The present paper features Triticale grain processing. The research involved two Russian cultivars of Tri- ticale grain, i.e. Ramzes and Saur. We investigated two schemes of processing these grain varieties into high-qua- lity baker’s grade flour. The first scheme was reduced and included only the processes of breaking and reduction, whereas the second scheme was more advanced and included breaking, sieving, sizing, and reduction processes. The paper gives a thorough description of the processing schemes, their parameters, and milling modes. A detailed ana- lysis proved the high efficiency of the advanced scheme which presupposed the use of sieve purifiers. Their expe- diency was determined by the specifics of break dunst products at breaks I, II, and III. The Triticale flour varie- ties were produced by mixing various flows of the central, intermediate, and peripheral parts of the Triticale grain endosperm. The reduced scheme produced a 40% yield for the Ramzes variety (ash content = 0.70%, according to the State Standard 34142-2017*), while the advanced technological scheme resulted in a 63% yield. As for the Saur variety, the advanced scheme produced a total yield of 78%, which was 0.6% higher than in the reduced scheme. The advanced scheme resulted in a 46% yield of the T-60 flour variety, which had the lowest ash content among all the va- rieties of Triticale flour, whereas the reduced scheme failed to produce the flour of this variety. The experiment also involved the first-ever study of the rheological properties of Triticale flour varieties with Mixolab (Chopin Technolo- gies, France). The study revealed significant differences in baking absorption, doughing time, batch, gluten, viscosi- ty, amylase, and retrogradation. The best baking properties were displayed by T-70 and T-80 Triticale flours that were obtained from the central part of the endosperm, both in reduced and advanced processing schemes. However, the advanced scheme proved to be the most effective way of processing Triticale grain into baker’s grade flour.
Triticale grain, grain processing, reduced and advanced technological scheme, rheological and baking properties of flour
The use of non-traditional grain products, such as Triticale, in various sectors of the food industry is currently attracting increasing attention of Russian researchers and manufacturers. The interest can be ex- plained by the increasing acreage, new Triticale va- rieties, and numerous studies of their technological, biochemical, and biological potential [1–7].
Triticale is a laboratory-made hybrid of wheat and rye. Its nutritional values are superior to those of both
* State Standard 34142-2017 Triticale flour. Specifications. Moscow:
Standartinform Publ., 2010. 8 p.
parental plants [1]. In Russia, Triticale grain is currently used in compound feed and alcohol production. Howe- ver, Triticale grain can substitute wheat baking flour as a very advantageous source of raw materials in the pro- duction of various pastries, e.g. cookies, biscuits, waf- fles, muffins, crackers, etc. Triticale flour can be used in the production of instant noodles and quick breakfasts, as well as dietary, therapeutic, and prophylactic bread varieties, e.g. wholegrain and multigrain bread [8–13]. In addition, Triticale grain can be used to manufacture mass-market pasta products. Other promising research areas are the technology of processing Triticale grain and bran for starch [15], dietary fibre [14, 16], and bio-
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logically modified products [17, 18]. However, there is currently no industrial production of high-quality Triti- cale flour in Russia.
Over the past decade, foreign scientists have focused mainly on the biology of Triticale cultivars, their biolo- gical safety and development, the origin of hexaploid trit- icale, industrial production of triticale, its competitive- ness with wheat, genomics, and biotechnology [19–28].
Until recently, Triticale grain has been considered as an analogue of rye, at least according to its technologi- cal properties [13]. However, Russian breeders have made it possible to develop and introduce new promising Tri- ticale varieties into agricultural practice. These varieties have a predominance of wheat genotype, which affects the phenotypic characteristics of Triticale kernels, i.e. size, shape (sphericity coefficient ≥ 0.8), colour, as well as structural, mechanical, and technological properties [1].
The recent studies conducted have made it possible to obtain new data about the technological properties, biochemical composition, and varietal characteristics of Triticale grain and its products. The studies resul- ted in new technologies of Triticale flours production, as well as a new grit variety with specific properties that will be in demand in the baking, macaroni, confec- tionery, starch, meat, and other food industries [2, 3, 5, 7, 29, 30].
The present research aims at developing an effective technological scheme for processing Triticale grain into high-quality baker’s grade flour.
STUDY OBJECTS AND METHODS
The experimental studies were conducted by the departments of complex grain processing and safety of grain and grain products at the All-Russian Scientific Research Institute for Grain and Products of its Proces- sing (V.M. Gorbatov Federal Scientific Centre for Food Systems of the Russian Academy of Sciences). The ex- periment involved samples of two Triticale varieties: Ramzes (harvest 2014) and Saur (harvest 2015). Both cultivars were bred at the Don Zonal Research Institute of Agriculture (Rostov region, Russia). Table 1 shows the initial quality indicators of Triticale grain. The grain was prepared for milling according to the previously es- tablished parameters of hydrothermal treatment [2].
The milling was carried out on two milling and sort- ing aggregates: with fluted rollers (RSA-4-2) and with fro- sted rollers (RSA-4). The intermediate products were en- forced in a laboratory sieve purifier. The set of sieves and the speed of the air flow depended on the size of the initial product. The milling products were sieved on a laboratory plansifter for 90 seconds. The parameters and regimes of milling corresponded to the ‘Rules for organizing and con- ducting the technological process at flour mills’.
