Keywords:

Triticum aestivum L.

Agronomic performance

Industrial quality

Flour

Bread

Agronomic performance and industrial quality of bread wheat (Triticum aestivum L.) genotypes

cultivated in the northeast of Mexico

Comportamiento agronómico y calidad industrial de genotipos de trigo para panicación (Triticum

aestivum L.) cultivados en el Noreste de México

Comportamento agronômico e qualidade industrial de genótipos de trigo panicável (Triticum

aestivum L.) cultivados no Nordeste do México

Nydia del Carmen Ramírez-Cortez

José Elías Treviño-Ramírez

Jesús Andrés Pedroza-Flores

Vania Urías-Orona

Lidia Rosaura Salas-Cruz

Guillermo Niño-Medina

Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228

ISSN 2477-9407

DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v42.n2.XII

Crop production

Associate editor: Dra. Evelyn Pérez Pérez

University of Zulia, Faculty of Agronomy

Bolivarian Republic of Venezuela

Universidad Autónoma de Nuevo León, Facultad de

Agronomía, Francisco Villa S/N, C.P. 66050, Col. Ex-

hacienda El Canadá, General Escobedo, Nuevo León,

México.

Universidad Autónoma de Nuevo León, Facultad de Salud

Pública y Nutrición, Av. Dr. Eduardo Aguirre Pequeño y

Yuriria, C.P. 64460, Col. Mitras Centro, Monterrey, Nuevo

León, México.

Received: 08-10-2024

Accepted: 17-04-2025

Published: 28-05-2025

Abstract

Wheat is one of the main crops worldwide, it is distributed

in dierent climatic, ecological and geographical regions around

the world, being a basic food for human nutrition. The search for

genotypes that have to dierent environments is a common practice

in agriculture. The objective of this study was to evaluate the

agronomic performance and industrial quality of four genotypes

of bread wheat (BW), namely, BW1 (Control) (San Isidro NL

M-2012), BW2 (Floreña NL M-2012), BW3 (Norteña F2007), and

BW4 (Conatrigo F2015). Wheat genotypes were evaluated using a

complete randomized block design with four replicates. Based on

results, BW4 (Conatrigo F2015) had better agronomic performance

with higher results in spike length (11.10 ± 0.38), number of

spikelets per spike (18.78 ± 0.91), number grains per spike

(55.65 ± 7.13), grain yield per hectare (6.42 ± 1.29), forage per

hectare (12.25 ± 1.30), and L* in the our (88.74 ± 0.15). BW4

(Conatrigo F2015) also had the lower weight loss (10.15 ± 1.30)

and the higher L* in crust (68.55 ± 0.09). In conclusion, genotypes

evaluated in the present work had similar or better results in most

of the agronomic performance and industrial quality compared with

BW1 (Control) (San Isidro NL M-2012), being BW4 (Conatrigo

F2015) the outstanding genotype.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228 April-June. ISSN 2477-9409.

2-7 |

Resumen

El trigo es uno de los principales cultivos a nivel mundial, se

distribuye en diferentes regiones climáticas, ecológicas y geográcas

alrededor del mundo, siendo un alimento básico para la nutrición

humana. La búsqueda de genotipos que se adapten a diferentes

ambientes es una práctica común en la agricultura. El objetivo de este

estudio fue evaluar el desempeño agronómico y la calidad industrial

de cuatro genotipos de trigo para panicación (BW), llamados, BW1

(Testigo) (San Isidro NL M-2012), BW2 (Floreña NL M-2012), BW3

(Norteña F2007) y BW4 (Conatrigo F2015). Los genotipos de trigo

se evaluaron mediante un diseño de bloques completos al azar con

cuatro repeticiones. Con base en los resultados, BW4 (Conatrigo

F2015) tuvo mejor desempeño agronómico con mayores resultados

en longitud de espiga (11.10 ± 0.38), número de espiguillas por

espiga (18.78 ± 0.91), número de granos por espiga (55.65 ± 7.13),

rendimiento de grano por hectárea (6.42 ± 1.29), forraje por hectárea

(12.25 ± 1.30) y L* en la harina (88.74 ± 0.15). BW4 (Conatrigo

F2015) también tuvo la menor pérdida de peso (10.15 ± 1.30) y el

mayor L* en corteza (68.55 ± 0.09). En conclusión, los genotipos

evaluados en el presente trabajo tuvieron resultados similares

o mejores en la mayor parte del comportamiento agronómico y

calidad industrial en comparación con BW1 (Testigo) (San Isidro NL

M-2012), siendo BW4 (Conatrigo F2015) el genotipo sobresaliente.

