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TECNOCIENCIACHIHUAHUA, Vol. XVI (3) e 1023 (2022)

https://vocero.uach.mx/index.php/tecnociencia

ISSN-e: 2683-3360

Artículo Científico

Valorization of oil industry wastes: Extraction of

phenolic compounds from different sunflower hull

fractions (Helianthus annuus L.)

Revalorización de residuo de la industria aceitera:

Extracción de compuestos fenólicos de distintas fracciones de cáscara

de girasol (Helianthus annuus L.)

*Correspondencia: Correo electrónico: mariamarcelarodriguez@hotmail.com (Marcela Rodríguez)

DOI: https://doi.org/10.54167/tch.v16i3.1023

Recibido: 16 de agosto de 2022; Aceptado: 18 de octubre de 2022

Publicado por la Universidad Autónoma de Chihuahua, a través de la Dirección de Investigación y Posgrado

Abstract

The recovery of antioxidant compounds present in sunflower hulls, a waste byproduct of the oil

extraction process, can be of industrial and environmental interest. The objective of the present

work was to determine different operating conditions for the extraction of phenolic compounds

from hulls oil sunflower seeds, using water at 90 °C and mechanical agitation. To select the

experimental conditions, the hulls of a black hull sunflower hybrid (SPS3120) were analyzed, five

particle sizes (>0.84, 0.84 to 0.42, 0.42 to 0.25, 0.25 to 0.149, <0.149 mm), three pH values (5, 7 and 9)

and samples with and without oil were evaluated. The selected conditions (pH 9, fractions of

particle size ≤0.25 mm- approximately 24 % of the hull, with a prior removal of the oil) were also

applied to other three black-oil hybrids (SyN3840, SyN3950, DK4065) and two striped sunflower

hybrids (CF201, PAN7077), evaluating the total phenol content and total flavonoid content in the

fractions of particle size ≤0.25 and >0.25 mm. By processing approximately 23-24 % of the

sunflower hull (≤0.25 mm particle-size fraction), it was possible to obtain a minimum of 59 and

62% of total phenols and total flavonoids of the total hull, respectively, under the selected

conditions.

Keywords: sunflower hulls, phenolic compounds, particle size, oil, pH.

Daiana Fanesi1, Susana Nolasco1,2 y Marcela Rodríguez1,3*

1 National University of the Center of the Province of Buenos, Faculty of Engineering, TECSE, Olavarria,

Buenos Aires, Argentina.

2 CIC – Group of Scientific Research of Buenos Aires Province, La Plata, Buenos Aires, Argentina.

3 CONICET, Tandil, Buenos Aires, Argentina.

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TECNOCIENCIACHIHUAHUA, Vol. XVI (3) e 1023 (2022)

Resumen

La obtención de compuestos antioxidantes presentes en la cáscara de girasol, residuo del proceso

de extracción de aceite, puede ser de interés industrial y ambiental. El objetivo del presente trabajo

fue determinar diferentes condiciones de proceso para la extracción de compuestos fenólicos de la

cáscara de híbridos de girasol, empleando agua a 90 °C y agitación mecánica. Para la selección de

las condiciones experimentales, las cáscaras de un híbrido de girasol de cáscara negra (SPS3120)

fueron analizadas, cinco dimensiones de partículas (>0.84; 0.84 a 0.42; 0.42 a 0.25; 0.25 a 0.149 y

<0.149 mm), tres valores de pH (5, 7 y 9) y muestras con y sin aceite. Las condiciones seleccionadas

(pH 9, fracciones de partículas de tamaño ≤0.25 mm- aproximadamente el 24 % de la cáscara,

previa eliminación del aceite de las mismas) fueron también aplicadas a otros tres híbridos de

cáscara negra (SyN3840, SyN3950, DK4065) y dos híbridos de cáscara estríada (CF201, PAN7077),

evaluando el contenido de fenoles totales y flavonoides en las fracciones de partículas ≤0.25 mm y

>0.25mm. Procesando aproximadamente el 23-24 % de la cáscara de girasol (fracción de partículas

≤0.25 mm) se logró obtener como mínimo el 59 y el 62 % de los fenoles totales y flavonoides del

total de la cáscara, respectivamente, en las condiciones operativas aplicadas.