A research conducted in the laboratory ‘Technolo- gy and equipment of the milling industry’ (2014–2015) showed that the processing of Triticale grain into baker’s grade flour is more similar to that of wheat in its tech- nological properties [1, 13]. The grit formation process is characterized by a significant number of grits that consist of pure endosperms. The research employed the method of analysis developed for intermediate products of grain milling at the All-Russian Scientific Research Institute for Grain and Products of its Processing. Ac- cording to the analysis, Triticale products were di- vided into 3 groups: the actual grits (particles of pure endosperm), clots of endosperm and shell, and tail-end products that differed in shape and colour. The ana- lysis proved the need for the introduction of sieve pu- rifiers [5]. The analysis also revealed a high content of grits in intermediate products of the high-quality mil- ling of Triticale grain. Hence, it was found recommen- dable to extract the grits. The use of sieve purifiers in the high-quality milling of Triticale grain made it possi- ble to increase the yield of top-quality flours, as well as to obtain granular substances and middling that can be used for pasta manufacturing.
The expediency of the extraction and enforcement of large-size grits of 560–950 micrometres (µm) was proved only for break I. It was revealed that middle-size grits (315–560 µm) were suspended during breaks I and II, while the small-size grits (224–315 µm) were sus- pended during breaks I, II, and III. The composition of the intermediate products of the fourth break was char- acterized mainly by the presence of bran particles with high ash content. Hence, it was found impractical for en- forcement in a sieve purifier.
Thus, we developed an advanced technological scheme for milling Triticale grain with a sieve puri- fier and sizing. The scheme was based on the principle of gradual milling and sorting. The construction of the tech- nological scheme was determined by the requirements for the finished products (quality and yield of flour), variety of grain, and productivity. The reduced technological scheme included four break systems (br.), six reduction systems (red.), and one scratch system (scr.) [22]. The technological process of the advanced scheme included four break systems, two sizing systems (sz.), three sieving (SV), and six reduction systems (red.) (Fig.1).
The break process of the advanced scheme con- sisted of the stage of grit formation (breaks I – II) and a scratch stage (break IV and reduction system VI). The sieving process involved a separate enforcing of large- size grits of the first break (SV-1), medium-size grits of break systems I + II (SV-2), and small-size grits of I + II + III breaks (SV-3) [5]. The parameters of the sie- ving process were characterized by extracting the tail- e-nd fraction in an amount of at least 80% of the ini-
Table 1. Basic quality indicators of Triticale varieties
Triticale variety Quality indicators
|
Mass of 1,000 kernels, g |
Grain hardness, % |
Grain-unit, g/l |
Ash content, % |
Moisture, % |
Ramzes (2014) |
31.8 |
18 |
625 |
2.07 |
10.2 |
Saur (2015) |
33.2 |
44 |
661 |
1.99 |
9.3 |
tial mass. The through product of the sieve purifier SV-1 was directed to the frosted rolls of the first roller mill of the sizing system. The through product of sieve purifiers SV-2 and SV-3 were combined and directed for the milling to the roller mill of the first reduction system. Tailings from the first and second sieving systems, which made up 15–20%, were combined and sent for additio- nal milling to the roller mill of the fifth reduction system. Tailings from the third sieving system were sent for addi- tional milling to the roller grinding machine of reduction system IV.
The break systems used fluted rollers that were fluted back on the back. All the reduction and sizing systems used roller machines with frosted rolls. The modes of milling were characterized by a total 75% extraction of large-size dunst products and flour on grinding mill of breaks I, II, and III. The extraction mode on the grinding mill of the first break was 25–30%. The extraction mode on the grinding mill of sizing systems I, II, and III was 25–30%. The removal on the grinding mill of reduction systems I, II, and III was at least 50%.
The whiteness of Triticale flour was determined by measuring the reflectivity of a compacted smoothed flour surface with a photoelectric device. To determine the ash content, the flour and bran were burnt, and the mass of the non-combustible residue was measured. The baking absorption and the rheological properties were measured by recording the consistency of dough in the process of its formation from water and flour. The change in the consistency of the dough during kneading was measured with the help of a Mixolab system (Chopin Technologies, France). The baking properties were measured by using the method of laboratory bread ba-king from Triticale flour. The method involved the vo-lume (cubic centime- tres) of bread made from 100 g of flour, as well as scoring the appearance and the bread crumb.
RESULTS AND DISCUSSION
The first stage of the research was devoted to stu- dying the basic milling properties of the initial Triticale grain samples. After laboratory milling, we selected four flows of Triticale flour that were obtained both with re- duced and advanced technological schemes.
Triticale flour varieties were formed by three flour flows: A, B, and C [3]. Stream A was the flour from the hcentral part of the endosperm obtained during reduc- tion systems I, II, and III + sizing system I (advanced scheme) and the flour obtained on reduction systems I, II, and III (reduced scheme). Stream B was the flour from the peripheral part of the endosperm and the su- baleurone layer obtained on the third and the fourth re- duction systems and on breaks I, II, and III. Stream C consisted of endosperm fragments and shells from other technological systems.