Palabras clave: Triticum aestivum L., desempeño agronómico,

calidad industrial, pan.

Resumo

O trigo é uma das principais culturas mundiais, está distribuído

em diferentes regiões climáticas, ecológicas e geográcas ao redor

do mundo, sendo um alimento básico para a nutrição humana.

A busca por genótipos adaptados a diferentes ambientes é uma

prática comum na agricultura. O objetivo deste estudo foi avaliar o

desempenho agronômico e a qualidade industrial de quatro genótipos

de trigo panicável (BW), denominados BW1 (Testigo) (San Isidro

NL M-2012), BW2 (Floreña NL M-2012), BW3 (Norteña F2007)

e BW4 (Conatrigo F2015). Os genótipos de trigo foram avaliados

em delineamento experimental de blocos casualizados com quatro

repetições. Com base nos resultados, o BW4 (Conatrigo F2015)

apresentou melhor desempenho agronômico com maiores resultados

em comprimento de espiga (11.10 ± 0.38), número de espigas

por espiga (18.78 ± 0.91), número de grãos por espiga (55.65 ±

7.13), produtividade de grãos por hectare (6.42 ± 1.29), forragem

por hectare (12.25 ± 1.30) e L* em farinha (88.74 ± 0.15). BW4

(Conatrigo F2015) também apresentou menor perda de peso (10.15 ±

1.30) e maior L* em casca (68.55 ± 0.09). Concluindo, os genótipos

avaliados neste trabalho tiveram resultados semelhantes ou melhores

na maior parte do comportamento agronômico e qualidade industrial

em comparação com BW1 (Testigo) (San Isidro NL M-2012), sendo

BW4 (Conatrigo F2015) o genótipo de destaque.

Palavras-chave: Triticum aestivum L., desempenho agronômico,

farinha, qualidade industrial, pão.

Introduction

Wheat is a very important crop with a production of 808.44 million

tons in the 2022 agricultural year according to data from the Food and

Agriculture Organization of the United Nations. The main producers

of this crop were China, India and Russia which contributed 17.03,

13.32, and 12.89 %, respectively (FAO, 2024). This crop is one of

the main crops worldwide together with maize, rice, barley, sorghum,

oat and rye, and it is distributed in dierent climatic, ecological,

and geographical regions around the world; and is a basic food for

humans, animal feed, and industrial raw materials (Le et al., 2019).

Within the genus Triticum, there are dierent species of great

interest mainly for human consumption, this is the case of bread

wheat (Triticum aestivum L.) genotypes, which is mainly used in

baking because it is a very elastic and extensible gluten (Hernández

et al., 2011). Bread wheat is hexaploid, which is the result of crossing

a tetraploid wheat (2n = 4x = 28, AABB) and a wild one (2n = 2x

= 14, DD) followed by spontaneous chromosome duplication. The

evolution of wheat is distinguished by domestication and natural

hybridization (Li et al., 2014).

Wheat can be evaluated in external and internal aspects. The rst

one is based on freedom from foreign material and weather damage,

type, and purity of color. The second one based on weight test,

moisture content, milling behavior and end-use of our (Khalid et

al., 2023).

The main products obtained from wheat are whole our and white

our. Whole our is obtained from the entire wheat grain and the

principal anatomical components (starchy endosperm, germ and bran)

are present in the same relative proportions as they exist in the intact

caryopsis with extraction yield of 100 % (Pagani et al., 2014). On the

other hand, white our classied in: straight our, which is obtained

by removing most of the bran and germ, using mainly endosperm

with extraction yield of 72 %; patent our, which is obtained from

the innermost part of the endosperm and is essentially free of bran

and germ with extraction yield between 45 and 65 %; and clear our,

obtained from the outer part of the endosperm with high content of

bran with extraction yield between 65 to 72 % (Finnie and Atwell,

2018; Figoni, 2010).

