Keywords:

Brix degrees

Moisture

Lipids

Total phenols

Antioxidant activity

Chemical and phytochemical characteristics as biochemical descriptors of diversity in cocoa

seeds from a collection from southern Ecuador

Características químicas y toquímicas como descriptores bioquímicos de la diversidad en semillas

de cacao de una colección del sur de Ecuador

Características químicas e toquímicas como descritores bioquímicos da diversidade em sementes

de cacau de uma coleção do sul do Equador

Facultad de Ciencias Agropecuarias. Universidad Técnica

de Machala (UTMACH). El Oro, Ecuador.

Facultad de Agronomía. Universidad del Zulia (LUZ).

Maracaibo, Venezuela.

Doctorado en Ciencias Agrarias, Division de Estudios para

Graduados, Facultad de Agronomía, Universidad del Zulia,

Venezuela.

Received: 17-02-2022

Accepted: 10-05-2022

Published: 06-05-2022

Abstract

The objective of this work was to determine the content of some

chemical and phytochemical characteristics, in seeds of 60 cocoa trees from

a collection in southern Ecuador; to identify their potential as biochemical

descriptors. Brix degrees (ºBrix), moisture (MO), lipids (LI), total phenols

(TP), and antioxidant activity (AA) were determined. Statistical analysis

indicated that there was low variability in ºBrix, MO and LI; and high

variability in TP and AA. ºBrix was distributed in ve classes; MO, LI,

and AA in four and TP in three; several trees presented high contents and

close to the standards: ºBrix (16-21.34 ºBrix), MO (7-7.90%), LI (50.03-

60.71%), TP (5.05-14.46 mg GAE.g

-1

) and AA (92.48-275.16 mg TE.g

-1

A signicant correlation (p<0.01) was found between LI and TP (r=-0.334),

and between TP and AA (r=0.802). The TP and AA variables showed a high

positive correlation, while LI and TP a low and negative. The accumulated

variance was 64.54%, represented by TP and AA. It is concluded that the

variability was inuenced by the genotype and was high in TP, and AA. TP

and AA constituted excellent biochemical descriptors of diversity in cocoa

seeds. The trees FCA58, FCA59, FCA48, FCA45, and FCA46 presented the

highest values of TP and AA, so they were promising as cultivars, for plant

breeding and industry, among others.

José Nicasio Quevedo Guerrero

1,3

Maribel Ramírez Villalobos

Elvis Portillo Paez

Ivanna Tuz Guncay

Jonathan Zhiminaicela Cabrera

Carlos Quezada Hidalgo

Rev. Fac. Agron. (LUZ). 2022, 39(2): e223930

ISSN 2477-9407

DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v39.n2.08

Food Technology

Associate editor: Dra. Gretty R. Ettiene Rojas

University of Zulia, Faculty of Agronomy

Bolivarian Republic of Venezuela

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). 2022, 39(2): e223930. April - June. ISSN 2477-9407.2-7 |

Resumen

El objetivo del presente trabajo fue determinar el contenido de

algunas características químicas y toquímicas en semillas de 60

árboles de cacao de una colección del sur de Ecuador, para identicar su

potencial como descriptores bioquímicos. Se determinaron contenidos

de grados Brix (ºBrix), humedad (HU), lípidos (LI), fenoles totales

(FT) y actividad antioxidante (AA). El análisis estadístico indicó que

hubo baja variabilidad en ºBrix, HU y LI; y alta variabilidad en FT y

AA. ºBrix se distribuyó en cinco clases; HU, LI y AA en cuatro; y FT

en tres; varios árboles presentaron contenidos altos y cercanos a los

estándares: en ºBrix (16-21,34 ºBrix), HU (7-7,90 %), LI (50,03-60,71

%), FT (5,05-14,46 mg GAE.g

-1

) y AA (92,48-275,16 mg TE.g

-1

). Se encontró

correlación signicativa (p<0,01) entre LI y FT (r=-0,334), y entre FT y AA

(r=0,802). Las variables FT y AA mostraron alta correlación positiva,

mientras que LI y FT baja y negativa. La varianza acumulada fue de

64,54%, representada por FT y AA. Se concluye que la variabilidad

estuvo inuenciada por el genotipo y fue alta en FT y AA. Los FT

y la AA constituyeron excelentes descriptores bioquímicos de la

diversidad en semillas de cacao. Los árboles FCA58, FCA59, FCA48,

FCA45 y FCA46 presentaron los mayores valores de FT y AA, por lo

que resultaron promisorios como cultivares, para el tomejoramiento

y la industria, entre otros.

Palabras clave: grados Brix, humedad, lípidos, fenoles totales,

actividad antioxidante.