Palabras clave: cáscaras de girasol, compuestos fenólicos, tamaño de partícula, aceite, pH.

1. Introduction

The growing demand for processed foods has led as a result to a substantial increase in

solid wastes (such as leaves, skins, seeds, pits, stems, pulps, pressed cakes, pomace and other

lignocellulosic fractions), generating great economic and environmental challenges to food

processing plants (Baiano et al., 2014; Angiolillo et al., 2015; Vats, 2017). Baiano (2014) and

Angiolillo et al. (2015) have reported about the large potential of these wastes as sources of

bioactive compounds (alkaloids, anthocyanins, phytosterols, carotenoids, stilbenes, lignans,

coumarins, and mainly polyphenols) with applications in the food industry and for manufacturing

pharmaceutical products and cosmetic formulations. Thus, their recovery represents a direct and

positive economic and environmental impact for the agri-food sector, adding value by optimizing

the use of natural resources with minimum food waste generation (Carciochi et al., 2017).

Phenolics compounds are capable of capturing free radicals, donate hydrogen atoms or electrons,

or quelate metallic cations, and thus inhibit oxidation. Within this group, polyphenols, which

include flavonoids, tannins and phenolic acids, are widely distributed in foods of vegetable origin

and represent the majority of the antioxidants present in our diet (Hayat et al., 2009). Further, a

number of studies have evaluated phenolic compounds (polyphenols) due to their beneficial effects

against chronic and acute medical conditions such as cancer, heart and inflammatory diseases

(Balasundram et al., 2006; Taha et al., 2012; Baiano et al., 2014).

The phenolic content of foods depends on the characteristics of the raw material related to intrinsic

(genus, species, cultivar) and extrinsic factors (agronomic, environmental, handling and storage

conditions) (Balasundram et al., 2006). The quality of the polyphenolic extracts, in terms of

antioxidant activity, will also depend both on the chemical structure of its phenolic components

and on the extraction method (Nkhili et al., 2009; Rodríguez et al., 2019). Therefore, the selection of

the appropriate conditions for extraction and the influence of the type of hybrid studied should be

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analyzed with great interest (Hayat et al., 2009). Solid-liquid extraction by solvent is the most

commonly used technique to obtain phenolic compounds, using water or solvents such as ethanol,

methanol, acetone or ethyl acetate, either concentrated or diluted in aqueous mixtures to reach the

polarity of the phenolic compound (Oroian et al., 2015). The structural variety of antioxidant

compounds is so wide that there is no single experimental condition that allows to extract all

phenolic compounds (Rodríguez et al., 2019). Thus in the literature the extraction procedures vary a

lot, and include conditions ranging from room temperature to boiling temperature or reflux, as

well as different processing times, various solvents and concentrations, varied sample to solvent

rations, pH, particle sizes and number of extraction steps, which directly affect the extraction

efficiency (Nkhili et al., 2009; Oroian et al., 2015). As a result, for each vegetable matrix, it is

necessary to select the experimental conditions that allow to maximize the yield and antioxidant

activity of the phenolic extracts, and at the same time, minimize the environmental impact (Baiano

et al., 2014).

Oilseed sunflower seeds consist mainly of the kernel, where the oil is synthesized, and the hull

which represents 17 to 31 % d.b. of the seed (De Figueiredo et al., 2015; Menzel et al., 2019). Prior to

oil extraction, the sunflower seeds are partially dehulled, until reaching a 10-12 % range of residual

hull (De Figueiredo et al., 2011), producing an important amount of residue of low specific weight

(approx. 0.1 ton (m3)-1). Several authors have examined sunflower hulls, reporting that they contain

between 0.7-5.4 % of total phenols present in the seed, with chlorogenic acid being the main

component (80 % of phenolic compounds) (Pedrosa et al., 2000; Weisz et al., 2009; Szydłowska-