Quality can have dierent meanings depending on the link in the

wheat value chain. For the farmer, a high-quality wheat crop could

require the least inputs and has the highest grain yield, and a good

price in the market. However, for the miller, quality is based on the

our yield, along with the energy needed to obtain it. For the industry,

quality is based on the characteristics of dierent products (Guzmán et

al., 2022).

Recommendation of wheat cultivars requires the knowledge of their

response to environmental conditions in particular locations or zones.

The best performing cultivars should be preferred for recommendation

in locations of similar environmental conditions (Iwańska et al., 2020).

The environmental conditions, determined by the altitude and

temperate-cold climate of the northeast region of Mexico, make

wheat cultivation viable, making it a productive option for this region.

Furthermore, the search for new wheat genotypes that adapt to new

production areas with improved development, yield, and industrial

quality characteristics is always a challenge. In this regard, the main

objectives of this work were as follows: evaluate the agronomic

performance of bread wheat (Triticum aestivum L) genotypes grown in

northeastern Mexico and determine the our and bread quality obtained

from Triticum aestivum L. genotypes grown in northeastern Mexico.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Ramírez-Cortez et al. Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228

3-7 |

Materials and methods

Characterization of the study site

Location of the study area was the experimental agricultural

campus of La Ascensión Academic Unit, Agronomy College, within

Universidad Autónoma de Nuevo León, in Ejido La Ascensión,

Aramberri (24°19.5‘ N, 99°54.5’ W) Nuevo León, Mexico, at

an altitude of 1963 m, with an average annual temperature and

precipitation of 19.9 °C and 425 mm, respectively (INEGI, 2023). The

soil characteristics were obtained by an external laboratory analysis

with next results: loam soil (33 % clay, 33 % silt and 33 % sand), pH

8.1, 3.24 % of organic matter content, electrical conductivity of 1.97

dS.m

-1

, rich in potassium (1026 ppm), optimum levels of nitrogen

(169 ppm) and poor in potassium (25 ppm).

Genetic material

The genotypes of bread wheat (BW) were BW1 (San Isidro

NL M-2012) (control), BW2 (Floreña NL M-2012), BW3 (Norteña

F2007), and BW4 (Conatrigo F2015). BW1 and BW2 genotypes were

developed by Dr. Ciro G. S. Valdés Lozano in the Agronomy College,

within the Universidad Autónoma de Nuevo León, while BW3 y

BW4 were developed by Villaseñor et al. (2012; 2020), respectively

at National Institute for Forestry, Agriculture and Livestock Research

(Instituto Nacional de Investigaciones Forestales, Agrícolas y

Pecuarias, INIFAP).

Wheat genotypes are registered in National Catalogue of Plant

Varieties (Catálogo Nacional de Variedades Vegetales [CNVV],

2024) as: TRI-136-190712, TRI-132-190712, TRI-102-260608, TRI-

174-231117 for BW1, BW2, BW3 and BW4, respectively. General

description of genotypes is presented in table 1.

Table 1. General description of bread wheat (Triticum aestivum

L.) genotypes.

Genotype Overview

BW1

Resistant to leaf rust, 65 cm plant height, 7.5 cm spike length,

good grain yield and good industrial quality.

BW2

Resistant to leaf rust, 80 cm plant height, 9.5 cm spike length,

good grain yield and good industrial quality.

BW3

Resistant to moderately susceptible to leaf rust, 86 cm plant

height, 15 cm spike length, high yield and good industrial

quality.

BW4

Resistant to rust, 89 cm plant height, high yield and good indus-

trial quality.

Experimental design and eld distribution

The genotypes were distributed in a randomized block design with

four replicates. Each experimental unit consisted of four furrows, 5

m length and 1.8 m width each, with a separation of 0.45 m among

them, resulting in an area of 9 m

. There was a gap of 2 m between

each block (gure 1).

