Separate standard stock solutions were made for all of 12 isoflav

Separate standard stock solutions were made for all of 12 isoflavone forms and stored at 4 °C. According to the retention time and the maximum UV absorbance for the 12 standards, we accurately detected all forms of isoflavone components based on the UV absorption value at 260 nm. The various components of isoflavones, the aglycone form of isoflavone and the total isoflavone content in soybean seeds were calculated as described by Sun et al. (2011). Soluble solids content is an important parameter for beverage

evaluation in food industry. Therefore, the soluble solids of soymilk were Everolimus molecular weight determined using a Digital Handheld “Pocket” Refractometer PAL-1 (ATAGO Co., LTD, Tokyo, Japan) at room temperature in three replicates before heating. The results were expressed as degrees Brix at 20 °C. The plots of each experiment were arranged in a randomised complete

block design with three replicates. All data were subjected to an ANOVA using the general linear model (GLM) procedure of the SAS 9.2 software for Windows (SAS Institute, 2009) to identify significant treatment effects. Comparisons among means were made using the Least Significant Difference (LSD) test at α = 0.05 or less when ANOVA indicated that model and treatment were significant. Pearson correlation C646 coefficients for seed quality traits and soymilk sensory attributes were calculated based on genotypic means across the years using the correlation procedure (PROC CORR) of SAS 9.2. Moreover, a Principal Component Analysis (PCA) of the correlation matrix was performed for ranking sum values of sensory attributes using the SAS 9.2 software. Stepwise regression was

performed with soymilk sensory parameters and soybean seed chemical traits using SAS 9.2 software. All proceeding treatments were duplicated and field treatments were triplicated. ANOVA showed significant differences in protein and oil contents, fatty acid composition, isoflavone content, Chlormezanone the ratio of 11S/7S, and soluble solid among 70 soybean genotypes (Table 1). This is consistent with previous studies (Poysa and Woodrow, 2002 and Yoshikawa et al., 2014). Moreover, the variance for each seed quality trait spanned a wide range among 70 genotypes in this study. Protein content ranged from 37.04% in HF48 to 47.87% in 09P-21; oil content ranged from 16.97% in LD4 to 22.88% in ZH31; the protein ratio of 11S/7S subunit ranged from 0.99 in SuN to 8.28 in JD12; and isoflavone content ranged from 769.55 μg g−1 in 09J-28 to 2558.56 μg g−1 in 09P-1. The wide variance of seed chemical quality traits suggested an abundant genetic diversity among the 70 soybean genotypes. It is noteworthy that isoflavone components were also significantly different among field experiment repeats, whereas no significant difference was observed in other chemical quality traits (Table 1).

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