Czerniak et al., 2011). Different studies have been conducted to determine the operating conditions

for the extraction of phenolic compounds from sunflower hulls. De Leonardis et al. (2005)

evaluated different solvents at different pH, while Szydłowska-Czerniak et al. (2011) analyzed the

effect of the polarity of the solvent, temperature and extraction time on the total phenolic content of

extracts obtained from sunflower hulls, before and after an enzymatic treatment of the hulls,

finding that the total phenolic content increased linearly with extraction temperature and the

polarity of the solvent. Taha et al. (2012) studied the optimization of the extraction of a phenolic

extract from sunflower hulls by analyzing the variables type of solvent, solvent:water ratio and

hull:solvent ratio. Zoumpoulakis et al. (2017) analyzed the ultrasound- and microwave-assisted

extraction, considering as independent variables the nature of the solvent (methanol, aqueous

methanol), solvent volume, temperature and operation time. Rodríguez et al. (2019) examined the

variables time and temperature for the microwave-assisted extraction (600 W) of phenolic

compounds from sunflower hulls using water as solvent. None of these studies analyzed the effect

of the particle size. In this respect, Menzel et al. (2019) evaluated the milling process of hulls from

snack sunflower using two sieves (<0.6 mm and <0.2 mm) and up to three milling steps. They were

able to mill about 90 % of the raw material to a size <0.6 mm in two milling stages (with a sieving

step prior to the second milling, including in this second stage the particles >0.6 mm), thus

increasing by approximately 17 % the phenolic extraction, compared to a single-stage milling.

Sunflower hulls also contain about 3-9 % d.b. of lipids, a part of which is wax (Cancalon, 1971;

Rodriguez et al., 2017). No studies were found that analyzed the effect of the prior oil extraction

from the hull on the phenolic yield. Taking into account this background, the objective of the

present work was to determine different operating conditions (particle size, pH, absence/presence

of oil) for the extraction of phenolic compounds from hulls oil sunflower seeds, using water at

90 °C and mechanical agitation.

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2. Materials and methods

2.1 Materials

Hulls of four black-hulls sunflower hybrid were evaluated: SPS3120 (Syngenta, 23.3 % d.b.

of hull, hull moisture 12.4 % d.b., oil content of the hull 6.4 % d.b.) SyN3840 (Syngenta, 21.3 % d.b.

of hull, moisture 11.7 % d.b., oil content of the hull 9.45 % d.b.), SyN3950 (Syngenta, 24.8 % of hull,

moisture 9.5 % d.b., oil content of the hull 4.60 % d.b.) and DK4065 (Syngenta, 22.4 % of hull,

moisture 12.1 % d.b., oil content of the hull 8.46 % d.b.). Also, hulls of two striped sunflower

hybrids, CF201 (Advanta, 21.0 % d.b. of hull, hull moisture 12.1 % d.b., oil content of the hull 7.73%

d.b.) and PAN7077 (Pannar, 21.4 % d.b. of hull, hull moisture 11.1 % d.b., oil content of the hull

5.08 % d.b.), were analyzed. All the sunflower hybrids were grown in Balcarce (37°45´S, 58°18´W),

province of Buenos (Argentina). Gallic acid and catechin were purchased from Sigma Chemical Co.

(St Louis, MO, USA).

2.2 Obtention of hulls fractions

The hulls of all sunflower hybrids were obtained by mechanical dehulling of the seeds (the

grains were previously cleaned by manually removing the foreign matter) in a centrifugal dehuller

with a peripheral speed of 38.8 m/s (De Figueiredo et al., 2015). The particle size analysis was

performed by grinding (Ultracomb MO-8100 grinder, China, 20 pulses) and then sieving the

samples considering five different particle sizes (>0.84, 0.84 to 0.42, 0.42 to 0.25, 0.25 to 0.149 and

<0.149 mm). The material retained in each sieve (ASTM, Argentina) was weighed, calculating the

percentage of each fraction. On the other hand, the % hulls of each hybrid (item 2.1) was

determined by manual shelling of 10 g of whole seeds. The hulls and kernel obtained were dried in

a forced air circulation oven (Dryinghorn DHG-9123A, China) for 3 hours at 130 °C and then

weighed. The test was carried out in duplicate, and the results were determined as the ratio

between the weight of the hulls and the total weight of the kernels and hulls, expressed as a

percentage.

