Influence of Wheat Flour Milling Yield on Physicochemical, Microbial, and Antioxidant Properties of Korea Wheat (Triticum aestivum L. var. Jokyoung)

Research Group of Food Processing, Korea Food Research Institute, Wanju-gun 55365, Republic of Korea Department of Biotechnology, College of Life Sciences and Biotechnology, Korea University, Seoul 02841, Republic of Korea Department of Food and Nutrition, Changwon National University, Changwon-si 51140, Republic of Korea Interdisciplinary Program in Senior Human Ecology, Changwon National University, Changwon-si 51140, Republic of Korea


Introduction
Wheat (Triticum aestivum L.) is one of the world's three major grains and accounts for approximately 28% of total cereal consumption [1,2]. In Korea, each individual consumes approximately 32 kg of wheat per year, and wheat consumption has increased gradually every year [3]. e market share of domestic wheat flour from the local wheat varieties in Korea is below 2%, with the majority of wheat being imported from the USA, Canada, and Australia [3]. For two decades, research institutes, companies, and growers have endeavored to develop new varieties and food products and increase the wheat-growing areas in Korea [4][5][6]. Food products made from domestic wheat flour are now distributed mainly through local grocery stores and cooperatives, which constitute a different distribution network to that used for conventional wheat products. As a result of these efforts, consumer awareness of Korean wheat flour is favorable and increasing [4].
Several studies on the domestic wheat in Korea have recently been published. Kwak et al. [7] compared the physicochemical properties of 160 imported wheat kernels and 433 domestic wheat kernels over a three-year period. ey found that domestic wheat flour had larger variations in the protein content and also showed that many samples had falling numbers below 300 s, which means that the products were not of good quality. In terms of the commercial wheat flour, domestic all-purpose wheat flours are similar to those that are imported [8]. However, domestic baking flours are of a lower quality compared to the imported varieties [9]. In a baking study comparing domestic and imported commercial wheat flours, the sensory profiles of pan breads made using imported wheat flours were similar to each other, while the pan breads made from domestic wheat flours showed larger variations in their sensory attributes [10]. Notwithstanding, the range of consumer acceptance ratings for the pan breads made from domestic and imported wheat flours were similar.
T. aestivum L. var. Jokyoung (Jokyoung), a Korean domestic wheat species, was developed in 2004 for baking purposes and can be grown in all regions of the Republic of Korea [11]. Approximately 20% of farmers grow Jokyoung mainly in the southeast region of the Korean peninsula [12]. Several studies have reported the physicochemical properties of wheat flour and food products made from Jokyoung. e wheat kernels of Jokyoung have a longer length and lower protein and ash contents than the kernels imported from the USA and Canada [13]. Kim et al. [14] reported that the overall baking quality from Jokyoung wheat flour was similar to that of US and Canadian wheat flours. Ham et al. [15] reported that a germinated Jokyoung species showed similar antioxidant activity in DPPH and ABTS assays compared with other domestic wheat varieties, such as Keumkang, Baekjung, and Goso. In application to rice wine making, consumer acceptance of rice wine made with Jokyoung wheat flour was found to be lower than for rice wine made using other wheat species [16].
Milling is a key process to producing wheat flour from wheat kernels. Several studies have been conducted to investigate milling and milling streams in terms of wheat flour quality. e cadmium distribution in millstream was detected mainly in the endosperm when analyzing 16 streams from a Buhler pneumatic laboratory mill for hard winter wheat in the USA [17]. Liao and Chen [18] showed that the SDS-insoluble proteins in wheat millstreams were various and were associated with noodle quality. In Indian wheat, the quality properties were similar for each milling stream, irrespective of the variety [19]. Fustier et al. [20] studied various composition of flours that were middlecut, clear, and produced from soft wheat flour milling for dough and cookie production. e clear millstream fraction was positively correlated with the cookies' hardness and density. Gomez et al. [21] showed that the final stream in their milling should be eliminated due to the negative impact on color, odor, and taste when cakes were made.
Previous milling studies provide evidence that a combination of wheat flour and the byproducts from each milling stream is used to produce the appropriate wheat flour from domestic or imported wheat kernels for each country. Several studies have reported on the physicochemical quality, pasting properties, and food application of wheat flour from one of the major wheat varieties in Korea, Jokyoung. However, no studies have reported for the quality characteristics of wheat flours produced from the various production yields from milling. e objective of this study, therefore, was to investigate the influence of wheat flour yield from milling on the physicochemical, microbial, and antioxidant properties for the Korean wheat variety (Triticum aestivum L. var. Jokyoung).

