0 and G230) fractions from micronized samples, semolina Antalis_MA. Different letters
0 and G230) fractions from micronized samples, semolina Antalis_MA. Distinctive letters 3.G250 and G230) obtained from Saragolla_LA, Antalis_BA and Antalis_MA. Various letters Figure indicate particle sizesignificant distinction (p 0.05, n = 2) inside each and every cultivar sample. frac(F250, Imply Charybdotoxin custom synthesis statistically fractions of micronized samples, semolina and air-classified tions (F250,statistically G230) obtained from Saragolla_LA, Antalis_BA and Antalis_MA. Unique indicate G250 and important difference (p 0.05, n = two) inside every single cultivar sample. lettersAsh Content material three.3. indicate statistically considerable difference (p 0.05, n = 2) inside each and every cultivar sample.three.3. In general, ash content of micronized samples and bran-enriched fractions was sigAsh Content 3.3. Ash Content0.05) larger compared to that of semolinabran-enriched fractions was substantially (p ash content material of micronized samples and (Figure four). Among F fractions, In general, Generally, 0.05) higher in comparison with to of semolina (Figure four). fractions fractions, ash content material(p ash content material of(Antalis_BA)samples(Antalis_MA), which was significantly nificantly ranged from 2.46 micronized that2.ten and bran-enriched Among Fwas considerably (p0.05) than in G, in comparison with thatto two.10 (Antalis_MA),4). Among F fractions, ash content material 0.05) greater varying from 1.89 (Antalis BA) to 1.59 which was drastically larger (p ranged from 2.46 (Antalis_BA) of semolina (Figure (Antalis_MA). ash content material 0.05) than in2.46varying from 1.89 (Antalis BA) to 1.59 (Antalis_MA). higher (p ranged from G, (Antalis_BA) to 2.10 (Antalis_MA), which was substantially higher (p 0.05) than in G, varying from 1.89 (Antalis BA) to 1.59 (Antalis_MA).Figure 4. Mean values of ash content material (d.m. ) of 5 milling solutions: micronized Etiocholanolone manufacturer sample, semolina, Figure 4. Imply values of ash content material (d.m. ) of 5 milling solutions: micronized sample, semolina, F250, G250 and G230 air-classified fractions obtained from Saragolla_LA, Antalis_BA and Antalis_MA. F250, G250 and G230 air-classified fractions obtained from Saragolla_LA, Antalis_BA and Antalis_MA. Various letters indicate statistically substantial variations micronizedeach cultivar sample. Figure four. Imply values of ash content (d.m. ) of five milling(p 0.05, n(p 0.05, n = sample, semolina, Unique letters indicate statistically important differences solutions: = three) within three) within each and every cultivar sample. F250, G250 and G230 air-classified fractions obtained from Saragolla_LA, Antalis_BA and Anta3.four. Alveographic Properties of Air-Classified Fractions lis_MA. Diverse letters indicate statistically considerable differences (p 0.05, n = 3) within each cultivar sample. Alveographic parameters of air-classified fractions, in comparison using the corre-sponding semolina samples, showed an elevated P/L ratio (Table two). Even though semolina samples showed P/L ratios ranging from a minimum of 1.49 0.15 (Antalis_BA) to a maximum of three.96 0.38 (Saragolla_LA), greater values were observed in air-classified fractions, varying from 4.69 0.21 (Antalis_BA G250) to 11.32 0.08 (Antalis_MA F250). The W parameters showed more homogeneous values involving air-classified fractions andFoods 2021, ten,eight ofsemolina in addition to a narrower range of variation (i.e., from 133 20 J0-4 (Antalis_BA F250) to 286 48 J0-4 (Antalis_MA semolina).Table two. Alveographic parameters of semolina and F250, G250 and G230 air-classified fractions obtained from 3 durum grain samples (Saragolla_LA, Antalis_BA, Antalis_MA). Unique lette.