2.3 Selection of the conditions for the solid-liquid extraction of phenolic

compounds

For the selection of the experimental conditions, hulls of a traditional hybrid of black-hulls

sunflower (SPS3120) were used. The extractions were carried out with 2 g of hulls of hybrid

SPS3120 by mechanical agitation for 2.65 h, using distilled water at 90 °C as solvent, which were

the optimum conditions found by Szydłowska-Czerniak et al., (2011) for the extraction of phenolic

compounds from sunflower hulls, with a sample to solvent ratio of 1:20 (Rodríguez et al., 2019).

The phenolic extracts were centrifuged (15 min at 3200 g; Thermo Fisher Scientific, Sorvall Legend

X1, Germany) and filtered (quantitative filter paper, black ribbon, pore size 28 μm, Brazil). The

filtrate was frozen (-18 °C) and later freeze-dried (-50 °C, 26 Pa, 12 h) (Boyikang Laboratory

Instruments Inc FD-1A-50, China) to constant weight (dry extracted product).

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2.3.1 Extraction of phenolic compounds by fraction hulls: The extractions of

phenolic compounds were carried out from 2 g of hulls corresponding to each of the five particle

sizes analyzed (>0.84, 0.84 to 0.42, 0.42 to 0.25, 0.25 to 0.149 and <0.149 mm). The assay was

performed in triplicate.

2.3.2 Extraction of phenolic compounds by variation of pH: Using the

selected particle size according to the highest total phenolic content, the influence of pH was

evaluated, using 0.2 M solutions of NaH2PO4.2H2O and Na2HPO4.12H2O to reach pH values of 5,

7 and 9 (De Leonardis et al., 2005). The pH values of the solutions were confirmed with a pH-

meter. The assay was performed in triplicate.

2.3.3 Extraction of phenolic compounds in the presence/absence of oil:

Subsequently, using all the selected conditions (particle sizes, pH), the effect of the defatting was

then analyzed, after the oil extraction in a Soxhlet apparatus for 6 h using n-hexane as solvent The

assay was performed in triplicate.

2.4 Solid-liquid extraction of phenolic compounds from hulls of sunflower

hybrids

After selecting the variables of particle size, pH and presence/absence of oil, the extraction

of phenolic compounds was carried out using water at 90 °C, by mechanical agitation for 2.65 h,

with a sample to solvent ratio of 1:20, from hulls of the three types of black-oil sunflower hybrids

and two striped sunflower hybrids. The extracted product, freeze-dried and weighed, was

characterized in terms of total phenols and total flavonoids.

2.4.1 Determination of total phenols: The effect of the variables of the extraction

process (particle size, pH and presence/absence of oil) was evaluated by determining the total

phenol content in the obtained extracts using the Folin-Ciocalteu colorimetric method (Rodríguez

et al., 2019). The content of total phenols in the hulls of the hybrids of sunflower of black hull and

striped hull was evaluated by this technique. The results were expressed as mg of gallic acid

equivalent (GAE) per 100 g of hull fraction and of hulls (d.b.).

2.4.2 Determination of total flavonoids: The total flavonoid content was

determined by the aluminum chloride method in a basic medium, according to the

spectrophotometric technique proposed by Molina-Quijada et al. (2010). The results were expressed

as mg of catechin equivalent (CE) per 100 g of hull fraction and of hulls (d.b.).

2.5 Statistical analysis

The results were analyzed by ANOVA, and Tukey’s test was used for comparing the

means. The statistical analysis was performed with a confidence level of 95 % using the InfoStat

software (Di Rienzo et al. 2014). All the tests were carried out in triplicate.

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3. Results and Discussion

Table 1 presents the total phenol content of each hull fraction obtained for the hybrid

black-hulls sunflower SPS3120. ANOVA analysis allowed to determine statistically significant

differences (p≤0.0001) of total phenol content for the analyzed hull fractions. In general, the total

phenol content increased significantly with decreasing particle size, within a range of 389.7 and

1646.2 mg GAE 100-1 g hull fraction (d.b.). The two smaller size fractions (0.25-0.149 mm and <0.149

mm) were significantly different from the rest of the fractions and between them, presenting a total

phenol concentration that was at least double or triple, respectively, that of the rest. Considering

the total phenols extracted from the total sunflower hulls (adding up the fractions, with the content

expressed as mg GAE 100-1 g hulls d.b.), approximately 51 % of the total phenols obtained from the

total hulls was found in the fractions ≤0.25 mm. It is worth noting that these two fractions

comprised approximately 24 % of the hull, which in an industrial process would represent a lower

solvent consumption, smaller machines or larger production. Therefore, a particle size smaller than

or equal to 0.25 mm (0.25-0.149 mm and <0.149 mm) was selected for this study.