Wheat Flour Milling.
Wheat kernels (var. Jokyoung) were directly purchased from a local cooperative (Hapcheon-gun, Korea; 35°33′59.8″N 128°09′57.1″E) located in the southeast of Korean peninsula which is one of the major wheat-growing regions for Jokyoung. e wheat kernels were kept in a refrigerator (4 ± 1°C) for 10 days and milled. e wheat kernels were tempered with 16% moisture content at room temperature for overnight and milled using a test milling machine (Buhler, Braunschweig, Germany), according to the American Association of Cereal Chemists (AACC) method 26-21A [22]. Wheat kernels (40 kg) were put into a test mill at 30 g/min for milling. e wheat flours from each step were collected for the three streams of break (B1: 8.1%, B2: 7.4%, and B3: 1.8%) and the three streams of reduction roll (R1: 26.5%, R2: 14.0%, and R3: 3.3%). e weights of the wheat flour of each stream were then measured (Table 1). e straight flour was 61.12% of the initial weight. e rest was divided into clear flour, wheat shorts, and wheat brans based on the particle size and were composed of 9.6%, 8.5%, and 20.7% wheat flour, respectively. Straight flour, clear, shorts, and wheat brans were added in an consecutive order to produce the samples, which were 60%, 65%, 70%, 75%, 80%, 85%, and 90% of the input kernel weight and labeled as Y60, Y65, Y70, Y75, Y80, Y85, and Y90, respectively (Table 2). e samples were tightly packed twice in polyethylene bags and stored at 0°C until used.

Physicochemical Properties of the Wheat Flour Samples.
e moisture, protein, and ash contents of the samples were measured according to AACC methods [20]. Wheat flour (3 (g) was put into a 130°C dry oven for 24 hours to measure its moisture content (AACC method 44-15A). Crude protein was measured according to the micro-Kjeldahl method (AACC method 46-12) using a Kjeltec autosampler system 1035 analyzer (Tecator Co., Hoganas, Sweden). e crude protein content was obtained by multiplying the nitrogen content and nitrogen conversion factor (5.95). e wheat flour was heated at 600°C for 12 hours to measure the ash content (AACC method 08-01). e experiments were conducted in triplicate. e Hunter color (L, a, and b) of the wheat flour was measured five times using a portable spectrophotometer (Spectrophotometer CM-700d, Minolta Co., Osaka, Japan).

Solvent Retention Capacity Profile of the Wheat Flour
Samples.
e solvent retention capacity (SRC) profile of wheat flour consists of its sodium carbonate SRC (SCSRC), sucrose SRC (SSRC), lactic acid SRC (LASRC), and water retention capacity (WRC) values. ese were measured according to the method proposed by Duyvejonck et al. [23], which is a modification of the AACC method 56-11A [22]. Briefly, 25 mL of a 5% (v/v) sodium carbonate solution, a 50% (w/w) sugar solution, a 5% (w/w) lactic acid solution, and distilled water were used for the SCSRC, SSRC, LASRC, and WRC measurements, respectively. Flour (5 g) was added to the solvent, mixed for 20 minutes, and then centrifuged at 6000 × g.
e SRC values were obtained from the weight of the precipitate after removing the supernatant.

Rapid Visco Analysis of the Wheat Flour Samples.
For the rapid visco analysis (RVA), 3.5 g of wheat flour, which was adjusted to a 14% moisture basis, was blended with 25 mL of distilled water according to the AACC method 76-21 [22]. After blending, the wheat flour slurry was transferred to a rapid visco analyzer (RVA Model 3D, Newport Scientific, Warriewood, Australia). e analysis was conducted according to the manufacturer's manual. e pasting properties of the wheat flour slurry were measured as dry weight (dw). e analyzer was set at 50°C as the starting temperature and kept at this temperature for 1 minute. e slurry was then heated to 95°C at a rate of 6°C/minute and maintained at 95°C for 2 minutes. e temperature of the slurry went down to 50°C at a rate of 6°C/ minute. e paste viscosity properties of the wheat flour were peak viscosity (the maximum viscosity while heating the wheat slurry), trough viscosity (the minimum viscosity after the peak viscosity measurement), and final viscosity (the viscosity of the paste after cooling). All the values were recorded in centipoise (cP). Two derived viscosity values, namely, breakdown viscosity (the peak viscosity minus the trough viscosity) and setback viscosity (SB; the final viscosity minus the peak viscosity), were also calculated. Additionally, the pasting temperature and peak time were recorded. e measurements were undertaken in triplicate.

