Determination of low molecular weight alcohols including fusel oil in various samples by diethyl ether extraction and capillary gas chromatography.

Low molecular weight alcohols including fusel oil were determined using diethyl ether extraction and capillary gas chromatography. Twelve kinds of alcohols were successfully resolved on the HP-FFAP (polyethylene glycol) capillary column. The diethyl ether extraction method was very useful for the analysis of alcohols in alcoholic beverages and biological samples with excellent cleanliness of the resulting chromatograms and high sensitivity compared to the direct injection method. Calibration graphs for all standard alcohols showed good linearity in the concentration range used, 0.001-2% (w/v) for all alcohols. Salting out effects were significant (p < 0.01) for the low molecular weight alcohols methanol, isopropanol, propanol, 2-butanol, n-butanol and ethanol, but not for the relatively high molecular weight alcohols amyl alcohol, isoamyl alcohol, and heptanol. The coefficients of variation of the relative molar responses were less than 5% for all of the alcohols. The limits of detection and quantitation were 1-5 and 10-60 microg/L for the diethyl ether extraction method, and 10-50 and 100-350 microg/L for the direct injection method, respectively. The retention times and relative retention times of standard alcohols were significantly shifted in the direct injection method when the injection volumes were changed, even with the same analysis conditions, but they were not influenced in the diethyl ether extraction method. The recoveries by the diethyl ether extraction method were greater than 95% for all samples and greater than 97% for biological samples.

Determination of amino acids in foods by reversed-phase HPLC with new precolumn derivatives, butylthiocarbamyl, and benzylthiocarbamyl derivatives compared to the phenylthiocarbamyl derivative and ion exchange chromatography.

New precolumn derivatizing reagents for analysis of amino acids by HPLC-butylisothiocyanate (BITC) and benzylisothiocyanate (BZITC)-reacted quantitatively with 22 standard amino acids and the amino acids in the acid hydrolysate of food and protein standard, bovine serum albumin (BSA), at 40 degrees C for 30 min to yield butylthiocarbamyl (BTC) amino acids and at 50 degrees C for 30 min to yield benzylthiocarbammyl (BZTC) amino acids. BTC and BZTC amino acids were successfully separated in 35 min on the reversed-phase Nova-Pak C18 column (30 cm x 3.9 mm, 4 microm). The optimum wavelengths for determination of BTC and BZTC derivatives were 240 nm and 246 nm, respectively. Analysis of the results obtained with BSA and food samples as BTC and BZTC derivatives showed good agreement with those determined as ionexchange chromatography and data presented in the literature. The advantage of BITC reagent over the phenylisothiocyanate (PITC) and BZITC was that it had high volatility, so the excess reagent and by-products were easily removed in about 10 min, compared to about 1 h in the PITC and BZITC reagents. In the BTC and BZTC derivatives, cystine and cysteine were determined separately, but in the PTC amino acids derivatized with PITC reagent they were resolved into single peak.