Land preparation for planting

To ensure proper crop establishment, it is necessary to undertake

a harrowing and crossing process, resulting in a more manageable

planting bed. Sowing was conducted manually on May 25, 2021,

with a sowing density of 100 kg.ha

-1

of seed three relief irrigations

were conducted in a sprinkler irrigation system, and they consisted of

8160 L per irrigation (1020 L.h

-1

, 4 h, 2 irrigation lines). In addition,

a commercial bio-stimulant (auxins, gibberellins and cytokinins at

0.09, 0.10 and 1.50 g.L

-1

, respectively) of organic origin containing

macronutrients (N, P

, K

O, Ca and Cu at 6.6, 13.3, 13.3, 2.0 and

4.0 g.L

-1

, respectively) and micronutrients (Cu, Fe, Mn and Zn at

13.3, 17.2, 13.3 and 26.5 g.L

-1

, respectively) in chelated form at a

dose of 2 mL.L

−1

(25 L of water). Weed control was conducted by

giving an application with 2,4-D (480 g.L

-1

) at a dose of 2 L.ha

−1

(35 L

of water), when the plant was 10 to 20 cm high, and then weed control

was conducted manually.

Harvesting

The harvest was carried out when crop reached 18 weeks of

development on September 28. The plants of each experimental unit

were harvested manually cutting plants from the base of the stem

using sickles. The plants were harvested in 3 m of two central furrows

with a separation of 0.45 m between them, resulting in an area of

1.35 m

. Samples were placed in kraft paper bags, identied and then

transported to the multipurpose agronomic laboratory, where they

were evaluated for development and performance traits.

Development and performance traits

Plant height

The measurement was made in 10 plants per replicate using a

exometer. The height was taken from the base of the stem to the tip

of the inorescence and reported in centimeters (cm).

Number of leaves per plant

Total number of leaves were counted in ten plants per replicate

from the stem to the inorescence including the ag leaf.

Number of tillers per plant

The tillers were counted in ten plants per replicate counting the

number of secondary stems. The determination was carried out when

owering exceeded 50 %.

Spike length

The length of the spikes of ten plants per replicate were measured

from the base to the apex of the terminal spikelet using a ruler and

reported in centimeters (cm).

Number of spikelets per spike

The number of spikelets in ten spikes per replicate were counted.

Figure 1. Experimental eld layout of wheat crop.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228 April-June. ISSN 2477-9409.

4-7 |

Number of grains per spike

The number of grains in ten spikes per replicate were counted.

Thousand grain weight

One thousand grains clean and free of damage were counted per

replicate, the weight was recorded using a balance (Truper® model

102317, Mexico) and the results were expressed in grams (g).

Forage Yield

Plants from 1 m

of central furrow per replicate were cut and

weighted in a balance (Torrey® model L-EQ 10/20, Mexico), data

were converted and reported as (t.ha

-1

Grain yield per hectare

Plants used in forage yield were threshed using a craft electric

thresher and the clean grains were weighed in a balance (Torrey®

model L-EQ 10/20, Mexico), data were converted and reported as

(t.ha

-1

Days to physiological maturity

It was determined counting from the day of sowing until the day

where 90 % of the plants per replicate lost chlorophyll and turned

yellow.

Grain moisture

The evaluation of grain moisture was carried out according to

Gutheil et al. (1984) using a electronic moisture tester (Steinlite®

model RCT, USA) and results were reported as percentage (%).

Production and physical characterization of wheat our

Production of wheat our

One kilogram of grain free of impurities was considered. Grains of

each bread were milled using an electric experimental mill by passing

the material through the mill twice. Subsequently, each sample was

passed through a physical testing sieve with #30 mesh (595 µm) and

our yield was reported as percentage (%).

Flour color

Flour color parameters were obtained using a colorimeter

(Minolta® model CR-20, Japan). A petri dish was lled with 100 g of

wheat our and chromatic parameters were obtained using CIELAB

(L*, a*, b*) and CIELCH (L*, C*, h) color systems, where L* denes

lightness (0= black, 100= white), a* indicate red (positive a*) or

green value (negative a*) and b* indicate yellow (positive b*) or blue

value (negative b*). In addition, C* (chroma) saturation level of h and

h (hue angle 0°= red, 90°= yellow, 180°= green and 270°= blue) were

also reported, according to Commission Internationale De L’ecleirage

(CIE, 2004). Color view was obtained by online software ColorHexa

(ColorHexa, 2023) color converter using L*, C* and h values.

Dough extensibility

Dough extensibility was measured using a texturometer (TA.XT

plus Stable Micro Systems, UK) and the Kieer dough and gluten

extensibility kit according to Dunnewind et al. (2003). Maximum

force (N) and distance (mm) of extensibility test were obtained at 30,

60 and 90 min after preparation of dough.