Tables 2 and 3 present the quality indicators of Tri- ticale flour flows of Ramzes and Saur varieties obtained according to different technological processing schemes. Figs. 2 and 3 show cumulative ash curves of the re- duction and quality formation processes for Ramzes and Saur flours. The cumulative curves (Figs. 1 and 2) demonstrate that the reduced scheme had three distinct stages of flour formation, where as the advanced tech- nological scheme had two stages. A statistical analy- sis showed that cumulative curves can be represented as three and two linear segments for different milling schemes [3]. In case of Ramzes grain, the yield of T-70 Triticale flour (ash content ≤ 0.70%) was 40% for the reduced technological scheme. For the advanced tech- nological scheme, the yield of T-70 flour was 63%. The overall yield of flour was higher by 3.4% according to the advanced scheme, as compared with the reduced scheme. However, the advanced scheme resulted in a 46% yield of T-60 flour variety, which has the lowest
Fig. 1. Technological process of the advanced scheme for processing Triticale grain into high-quality baker’s grade flour
Table 2. Quality indicators of Ramzes Triticale flour flows obtained according to different processing schemes
Product Whiteness, conventional units Ash content, %
|
Reduced scheme |
Advanced scheme |
Reduced scheme |
Advanced scheme |
|
Flour from: |
|
|
|
break I |
45.0 |
46.7 |
0.87 |
0.69 |
break II |
52.0 |
55.5 |
0.69 |
0.57 |
break III |
51.7 |
46.5 |
0.84 |
0.74 |
break IV |
29.4 |
33.8 |
1.59 |
1.27 |
sizing system I |
– |
57.9 |
– |
0.64 |
sizing system II |
– |
45.4 |
– |
0.83 |
reduction system I |
50.0 |
60.7 |
0.71 |
0.50 |
reduction system II |
48.7 |
54.2 |
0.70 |
0.57 |
reduction system III |
44.0 |
41.4 |
0.69 |
0.85 |
reduction system IV |
34.8 |
23.6 |
0.77 |
1.29 |
reduction system V |
26.7 |
6.1 |
0.88 |
1.70 |
reduction system VI |
13.3 |
–1.8 |
1.27 |
1.83 |
scratch system I |
–5.9 |
– |
1.63 |
– |
Bran from:
break systems |
– – 6.35 |
5.26 |
reduction systems |
– – 3.94 |
4.43 |
Table 3. Quality indicators of Saur Triticale flour flows obtained according to different processing schemes
Product |
Whiteness, conventional units |
Ash content, % |
||
|
Reduced scheme Advanced scheme |
Reduced scheme Advanced scheme |
||
|
Flour from: |
|
||
break I |
45.3 |
42.5 |
0.67 |
0.77 |
break II |
51.8 |
55.1 |
0.57 |
0.50 |
break III |
53.1 |
40.1 |
0.56 |
0.82 |
break IV |
38.3 |
22.6 |
1.05 |
1.91 |
sizing system I |
– |
62.7 |
– |
0.63 |
sizing system II |
– |
55.5 |
– |
0.65 |
reduction system I |
48.4 |
65.1 |
0.59 |
0.54 |
reduction system II |
50.6 |
60.8 |
0.58 |
0.53 |
reduction system III |
42.7 |
53.3 |
0.77 |
0.60 |
reduction system IV |
29.2 |
43.3 |
1.02 |
0.75 |
reduction system V |
15.7 |
25.8 |
1.28 |
1.19 |
reduction system VI |
1.6 |
6.3 |
1.73 |
1.53 |
scratch system I |
–16.6 |
– |
2.17 |
– |
Bran from:
break systems |
– – 5.89 |
7.05 |
reduction systems |
– – 4.45 |
4.16 |
ash content (State Standard 34142-2017**). The reduced
scheme resulted in 0% of T-60 flour.
When processing Saur grain variety, the yield of T-70 Triticale flour was 73% according to both schemes (Table 3). The overall flour yield increased by 0.6%. The advanced processing scheme resulted in obtaining 42% of Triticale flour with ash content ≤ 0.55%.
The second stage of the research featured the rheo- logical properties [31] of ten separate flows of Tritica- le flour from Saur grain variety, obtained according to the advanced technological scheme by using a Mixolab system (Chopin Technologie, France). The Chopin+ protocol presupposes 5 research phases. Stage I lasts 8 min at 30°C; stage II lasts 15 minutes with a consis-
** State Standard 34142-2017. Triticale flour. Specifications. Moscow:
Standartinform Publ., 2010. 8 p.
tent increase in temperature at a rate of 4°C per minute from 30 to 90°C; stage III lasts 8 min at 90°C; stage IV lasts 10 min, with a consistent decrease in tempera- ture from 90 to 50°C; stage V lasts 5 min at 50°C. The rotational input in the analyzed points of the graph, from the point of view of biochemical processes, characte- rizes: formation of the dough (C1); dough dilution (C2); the maximum rate of starch gelatinization (C3); and the beginning and the end of the retrogradation of starch (C4 and C5). ά, β, and γ are the rates of biochemical re- actions (calculated values). The analysis also included the following indicators: the baking absorption of the dough, %; dough formation time, min; dough stability, min. The data of the integral evaluation of the rheolo- gical properties of the dough are visualized on the graph of the rotational input versus time in a particular tem- perature mode (Fig. 4, Tables 4 and 5) [31–33].
Reduced scheme Advanced scheme |
Reduced scheme Advanced scheme |
Fig. 2.Cumulative curves of ash content in Ramzes flour
Fig. 3. Cumulative curves of ash content in Saur flour
baking absorption |
Retrogradation |
batch |
amylase |
Gluten+ |
viscosity |
Time, min |
Time, min |
Rotational input, Nm |
Rotational input, Nm |
Temperature, C ° |
Temperature, C ° |
baking absorption |
Retrogradation |
batch |
amylase |
Gluten+ |
viscosity |
baking absorption |
Retrogradation |
batch |
amylase |
Gluten+ |
viscosity |
Rotational input, Nm |
Temperature, C ° |
Time, min
The fourth reduction system
Fig. 4. Phases of rheological analysis of the dough and Mixolab profiles of Triticale Saur flour flows from different technological
systems.
The rheological analysis made it possible to create graphical profiles inherent in each flow of Triticale flour. Fig. 4 shows the phases of the rheological analysis of the dough and the Mixolab profiles of the three flour flows: break I, reduction systems I and IV, since they demon- strated the greatest differences.
The viscosity value was different: 2, 7, and 5 scores for break I, reduction system I, and break system IV, re- spectively. It should be mentioned that viscosity depends on the state of starch, the activity of amylases, and the peripheral parts that contain non-starchy polysaccha- rides. The amylase index depends on the amylolytic ac- tivity of the flour. The higher it is, the lower the activity of enzymes. The starch retrogradation index is related to the rate of staling of the finished product. Its high value indicates a faster rate of staling.