Resumo

O objetivo deste trabalho foi determinar o conteúdo de algumas

características químicas e toquímicas em sementes de 60 cacaueiros

de uma coleção no sul do Equador, para identicar seu potencial

como descritores bioquímicos. Graus Brix (ºBrix), umidade (UM),

lipídios (LI), fenóis totais (FT) e atividade antioxidante (AA) foram

determinados. A análise estatística indicou baixa variabilidade em

ºBrix, HU e LI; e alta variabilidade em FT e AA. ºBrix foi distribuído

em cinco classes; UM, LI e AA em quatro; e FT em três; várias

árvores apresentaram teores elevados e próximos aos padrões: em

ºBrix (16-21,34 ºBx), UM (7-7,90%), LI (50,03-60,71%), FT (5,05-

14,46 mg GAE.g

-1

) e AA (92,48-275,16 mg TE.g

-1

). Foi encontrada

correlação signicativa (p<0,01) entre LI e FT (r=-0,334), e

entre FT e AA (r=0,802). As variáveis FT e AA apresentaram alta

correlação positiva, enquanto LI e FT baixa e negativa. A variância

acumulada foi de 64,54%, representada por FT e AA. Conclui-se que

a variabilidade foi inuenciada pelo genótipo e foi alta em FT e AA.

FT e AA foram excelentes descritores bioquímicos de diversidade

em sementes de cacau. As árvores FCA58, FCA59, FCA48, FCA45

e FCA46 apresentaram os maiores valores de FT e AA, por isso se

mostraram promissoras como cultivares, para melhoramento de

plantas e indústria, entre outras.

Palavras-chave: graus Brix, umidade, lipídios, fenóis totais,

atividade antioxidante.

Introduction

Cocoa (Theobroma cacao L., Malvaceae family) is an important

item in the economy of many countries dedicated to the production

of its seeds, called “almonds” or “beans” because it generates foreign

exchange, and jobs in its production and marketing chain. Among the

main exporters of America is Ecuador, which has the fourth position

worldwide (Alcívar et al., 2021). Knowledge of the diversity of

chemical substances contained in cocoa seeds is a fundamental key to

the selection of materials to be used in the genetic breeding of the crop

(Quevedo et al., 2020). In addition to nutritional and sensory quality,

markets have evolved to offer consumers products with biomolecules

that benet their health, among them phenolic compounds especially

catechins, avonoids, anthocyanins, and proanthocyanins, secondary

metabolites responsible for the antioxidant activity (AA) of cocoa

(Castro et al., 2016). In this regard, Vázquez et al. (2016) have

pointed out that endogenous enzymes in cocoa seeds, when activated,

are fundamental in the development of biomolecules associated with

avor and aroma.

Lipids, also called ‘‘fats’’, allow the cocoa to have an adequate

consistency when processed to obtain chocolate, with saturated fatty

acids being the most present (Lares et al., 2012). However, in some

cases the “defatting” of cocoa liquor increases the content of phenols,

and antioxidants, improving its quality (Castro et al., 2016). In this

regard, some works point out that cocoa seeds are characterized by

their high phenol content (Quiñones et al., 2013; Ordoñez et al.,

2020) and the amount varies according to the clone. Variations in

phenol content and antioxidant activity have been reported (Zapata et

al., 2013; Bustamante et al., 2015) due to the post-harvest processing

and morphoagronomic characteristics of the cultivar. Based on these

premises and the morphoagronomic diversity found in the UTMACH

collection of T. cacao trees (Quevedo et al., 2020), the objective of

this research was to determine the content of some chemical (ºBrix,

MO, LI) and phytochemical (TP and AA) characteristics in seeds of

60 cocoa trees from the UTMACH collection, in southern Ecuador,

with the purpose to identify their potential as biochemical descriptors.

Materials and methods

The research was carried out at the Granja Experimental Santa

Inés de la Universidad Técnica de Machala (UTMACH), ‘‘El Oro’’

province, Ecuador; coordinates 3°17 ́30” S, 79° 54 ́51” W; with

clay loam soil, order Entisols; located between dry and semi-humid

forest with annual average temperatures of 28 ºC (minimum 24 ºC,

maximum 30 ºC), relative humidity of 80% and rainfall between 500

and 1,000 mm, distributed in two periods: one of higher rainfall from

December to May (rainy period), and another of lower rainfall from

June to November (dry period).

Plant material

Sixty trees of approximately 42 years of age were selected,

representatives of the morphoagronomic diversity of the UTMACH

cocoa collection, obtained by Quevedo et al. (2020). Trees with

continuous numbering from 01 to 60 with the prex FCA (Facultad

de Ciencias Agropecuarias) were identied.

Sample preparation

Five fruits per tree were harvested according to homogeneity

criteria (maturity, size, color, shape) and health (no pests, diseases,

or mechanical damage). Immediately, the seeds were extracted and

placed in a wood fermenter made of white laurel (Cordia alliodora

(Ruiz & Pav.) Oken) for three days. The samples were placed

separately in mesh bags, duly labeled, removing the seeds every 24

hours for 10 min, then they were dried in a marquee for 10 days.

The fermented and dry seeds from each tree were placed in identied

Zip® plastic bags, to be transferred to the laboratory.