The process was carried out with a solvent (water) that does not pose any health risk, with easy

and flexible handling, and whose efficiency in the extraction of phenolic compounds at 90 °C has

been proven by different authors (Paladino, 2008; Szydlowska-Czerniak et al., 2011). The obtained

results could be explained by the increase in the interfacial area as the particle size decreased,

facilitating the mass transfer and a more efficient solvent-substrate access. The results also suggest

the possibility of a non-homogeneous distribution of the phenolic compounds in the structure of

the hull, with a larger presence in areas that can break more easily. A similar tendency can be

observed when analyzing the data reported by Menzel et al. (2019), who evaluated the milling

process of hulls from snack sunflowers using two sieves (<0.6 mm and <0.2 mm) and up to three

Table 1. Selection of particle size for the solid-liquid extraction of phenolic compounds from sunflower

hulls (hybrid black-hull SPS3120).

Tabla 1. Selección del tamaño de partícula para la extracción sólido-líquido de compuestos fenólicos de

cáscaras de girasol (híbrido de cáscara negra SPS3120).

Variables

Levels

Hull yield

(%)

Total phenols

(mg GAE.100-1 g

hull fraction d.b.)*

Average of total

phenols extracted

(mg GAE.100-1 g

hulls d.b.)

Particle size

(mm)

>0.84

7.5 ± 1.2

413.4 ± 17.7a

31.0

0.84-0.42

35.4 ± 0.6

389.7 ± 7.1a

138.0

0.42-0.25

33.3 ± 1.5

518.3 ± 19.4b

172.6

0.25-0.149

13.5 ± 1.0

1387.0 ± 6.2c

187.2

<0.149

10.3 ± 1.1

1646.2 ± 38.9d

169.6

*Different letters indicate significant differences (p≤0.05) between the values of total phenols obtained for

each particle size

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milling stages. They found that the particles <0.6 mm obtained in the first milling fraction

presented a total phenolic content 88 % higher than that of the particles obtained after milling the

particles >0.6 mm again, even though they did not report on the size distribution of this second

fraction of particles <0.6 mm.

Table 2 shows the total phenol content for the hull fraction of particle size ≤0.25 mm of hybrid

SPS3120, considering the operating variables pH and presence/absence of oil.

Table 2. Selection of the variables pH and presence/absence of oil for the solid-liquid extraction of phenolic

compounds from sunflower hulls (hybrid black-hull SPS3120).

Tabla 2. Selección de las variables pH y presencia/ausencia de aceite para la extracción sólido-líquido de

compuestos fenólicos de cáscaras de girasol (híbrido de cáscara negra SPS3120).

Variables

Levels

Total phenols

(mg GAE.100-1 g hull fraction d.b.)*

pH**

1219.8 ± 51.2a

1422.0 ± 44.3b

1730.9 ± 38.9c

Oil***

W/O

2091.9 ± 48.3a#

1907.2 ± 42.8a#

*Different letters indicate significant differences (p≤0.05) between the values of total phenols obtained for each

pH level or for the absence/presence of oil;

**Fraction of particle size ≤0.25 mm;

***pH 9, #mg GAE.100-1 g hull fraction without oil d.b. W/O, hulls without oil; O, hulls with oil

The increase in pH allowed to extract a significantly higher (p≤0.0034) amount of total phenols,

obtaining a maximum of 1730.9 mg GAE 100-1 g hull fraction (d.b) of size ≤0.25 mm (equivalent to

approximately 412 mg GAE/100 g of hulls d.b.). De Leonardis et al. (2005) observed a similar

tendency when they studied the influence of pH (5, 7 and 9) on the extraction with water at a lower

temperature (25 ºC) than used in this work. It is worth noting that the pH increase also results in

extracts with higher protein content, which could require a later stage of purification. However,

different authors (Rawel et al., 2005; Guimarães Drummond e Silva et al., 2017) have reported on

the advantages of the association of proteins and phenolic compounds as potential emulsifiers with

antioxidant activity.