Table 4 demonstrates that the baking absorption increased from the first reduction system to the sixth reduction system, which was connected with a larger number of peripheral water-absorbing particles in the flour. The first, second, and third breaks also showed an increase in baking absorption. The sizing sys- tem occupied an intermediate position between the break and the reduction systems. Its baking absorption was 55.0%.
During the first stage (C1), the flow stability was uneven. However, the stability time tended to decrease from reduction systems I – VI, which could also be con- nected with an increase in the content of peripheral par- ticles and a decrease in the dough formation time.
At the second stage (C2) of the curve of the mi- xolabogram, one can observe the smallest rotational input, which is associated with the dough dilution and indirect- ly characterizes the state of the protein complex. Visco- sity increased from breaks I – III. The sizing system had the lowest viscosity. The reduction systems demonstrated an increase in rotational input followed by its decrease, which was apparently due to an increase in the share of peripheral fractions in the flour of these systems.
During the third stage (C3), the starch granules broke down and gelatinized, which led to an increase in rotational input. There was a clear dependence of the increase in the rotational inputon the grain-size compo- sition of the flour at the break system and its reduction at the reduction system.
During the fourth stage (C4), one could observe a gradual increase in the rotational input of the break sys- tems and its decrease during the final reduction systems. The highest rotational input was registered during the second reduction system.
Table 6 visualizes the rheological characteristics of the flows as six consecutive indices: the index of water absorption index, the mixing index, the gluten index, the viscosity index, the amylase index, and the starch retro- gradation index.
The fifth stage (C5) characterized the process of starch retrogradation during cooling and the rate of staling of the finished flour products. Here, the rotational input on the reduction systems fell significantly from 4.221 Nm on re- duction system I to 2.731 Nm on reduction system I.
Table 4. Main parameters of the phases of rheological analysis of the dough of individual flows of Saur Triticale flour
Flour sample from: |
Water absorption, % |
Stability, min |
C1 |
C2 |
C3 |
C4 |
C5 |
break I |
54.2 |
4.42 |
1.030 |
0.253 |
1.273 |
2.178 |
3.644 |
break II |
53.1 |
3.87 |
1.109 |
0.286 |
1.401 |
2.294 |
3.766 |
break III |
53.5 |
4.78 |
1.226 |
0.335 |
1.809 |
2.245 |
3.529 |
sizing system I |
55.0 |
5.23 |
0.992 |
0.299 |
2.031 |
2.438 |
3.859 |
reduction system I |
54.1 |
5.62 |
1.093 |
0.335 |
1.947 |
2.449 |
4.221 |
reduction system II |
55.0 |
5.72 |
1.159 |
0.367 |
2.035 |
2.490 |
4.150 |
reduction system III |
57.0 |
5.42 |
1.156 |
0.372 |
1.820 |
2.441 |
3.957 |
reduction system IV |
57.6 |
5.65 |
1.081 |
0.337 |
1.752 |
2.258 |
3.489 |
reduction system V |
57.7 |
5.05 |
1.113 |
0.329 |
1.497 |
1.953 |
3.059 |
reduction system VI |
58.3 |
4.62 |
1.236 |
0.354 |
1.875 |
1.826 |
2.731 |
Table 5. Calculated values of reaction rates * for individual flows of Saur Triticale flour
Flour sample from: |
α, Nm/min |
β, Nm/min |
γ, Nm/min |
Rotational input, Nm/min |
Amplitude, Nm/min |
break I |
–0.036 |
0.130 |
0.088 |
3.644 |
0.134 |
break II |
–0.056 |
0.160 |
0.078 |
3.766 |
0.141 |
break III |
–0.064 |
0.374 |
0.010 |
3.529 |
0.140 |
sizing system I |
–0.056 |
0.322 |
0.032 |
3.859 |
0.103 |
reduction system I |
–0.060 |
0.286 |
0.038 |
4.221 |
0.108 |
reduction system II |
–0.062 |
0.416 |
0.042 |
4.150 |
0.141 |
reduction system III |
–0.056 |
0.292 |
0.020 |
3.957 |
0.168 |
reduction system IV |
–0.058 |
0.316 |
0.020 |
3.489 |
0.073 |
reduction system V |
–0.052 |
0.206 |
0.028 |
3.059 |
0.097 |
reduction system VI |
–0.060 |
0.388 |
0.022 |
2.731 |
0.154 |
*) α is characteristic of the dilution reaction rate expressed by the angle of the tangent to the mixolabogram from the moment the temperature rea- ches 30°C to the point C2; β is characteristic of starch gelatinization reaction rate, expressed by the angle of the tangent to the mixolabogram on the
C2 – C3 segment; γ is characteristic of the amylolysis rate, expressed by the angle of the tangent to the mixolabogram in the C3 – C4 segment.
