Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
Pesquisas Agrárias e Ambientais
DOI: https://doi.org/10.31413/nativa.v11i2.15977
ISSN: 2318-7670
Extract from
Bixa orellana
L. seed: development of biodegradable packaging
and biological activities
Leonardo Almeida JATOBÁ1, Antonio Carlos Pereira de MENEZES FILHO2* ,
Marconi Batista TEIXEIRA2, Frederico Antônio Loureiro SOARES2,
Carlos Frederico de Souza CASTRO2, Porshia SHARMA3, Matheus Vinícius Abadia VENTURA1,2
1UniBRAS University Center of Southwest Goiás, Rio Verde, GO, Brazil
2Goiano Federal Institute, Rio Verde, GO, Brazil.
3Institute for Innovative Learning and Research (IILR), Madhya Pradesh, Indore, India.
*E-mail: astronomoamadorgoias@gmail.com
Submitted on 07/19/2023; Accepted on 08/14/2023; Published on 08/17/2023
ABSTRACT: Active biodegradable packaging with Bixa orellana extract has potential for producing new
products that combine natural renewable use and food conservation. B. orellana seeds were collected and their
extract was produced. The packages were produced and incorporated with different concentrations of B. orellana
extract. Phytochemical parameters were tested in several groups of special metabolism; physicochemical for
thickness, moisture, solubility, UV-Vis light transmission, color L*, a* and b*; biodegradability in soil and
antifungal activity on Sclerotinia sclerotiorum, Colletotrichum acutatum and Colletotrichum gloeosporioides. The packaging
showed potential for use as a new product for food, the large number of phytocompounds allows an active
packaging, in addition to physicochemical characteristics of thickness, humidity and ideal solubility and use for
foods that need protection at different wavelengths in the UV-Vis that deteriorate important characteristics of
the product. Moreover, it demonstrated an effect with biodegradability of less than 40 days and antifungal
activity on phytopathogenic fungi that cause deterioration in vegetables of agricultural interest.
Keywords: Bixa genus; bixin; carotenoids; natural Polymer; norbixin; polymer matrix.
Extrato das sementes de
Bixa orellana
L.: desenvolvimento de embalagens
biodegradáveis e atividades biológicas
RESUMO: Embalagens biodegradáveis ativas com extrato de Bixa orellana apresentam potencial para a
produção de novos produtos que aliam o uso renovável natural e a conservação de alimentos. Sementes de B.
orellana foram coletadas e o extrato produzido. As embalagens foram produzidas e incorporadas com diferentes
concentrações do extrato de B. orellana. Foram testados parâmetros fitoquímicos em diversos grupos do
metabolismo especial; físico-químicos para espessura, umidade, solubilidade, transmissão de luz UV-Vis, cor
L*, a* e b*; biodegradabilidade em solo e atividade antifúngica sobre Sclerotinia sclerotiorum, Colletotrichum acutatum
e Colletotrichum gloeosporioides. As embalagens demonstraram potencial para uso como novo produto para
alimentos, o grande número de fitocompostos admite uma embalagem ativa, além de características físico-
químicas de espessura, umidade e solubilidade ideais e uso para alimentos que necessitam proteção em
diferentes comprimentos de ondas no UV-Vis que deterioram características importantes do produto. Além
disso, demonstrou efeito com biodegradabilidade inferior a 40 dias e atividade antifúngica sobre fungos
fitopatogênicos que causam deterioração em vegetais de interesse agrícola.
Palavras-chave: gênero Bixa; bixina; carotenóides; matriz polimérica; norbixina; polímero natural.
1. INTRODUCTION
Bixa orellana is a South and Central American native plant
that can also be grown in Peru, Mexico, Ecuador, Indonesia,
India, Kenya, and East Africa. The seeds contained in it have
natural dyes (bixin and norbixin) that are being used in the
Pharmaceutical and Food industries as they contribute in
several biological activities (HIRKO; GETU, 2022).
The usage of substances extracted from special
metabolism of plants have been gaining popularity due to
their various qualities that help development of active and
intelligent packaging. It is observed that bixin and norbixin
(carotenoids) are potentially able to work as antioxidant,
antifungal, anticarcinogenic and among other biological
activities. Bixin is a linear apocarotenoid having double
bonds and costitutes up to 80% of the total carotenoid
content present in B. orellana (annatto or urucum) seeds
(LUIGGI et al., 2020).
The incorporation of plant extracts in natural polymeric
matrices is beneficial as it provides; reduction of synthetic
packaging, easily degradable on discarding in atmosphere, has
little to no pollution rate and also serves the purpuse of
preservation of food from harmful micro-organisms and
oxidation (Shaikh et al., 2021). The usage of biodegradable
materials in food packaging counts as a promising alternative
as it reduces investment and also the treatment cost during
waste management.