The effect of the present/absence of oil was evaluated for the operating conditions sample:solvent

ratio of 1:20, particle size ≤0.25 mm and pH 9. The prior removal of the oil from the hulls allowed

to increase the extraction yield of total phenols from 1907.2 to 2091.9 mg GAE 100-1 g hull fraction.

Although from a statistical point of view the increase was not significant, it must be pointed out

that the removed oil is another byproduct of this waste from the oil industry. The oil obtained from

the sunflower hulls is a potential source of waxes for the pharmaceutical and cosmetic industry,

the production of biodegradable films, and foods, among other applications (Carelli et al., 2002).

The wax content of the sunflower hybrids used in the present study was determined, obtaining

values in a range between 0.64 and 2.08 g wax 100-1 g hulls d. b. (Rodríguez et al., 2017). Different

studies have shown the feasibility of using sunflower waxes as gelling agents, even at low

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concentrations, for obtaining organogels, replacing saturated and trans fatty acids of the solid

phase in the formulation of products such as margarines (Hwang et al., 2015).

Thus the values selected as the most adequate for the analyzed variables for the extraction of

phenolic compounds were: fraction of particle size ≤ 0.25 mm (which comprises 24% of the hull),

pH 9, with a prior removal of the oil of the hull.

3.1 Extraction of phenolic compounds from sunflower hulls under the selected

conditions

3.1.1 Black Hulls Sunflower Hybrids

Table 3 presents the amount of phenolic compounds (total phenolic and total flavonoids)

extracted from each hull fraction of the three studied sunflower hybrids. Based on the percentage

of each fraction, the concentration of phenolic compounds in relation to total hulls was also

calculated.

The smaller particles (≤0.25 mm) represented a low percentage (approximately between 23-24 %)

compared to the larger particles, in agreement with the methodological conditions. The total

phenol content determined for the fractions of smaller particle size (≤0.25 mm) varied between

504.2 and 1291.9 mg GAE 100-1 g hull fraction (d.b.), with the content for each hybrid being

significantly higher (p≤0.05) than that found for the larger size fractions (in the range of 75.9 and

194.8 mg GAE 100-1 g hull fraction (d.b.)). The total flavonoid content varied between 423.5 and

830.2 CE 100-1 g hull fraction (d.b.) for particle sizes ≤0.25 mm, and between 66.6 and 75.2 CE 100-1 g

hull fraction (d.b.) for particle sizes >0.25 mm, showing that the total flavonoid content was

significantly higher (p≤0.05) when the extractions were carried out with particles ≤0.25 mm.

Table 3. Phenolic compounds extracted from the hull of different sunflower hybrids (black-hull) grown in

Argentina (solid-liquid extraction, mechanical agitation).

Tabla 3. Extracción de compuestos fenólicos de cáscaras de girasol de diferentes híbridos (cáscara negra)

cultivados en Argentina (extracción sólido-líquido, agitación mecánica).

Hybrids

Particle

size (mm)

Hull yield

(%)

Total

phenols

Total

flavonoids

Total

phenols

Total

flavonoids

*Hull fraction

**Hulls

(calculated)

SyN3840

≤0.25

23.7

845.7 ± 26.3b

627.5 ± 3.8b

200.4

148.7

>0.25

76.3

181.6 ± 0.5a

66.6 ± 4.6a

138.6

50.8

SyN3950

≤0.25

23.2

1291.9 ± 76.5b

830.2 ± 94.9b

299.7

192.6

>0.25

76.8

194.8 ± 15.6a

74.7 ± 4.2a

149.6

57.4

DK4065

≤0.25

22.8

504.2 ± 72.3b

423.5 ± 87.2b

115.0

96.6

>0.25

77.2

75.9 ± 13.2a

75.2 ± 21.6a

58.6

58.1

d.b., dry basis

Different letters indicate significant differences (p≤0.05) between particles sizes of each hybrid

*Total phenols (mg GAE.100-1 g hull fraction d.b.), *Total flavonoids (mg CE.100-1 g hull fraction d.b.)