Table 6. Indices of the Mixolab profiles for Saur Triticale flour
Flour sample from: Indices of the Mixolab profiles
|
Water absorption index |
Mixing index |
Gluten index |
Viscosity index |
Amylase index |
Starch retrogra- dation index |
break I |
1 |
1 |
5 |
2 |
9 |
8 |
break II |
1 |
0 |
5 |
3 |
9 |
8 |
break III |
1 |
2 |
2 |
6 |
8 |
8 |
sizing system I |
2 |
1 |
5 |
8 |
8 |
8 |
reduction system I |
1 |
2 |
4 |
7 |
9 |
8 |
reduction system II |
2 |
2 |
3 |
8 |
9 |
8 |
reduction system III |
3 |
2 |
3 |
6 |
9 |
8 |
reduction system IV |
4 |
2 |
4 |
5 |
9 |
8 |
reduction system V |
4 |
2 |
4 |
3 |
8 |
7 |
reduction system VI |
5 |
2 |
3 |
3 |
8 |
7 |
The analysis of the graphical profiles (Fig. 4, Table 5) showed that the highest value of the baking absorption index was registered in the flour from the sixth reduction system. The high water absorption capacity could be ex- plained by the fact that the system contained the largest number of peripheral parts of the kernels. The mixing index was related to the stability of the dough during kneading, which was 4.42 min for break I (1 score),
5.62 min for reduction system I (2 scores), and 5.65 min for reduction system IV (2 scores). The gluten index characterizes the stability of protein molecules when the dough was heated from 30°C to 60°C. It is rather difficult to interpret the gluten index since two very important phenomena occurred while the dough was being heated. First, starch granules began to swell; se- cond, their structure remained unchanged, while the ef- fect of α-amylase was insignificant. The consistency of
At the third stage of the research, we studied the samples of Ramzes and Saur Triticale flour from diffe- rent flows to determine the baking properties. To form a Triticale flour variety, three flows had to be formed on the basis of cumulative ash curves. These flows were three components of different anatomical parts of the kernels (Z – ash content, Y – yield). The first flow was Triticale flour from the central part of the endosperm, the second flow contained the peripheral part of the endo- sperm and the subaleurone layer, and the third flow was the flour from endosperm fragments and well-grin-ded shells. Below one can see the algorithm for the formation of three flows that form the Triticale flour varieties.
Flow formation for the Ramzes Triticale flour:
Milling 1 (reduced scheme):
Flow A – break II + reduction system III + reduction system I.
the dough changes due to the changes in the structure
of gluten proteins: hydrogen bonds break, stability of
Total: yield/ash content was 29.6/0.69; ZA 0.302×10–3 Y ; R2 = 0.82.
= 0,686 +
proteins improves, which is also related to their spatial
Flow B
A
– reduction system I + reduction system IV +
structure, and, ultimately, the nature of these protein
complexes [34, 35]. Such fractions of gluten proteins as
break III + break II + reduction system V.
Total: yield/ash content 35.8/0.80; Z
= 0.615 +
gliadin and glutenin play a decisive role in gluten quali-
ty formation and its elastic properties. However, it is ne-
0.211×10–2
B
|
cessary to take into account the role of other compounds that interact with gluten proteins and affect the structure and properties of gluten. They are lipids, carbohydrates, and enzymes, namely proteases and their protein inhibi- tors, amylases, lipoxygenase [36].
The viscosity index scored 2 for the flour from break I, 7 for the flour from reduction system I, and 5 for the flour from reduction system IV. This indicator characterizes the phase at which the greatest number of physicochemical and biochemical parameters start to in- teract. It should be mentioned that the viscosity in these samples depended not only on the activity of amylases, but also on the state of starch, its quality characteristics, and the presence of peripheral parts containing non- starch polysaccharides. The amylase index indirectly characterizes the amylolytic activity of the flour. A high amylase index indicates a weak activity of α-amylase in all the flour flows. The starch retrogradation index is connected with the ability of the finished product to re- sist staling. A high value of this indicator characterizes
a faster staling rate.
Flow C – reduction system VI + break IV + break V.
|
|
Milling 2 (advanced scheme):
Flow A + B – reduction system I + reduction system II + break II + sizing system I + break I + break III + sizing system II + reduction system III.
|
|
Flow C – break IV + reduction system IV + reduc- tion system V + reduction system VI.
|
|
Flow formation for the Saur Triticale flour:
Milling 1 (reduced scheme):
Flow A – break III + break II + reduction system II + reduction system I.
|
|
Flow B – break I + reduction system III + reduction
system IV + reduction system V.
Table 7. Quality indicators for samples of Triticale grain flour
№ |
№ of milling, |
Flour |
Moisture, |
Gluten, |
Gluten quality |
|
Falling |
|
Triticale variety |
variety |
% |
% |
Gluten Deformation Measurement |
group |
number, sec |
1 |
Ramzes, milling 1 |
T-80 |
11.0 |
20.6 |
49 |
II (strong enough) |
336 |
2 |
Ramzes, milling 1 |
T-120 |
11.0 |
19.5 |
50 |
II (strong enough) |
322 |
3 |
Ramzes, milling 1 |
T-70 |
10.6 |
26.2 |
52 |
II (strong enough) |
168 |
4 |
Ramzes, milling 2 |
T-80 |
11.0 |
26.7 |
71 |
I (good) |
178 |
5 |
Ramzes, milling 2 |
T-120 |
10.8 |
20.8 |
46 |
II (strong enough) |
305 |
6 |
Ramzes, milling 2 |
T-70 |
11.0 |
25.9 |
76 |
I (good) |
167 |
7 |
Saur, milling 1 |
T-70 |
10.6 |
27.2 |
67 |
I (good) |
171 |
8 |
Saur, milling 1 |
T-120 |
11.6 |
20.9 |
38 |
II (strong enough) |
353 |
9 |
Saur, milling 1 |
T-80 |
9.8 |
27.6 |
66 |
I (good) |
167 |
Table 8. Results of trial laboratory baking
№ Volume yield, cm3/100 g Shape sta-
Weight, g Appearance
|
Tin formed bread |
Oven-bot- tombread |
bility |
Tin formed bread |
Oven-bottom bread |
Shape |
Crust surface |
Crust co- lour |
1 |
350 |
400 |
0.48 |
135 |
132 |
regular, semi-oval |
slightly nodular |
pale |
2 |
350 |
350 |
0.48 |
136 |
132 |
regular, semi-oval |
cracked crust |
pale |
3 |
390 |
380 |
0.45 |
135 |
133 |
regular, semi-oval |
smooth, level |
brown |
4 |
430 |
450 |
0.51 |
134 |
128 |
regular, semi-oval |
smooth, level |
brown |
5 |
380 |
400 |
0.52 |
140 |
134 |
regular, semi-oval |
smooth, level |
pale |
6 |
460 |
470 |
0.58 |
134 |
130 |
regular, oval |
smooth, level torn from three sides |
brown |
7 |
470 |
470 |
0.57 |
135 |
131 |
regular, semi-oval |
smooth, level |
brown |
8 |
340 |
370 |
0.67 |
134 |
129 |
regular, semi-oval |
smooth, level |
pale |
9 |
420 |
450 |
0.50 |
133 |
127 |
regular, semi-oval |
smooth, level |
brown |
|
|
= 0.396 +
for one tin formed bread was 340–470 cm3/100g of flour
and 350–470 cm3/100g of flour for one oven-bottom loaf.