Differential Scanning Calorimetry.
e transition properties of the wheat flour samples were measured with a differential scanning calorimeter (DSC 7, Perkin-Elmer Co., Waltham, MA, USA) following the method of Lund and Lorenz [24]. e calorimeter was calibrated using an indium standard. e wheat flour samples (approximately 12 mg) were weighted into DSC stainless pans, and deionized water was added to obtain a wheat flour/water ratio of 3 : 7 (w/v). e pans were sealed and equilibrated at room temperature for 1 h. e samples were then cooled down at 10°C for 1 min and heated to 130°C at a heating rate of 10°C/min. An empty aluminum pan was used as a reference. e thermal transition parameters (onset, peak, conclusion and end temperatures and enthalpy change (ΔH)) were determined from the data recording software. All the measurements were performed in triplicate.

Microbiological Testing of the Wheat Flour Samples.
e aerobic plate count (APC) of the wheat flour was determined using a 3M APC Petrifilm (3M Co. Ltd., St. Louis, MO, USA), and the yeast and mold (YM) were counted using a 3M YM count plate Petrifilm (3M). A flour sample (10 g) and sterilized 0.85% NaCl solution (90 mL) were put into a stomacher (HG 400, Wiggens Co., Ltd., Beijing, China) and homogenized for 10 minutes. Serial 10-fold dilutions were carried out using a sterilized 0.85% NaCl solution. Homogenates (1 mL) were spread on the 3M Petrifilm and put into incubators-APC at 35°C for 48 hours and YM count plate Petrifilm at 25°C for 72 hours-for colony counting. e colonies were converted to log CFU/g.

DPPH Radical Scavenging Activity and Total Polyphenol
Content.
e DPPH radical scavenging activity (RSA) is one of the methods to identify antioxidant activity for wheat flour, wheat roasting, polished wheat, and baked products [2,[24][25][26]. e DPPH RSA of the wheat flour samples was measured according to the methods from Brand-William    [27,28]. Briefly, wheat flour (5 g, 14% w/w moisture content) was mixed with 50 mL of a methanol solution (80%, v/v) and blended at 37°C in a constant-temperature waterbath at 100 rpm for 2 hours for extraction. e mixture was vacuum-filtered using a Whatman No. 2 filter (Whatman plc, Maidstone, UK) and centrifuged at 7,165 ×g. e supernatant was evaporated using an evaporator (HS-2001N, Hahshin Science Co., Jeonju -si, Korea) until the volume of the supernatant was below 5 mL. After evaporation, 80% (v/v) methanol was added to the volume of 10 mL and was then filtered using a 0.45 μm filter (Merck, Darmstadt, Germany) for DPPH analysis. e extraction (0.1 mL) was blended with a 6 × 10 −5 mol/L DPPH solution at room temperature in the dark. After 30 minutes, the absorbance was measured at 515 nm using a SpectraMax ® i3 plate reader (Molecular Devices, Sunnyvale, CA, USA). e methanol solution (80%, v/v) was used as a control. e DPPH RSA (%) was calculated based on the following formula: (1) e total polyphenol content (TPC) of the wheat flour samples was measured according to the methods proposed by Hung et al. [2] and Gujral et al. [29]. Briefly, wheat flour (10 g, 14% w/w moisture content) was mixed with a 50 mL methanol solution (80%, v/v) and blended at 60°C in a constant-temperature waterbath at 100 rpm for 3 hours for extraction.
e mixture was vacuum-filtered using a Whatman No. 2 filter (Whatman plc, Maidstone, UK) and centrifuged at 3,000 rpm for 15 minutes. e supernatant was evaporated using an evaporator (HS-2001N, Hahshin Science Co., Bucheon-si, Korea) until the volume of the supernatant was below 1 mL. e concentrated extraction (100 μL), Folin-Ciocalteu reagent (500 μL), and 20% sodium carbonate (1.5 mL) were blended. ereafter, distilled water was added until the volume was 10 mL, and the solution was kept at room temperature for 2 hours. e absorbance was measured at 765 nm using a spectrophotometer (V-650, JASCO, Easton, MA, USA), and an ethanol solution (80%, v/v) was used as a control. e total polyphenol content was calculated as the gallic acid equivalent (GAE)/g of wheat flour (dwb).