**Total phenols (mg GAE.100-1 g hulls d.b.), **Total flavonoids (mg CE.100-1 g hulls d.b.)

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By comparing the fractions of smaller size (particles ≤0.25 mm), a significant difference was

detected between the hybrids, both in total phenolic content and total flavonoid content (p≤0.0025

and p≤0.0276, respectively). As for total phenols, all the hybrids differed, with the fraction of

hybrid SyN3950 presenting the highest value, followed by SyN3840 and DK4065, in decreasing

order. This fraction of SyN3950 was also characterized by a higher total flavonoid yield, but

without being significantly different from SyN3840 (Fig. 1A). On the other hand, in the fractions of

larger particle size (>0.25mm), ANOVA only revealed significant differences between hybrids for

total phenolic content (p≤0.0037), with hybrid DK4065 exhibiting the lowest value. The other two

hybrids were not significantly different (Fig. 1B).

Fig. 1. Total phenols and total flavonoids in sunflower hulls fractions (black-hull). A: Size ≤0.25 mm, B: Size:

>0.25mm.

Fig. 1. Fenoles totales y flavonoides totales en fracciones de cáscaras de girasol (cáscara negra). A: Tamaño

≤0.25 mm, B: Tamaño: >0.25mm.

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Although the statistical analysis allowed finding significant differences between the hybrids

studied. It is worth noting that Rodriguez et al. (2019), when evaluating the total phenol and total

flavonoid contents in sunflower hulls using a microwave-assisted extraction process (water at 90

ºC, 10 min, 600 W, sample:solvent ratio of 1:20, particle size of the hull ≤0.42 mm), did not observe

significant differences between these three hybrids grown in two districts in the Buenos Aires

province, Argentina.

By processing the fractions of particle size ≤0.25 mm by the selected method, it was possible to

obtain approximately 59 %, 67 % and 66 % of total phenols from the hulls of hybrids SyN3840,

SyN3950 and DK4065, respectively, and approximately 75 %, 77 % and 62 % of total flavonoids,

respectively (values calculated based on the last 2 columns of Table 3). Therefore, by processing

only between 22.8 and 23.7 % of the hull of these hybrids (particle size 0.25mm) by mechanical

extraction (agitation), a minimum of 59 % of total phenols and 62 % of total flavonoids was

extracted, in relation to total hulls, with a maximum yield of 67 % and 77 %, respectively.

3.1.2 Striped Hulls Sunflower Hybrids

Two striped-hull sunflower hybrids, CF201 and PAN7077 were also evaluated. While hybrid

CF201 exhibited similar tendencies to those observed for the black oil hybrids (Table 4), although

with lower relative yield percentages (53 % and 66 % for total phenols and total flavonoids,

respectively, obtained from the fraction of particle size ≤0.25 mm), the hybrid PAN7077 did not

present differences in the concentration of total phenols between the fractions, indicating that only

30 % of total phenols were extracted from the smaller size fraction, while the larger proportion of

total flavonoids was the same (60 % of total flavonoids of the hull). These results would suggest a

differential behavior of the striped sunflower hybrids, with further studies being necessary to

examine a larger number of hybrids and evaluate possible relations with morphological differences

of the hull (Lindström et al., 2000).

Table 4. Phenolic compounds extracted from hulls of two sunflower hybrids (striped hull) grown in Balcarce,

Argentina (solid-liquid extraction, mechanical agitation).

Tabla 4. Extracción de compuestos fenólicos de cáscaras de dos híbridos de girasol (cáscara estriada)

cultivados en Balcarce, Argentina (extracción sólido-líquido, agitación mecánica).