Flow C – reduction system V + reduction system VI
+ break IV.
Tables 8 and 9 represent the results of the trial labo-
ratory bread baking from nine samples of Triticale flour.
|
|
= –0.111 +
The tin formed bread baked from T-70 Saur flour
had the largest volume yield, while the smallest volume
After that, the Triticale flour flows from different technological systems were mixed in order to obtain in- dividual types of flour. As a result, three types of flour were obtained in accordance with the State Standard 34142-2017*** ‘Triticale flour. Technical conditions’: T-70, T-80, and T-120. The conventional name for the va- rieties includes the T index (Triticale), and a number that stands for the ash content × 100. Thus, T-60 flour was flow A with 0.60% ash content; flour T-70 was a mixture of A + B flows with 0.70% ash content; flour T-80 was a mixture of streams B + C with 0.80% ash content; flour T-120 was a mixture of flows A + B + C with 0.12% ash content.
All the formed triticale flour samples were analysed for such quality indicators as humidity, the quantity and quality of gluten, and the falling number (Table 7).
At the fourth stage of the research, we defined the baking properties of the nine samples of Triticale flour varieties, obtained according to different technological schemes (Table 8). The bread was baked from Triticale flour of various varieties according to the methodology of the State Committee on Agriculture. The volume yield
*** State Standard 34142-2017. Triticale flour. Specifications. Mos-
yield belonged to the bread baked from T-120 Ramses
flour (Fig. 5). The tin formed bread sample made from T-120 Ramses flour had the largest weight, whereas the lowest weight was registered for the sample made from T-80 Saur flour. Patterns with a smooth level surface had are regular semi-oval shape (samples 3–5, 7–9). Sample 1 had a slightly nodular surface. Sample 2 had a cracked crust; sample 6 was torn at three sides, respectively. The colour of the crust in samples 1, 2, 5, and 8 was pale due to the low activity of amylolytic enzymes. Samples 3, 4, 6, 7, and 9 had a brown crust. All the samples demon- strated a good crumb resilience and fine texture with uneven porosity. The thickness of the pore walls was found thick-walled and poorly developed for samples 1, 2, and 8. The taste was typical of Triticale flour bread. No stickiness, crunch, or crumbling were registered in any of the samples.
The best volume yield and total bakery assessment results belonged to the following samples: samples of Ramzes T-70 and T-80 (advanced scheme), Ramzes T-70 (reduced scheme), and Saur T-70 and T-80 (reduced scheme). These loafs also demonstrated the highest sen- sory assessment results (5 scores). The worst total ba-
kery assessment belonged to the sample made from
Fig. 5. Bread baked from the obtained varieties of Triticale flour
Table 9. Results of the trial laboratory baking
№ Porosity, % Crumb condition Sensory assessment
|
Elasticity, evenness, colour |
Porosity |
Appearance |
Crumb |
|
1 |
74 |
elastic, good, creamy-pale |
fine, thick-walled, uneven, poorly developed |
3 |
3 |
2 |
73 |
elastic, good, creamy |
fine, poorly developed, thick-walled, uneven |
2 |
3 |
3 |
78 |
elastic, good, dark |
fine, thick-walled |
5 |
5 |
4 |
81 |
elastic, good, creamy |
fine, thick-walled |
5 |
5 |
5 |
77 |
elastic, good, creamy-pale |
fine, uneven |
4 |
4 |
6 |
81 |
elastic, good, unevenly creamy-pale |
fine, thin-walled |
5 |
5 |
7 |
81 |
elastic, good, creamy-pale |
fine, thin-walled |
5 |
5 |
8 |
78 |
elastic, good, creamy-pale |
poorly developed crumb |
4 |
4 |
9 |
81 |
elastic, good, creamy-pale |
fine, thin-walled, uneven |
5 |
5 |
CONCLUSION
The research proved that, if processed according to the advanced technological scheme, Triticale grai- nincreases the total yield of flour by 0.6–3.4% compared to the reduced technological scheme. However, when Ramzes variety was processed according to the advanced scheme, the yield of T-60 flour with the lowest ash con- tent (according to State Standard 34142-2017****) was 46%, and the reduced scheme failed to produce the T-60 flour at all. When Saur variety was processed according to the advanced scheme, it gave a 55% yield of T-60 Triti- cale flour, where the reduced scheme resulted in 48%.
The study also helped to establish the effect of the grain hardness on the grit formation and on the yield of graded flour.
Sieve purification of intermediate Triticale products proved to increase the yield of flour from the central part of endosperm and the total yield of graded flour.
The cumulative ash curve for Triticale flour pro- cessed according to the advanced technological scheme can be represented in the form of two, rather than three linear sections that are used to describe the reduced scheme.