Statistical
Analysis. Analysis of variance (ANOVA) was performed to determine the differences among the samples using the XLSTAT software version 2016 (Addinsoft, Paris, France). When significant differences were found among the samples, Fisher's least significant difference test was conducted to separate the means at p < 0.05.

Physicochemical Properties.
e physiochemical properties of the wheat flour samples in terms of color, moisture, protein, ash, and fat content are presented in Table 3. e moisture content was 11.88-12.12% (w/w), and there was no significant difference across the samples (p > 0.05). e addition of shorts and brans to the flour did not influence the moisture content of the wheat flour. e protein, ash, and fat contents were 12.91-14.04%, 0.42-0.97%, and 0.61-1.11%, respectively. ese were increased significantly (p < 0.05) as the clear flour, shorts, and brans were added in that order. e increases were because of the relatively higher contents of protein, ash, and fat in the shorts and brans of the wheat kernel rather than the endosperm [30,31]. e protein content of the white flour samples (Y60-Y70) was approximately 13% and meets the requirement of bakingpurpose wheat flour. e grade of the wheat flour in Korea is determined by its ash content. e Y60-Y75 samples were below 0.6%, which indicated first-grade wheat flour. e shorts-containing samples, Y80 and Y85, had 0.67% and 0.86% ash content, respectively, indicating second-grade wheat flour (0.6-0.9% of ash). e rest of the samples were found to be third grade, as they had an ash content above 0.9% [32]. In terms of the color of the flour, L value, a value, and b values were 90.06-95.14, 0.21-1.37, and 8.61-9.59, respectively. Lightness (L) was significantly decreased from the Y80 samples (p < 0.05), while redness (a) was significantly increased (p < 0.05) due to the addition of the shorts and brans that have a reddish color. e yellowness of the flours did not show an increased or decreased trend. Furthermore, the whiteness of the flour showed a similar trend to the lightness, decreasing from 79.20 (Y60) to 67.33 (Y90). e particle size of each sample ranged 15.7-25.7 µm and was similar to the Chinese wheat flour [33].

Solvent Retention Capacity.
e SRCs of the wheat flour from Jokyoung according to milling yields are shown in Table 4. According to Kweon et al. [33], starch damage is related to the SCSRC. e SCSRC was lowest in the Y60 sample at 60.80%, but gradually increased to 86.02% in the Y90 sample. e gold standard target for the SCSRC is below 72% for sponge and dough products [33], and the Y60-Y80 samples met this standard. e SCSRC increased drastically from Y85 due to the addition of brans to the wheat flour, which negatively influences starch damage [34]. According to Lindgren and Simsek [35], the arabinoxylan content is related to the SUSRC. As the milling yield increased, the SUSRC increased, which meant that the Y80-Y90 samples had a higher arabinoxylan content that existed in shorts and brans. Below 96% of the SUSRC is recommended for baking purpose [33], and all the samples were below this standard. e LASRC is the indicator of the gluten quality of wheat flour [34]. In this study, the LASRC decreased as the milling yield increased. e Y60-Y70 samples had the LASRCs above 118% but decreased significantly from the Y75 sample as the shorts and brans were added (p < 0.05). Y60-Y75 have above 100% of the LASRC, which is the gold standard target [33]. e WRC reflects the water absorption in wheat flour and recommended below 57% for baking purpose [24,36]. e Y60-Y75 samples, which did not contain shorts or brans, had similar WRCs to the Korean commercial baking flour samples [9]. As the brans were added to the flour, the WRC increased significantly (p < 0.05), and the WRC was over 80% from Y80. is increase of the WRC generates lower-quality paste properties due to the high moisture content of the paste. Schmiele et al. [37] reported that bread quality is reduced as more whole-wheat flour is added to the bread. erefore, maximizing milling yield for cost-benefit would generate low-quality wheat flour and also influence its paste properties.