Extract from Bixa orellana L. seed: development of biodegradable packaging and biological activities
Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
260
Some studies demonstrate the incorporation of bixin into
a polymeric matrix; this results in formation of great barrier
against oxygen, water vapour, thermal stability and to
different wavelengths of light such as ultraviolet (UV) and
visible (Vis) (STOLL et al., 2021a). Although, there is no
experimental evidence of using polymeric matrix of starch
obtained from Maranta arundinacea L. (arrowroot or araruta)
with extract of B. orellana. Thus, there is no known proof of
interaction between this polymer and bixin extract obtained
from the seeds. Thus, this study aimed to evaluate the
addition of ethanolic extract of Bixa orellana seeds regarding
phytochemical constitution, formation of biodegradable
packaging (BP), physicochemical characteristics,
biodegradability and antifungal activity at different
concentrations.
2. MATERIAL AND METHODS
2.1. Reagents, equipments and glasswares
Ethyl alcohol P.A - ACS (Neon, Brazil), glycerin P.A
ACS (Dinâmica, Brazil), fungicide Frowncide 500 SC (ISK,
Brazil) Fluazinam concentration (500 g/L-1), Tween 80 P.A
ACS (Dinâmica, Brazil), PDA culture medium (Himedia,
India).
Digital analytical balance (Shimadzu, Mod. AY220,
Brazil), digital colorimeter (HunterLab, Mod. ColorFlex EZ,
U.S.A), digital caliper (Mitutoyo, Mod. 500-196-30, Japan),
digital thermometer (Bmax, Mod. TP-101, Brazil), electric
greenhouse with forced air circulation (Thoth, Mod. th-510-
480, Brazil), lyophilizer (Terroni, Mod. LS6000 B, Brazil),
magnetic stirrer with heating (Solab, Mod. SL 91, Brazil), UV-
Vis spectrophotometer (Bel, Mod. M-51, Italy).
Beaker 500 mL (Deltex, Brazil), glass rod (Uniglas,
Brazil), precipitation cup 250 and 500 mL (Uniglas, Brazil),
polystyrene Petri dish (FirstLab, Mod. FL3-9015RI, China),
qualitative filter paper (Unifil, Brazil), universal tip 1 mL
(Olen, U.S.A), variable micropipette 10-1000 µL (Peguepet,
Brazil).
2.2. Species collection and identification
Bixa orellana seeds were collected in July 2022 in the
municipality of Rio Verde, Goiás State, Brazil, with the
following geographic coordinate (17º48’00.0’’S and
50º54’41.5’’W). The species was identified, exsiccate
herborized and deposited in the Herbarium of the
Laboratório de Sistemática Vegetal at Instituto Federal
Goiano, Rio Verde, Goiás State, Brazil. Voucher (HRV:
17.786).
2.3. Seed processing
The seeds were grounded in a food processor for 3 min.
After this, the obtained seed powder was stored in a plastic
food packaging and was kept at -12 °C until further analysis.
2.4. Production of extract
Extraction was carried out with 50 g sample and 100 mL
ethanol (m/v); it was kept under constant magnetic agitation
for 4 h. Contact between solvent and raw material was kept
for seven days at room temperature (25 °C), in the dark. It
was manually agitated on a daily basis. The mixture that
resulted from the extraction was separated through filtration
(Whatman qualitative filter), followed by solvent evaporation
which was carried out by a vacuum rotary evaporator at 70
°C. The lyophilized extract was kept under refrigeration at -
12 °C until further analysis. The extracts were lyophilized.
The yield seed ethanolic (EEBO) extract from B. orellana
content was determined by equation 1.
Yield (%) = (Em/Sm) * 100 (01)
where: Em = Extract mass; Sm = sample mass.
2.5 Phytochemical analysis
For phytochemical analysis, 50 mL of ethanol solution
containing 5 g (w/v) of extract was prepared. Crude ethanolic
extract of B. orellana seeds was subjected to number of
analysis for phytochemical characterization according to
Bessa et al. (2013) and Shaikh; Patil (2020) with adaptations.
The positivity for each group of special metabolites and
constituents analyzed was achieved from the development of
color and/or precipitate, characteristic for analysis of each
phytoclass. saponins, alkaloids, anthraquinones, catechins,
coumarins, steroids and triterpenoids, phenols, tannins,
flavonoids, quinones, organic acids, carboxylic acids,
polysaccharides, aromatic and aliphatic compounds, oxylates,
bixin and norbixin, reducing sugars, non-reducing sugars and
carbohydrates were evaluated. The detection was based on
visual observations of a color change or precipitate formation
after adding specific reagents.
2.6. Biodegradable packaging preparations
Biodegradable films were obtained by a casting technique,
use of the methodology proposed by Issa et al. (2017),
modified. To produce each film, 5 g arrowroot starch was
dissolved in 100 mL deionized water. The solution was then
moderately agitated at room temperature 25 °C. Afterward, it
was heated at 70 °C, at constant agitation for 30 min.