The rheological properties of Triticale flour from va- rious technological systems (flows) clearly demonstrated a regular increase in the baking absorption. Moreover, stability time during dough kneading decreased as the number of peripheral parts of the kernel. The state of protein-proteinase and carbohydrate-amylase complexes of individual flour flows had a more significant influence
**** State Standard 34142-2017. Triticale flour. Specifications. Mos-
on the viscosity index. Other factors included non-starch polysaccharides from the peripheral parts of the grain. The index rose between the first and the third breaks and fell between the first to the sixth reduction systems.
T-70 and T-80 Triticale flour varieties, obtained from the central part of the endosperm, have excellent baking properties, both according to the reduced and the ad- vanced schemes.
The advanced scheme with breaking, sieving, sizing, and reduction systems proved to be the most effective way to process Triticale grain into high-quality baker’s grade flour.
CONFLICT OF INTEREST
The authors declare that there are no conflicts of in- terest related to this article.
ACKNOWLEDGEMENTS
The authors would like to express their sincere grati- tude to Professor A.I. Grabovets, Doctor of Agricultural Science, Head of the Department of Wheat and Triticale Breeding and Seed Production (Don Zonal Research In- stitute) for the Triticale grain samples.
FUNDING
The studies received governmental funding in the framework of research project No. 0586-2014-0002 for 2015-2017 ‘Development of biomechanical models for the transformation of wheat, oats, and triticale grain with the aim of their deep processing and obtaining new food products and ingredients for general and functional
1. Sokol N.V. Tritikale - khlebnaya kulʹtura [Triticale is a bread culture]. Saarbrucken: Palmarium Academic Publ., 2014. 145 p. (In Russ.).
2. Kandrokov R.Kh., Starichenkov A.A., and Shteynberg T.S.Effect of hydrothermal processing on the yield and qualitytriticale flour. Bread products, 2015, no. 1, pp. 64-65. (In Russ.).
3. Pankratov G.N., Meleshkina E.P., Kandrokov R.Kh., and Vitol I.S. Technological properties of new varieties of triti- cale flour. Bread products, 2016, no. 1, pp. 60-62. (In Russ.).
4. Vitol I.S., Karpilenko G.P., Kandrokov R.H., et al. Protein-proteinase Complex Grain Triticale. Storage and proces- sing of farm products, 2015, no. 8, pp. 36-39. (In Russ.).
5. Pankratov G.N. and Kandrokov R.H. Investigation of the process of dressing grits in the grinding of grain triticale.Food processing industry, 2017, no. 7, pp. 30-33. (In Russ.).
6. Vitol I.S., Meleshkina E.P., Kandrokov R.Kh., Verezhnikova I.A., and Karpilenko G.P. Biochemical characteristic of new grades of triticale flour. Bread products, 2016, no. 2, pp. 42-43. (In Russ.).
7. Kandrokov R.Kh. and Pankratov G.N. Technology of processing of grain triticale wheat type semolina.Bread pro- ducts, 2017, no. 1, pp. 52-54. (In Russ.).
8. Magomedov G.O., Malyutina T.N., Shapkarina A.I., and Sirotenko N.Y. Development of aerated confectionery products of high nutritional value using triticale flour. Proceedings of the Voronezh State University of Engineering Technologies, 2016, no. 1, pp. 106-109. (In Russ.).DOI: https://doi.org/10.20914/2310-1202-2016-1-106-109.
9. Karchevskaya O.V., Dremucheva G.F., and Grabovets A.I. Nauchnye osnovy i tekhnologicheskie aspekty primene- niya zerna tritikale v proizvodstve khlebobulochnykh izdeliy [Scientific basis and technological aspects for the use of Triticale grain in bakery]. Baking in Russia, 2013, no. 5, pp. 28-29. (In Russ.).
10. Woś H., Brzeiński W., and Woś J. Breadmaking quality Triticale bred in Poland. 8th International Triticale Sympo- sium. Belgium, Ghent, 2013, pp. 23.
11. Koryachkina S.Ya., Kuznetsova E.A., and Cherepnina L.V. Tekhnologiya khleba iz tselogo zerna triticale [Bread ba- king technology from whole Triticale grain]. Orel: Orel State University named after I.S. Turgenev Publ., 2012. 176p. (In Russ.).
12. Chirkova L.V., Kandrokov R.Kh., and Pankratov G.N. Tritikale: ot zerna k muke. 140 let istorii [Triticale: from grain to flour. 140 years of history]. Confectionary and bread baking, 2015, vol. 160, no. 9, pp. 8-9. (In Russ.).
13. Grabovets A.I., Krokhmal A.V., Dremucheva G.F., and Karchevskaya O.E. Breeding of triticale for baking purposes.Russian Agricultural Sciences, 2013, vol. 39, no. 3, pp. 197-202.DOI: https://doi.org/10.3103/S1068367413030087.
14. Rakha A., Aman P., and Andersson R. Rheological characterisation of aqueous extracts of triticale grains and its re- lation to dietary fibre characteristics. Journal of Cereal Science, 2013, vol. 57, no. 2, pp. 230-236. DOI: https://doi. org/10.1016/j.jcs.2012.11.005.
15. Andreev N.R., Nosovskaya L.P., Adikaeva L.V., Nekrasova O.A., and Goldshtein V.G.Quality of Dry Fodder from Secondary Products of Processing of Triticale Grain for Starch. Achievements of Science and Technology of AIC, 2016, vol. 30, no. 11, pp. 73-75. (In Russ.).
16. Igoryanova N.A. and Meleshkina E.P.The possibility of using the secondary products of grain processing to obtainingredients with dietary fibre. Breadproducts, 2017, no. 10, pp. 41-44. (InRuss.).