Obtaining the aqueous extract

From each tree, in triplicate, 0.1 g of fermented and dry seed

sample without seed coat, ground (Daewoo DCG362 electric mill),

and sieved (100 mm) were weighed on an analytical balance, placed

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

Quevedo et al. Rev. Fac. Agron. (LUZ). 2022, 39(2): e2239303-7 |

in Eppendorf tubes; then three (3) mL of boiling double-distilled water

was added and centrifuged at 1,000 rpm for 15 min (MiniSpin plus-

Eppendorf AG, Hamburg). The aqueous solution was transferred to

centrifuge tubes rooted to ve (5) mL with double-distilled water and

then to test tubes (Vacutainer TM) at -4 °C, for which the Electrolux

freezer (EFCC20A6HQW) was used.

Study variables

Brix degrees. Five ripe and healthy fruits were taken from each

tree; they were opened with the help of a wooden mallet to extract

the fresh seeds with juicy mucilage from the central part of the fruit,

to which three Brix degree readings were made with a refractometer

(BOECO-103).

Moisture. The percentage of moisture was obtained with a digital

moisture meter (SAMAP-O-TEST 40 model, program 29), according

to Popa & Popescu (2017), calibrated for cocoa. Three readings per

tree were done when the temperature was maintained at 20 °C, and

100 g.tree

-1

of fermented and dry seeds with seed coat were used.

Lipids. The Soxhlet extraction method (NTE INEN 535:2013) was

applied; for the extraction and quantication 3 g.tree

-1

of fermented

and dry seeds without seed coat were used, and three repetitions per

sample were made (Luque & Priego, 2010).

Total phenols. They were determined by the Folin-Ciocalteu

method, modied by Kraujalyte et al. (2015).

Table 1. Descriptive statistics of Brix degrees, moisture, lipids, total phenols (TP), and antioxidant activity (AA) in seeds of 60 cocoa

trees.

Descriptive statistics Brix degrees (ºBrix) Moisture (%) Lipids (%)

(mg GAE.g

-1

)

(mg TE.g

-1

)

Mean 17.72 6.45 48.70 4.79 82.16

Standard deviation 1.88 1.36 7.73 2.72 61.03

Range 7.67 5.10 30.52 13.67 271.59

Minimum value 13.67 5.00 30.19 0.79 3.57

Maximum value 21.34 10.10 60.71 14.46 275.16

Mode 20.00 500

Median 1716 6.00 49.71 4.36 69.61

Variance 3.55 1.85 59.77 7.38 3724.20

Coefcient of variation (%) 10.63 21.12 15.87 56.78 74.28

Standard error 0.24 0.18 1.00 0.35 7.88

For quantication, a calibration curve was prepared with gallic

acid (GA) ratio 1:10 (V:V), a method modied by Zhapan et al.

(2021).

The results were expressed in equivalent milligrams of GA (GAE)

per gram of dry sample (mg GAE.g

-1

Antioxidant activity. It was quantied according to the method

described by Ordoñez et al. (2020) and expressed in equivalents

milligrams of Trolox (TE) per gram of dry sample (mg TE.g

-1

Statistical analysis

Descriptive statistics of summary and frequency distribution were

performed in the study variables, PCA analysis, and hierarchical

cluster analysis, in order to know the physicochemical relationships

between the study trees.

Results and discussion

The descriptive statistical analysis showed that there was

variability in the contents of Brix degrees, moisture, lipids, total

phenols (TP), and antioxidant activity (AA) in the seeds of the 60

cocoa trees (table 1). In the rst three variables, low values of standard

deviation and coefcient of variation (about 20 %) were observed.

Whereas, for TP and AA, the variability was higher.

In the frequency distribution, it was found that ˚Brix presented

ve classes or categories; moisture, lipids, and AA four classes, and

TP three (table 2).

Table 2. Frequency distribution of variables: Brix degrees, moisture, lipids, total phenols, and antioxidant activity in seeds of 60 cocoa

trees.

Variables Class Class denomination Absolute frequency (trees) Relative frequency (%)

Brix degrees (ºBrix) 13 – 14.99 Very low 4 6.67

15 – 16.99 Low 21 35.00

17 – 18.99 Medium 18 30.00

19 – 20.99 High 13 21.67

21 – 22.99 Very high 4 6.67

Moisture (%) 5 – 6.49 Very low 31 51.67

6.50 – 7.99 Low 20 33.33

8 – 9.49 High 8 13.33

9.50 – 10.99 Very high 1 1.67

Lipids (%) 30 – 39.99 Very low 8 13.33

40 – 49.99 Low 23 38.33

50 – 59.99 High 28 46.67

60 - 69.99 Very high 1 1.67

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The values obtained in several trees are similar to those

published by Graziani et al. (2003), for three types of cocoa

from Cumboto locality, Venezuela; 50.99% in Criollo, 49.52% in

forastero amazónico, and 52.24% in trinitario. The percentage of

FCA33 has similarity with that indicated by Lares et al. (2013),

of 52.85±0.21 % in fermented and dried cocoa in Chuao region,

Venezuela; while that of the rest of the trees was different.