Industrial quality evaluation of bread wheat

Breadmaking process

The Bread preparation was done by using 200 g of our, 6 g of

yeast and 3 g of salt, while water used was 140 mL for BW1, 145

mL for BW3 and 150 mL for BW2 and BW4. Solid ingredients were

mixed in a mixer (KitchenAid model KSM7586PSR, USA) at speed

1 for 1 min, after that, water was added and mixed for 10 min at speed

4. Later, dough was divided in 4 pieces of 85 g and they were placed

in steel mini loaf pans (9.5 x 5.7 x 3.2 cm), left for fermentation at

35.5 °C for 30 min, afterwards baking at 200 °C for 30 min in a rotary

gas oven (Century Model 20, Mexico) and nally bread pieces were

cooled at room temperature.

Physicochemical evaluation of bread

Physicochemical evaluations were conducted according to

according to Niño-Medina et al. (2017) with minor modications.

The height of bread was measured with a Vernier caliper (Steren

model HER-411, Mexico) on the central part of the bread pieces,

and it was reported in millimeters (mm). The weight loss (WL) was

obtained with the next equation (Eq. 1):

(Eq. 1)

where: WBB= weight before baking and WAB= weight after

baking. Hardness was evaluated with a texture analyser (Stable

Micro Systems TA.XT.Plus, UK) using a compression plate of 75

mm diameter and a compression distance to 30 % of the bread height.

Chromatic evaluation was done in the bread crust of the bread pieces

using a colorimeter (Minolta model CR-20, Japan) and chromatic

parameters were obtained using CIELAB (L*, a*, b*) and CIELCH

(L*, C*, h) color systems where L* denes Lightness (0= black and

100= white), a* indicate red (positive a*) or green value (negative

a*) and b* indicate yellow (positive b*) or blue value (negative b*).

In addition, C* (Chroma) saturation level of h and h (hue angle 0°=

red, 90°= yellow, 180°= green and 270°= blue) were also reported

according to Commission Internationale De L’ecleirage (CIE, 2004).

Color view was obtained by online software ColorHexa (ColorHexa,

2023) color converter using L*, C* and h values.

Statistical analysi

The statistical analysis was conducted using Minitab software

14.0 (Minitab, 2023). In addition, comparison among genotypes

was conducted using a randomized complete block design model. A

multiple comparison of means was performed using the Tukey test

(p≤0.05).

Results and discussion

Development and performance traits parameters in bread wheat

(Triticum aestivum L.) genotypes are shown in table 2. The PH and

NLP per plant are critical variables that impact the yield. There

was no statistical dierence between genotypes for PH and NLP

variables. Our results show plant heights below the range of 84 to105

cm observed by Noriega-Carmona et al. (2019) whom evaluated the

eect of sowing date in 34 wheat genotypes developed in Guanajuato,

Mexico. The NTP showed statistically signicant dierence (p≤0.05)

among the genotypes. Our results are similar with those reported by

Huanca et al. (2016) whom also reported an average of four tillers per

plant in 15 wheat bread genotypes in Totora, Peru.

Signicant statistical dierence (p≤0.05) between genotypes were

observed in SL, which is below the 13.74 to 15 cm range reported

by Plana et al. (2006) for two bread wheat genotypes cultivated in

La Habana, Cuba. The NSS data indicates a signicant statistical

dierence (p≤0.05) between bread wheat genotypes, but our results

are below to those reported by Ortega et al. (2004) whom found values

between 19 and 22 NSS in 16 wheat bread genotypes developed in

Cordoba, Argentina. The NGS resulted with a signicant statistical

dierence (p≤0.05) among genotypes and are closely resemble to

those reported by Solis-Moya et al. (2004) with 42 to 57 grains per

spike in 6 genotypes developed in Guanajuato, Mexico.

WL =

WBB

− WAB

WBB

∗ 100 1

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Ramírez-Cortez et al. Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228

5-7 |

Table 2. Growth parameters in bread wheat (Triticum aestivum L.) genotypes.