Pasting Properties of the Wheat Flour Samples by RVA.
e pasting properties of wheat flour by RVA represents the flour quality based on starch swelling, retrogradation, and gelatinization [38]. e peak, trough, and final viscosities, breakdown and setback values, peak times, and pasting temperatures of the wheat flour samples in this study are shown in Table 5. All the parameters, except the pasting temperatures, showed significant differences among the samples (p < 0.05) and decreased as milling yield increased in general. Y60-Y70, which contained only flour parts, showed consistent ranges for the peak, trough, and final viscosities as 916.0-1367.3 cP, 580.3-952.7 cP, and 1274.0-1831.7 cP, respectively. e flour part samples, Y60-Y70, showed similar cP results compared to commercial Korean wheat flour used for baking purposes [9]. When the shorts and brans were added in the Y75-Y90 samples, the peak, trough, and final viscosities dropped significantly to 916.0 cP, 580.3 cP, and 335.7 cP, respectively. According to Blazek and Copeland [39], peak and trough viscosities are related to the swelling power of dough. In this study, as the flour yield increased, the dough quality decrease due to the addition of the shorts and brans. e setback value represents starch retrogradation [40]. e setback values were above 840 cP for the Y60-Y75 samples, but as large volumes of shorts and brans were added from Y80, the values dropped significantly to 673.7 cP. Moisture content, the ratios of amylose and amylopectin, the interaction of starch and protein, and temperature affect starch retrogradation [40][41][42]. In this study, starch retrogradation was prevented due to the fibers in shorts and brains, which inhibit recrystallization of amylose chains. e trend was also reported that the final millstream had a lower setback value in wheat flour milling [21]. ere was no significant difference in the peak times for the Y60-Y70 samples at 5.9-6.0 minutes (p > 0.05).
Lindgren and Simsek [35] reported that the peak times in the white flour parts were not significantly different across the millstreams. e peak time in this study gradually decreased from the Y75 (5.8 min) to the Y90 sample (5.5 min; p < 0.05). is was due to the low peak viscosity as the flour yield increased.
ere was no significant difference across the samples for the pasting temperature (p > 0.05).
e results of the pasting properties of the samples showed similar trends to those of the SRCs (Table 4), with lower variations among the Y60-70 samples, which comprised only straight and clear flours as the results from the negative correlation of SRC and RVA characteristics [35]. e RVA results of these samples had similar physicochemical properties to commercial bakingpurpose flour [9]. erefore, considering Jokyoung variety  Protein, ash, and fat contents were revised based on 14% of a moisture content of wheat flour. 2) 'ns' means no significant difference across the samples at p < 0.05 by Fisher's least significant difference test. 3) Mean values with different superscripts within each column are significantly different across the samples at p < 0.05 by Fisher's least significant difference test.
is used for baking purpose, the addition of shorts and brans should be carefully managed for dough and baking qualities.

ermal Transition Properties by Differential Scanning
Calorimetry.
e onset, peak, and end temperatures and enthalpy changes (ΔH) during gelatinization of the wheat flour samples according to milling yield are shown in Table 6. ere was no statistical significance in the onset and peak temperatures across the samples (p > 0.05) as 60.9-61.8°C and 65.0-65.7°C, respectively. ese results were similar to those for commercial domestic wheat flour for baking purposes, which showed onset temperatures of 59.5-59.8°C and peak temperatures of 64.9-65.2°C [9], and different ranges were similar to Chinese wheat flour [33], which used a single variety study with various millstreams. e onset temperature is related to the melting of the least stable starch crystallites [43], and the addition of clear flour, shorts, and brans did not affect the melting of starch crystallites. e end temperatures were 67.6-70.8°C and were significantly different among the samples. e wheat flour only sample (Y60-Y70) had a relatively lower end temperature, but there was no distinctive increasing or decreasing pattern based on flour yield. e ΔH is the energy necessary to melt starch crystallites when water is present [44]. e ΔH ranged between 4.9 J/g for Y90 and 10.0 J/g for Y65. Since there was no increasing or decreasing patterns, it is difficult to conclude that the addition of clear flour, shorts, and brans influenced the melting of starch crystallites. Overall, the above thermal transition results showed that the starch granules of each sample had similar thermal properties. e addition of shorts and brans to Y75-Y90 did not influence the thermal properties of the wheat flour. is could be due to the use of the same wheat kernels for milling and combining for wheat flour. Different millstreams using the same kernels displayed similar thermal transition properties for spring and winter wheat and rye in Sweden [45,46].

