The method is suitable for the determination of water vapor volatile aroma compounds in beer.
Volatile aroma compounds are driven out of the sample through steam distillation. The ethanolic distillate is saturated with NaCl. Potassium hydrogen sulfite is added to separate carbonyl groups that might interfere with the analysis. The extraction of the aroma compounds is performed by shaking out with dichloromethane and the phases separated by centrifuging.
This method is suitable for the determination of steam-volatile aroma compounds in wort.
Volatile aroma compounds are driven out of the sample through steam distillation. The ethanol distillate is adjusted to be alkaline and saturated with NaCl. The extraction of the aroma compounds is performed by shaking out with dichloromethane and the phases separated by centrifuging. The organic phase is further concentrated in a stream of nitrogen gas. An ammonia solution is added to remove the acids, because the acids would co-elute, thus preventing quantification of the target substances.
Simultaneous determination of iso-a-acids and reduced iso-a-acids (rho, tetra, hexa) in beer and beer-based beverages using HPLC
This method is not suitable for beer and beer-based beverages containing a mix of hexa- and iso-products (co-elution).
This method separates iso-α-acids and reduced iso-α-acids (rho, tetra, hexa) chromatographically [2].
The separated compounds are detected spectrophotometrically at 270 nm. Quantification is performed using International Calibration Standards (ICS).
These standards do not contain all of the isomers of a certain type of iso-α-acids. Currently, ICS-I (DCHA-Iso) contains only the trans-isomeric complexes with dicyclohexylamine (DCHA). ICS-R (DCHA-rho) only has the cis-isomers in a complex with DCHA. ICS-T (tetra) comprises both cis- and trans-isomer complexes with DCHA, and ICS-H (DCHA-hexa) includes only cis-isomers with DCHA.
Commercially available hop products contain a greater number of isomers than the standards.
Thus, there are more peaks in the chromatogram than in the corresponding international calibration standards, in particular, with the cis-iso-cohumulone as well as the cis-iso-n-humulone and cis-iso-ad-humulone. The application of this method to these kinds of beers should be conducted with this in mind, since it is not entirely known whether these additional peaks are actually isomers of iso-α-acids.
The method is suitable for beers of all original gravities and of any alcohol content.
The gas chromatography headspace method is used to determine the higher alcohols and esters present in beer, i.e., the volatile compounds are transferred from the headspace in the sample vial into the GC system for analysis. The following substances are measured in this analysis:
Acetaldehyde
Propanol-1
Ethyl acetate
2-Methylpropanol
3-Methylbutanol
2-Methylbutanol
2-Methylpropylacetate
Butyric acid ethyl ester
3-Methylbutyl acetate
2-Methylbutyl acetate
Hexanoic acid ethyl ester
The method is suitable for beer brewed to any original gravity or to any alcohol content.
Volatile compounds in beer are concentrated through distillation and extracted with dichloromethane. The solvent phase is analyzed with a gas chromatograph. The linearity of the detector and the determination of the concentrations of analytes in the sample are achieved by using multiple concentration levels within the relevant range and through evaluation of the relative area under the peaks.
The method is suitable for the determination of steam-volatile aging indicators in beer.
Volatile aging indicator substances are driven out of the sample through steam distillation. The ethanol distillate is adjusted to be alkaline and saturated with NaCl. The extraction of the aroma compounds is performed by shaking out with dichloromethane and the phases separated by centrifuging. The organic phase is further concentrated in a stream of nitrogen gas. Ammonia solution is added to remove the acids, as the acids would coelute, thus preventing the quantification of important substances.