Genotype PH NLP NTP SL NSS NGS

BW1 73.63 ± 1.16

3.58 ± 0.22

3.08 ± 0.33

9.63 ± 0.30

15.98 ± 0.43

43.50 ± 2.85

BW2 74.30 ± 5.45

3.79 ± 0.41

2.68 ± 0.22

9.06 ± 0.31

15.33 ± 1.19

44.98 ± 4.16

BW3 70.93 ± 10.72

3.88 ± 0.13

2.60 ± 0.44

9.00 ± 0.27

15.70 ± 1.56

42.10 ± 3.16

BW4 66.58 ± 4.92

3.90 ± 0.15

4.48 ± 0.44

11.10 ± 0.38

18.78 ± 0.91

55.65 ± 7.13

PH = plant height (cm), NLP = number of leaves per plant, NTP = number of tillers per plant, SL = spike length (cm), NSS = number of spikelets per spike, NGS = number of grains per spike.

Dierent letters in columns indicate statistical dierence p≤0.05 (n= 4).

Yield parameters and phenology of bread wheat are shown in

table 3. The WTG showed a signicant statistical dierence among

genotypes, BW3 was 1.17, 1.14 and 1.10 fold higher than BW1,

BW2 and BW4, respectively in WTG. The WTG data obtained in this

present study is higher than those reported by Martinez-Cruz et al.

(2020), whom recorded 31 to 43 g in eight genotypes of wheat bread

cultivated in Guanajuato, Mexico. The FH did not show signicant

statistical dierence (p≥0.05) between genotypes.

In the GYH of bread wheat no signicant dierences were

observed among genotypes. A study by Suaste-Franco et al. (2013)

in Guanajuato, Mexico using two wheat bread genotypes showed

a yield of 4.73 to 6.16 t.ha

−1

which is similar to that was found in

the present study. Regarding the DPM, the results indicated ranges

between 111.75 and 118 days, nding a signicant dierence among

the genotypes, where the BW2 genotype stood out for obtaining the

fewest number of days to reach maturity, followed by the control

genotype BW1. Santa-Rosa et al. (2016) found dierent results in

wheat cultivars planted under rainfed conditions in Coatepec, Mexico

with data ranging from 120.6 to 132.2 in DPM.

The moisture and our yield of bread wheat are shown in table

4. Moisture inuences the wheat industrial performance, a range

from 13.61 to 13.76 % obtained in this study did not show signicant

dierence (p≥0.05) among genotypes (table 3).

Table 3. Yield parameters and phenology of bread wheat (Triticum aestivum L.) genotypes.

Genotype WTG FH GYH DPM

BW1 48.25 ± 2.37

9.35 ± 2.43

4.89 ± 1.15

116.75 ± 1.26

BW2 49.75 ± 3.84

11.76 ± 0.64

5.04 ± 1.21

111.75 ± 1.26

BW3 56.75 ± 2.54

9.73 ± 1.14

4.62 ± 1.01

117.00 ± 0.82

BW4 51.25 ± 0.99

12.25 ± 1.30

6.42 ± 1.29

118.00 ± 0.82

WTG = weight of a thousand grains (g), FH = forage per hectare (t.ha

−1

), GYH = grain yield per hectare (t.ha

−1

), DPM = days to physiological maturity. Dierent letters in columns indicate statistical

dierence p≤0.05 (n= 4).

Table 4. Moisture and our yield of bread wheat (Triticum aestivum L.) genotypes.

Genotype Grain moisture (%) Flour yield (%)

BW1 13.61 ± 0.30

93.16 ± 0.40

BW2 13.76 ± 0.25

97.28 ± 0.66

BW3 13.72 ± 0.37

88.75 ± 0.79

BW4 13.61 ± 0.37

95.29 ± 0.67

Dierent letters in columns indicate statistical dierence p≤0.05 (n= 4).

According to Castillo and Chamorro (2009), the ideal grain

moisture levels for producing high-quality wheat our are between

13 % and 15 %, therefore, the grains produced in this study meet this

range for storage and our production.

The our yield varied between 88.75 % to 97.28 %, showing a

signicant statistical dierence (p≤0.05) among the genotypes (table

3). In addition, BW2 showed the highest yield, followed by BW4,

BW1 and BW3. Although BW3 had the lowest yield, its average

value is higher than our yield reported by Rozo-Otega et al. (2021),

whom obtained our yield of 69 to 64 % in four genotypes developed

in Argentina.

