In this study, the physicochemical properties of aromatic rice prepared using different milling recoveries and roasting procedures were investigated. As a result, we found that the L value of different milling recoveries of aromatic rice (BA-1, BA-2, BA-4, and BA-6) increased as the aromatic rice (BA-0) decreased, while the a and b values decreased as the different milling recoveries increased. The major contributors to the different milling recoveries of aromatic rice were total polyphenol (28.11-33.84 mg/100 g), amylose (24.97-31.06 mg/100 g), total starch (68.27-73.04%) content. In addition, three different roasting methods were applied; the aromatic rice was roasted at 250℃ for 0 min (BAR-0M), 15 min (BAR-15M), or 30 min (BAR-30M). As a result, the color in terms of the L value decreased, whereas the a and b values increased. Also, the total phenolic and flavonoid contents in BAR-30M (41.65 mg/100 g and 22.30 mg/100 g, respectively) were higher than those in BAR-0M (33.00 mg/100 g and 20.78 mg/100 g, respectively). Similarly, the amylose and total starch contents in BAR-30M (26.10 g/100 g and 81.81%, respectively) were higher than those in BAR-0M (22.10 g/100 g and 74.26%, respectively). Furthermore, the DPPH, superoxide radical scavenging activity, and ferric reducing antioxidant potential of BAR-0M at 5,000 μg/mL were found to be 67.78%, 52.90%, and 0.79 mM, respectively. Based on these results, we can conclude that in order to provide the best physicochemical characteristics of aromatic rice, it should be manufactured in the following conditions: 20% milling recovery of the aromatic rice and roasting at 250℃ for 30 min.

This study was conducted to investigate the β-glucan contents and their characteristics of winter cereals according to particle sizes and milling recoveries. Sieved fractions differed in their average contents of β-glucans, and the coarse fraction had higher contents of β-glucan than finely milled fractions. In all winter cereals, the β-glucan contents of raw flours were higher than those of their brans, and the highest β-glucan contents of every cereals were observed at 100 mesh 〉 or 100-140 mesh fractions except the Chalssalbori fractions which showed the higest β-glucan contents (12.9%) at 140-200 mesh fraction. As compared with the β-glucan content of Chalbori among the various milling recoveries, the β-glucan was distributed more evenly throughout the endosperm but β-glucan content in bran of Chalbori was only 1.5%. However, β-glucan content of Chalssalbori (hull-less waxy barley) was the highest in the subaleurone region (8.2%) and declined slightly toward inner layers of grain. This results suggest that β-glucan distribution between high (Chalbori) and low β-glucan barley (Chalssalbori) may explain the difference in milling performance of barley. On the other hand, β-glucan contents of two rye varieties (Chilbohomil, Chunchoohomil) were lower than those of two waxy barley varieties, and the higest β-glucan contents were observed at the 60% milling recoveries. In all winter cereals, the L-values (lightness) of raw flours were higher than those of brans. And the L-values of barley varieties were higher than those of oat and rye varieties. As the particle sizes and milling recovery ratios were decreased, the L-value were increased. The a-values (redness) in brans of every winter cereals were higher than those of every particle size flours and every milling ratio fractions, and this tendency was observed in the b-values (yellowness) of every particle size of cereal flours. The L and b-value of barley, the b-value of oat, and L, a, b-value of rye have the significant relationship with the β-glucan contents, respectively. This results represent the fact that β-glucans affected the color of the flours and pounded grains of winter cereals.