone (28) is generally described as a formal oxidation product of furanoid linalool oxides (21) and (22), but the biogenetic formation of this compound has not been elucidated yet. 

FIGURE 19.22 Four stereoisomers of furanoid linalool oxides. (Modi ed from Noma, Y. et al.. Reduction of terpene aldehydes and epoxidation of terpene alcohols by S. ikutamanensis, Ya-2-1, Proceedings of 30th TEAC, 1986, pp. 204-206.)... 

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