The chromatic parameters in bread wheat ours are shown in

table 5. Regarding our color, luminosity (L*) values ranged from

83.49 to 88.74, with the BW4 genotype having the highest value,

indicating a signicant dierence (p≤0.05) between genotypes. The

values on the a* ranged from 2.64 to 3.53, indicating a signicant

statistical dierence between genotypes (p≤0.05). In addition, the

b* axis values ranged from 11.10 to 13.43, indicating a signicant

dierence between genotypes (p≤0.05).

The chroma C* factor ranged from 11.41 to 13.75 with a

signicant dierence (p≤0.05) between genotypes, with the BW3

genotype obtaining the highest value. Moreover, the Hue angle h* has

Table 5. Chromatic parameters in bread wheat (Triticum aestivum L.) ours.

Genotype L* a* b* C* h* Color view

BW1 86.69 ± 0.50

2.88 ± 0.13b

11.38 ± 0.21

11.74 ± 0.21

75.91 ± 0.34

BW2 86.43 ± 0.39

2.94 ± 0.11

11.38 ± 0.19

11.75 ± 0.20

75.50 ± 0.36

BW3 83.49 ± 0.56

3.53 ± 0.13

13.43 ± 0.19

13.78 ± 0.09

75.15 ± 0.40

BW4 88.74 ± 0.15

2.64 ± 0.05

11.10 ± 0.17

11.41 ± 0.19

76.56 ± 0.11

Dierent letters in columns indicate statistical dierence (p≤0.05) (n= 4). L*=Lightness (0=black, 100=white), a*=red (positive a*) or green (negative a*), b*=yellow (positive b*) or blue (negative

b*). C*=saturation level of h*, h*=hue angle, 0°=red, 90°=yellow, 180°=green, 270°=blue.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228 April-June. ISSN 2477-9409.

6-7 |

values ranging from 75.15 to 76.56, indicating a signicant dierence

(p≤0.05) between genotypes (table 4).

In this study, these ranges are dierent from those reported by

Montoya-López et al. (2012), who evaluated the color in commercial

wheat ours with prior bleaching, obtaining an average luminosity L*

of 92.01, an average C* of 9.79, and average h* of 86.74. Moreover,

Oliver et al. (1992) used two colorimeters to measure our from white

spring wheat and observed minimal variations in the measurements.

The average L* value obtained using the HunterLab colorimeter

(D25-9SM) was 91.73, ranging from 90.95 to 92.95. The Minolta

colorimeter (CR 200) yielded an average value of 91.33, with values

ranging from 90.35 to 92.55. These results are also higher than our

data.

According to Rodriguez-Sandoval et al. (2005), food texture is

crucial for consumer acceptance and approval. The textural properties

of a food are the group of physical characteristics that depend on the

structural elements of the material and are related to deformation,

integration, and ow owing to the application of a force.

An important property of the food that is associated with the

texture is the rheological behavior; therefore, when conducting this

analysis on the dough extensibility, the strength results at 30 min

did not show a signicant statistical dierence among genotypes,

obtaining data from 0.17 N to 0.25 N, whereas at 60 min, there was a

signicant statistical dierence (p≤0.05) where BW1 required a force

of 0.42 N, unlike BW4 that required 0.30 N. At 90 min, values ranged

from 0.39 to 0.65 N, showing statistical dierence (p≤0.05) with the

genotypes being BW4 the lower in this parameter (table 6).

Table 6. Bread wheat dough extensibility (Triticum aestivum L.).

Parameter

Time

(min)

Genotype

BW1 BW2 BW3 BW4

Force

(N)

30 0.25 ± 0.06

0.25 ± 0.04

0.23 ± 0.05

0.17 ± 0.02

60 0.42 ± 0.09

0.37 ± 0.02

0.32 ± 0.06

0.30 ± 0.03

90 0.65 ± 0.10

0.52 ± 0.07

0.53 ± 0.08

0.39 ± 0.04

Rupture

(mm)

30 75.13 ± 12.49

61.29 ± 17.67

57.97 ± 18.19

76.10 ± 14.57

60 68.22 ± 9.15

48.70 ± 7.88

61.53 ± 7.00

67.34 ± 8.05

90 42.21 ± 4.14

36.46 ± 3.17

41.81 ± 6.69

65.06 ± 9.38

Dierent letters in rows indicate statistical dierence p≤0.05 (n= 4).

Table 7. Baking attributes and texture of bread obtained from Triticum aestivum L. genotypes.