Although, the values obtained diverge from other works (gure

3); only two trees FCA13 and FCA18 were close to that reported

by Castro et al. (2016), 30.71 % in fermented and dry cocoa seeds;

Table 2. Frequency distribution of variables: Brix degrees, moisture, lipids, total phenols, and antioxidant activity in seeds of 60 cocoa

trees (continuación).

Variables Class Class denomination Absolute frequency (trees) Relative frequency (%)

Total phenols 0 – 4.99 Low 37 61.67

(mg GAE.g

-1

) 5 – 9.99 Medium 21 35.00

10 – 14.99 High 2 3.33

Antioxidant activity 0 – 74.99 Very low 32 53.33

(mg TE.g

-1

) 75 – 149.99 Low 21 35.00

150 – 224.99 High 6 10.00

225 – 299.99 Very high 1 1.67

In ˚Brix degrees, classes two, three and four were made up of

35, 30 and 21.67 % of the 60 trees evaluated, representing 86.67

%; while the rst and last class obtained 6.67 %, respectively, thus

demonstrating a high diversity. When comparing the ˚Brix with those

obtained in other works, it was observed that the values of 26 trees

located between classes two and three (table 2; gure 1) corresponded to

the range indicated by Guzmán & Gómez (2014), between 16±0.4

and 17±0.4 ºBx, for cocoa trees from six municipalities in southern

Bolívar, Colombia.

Of the 60 cocoa trees, 25 recorded values greater than and

equal to 18 ºBrix; of these, four presented between 18, and 18.2

ºBrix, and 21 between 18.34, and 21.34 ºBrix (gure 1). This result,

together with the classes described (table 2), showed that 25 trees

presented medium to very high ºBrix contents. Values similar to

those reported by Loureiro et al. (2017) who classied PH-16 cocoa

pulp as high, with a value of around 18 ºBrix. In Ecuador, Vallejo

et al. (2016) reported 16 ºBrix for national cocoa, and 15 ºBrix for

Trinitario CCN-51, which differs from the results obtained in this

work, 53 of 60 trees exceeded 16 ºBrix.

Of the four moisture classes, the rst stood out for grouping

close to half of the trees, the second 33.33%, and the last two few

individuals (table 2, gure 2).

Figure 1. Brix degrees in seeds of 60 cocoa trees from the

Universidad Tecnica de Machala (UTMACH)

collection.

The mean moisture content of the seeds of the trees studied (table

1) was higher than those reported by Guzmán & Gómez (2014),

in cocoas from six municipalities in southern Bolivar (Colombia),

between 4.22±1.3, and 6.62±1.7 %; although, some of the trees

(gure 2) were placed in that range. The mean also contrasted with

the research of Lares et al. (2012), who obtained 4.31±0.06 % of

moisture in fermented and dry cocoa from the Barlovento region,

Venezuela.

The values of some trees were similar to those indicated by

Steinau et al. (2017), and Lares et al. (2013), between 6.8, and

7.1 % moisture in seeds dried with seed coat, in trinitario cocoa.

According to the standards -classication and quality requirements-

the maximum moisture value established is 7 % (INEN, 2018;

ICONTEC, 2012). For their part, CAOBISCO et al. (2015) indicated

a moisture content of 7 %, and an absolute maximum of 8 %, for

well-fermented and dry seeds. Based on this, it was found that, out

of the 20 trees, in the second class, 17 recorded between 7, and 7.9

% moisture; there was little variation in moisture content (table 1),

adjusted according to standards or technical norms (INEN, 2018).

Regarding lipids, 46.67 % of the trees were in the third class

and 38.33 % in the second class, equivalent to 85 % (29 trees),

with contents from medium to high; FCA57 qualied as very high

(table 2; gure 3).

FCA32

FCA08

FCA35

FCA14

FCA28

FCA31

FCA44

FCA45

FCA13

FCA26

FCA17

FCA23

FCA43

FCA34

FCA22

FCA25

FCA05

FCA21

FCA10

FCA12

FCA42

FCA07

FCA18

FCA27

FCA06

FCA48

FCA55

FCA09

FCA11

FCA33

FCA57

FCA59

FCA50

FCA37

FCA04

FCA58

FCA52

FCA03

FCA30

FCA20

FCA47

FCA54

FCA15

FCA16

FCA02

FCA36

FCA19

FCA51

FCA49

FCA53

FCA01

FCA60

FCA38

FCA56

FCA39

FCA41

FCA40

FCA29

FCA24

FCA46

Brix degrees (ºBx)

cocoa tress

4.5

5.5

6.5

7.5

8.5

9.5

10.5

FCA42

FCA46

FCA60

FCA52

FCA03

FCA24

FCA53

FCA22

FCA37

FCA40

FCA54

FCA33

FCA39

FCA51

FCA59

FCA50

FCA55

FCA23

FCA29

FCA28

FCA34

FCA35

FCA27

FCA58

FCA32

FCA14

FCA38

FCA36

FCA21

FCA17

FCA31

FCA20

FCA43

FCA19

FCA57

FCA12

FCA45

FCA47

FCA26

FCA44

FCA56

FCA01

FCA16

FCA02

FCA04

FCA05

FCA06

FCA07

FCA08

FCA09

FCA10

FCA11

FCA13

FCA15

FCA18

FCA25

FCA30

FCA41

FCA48

FCA49

Moisture content (%)

cocoa trees

Figure 2. Moisture content in seeds of 60 cocoa trees from

the Universidad Tecnica de Machala (UTMACH)

collection.