17. Meleshkina E.P., Pankratov G.N., Vitol I.S., Kandrokov R.H., and Tulyakov D.G. Innovative Trends in the Develop- ment of Advanced Triticale Grain Processing Technology. Foods and Raw Materials, 2017, vol. 5, no. 2, pp. 70-82. DOI: https://doi.org/10.21603/2308-4057-2017-2-70-82.
18. Pankratov G.N., Meleshkina E.P., Vitol I.S., and Kandrokov R.Kh.Current trends of technological development of the production of milling industry and food processing industry. Food processing industry, 2017, no. 8, pp. 44-49. (In Russ.).
19. Barnett R.D., Blount A.R., Pfahler P.L., et al. Environmental stability and heritability estimates for grain yield and test weight in triticale. Journal of Applied Genetics, 2006, vol. 47, no. 3, pp. 207-213.DOI: https://doi.org/10.1007/ BF03194625.
20. Dennett A.L. and Trethowan R.M. The influence of dual-purpose production on triticale grain quality. Cereal Research Communications, 2013, vol. 41, no. 3, pp. 448-457. DOI: https://doi.org/10.1556/CRC.2013.0022.
21. Blum A. The abiotic stress response and adaptation of triticale - A review. Cereal Research Communications, 2014, vol. 42, no. 3, pp. 359-375. DOI: https://doi.org/10.1556/CRC.42.2014.3.1.
22. De Laethauwer S., Reheul D., De Riek J., and Haesaert G. Vp1 expression profiles during kernel development in six genotypes of wheat, triticale and rye. Euphytica, 2012, vol. 188, no. 1, pp.61-70. DOI: https://doi.org/10.1007/ s10681-011-0613-9.
23. Dennett A.L., Cooper K.V., and Trethowan R.M. The genotypic and phenotypic interaction of wheat and rye storage proteins in primary triticale. Euphytica, 2013, vol. 194, no. 2, pp. 235-242. DOI: https://doi.org/10.1007/s10681-013- 0950-y.
24. Manley M., McGoverin C., Snyders F., et al. Prediction of triticale grain quality properties, based on both chemical and indirectly measured reference methods using near-infrared spectroscopy. Cereal Chemistry, 2013, vol. 90, no. 6, pp. 540-545. DOI: https://doi.org/10.1094/CCHEM-02-13-0021-R.
25. McGoverin C., Snyders F., Muller N., et al. A review of triticale uses and the effect of growth environment on grain quality. Journal of the Science of Food and Agriculture, 2011, vol. 91, no. 7, pp. 1155-1165. DOI: https://doi. org/10.1002/jsfa.4338.
26. He M.L., McAllister T.A., Hernandez-Calva L.M., et al. Effect of dietary inclusion of triticale dried distillers’ grain and oilseeds on quality and fatty acid profile of meat from feedlot steers. Meat Science, 2014, vol. 97, no. 1, pp. 76-82. DOI: https://doi.org/10.1016/j.meatsci.2014.01.008.
27. Ukalska J. and Kociuba W. Phenotypical diversity of winter triticale genotypes collected in the Polish gene bank between 1982 and 2008 with regard to major quantitative traits. Field Crops Research, 2013, vol. 149, pp. 203-212. DOI: https://doi.org/10.1016/j.fcr.2013.05.010.
28. Bona L., Acs E., Lantos C., et al. Human utilization of triticale: technological and features, milling and baking expe- riments. Abstracts 8th international triticale symposium. Ghent, Belgium, 2013, pp. 46.
29. Kandrokov R.Kh. and Pankratov G.N. Sposob proizvodstva muki iz zerna triticale [Method for the production of flourfrom Triticale grain]. Patent RF, no. 2612422, 2015.
30. Chirkova L.V., Pankratʹeva I.A., and Politukha O.V. Sposob vyrabotki krupyanykh produktov iz zerna triticale [The method of cereal production from Triticale grain]. Patent FR, no.2616416, 2015.
31. Rukovodstvo po prilozheniyam Mixolab. Reologicheskiy i fermentnyy analiz (Manueld’ applications Mixolab) [Mi- xolab Application Guide. Rheological and enzyme analysis (Manueld’applications Mixolab)], 2009, no. 28, pp. 79. (In Russ.).
32. ICC № 173. Whole meal and flour from T. aestivum - Determination of rheological behavior as a function of mixingand temperature increase. Vienna, ICC Standard, 2008.
33. Antanas S., Alexa E., Negrea M., Guran A., and Lazureanu E. Studies regarding rheological properties of triticale,wheat and rye flours. Journal of Horticulture, Forestry and Biotechnology, 2013, vol.17, no. 1, pp. 345-349.
34. Tulyakov D.G., Meleshkina E.P., Vitol I.S., Pankratov G.N., and Kandrokov R.Kh.Evaluation of Triticale Grain FlourBased Rheology System Using Mixolab. Storage and processing of farm products, 2017, no. 1, pp. 20-23. (In Russ.).
35. Dubat A. Le mixolab Profiler: un outilcomplet pour le controlequalite des bles et des farines. Industries des Cereales, 2009, no. 161, pp. 11-26.
36. Dubtsova G.N., Nechaev A.P., and Molchanov M.I. Molekulyarno-biologicheskie aspekty formirovaniya lipid- belkovykh kompleksov i otsenka ikh roli v strukture kleykoviny [Molecular and biological aspects of the formation of lipid-protein complexes and their role in the structure of gluten]. In: Rastitelʹnyy belok: novye per-spektivy [Plant Protein: New Perspectives]. Moscow: Pishepromizdat, 2000, pp. 100-121. (In Russ.).