Gas chromatographic detection of d-amino acids in natural and thermally treated bee honeys and studies on the mechanism of their formation as result of the Maillard reaction

Abstract

Relative quantities of d-amino acids, (%D) calculated from the sum of d- and l-amino acids were determined in bee honeys (n=6) by GC-SIM-MS. Amino acids were isolated by treatment with Dowex 50 W X8 cation exchanger and converted into N(O)-perfluoroacyl amino acid propyl esters. In all honeys d-Ala, ranging from 2.2–6.2% d-Ala, was detected. Other d-amino acids were also found, albeit not in all honeys and approached 5.9% d-Glx, 5.4% d-Lys, 3.0% d-Phe, 2.1% d-Orn, 1.7% d-Asx, 1.5% d-Ser, 0.1% d-Pro, and 0.4% d-Val in certain honeys. Quantities of d-amino acids increased very much on experimental heating of honeys in an oven and on a microwave treatment. Conventional heating of a forest honey (no. 1) at 65 °C for 450 h leads to an increase of d-Ala (2.2–12.5%), d-Pro (0.0–5.0%), d-Ser (1.5–9.1%), d-Asx (1.7–9.8%), d-Phe (0.4–5.0%) and d-Glx (1.5–5.8%); first numbers in parentheses refer to unheated honeys. Relative quantities of other d-amino acids also increased. Experimental heating of another forest honey (no. 2) in a microwave oven for 3 min at 180 W leads to an increase of d-Ala (3.7–11.0%), d-Glx (1.5–13.7%), d-Asx (0.7–10.2%), d-Phe (0.3–4.8%), d-Val (0–4.2%), and d-Pro (0.1–2.3%). Microwave treatment at 700 W for 1 min of a blossom honey (no. 3) leads to an increase of d-Ala (6.2–26.7%) and of d-Phe (3.0–10.9%). Microwave treatments were accompanied by intensive destruction of amino acids. Heating of a model mixture mimicking the major components of honey (d-glucose, d-fructose, and l-amino acids at 20% water content) at pH 2.6–9.0 and at 180 W for 1–3 min leads to the generation of d-amino acids and was also accompanied by intensive decay of amino acids. From the data it is concluded that d-amino acids are formed in honeys in the course of the Maillard reaction. A mechanism is presented based on amino acid racemization of reversibly formed Heyns and Amadori compounds (fructose-amino acids).