FCA57

FCA43

FCA05

FCA52

FCA09

FCA53

FCA26

FCA54

FCA48

FCA31

FCA10

FCA02

FCA25

FCA40

FCA41

FCA46

FCA38

FCA01

FCA33

FCA42

FCA49

FCA30

FCA34

FCA06

FCA28

FCA39

FCA07

FCA51

FCA20

FCA45

FCA29

FCA37

FCA03

FCA50

FCA56

FCA36

FCA21

FCA16

FCA04

FCA12

FCA08

FCA55

FCA58

FCA35

FCA11

FCA24

FCA47

FCA60

FCA59

FCA44

FCA32

FCA23

FCA27

FCA22

FCA19

FCA15

FCA17

FCA14

FCA18

FCA13

Lipids content (%)

cocoa trees

Figure 3. Lipid content in the seeds of 60 cocoa trees from

the Universidad Tecnica de Machala (UTMACH)

collection.

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

Quevedo et al. Rev. Fac. Agron. (LUZ). 2022, 39(2): e2239305-7 |

and two other trees were close to that reported by Lares et al. (2012),

46.27±0.30 %. CAOBISCO et al. (2015) pointed out contents for

intact seeds of 43.6 and 44.2 % in Ecuador, and 44.6 % in Brazil,

and for dry “dehulled” seeds of 55-58 % in West Africa; the results

obtained in some of the trees (gure 3) are related to the mentioned

amounts; as well as, with the work of Steinau et al. (2017), who

reported 38.95 and 40.73 % in pre-dried seeds of category A.

The variability found in lipid content may be due primarily to the

genetic condition of each tree (tables 1 and 2), representatives of the

morphoagronomic diversity of the UTMACH collection (Quevedo et

al., 2020); because they had the same environmental and management

conditions. In this regard, Lares et al. (2012) explained that genetic

and environmental factors have a decisive inuence on the lipid

content in seeds, mainly in the cotyledons; which varies according to

the type of cocoa, being lower in the forastero amazónico and higher

in the trinitario.

For TP content, 61.67% of the trees were in the rst class, 35%

in the second class and 3.33% in the third class (table 2); in the last

two classes, classied as medium and high, respectively, there were

29 trees (gure 4).

100

150

200

250

300

FCA58

FCA59

FCA45

FCA56

FCA48

FCA40

FCA60

FCA19

FCA30

FCA22

FCA17

FCA21

FCA55

FCA34

FCA49

FCA35

FCA43

FCA28

FCA26

FCA18

FCA36

FCA46

FCA33

FCA09

FCA37

FCA29

FCA44

FCA42

FCA41

FCA10

FCA01

FCA39

FCA32

FCA14

FCA27

FCA15

FCA50

FCA54

FCA23

FCA16

FCA25

FCA02

FCA24

FCA53

FCA13

FCA31

FCA08

FCA51

FCA38

FCA57

FCA12

FCA06

FCA05

FCA47

FCA04

FCA03

FCA11

FCA20

FCA52

FCA07

AA (mg TE.g

-1

)

cocoa trees

Figure 4. Total phenol content (TP) in seeds of 60 cocoa trees

from the Universidad Tecnica de Machala (UTMACH)

collection.

The values of 59 trees, out of 60, coincide with the range indicated

by Tello et al. (2020), in eight clones of Mexican cocoa (criollos and

trinitarios); from 1.01 to 31.12 mg GAE.g

-1

in dry seeds, and from

0.75 to 7.92 mg GAE.g

-1

in fermented seeds. In addition, the contents

of 35 trees were in the range indicated by Avendaño et al. (2021),

from 7.50 to 85.20 mg GAE.g

-1

in dry seeds.

The results obtained differ from other studies such as those

conducted by Castro et al. (2016), on fermented and dry seeds (53.90

mg GAE.g

-1

) and Zapata et al. (2013), on fermented seeds (22.58 to

50.23 mg GAE.g

-1

). The variation in TP content, of the 60 cocoa trees

(tables 1 and 2), was mainly attributed to the effect of the genotype. In

this regard, some authors have indicated that cocoa clone or genotype

affects TP content (Quiñones et al., 2013; Avendaño et al., 2021).

According to Zapata et al. (2013); Castro et al. (2016), and Vázquez

et al. (2016), the quantity and quality of phenolic compounds can

vary by internal factors, such as genetic diversity, lipid content;

and external factors such as temperature, crop management, seed

processing (fermentation, drying, others). The low TP content in the

60 cocoa trees (tables 1 and 2), can be observed in the light tonality of

the seeds, which is indicative of lower phenol content and higher lipid

content, allowing them to be very aromatic (Vázquez et al., 2016).