Property

Hybrid CF201

Hybrid PAN7077

≤0.25

>0.25

≤0.25

>0.25

Hull yield (%)

30.8

69.2

24.5

75.5

Total phenols

*Hull fraction

437.7 ± 17.8b

171.9 ± 40.6a

230.6 ± 24.5a

176.8 ± 9.1a

Total flavonoids

436.6 ± 48.9b

99.1 ± 0.1a

369.5 ± 2.1b

78.6 ± 2.1a

Total phenols

**Hulls

134.8

119.0

56.5

133.5

Total flavonoids

134.5

68.6

90.5

59.3

Different letters indicate significant differences (p≤0.05) between particles sizes of each hybrid;

*Total phenols (mg GAE.100-1 g hull fraction d.b.),*Total flavonoids (mg GAE.100-1 g hull fraction d.b.);

**Total phenols (mg GAE.100-1 g hulls d.b),**Total flavonoids (mg CE.100-1 g hulls d.b.);

d.b., dry basis

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TECNOCIENCIACHIHUAHUA, Vol. XVI (3) e 1023 (2022)

Hemery et al. (2011) and Laguna et al. (2018) reported that the ultrafine milling with electrostatic

sorting or turbo separation are new eco-friendly and energy-efficient technologies that are being

studied for the concentration of components of different agricultural resources, such as proteins,

cellulose, lignin and polyphenols. Laguna et al. (2018) reported that with an adequate combination

of these technologies it is possible to recover fractions rich in proteins and phenolic compounds

from residual meals of sunflower and canola oil extraction processes. Proteins were separated

together with the phenolic compounds, and thus dry fractionation constitutes a pre-purification

process, prior to solid-liquid extraction. Taking into account the results obtained in the present

work, further studies are desirable to determine the potentiality of applying these technologies to

the extraction of phenolic compounds from sunflower hulls with distinguishing features.

The type and amount of phenolic compounds present in the sunflower hulls and in the extracts

obtained from the hulls, as well as the antioxidant properties of the extracts, have been reported by

various authors (De Leonardis et al., 2005; Weisz et al., 2009; Szydlowska-Czerniak et al., 2011; Taha

et al., 2012; Zoumpoulakis et al., 2017; Rodríguez et al., 2019). Taha et al. (2012) also found that

phenolic extracts of sunflower hulls exhibited antimicrobial activity at different levels against

different pathogenic bacteria, as well as anti-carcinogenic activity, which differed between the cell

line carcinomas. Rodríguez et al. (2019) determined and compared the antioxidant activity of

extracts of phenolic compounds (microwave-assisted extraction with water as solvent, 90 °C) from

hulls of the sunflower hybrids studied in the present work, grown in two districts in the Buenos

Aires province, Argentina. Further studies are necessary to determine the impact of the dry

fractionation proposed in this work.

4. Conclusions

The extraction of phenolic compounds from hulls of sunflower hybrids by solid-liquid

extraction using water at 90 °C, mechanical agitation for 2.65 h and a sample:solvent ratio of 1:20

was evaluated, selecting as the most adequate experimental conditions a particle size ≤0.25 mm,

pH 9, with prior removal of the oil from the hulls. Between 23-24 % of hulls of particle size ≤0.25

mm and between 76-77 % of size >0.25 mm were obtained by grinding the hulls of the hybrids

under study. It was possible to extract between 59-67 % of total phenols and 62-77 % of total

flavonoids from the fraction of smaller size, with respect to total hulls, observing differences in

behavior between the hybrids. The present work shows the advantages of combining the grinding

process with an adequate classification of the obtained product, which would allow to reduce the

material to be extracted, obtaining a good yield of phenolic compounds for their potential

application in the formulation of functional foods, or in the pharmaceutical and nutraceutical

industries. The differential behavior observed between the hybrids also suggests the need to

evaluate and select adequate strategies to process and add value to the hulls of sunflower hybrids

with differential structural characteristics.

Aknowledgments

The authors acknowledge the financial support from National Agency for Scientific and

Technological Promotion (ANPCyT), National University of the Center of the Province of Buenos

Daiana Fanesi et.al

TECNOCIENCIACHIHUAHUA, Vol. XVI (3) e 1023 (2022)

Aires and Scientific Research Commission of the Province of Buenos Aires (CIC), Argentina. The

authors wish to thank INTA’s Agricultural Experimental Station for providing sample material.

Interest conflict

All the authors declare that they have no conflict of interest and have no competing

financial interest for the work covered in this paper.

Nomenclature

d.b.

dry base

relative centrifugal force

GAE

gallic acid equivalent

catechin equivalent

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