Exogenous glutamic acid effectively involved in N-(1-deoxy-D-galulos-1-yl)-glutamic acid degradation for simultaneous improvement of both milk-like and baking flavor

Abstract

This research elucidated the reason of flavor deficiency during the thermal degradation of glutamic acid (Glu)-galactose (Gal) Amadori rearrangement product (GG-ARP) and the solution. The flavor formation from GG-ARP during the thermal degradation was investigated. Compared to the volatile compounds in Glu-Gal Maillard reaction products (GG-MRP), pyrazines in the volatile compounds derived from GG-ARP were restrained. The disadvantage in evolution asynchrony and content sufficiency of α-dicarbonyl compounds and Glu in the GG-ARP model limited the pyrazines formation. With the addition of Gal, the asynchronous effect was further exacerbated, and the furans in the GG-ARP-Gal model (956.81 μg/L, 120 °C, 60 min) were more significantly dominant among the volatile flavor compounds than in the GG-ARP model (454.98 μg/L, 120 °C, 60 min), while the pyrazines were still missing. Whereas, the extra-added Glu in the GG-ARP model could offset the deficiency of amino acids growth after α-dicarbonyl formation and promote the formation of pyrazines (74.47 μg/L, 120 °C, 60 min). Meanwhile, the formation of diketones (92.96 μg/L, 120 °C, 60 min) was promoted. The addition of Glu enhanced both milk-like and baking flavor of the GG-ARP system simultaneously. Formulated GG-ARP-Glu mixture was proposed to promisingly achieve the controlled formation of process flavors for baked foods with both desirable milk-like and baking scent.