The results of AA showed that the largest number of trees was in

the rst class (53.33 %), followed by the second (35 %), with contents

classied as low and medium, respectively (table 2), in the other two

classes there were few trees that stood out for having high levels

(FCA59 to FCA60) and very high (FCA58) (gure 5).

0.0

2.5

5.0

7.5

10.0

12.5

15.0

FCA48

FCA58

FCA59

FCA30

FCA56

FCA60

FCA24

FCA09

FCA22

FCA19

FCA17

FCA45

FCA16

FCA21

FCA40

FCA28

FCA15

FCA49

FCA14

FCA35

FCA34

FCA26

FCA10

FCA13

FCA55

FCA36

FCA44

FCA32

FCA18

FCA33

FCA29

FCA27

FCA05

FCA01

FCA23

FCA41

FCA43

FCA12

FCA46

FCA42

FCA08

FCA02

FCA39

FCA31

FCA37

FCA50

FCA25

FCA04

FCA03

FCA11

FCA06

FCA20

FCA38

FCA07

FCA57

FCA54

FCA47

FCA51

FCA53

FCA52

TP (mg GAE.g

-1

)

cocoa trees

Figure 5. Antioxidant activity (AA) in seeds of 60 cocoa trees

from Universidad Tecnica de Machala (UTMACH)

collection.

The AA of 18 cocoa trees was located in the range obtained by

Zapata et al. (2013), from 63.51 to 116.29 mg TE.g

-1

in fermented

seeds of ve cocoa clones. In contrast, the values of 22 trees -from

FCA46 to CFA36- (gure 5), exceeded that indicated by Zapata et al.

(2013), for dry and fermented seeds (90.36 mg TE.g

-1

); while in the

rest of the trees (38) they were lower and ranged from 3.57 to 88.80

mg TE.g

-1

. Based on the results, it was established that AA varied in

the 60 trees with levels ranging from very low to very high (table 2),

being a discriminating variable in this case.

Six trees in the second class, designated as low (table 2), had high

AA; and trees in classes three and four had very high AA, for a total

of thirteen; individuals in the last two classes were promising for the

food, pharmaceutical, and cosmetic industries. The high variability

observed in the AA, in the 60 trees (tables 1 and 2), conrms the

biochemical diversity in the seeds. This result agrees with the report

of Avendaño et al. (2021), who found differences among cocoa

phenotypes for AA.

Regarding the correlation between variables, it was observed

that it was highly signicant (p<0.01) only between lipids, and FT,

and between FT, and AA (table 3); which showed the tendencies: the

lower the lipid content, the higher the TFA, and the higher the TFA,

the higher the AA.

Table 3. Spearman’s correlation coefcients between the

variables.

Variables Moisture Lipids Total phenols

Antioxidant

activity

Brix degrees -0.206 -0.179 0.097 0.018

Moisture -0.047 -0.070 0.159

Lipids -0.334 ** -0.134

Total phenols 0.802 **

**: Highly signicant (p<0.01). *: Signicant (P<0.05).

The correlation between TP and AA was positive and high

(r=0.802), while that of lipids, and TP was low (r=-0.334), although

it was negative and highly signicant. In other works, the correlation

between TP and AA has also been reported (Zapata et al., 2013;

Avendaño et al., 2021). For the correlation between lipids, and

TP, Castro et al. (2016), pointed out that the TP was lower in dry

fermented seeds with ‘‘fat’’ and higher in seeds without ‘‘fat’’. On the

other hand, Cienfuegos et al. (2016) reported a negative correlation

between lipids and TP, which coincides with the results obtained in

this research; it should be noted that cocoa from Ecuador (CCN-51),

Venezuela (criollo), and Ivory Coast (forastero) were used in this

research.

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

Quevedo et al. Rev. Fac. Agron. (LUZ). 2022, 39(2): e2239306-7 |

On the other hand, the accumulated variance of the two-

dimensional PCA of the variables (gure 6) determined 38.70 % in

component 1 and 25.83 % in component 2, for a total of 64.54 % of

the total variance explained; of which the most representative and

related between them were TP and AA, so that both variables were

considered excellent biochemical descriptors of diversity in cocoa

seeds.

Figure 6. Two-dimensional principal component analysis of

the variables studied in seeds of 60 cocoa trees from

the Universidad Tecnica de Machala (UTMACH)

collection.

Of 60 cocoa trees, FCA58 presented the highest amount of FT and

AA; other trees that also stood out were FCA59 and FCA48. These

three trees showed greater relation with the phytochemical substances

associated with quality (TP and AA), according to previous studies

that established that sensory quality is directly proportional to the

aromatic phenolic compounds present in cocoa seeds (Delgado et al.,

2018).

The hierarchical cluster analysis allowed discriminating the 60

cocoa trees, thus, the most signicant were FCA58, FCA59, FCA48,

FCA45, and FCA46, which showed the highest values of TP, and AA,

compounds that have positive perspectives for human consumption.

The dendrogram (gure 7) shows the relationships between the 60

trees studied, which formed 15 groups at a Euclidean distance of 20.