Microbial Properties of the Wheat Flour Samples.
e microorganisms in wheat flour proliferate because of the heat and moisture generated during milling, negatively influence wheat flour quality and cause food-poisoning [30,47,48]. Especially, the above log 5 CFU/g may lower the flour quality and cause foodborne disease [48]. e results of the APC, mold (MC), and yeast (YC) counts in the wheat flour samples are shown in Table 7. e APC was the highest in Y60 at 4.11 log CFU/g and the lowest in Y65 at 2.71 log CFU/g. ere was no distinctive trend in the APC across the samples. In terms of the FC, the fungi were between 2.79 and 3.01 log CFU/g and also showed no distinctive increasing or decreasing trend across the samples. ese results were similar to the previous to the two Jokyoung varieties that showed the APC and MC for two Jokyoung kernels were 3.76 and 4.27 log CFU/g and 2.52 and 3.56 log CFU/g, respectively [13]. e YC in the wheat flour samples were 1.90-2.80 log CFU/g, and there were no significant differences among the samples. e levels of mold and yeast were below log 5 CFU/g [48]; therefore, the samples in this study were below the maximum limits and were microbially safe, although brans were added. In a microbial study of 71 Australian wheat flour samples, the APC was 1-7 log CFU/g, the MC was 2-3 log CFU/g, and the YC was 2-3 log CFU/g   Journal of Food Quality [30]. erefore, the wheat flour from Jokyoung in this study was similar to that of the samples from the major wheatgrowing countries.

DPPH Radical Scavenging Activity and Total Polyphenol
Content. e DPPH RSA of the Jokyoung wheat flour according to milling yield is shown in Figure 1(a). Y60, which was a straight flour, had the lowest DPPH RSA at 0.96%, but this was slightly increased in the Y75 sample, which contained clear flour. is seemed to be additional small particles from the shorts and brans in the clear flour for Y70 and Y75. As the shorts and brans were added to the flour, the DPPH RSA increased significantly from Y75, with Y90 having the highest activity at 10.36% (p < 0.05). According to P. V. Hung et al. [2], the outer layer of the wheat kernel showed stronger DPPH RSA, and as the wheat kernels were polished, the DPPH RSA decreased. Stronger DPPH RSA was observed until 30% of the wheat kernels were polished. In this manner, our study also showed stronger DPPH RSA from 80% milling yields due to the addition of shorts and brans. Kwak and Kim [49] reported a similar DPPH RSA trend for another Korean wheat variety. e free phenolic compounds of the Jokyoung wheat flour according to milling yields is shown in Figure 1(b). e Y60-Y75 samples showed 2.25-3.22 mg GAE/g. is result demonstrated a similar TPC range compared to that of the imported and domestic wheat kernels (2.26-3.08 mg GAE/g) and the Keumkang variety (3.24-3.85 mg GAE/g) [19,50].
ere was a slight decrease in TPC from Y80 to Y90. ese free TPCs are polyphenolic compounds that can be absorbed in human intestines. e grains also contain significant amounts of bound phenolic compounds in their outer layers [2,51]. Since only 80% (v/v) methanol was used in the extraction process, the bound phenolic compounds in brans were hardly extracted for analysis. e first 30% of polished wheat kernels contained significantly higher bound phenolic compounds than the inner part of the kernels [2]. e reason that samples Y80-Y90 showed the same levels of free phenolic compound contents is due to the unextracted bound phenolic compounds from brans in samples Y85 and Y90. Although bound phenolic compounds are receiving interest [51], the addition of brans to wheat flour hardly influences free phenolic compounds.

Conclusions
Approximately 30,000 tons of wheat are harvested in Korea each year; therefore, the information for milling Korean wheat is rarely known within the industry. Various yields of Mean values with different superscripts within each column are significantly different across the samples at p < 0.05 by Fisher's least significant" difference test. 2) "ns" means no significant difference across the samples at p < 0.05 by Fisher's least significant difference test. wheat flour from the addition of clear flour, shorts, and brans to straight flour affected physicochemical and antioxidant properties. roughout this study, the wheat flour quality was identified according to the yield, and the quality change according to the yield can deliver valuable information for milling one of the two major wheat varieties in Korea. Significant changes in proximate analysis, color, SRC, RVA, and antioxidant activity were observed as the yield increased to maximize the production of wheat flour from wheat kernels. Adding clear flour and shorts (Y65-Y75) did not significantly affect the wheat flour quality in general. As brans were added to the flour portion (Y80-Y90), wheat flour quality decreased significantly due to the abundant fibers in brans. Maximizing wheat flour yield after milling is a key to minimize the production cost of Korean wheat flour, considering Korean wheat is approximately three times more expensive than the imported wheat flour. Adding a certain portion of shorts seems not to significantly influence the overall quality of wheat flour and can maximize the costbenefit in milling of Korean wheat kernels. One limitation is that this milling study was conducted using a single-year crop, the same as other researchers' milling studies; therefore, this study could not generalize the wheat flour quality for the Jokyoung variety due to not considering climate and growing conditions over several years.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that they have no conflicts of interest.