Genotype Height (mm) Weight loss (%) Hardness (N)

BW1 49.66 ± 0.39

10.74 ± 1.30

31.88 ± 0.79

BW2 49.91 ± 0.43

11.03 ± 1.30

31.86 ± 1.93

BW3 52.19 ± 2.13

12.50 ± 0.29

33.26 ± 0.18

BW4 49.47 ± 2.39

10.15 ± 1.30

32.43 ± 6.69

Dierent letters in columns indicate statistical dierence p≤0.05 (n= 4).

Table 8. Chromatic parameters of bread crust obtained from Triticum aestivum L. genotypes.

Genotype L* a* b* C* h* Color view

BW1 65.43 ± 2.38

7.94 ± 1.77

24.25 ± 1.96

25.53 ± 2.39

72.04 ± 2.51

BW2 65.43 ± 0.33

7.99 ± 0.82

25.29 ± 1.46

26.55 ± 1.62

72.50 ± 0.75

BW3 67.54 ± 0.78

7.14 ± 0.36

23.14 ± 0.58

24.25 ± 0.62

72.80 ± 0.47

BW4 68.55 ± 0.09b

6.05 ± 0.51

21.93 ± 1.03

22.76 ± 1.13

74.63 ± 0.56

Dierent letters in columns indicate statistical dierence p≤0.05 (n= 4). L*= Lightness (0= black, 100= white), a*= red (positive a*) or green (negative a*), b*= yellow (positive b*) or blue

(negative b*). C*= saturation level of h*, h*= hue angle, 0°= red, 90°= yellow, 180°= green, 270°= blue.

A good average height and texture of the bread are possible

because wheat has a group of proteins (gliadins and glutenins) that, in

the presence of water, hydrate and interact to form gluten, allowing the

dough to retain the gas produced during the fermentation. Therefore,

a strong and extensible gluten allows the preparation of doughs with

good gas retention capacity during fermentation, which can expand,

giving rise to breads with a high volume, soft, and spongy crumb

(Robles-Sosa et al., 2005).

Table 7 presents the results of height (mm), percentage of weight

loss during baking, and bread hardness (N) where the genotypes did

not show a signicant dierence however, genotype BW3 is the one

with the highest average in the three variables evaluated, reaching

52.19 mm in height, 12.50 % weight loss during baking, and 33.26 N

in bread hardness.

The color of the bread crust

The weight loss results in baking are similar to the ndings by

Calvo-Carrillo et al. (2020), who reported an 11.84 % loss in wheat

our bread, and is lower than Vega et al. (2015), who reported a

higher loss of 15.54 %.

During the bread-baking process, the color of the crust develops

owing to caramelization, giving it a crispy and shiny texture.

According to Mohammed et al. (2012), the luminosity value (L*)

plays a vital role in determining the commercial value owing to its

direct impact.

BW4 presented the greatest range of luminosity, chroma, and

hue angle. In addition, the genotype that showed the lowest ranges

in the a* and b*, resulting in a lighter visible shade compared with

BW1 (Table 8). Our research ndings align with those of Domínguez

Zarate et al. (2019), who reported similar values in boxed bread made

from wheat our, with a luminosity of 67.80.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Ramírez-Cortez et al. Rev. Fac. Agron. (LUZ). 2025, 42(2): e254228

7-7 |

Conclusions

BW4 had the highest values in yield and most of the yield

components as spike length, number of spikelets per spike, number

grains per spike, grain yield per hectare, forage per hectare. Regarding

to the industrial quality, BW4 also had the lower weight loss and the

higher luminosity in our and bread crust, being the outstanding

genotype among genotypes evaluated and a good option for producers

of bread wheat aimed to industrial purposes.

Acknowledgements

Nydia del Carmen Ramírez-Cortez acknowledges to Consejo

Nacional de Ciencia y Tecnología (CONACYT) for the Master of

Science scholarship. Thanks to Programa de Apoyo a la Investigación

Cientíca y Tecnológica 2022 de la Universidad Autónoma de Nuevo

León (PAICYT-UANL) for the Project 64-CAT-2022 (Evaluación

de las propiedades tecnológicas y nutraceúticas de trigos harineros

(Triticum aestivum L.) y trigos cristalinos (Triticum durum L.)

cultivados en La Ascensión Aramberri Nuevo León) awarded to

Guillermo Niño-Medina.

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