Conclusions

Variability in cocoa seeds was inuenced by the genotype; it was

low in Brix degrees, moisture, and lipids; and high in total phenols

and antioxidant activity. Several trees presented promising contents,

towards high or towards the standards, in these parameters. Total

phenols and antioxidant activity showed a high positive correlation;

and lipids and total phenols, a low negative correlation; both highly

signicant. Total phenols and antioxidant activity accumulated

64.54% of the variability and constituted excellent biochemical

descriptors of diversity in cocoa seeds. The trees FCA58, FCA59,

FCA48, FCA45, and FCA46 presented the highest contents of total

phenols and antioxidant activity; so they resulted promising as

cultivars, for plant breeding, industry, among others.

Literature cited

Alcívar, K., Campoverde, J., Unda, S., Montealegre, V., & Romero, H. (2021).

Análisis económico de la exportación del cacao en el Ecuador durante

el periodo 2014-2019. Polo del Conocimiento: Revista Cientíco-

Profesional. 6(3): 2430-2444. Recuperado a partir de https://bit.

ly/3kX393t

Avendaño, C., Campos, E., López, C., Martínez, M., Caballero, J., Báez, M.,

Ariza, R., & Cadena, J. (2021). Actividad antioxidante en genotipos de

Theobroma spp. (Malvaceae) en México. Revista de Biología Tropical.

69(2): 507-523. Recuperado a partir de https://bit.ly/3KWpBVb

Bustamante, S., Tenorio, A., & Rojano, B. (2015). Efecto del tostado sobre los

metabolitos secundarios y la actividad antioxidante de clones de cacao

colombiano. Revista Facultad Nacional de Agronomía-Medellín. 68(1):

7497-7507. Recuperado a partir de https://bit.ly/3M74Rv2

CAOBISCO, ECA & FCC. (2015). Cacao en grano: requisitos de calidad de

la industria del chocolate y cacao. M. End & R. Dand (Eds). P. Edson

& A. Montero (Tr). Chocolate, Biscuits y Confectioeary of Europe

(CAOBISCO), Eupoean Cocoa Association (ECA), Federation of Cocoa

Commerce (FCC). 110 p. Recuperado a partir de https://bit.ly/3M2avPd

Castro, M., Hernández, J., Marcilla, S., Córdova, J., Solari, F., & Chire, G.

(2016). Efecto del contenido de grasa en la concentración de polifenoles

y capacidad antioxidante de Theobroma cacao L. Ciencia e Investigación.

19(1): 19-23. https://bit.ly/3M5QWFx

Cienfuegos, E. (2016) Estudio del contenido de compuestos bioactivos del cacao y

su aplicación en la obtención de un ingrediente rico en (poli) fenoles para

el diseño de un chocolate enriquecido (Doctoral dissertation, Universidad

de Murcia). 213. Recuperado a partir de https://bit.ly/38czHE9

Delgado, J., Mandujano, J., Reátegui, D., & Ordoñez, E. (2018). Desarrollo

de chocolate oscuro con nibs de cacao fermentado y no fermentado.

Scientia Agropecuaria. 9(4): 543-550. Recuperado a partir de https://bit.

ly/3lh5iHH

Graziani, L., Ortiz, L., & Parra, P. (2003). Características químicas de la semilla de

diferentes tipos de cacao de la localidad de Cumboto, Aragua. Agronomía

Tropical. 53(2): 133-144. Recuperado a partir de https://bit.ly/3L2yfS1

Guzmán, J., & Gómez, S. (2014). Evaluación sensorial de cacao (Theobroma

cacao L.) cultivado en la región sur del departamento de Bolívar

(Colombia). Revista de Investigación Agraria y Ambiental. 5 (2): 221-

236. Recuperado a partir de https://bit.ly/3M5yJYW

ICONTEC. (2012). NTC 1252. Cacao en grano. Norma Técnica Colombiana

(NTC) (24-09-2012). Cuarta actualización. ICONTEC Internacional. 13

p. Recuperado a partir de https://bit.ly/3L3phUH

INEN. (2018). NTE INEN 176. Granos de cacao. Requisitos. Norma Técnica

Ecuatoriana (NTE). Quinta Revisión. Servicio Ecuatoriano de

Normalización, INEN. Quito, Ecuador. 8 p. Recuperado a partir de https://

bit.ly/3KWsOEd

Kraujalyte, V., Rimantes, P., Pukalsckas, A., Cesoniene, L., & Daubaras, R.

(2015). Antioxidant properties, phenolic composition and potentiometric

sensor array evaluation of commercial and new blueberry (Vaccinium

corymbosum) and bog blueberry (Vaccinium uliginosum) genotypes. Food

Chemistry. 188: 583-590. Recuperado a partir de https://bit.ly/396n0uu

Lares, M., Pérez, E., Álvarez, C., Perozo, J., & El Khori, S. (2013). Cambios de las

propiedades físico-químicas y perl de ácidos grasos en cacao de Chuao,

durante el benecio. Agronomía Tropical. 63(1-2): 37-47. Recuperado a

partir de https://bit.ly/3KYKij7

Lares, M., Gutiérrez, R., Pérez, E., & Álvarez, C. (2012). Efecto del tostado

sobre las propiedades físicas, sicoquímicas, composición proximal

y perl de ácidos grasos de la manteca de granos de cacao del estado

Miranda, Venezuela. Revista Cientíca UDO Agrícola. 12 (2): 439-446.

Recuperado a partir de https://bit.ly/3yqP9Hl

Loureiro, G., de Araujo, Q., Valle, R., Sodré, G., & de Souza, S. (2017). Inuencia

de factores agroambientales sobre la calidad del clon de cacao (Theobroma

Figure 7. Hierarchical cluster analysis applying Euclidean

distances (AVERAGE method) in 60 cocoa trees from

the Universidad Tecnica de Machala (UTMACH)

collection.

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

Quevedo et al. Rev. Fac. Agron. (LUZ). 2022, 39(2): e2239307-7 |

cacao L.) PH-16 en la región cacaotera de Bahia, Brasil. Ecosistemas y

Recursos Agropecuarios. 4 (12): 579-587. Recuperado a partir de https://

bit.ly/3PbUXKJ

Luque, M., & Priego, F. (2010). Soxhlet extraction: Past and present panacea.

Journal of Chromatography A. 1217(16): 2383-2389. Recuperado a partir

de https://bit.ly/3N4mBHM

Ordoñez, F., Bernal Pita Da Veig, M., de los Ángeles, M., Vidal, N., & Moreno, A.

(2020). Efectos antioxidantes de Moringa oleifera LAM en vitroplantas

de banano clon Williams enraizadas en sistemas de inmersión temporal

RITA. Revista Cientíca Agroecosistemas, 7(3): 57-63. Recuperado a

partir de https://bit.ly/3L2XeED

Ordoñez, E., Quispe, Y., & García, L. (2020). Cuanticación de fenoles,

antocianinas y caracterización sensorial de nibs y licor de cinco variedades

de cacao, en dos sistemas de fermentación. Scientia Agropecuaria. 11(4):

473-481. Recuperado a partir de https://bit.ly/3yJP8yv

Popa, B., & Popescu, D. (2017). Summary of bread production and review of new

methods for estimating process parameters. Annals University of Craiova

Series: Automation, Computers, Electronics and Mechatronics. 14(41):

26-33. Recuperado de https://bit.ly/38cCk8Z

Quevedo, J., Ramírez, M., Zhiminaicela, J., Noles, M., Quezada, C., & Aguilar,

S. (2020). Diversidad morfoagronómica: caracterización de 650 árboles

de Theobroma cacao L. Revista Universidad y Sociedad. 12(6): 14-21.

Recuperado a partir de https://bit.ly/3wm3G4r

Quiñones, J., Trujillo, R., Capdesuñer, Y., Quirós, Y., & Hernández, M. (2013).

Potencial de actividad antioxidante de extractos fenólicos de Theobroma

cacao L. (cacao). Revista Cubana de Plantas Medicinales. 18(2): 201-

215. Recuperado a partir de https://bit.ly/3PcSa3L

Steinau, I., González, S., & Castañeda, V. (2017). Evaluación de la incidencia

de la fermentación en la calidad del grano de cacao trinitario en Caluco,

Sonsonate, El Salvador. Agrociencia. 1(1): 12-25. Recuperado a partir de

https://bit.ly/37xjmcy

Tello, S., Avendaño, C., Vásquez, M., & López, M. (2020). Contenido de

compuestos bioactivos en Theobroma cacao L. de la región del

Soconusco, Chiapas. Investigación y Desarrollo en Ciencia y Tecnología

de Alimentos. 5: 584-589. Recuperado a partir de https://bit.ly/3L0rcJt

Vallejo, C., Díaz, R., Morales, W., Soria, R., Vera, J., & Baren, C. (2016).

Utilización del mucílago de cacao, tipo nacional y trinitario, en la

obtención de jalea. Revista ESPAMCIENCIA ISSN 1390-8103, 7(1): 51-

58. Recuperado a partir de https://bit.ly/39dffDb

Vázquez, A., Ovando, I., Adriano, L., Betancur, D., & Salvador, M. (2016).

Alcaloides y polifenoles del cacao, mecanismos que regulan su biosíntesis

y sus implicaciones en el sabor y aroma. Archivos Latinoamericanos de

Nutrición. 66(3): 239-254. Recuperado a partir de https://bit.ly/3wgFgJz

Zapata, S., Tamayo, A., & Alberto, B. (2013). Efecto de la fermentación sobre la

actividad antioxidante de diferentes clones de cacao colombiano. Revista

Cubana de Plantas Medicinales. 18(3): 391-404. Recuperado a partir de

https://bit.ly/3sqUGcY

Zhapan, M., Lima, K., Bernal, M., & Moreno, A. (2021). Potencial antioxidante

de hojas de guanábana (Annona muricata L.) para sistemas productivos

de banano. Revista Cientíca Agroecosistemas. 9(1): 35-40. Recuperado

a partir de https://bit.ly/3N6EVzM