After starch gelatinization, glycerol was added as a
plasticizer (30% w/w); this dispersion was agitated for 5 more
min. When the filmogenic solutions reached 50 °C, the
control did not show any EEBO incorporated into it, while
EEBO dose of (250 (EESBO), 500 (EESBO), 750 (EESBO)
and 1000 (EESBO) µL mL-1) were added to the others under
constant agitation for 15 min. The seeds extract from B.
orellana was better solubilized as 200 mg EEBO per 1 mL
Tween 80 at 5%. All filmogenic solutions were poured on
polystyrene slabs and dried in an air circulation oven at 30 °C
for about 36 h.
2.7. Characterization of biodegradable packaging
incorporating
2.7.1. Thickness
Biodegradable packaging thickness was measured by a
digital caliper in millimeters (mm). Measurements were
carried out in 10 spots on every packaging and the thickness
mean was calculated.
2.7.2. Moisture content
The moisture content of packaging was weighed and then
dried in an oven at 105 °C for 4 h. Three replicates per
packaging treatment were used, in agreement described by
Santos et al. (2021).
2.7.3. Measurement of water solubility
Biodegradable packaging which measured about (2 x 2
cm2) was dried in oven at 50 °C for 4 h and then weighed so
that initial mass (Mi) could be determined. They were
Jatobá et al.
Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
261
immersed in 60 mL distilled water and kept under constant
agitation (170 rpm) at 25 °C for 24 h.
Afterward, solutions with the packaging were filtered
using filter paper (qualitative filter) with packaging had been
previously weighed. Sheets of filter papers with
biodegradable packaging were dried at 105 °C for 24 h and
weighed so that final mass (Mf) could be found, in agreement
with the methodology described by Jahed et al. (2017). Every
treatment was analyzed in quadruplicate. Biodegradable
packaging solubility in percentage (%) was calculated by
equation 2.
Water solubility (%) = Mi – (Mf/Mi) * 100 (02)
2.7.3. Light transmittance (UV-Vis)
Ultraviolet (UV) and visible light (Vis) transmittance of
film was conducted with the help of UV-Vis
spectrophotometer. The BP samples were cut and placed in
quartz cuvettes so that transmittance could be measured over
a wavelenght range between 900 at 200 nm as described by
Hosseini et al. (2015).
2.7.4. Analysis of color
Analysis of BP color was carried out a ColorEZ digital
colorimeter. Parameters under evaluation were L*
(luminosity) (0- lower brightness and 100- higher brightness)
and chromaticity parameters a* (green -180 and red +180)
and b* (yellow +180 and blue -180). The equipment was
calibrated with black crystal, green crystal and white crystal.
Measurements were conducted on three randomly selected
packaging spots.
2.8. Biodegradable activity
The soil biodegradability test was performed using by the
methodology described by Martucci; Ruseckaite (2009). The
BP samples (2 x 2 cm2) were dried up to constant weight so
that initial mass (Mi) could be determined.
Samples were then placed in open polyethylene packaging
to enable microorganisms and moisture to gain access to
them. Now, these were buried in previously prepared organic
soil (red dystroferric soil type) at constant moisture and room
temperature. Thirty days after the experiment installment, the
biodegradable packages with the samples were removed from
the soil, cleaned with a fine brush and dried up to constant
weight (Mf). Biodegradability in percentage (%) was
calculated by equation 3.
Biodegradability (%) = Mf – (Mf/Mi)*100 (03)
2.9. Antifungal assay
Antifungal activity of BP was analyzed against the
phytopathogenic fungi Sclerotinia sclerotiorum, Colletotrichum
acutatum and C. gloeosporioides by a disk diffusion assay. Petri
dishes, half full with potato, dextrose and agar medium
(PDA), were inoculated with 100 µL suspension with 107
CFU mL-1.
Then, four samples of packaging which had been cut in
circles of about 7 mm were placed on every dish. Petri dishes
were incubated at 25 °C for 15 days. As standard fungicide
Frowncide 500 SC concentration 10 µL mL-1was used.
Finally, diameters of the zone of inhibition were measured
using a digital caliper and expressed in millimeters (mm),
described by Valadares et al. (2020) and Menezes Filho et al.
(2022b) modified.
2.10. Statistical analysis
Analysis was carried out in triplicate and quadruplicate
and the standard deviations (SD) among them were
calculated. The data were collected and represented as the
standard error of the mean. Following ANOVA, a Duncan
test was used to examine the statistical relevance of the mean
differences at P < 0.05, using SigmaPlot statistical software.
3. RESULTS
3.1. Phytochemical screening
A low number of groups of phytomolecules present in
both extract from B. orellana seeds were observed (Table 1).
Some phytomolecules were found in both extracts such as
alkaloids, reducing sugars, flavonoids, phytosterols,
carotenoids, coumarins, organic acids, aromatic compounds,
proteins, hemolytic saponins, bixin and norbixin.
Table 1. Phytochemical prospection of ethanolic extract of Bixa
orellana seeds.
Tabela 1. Prospecção fitoquímica do extrato etanólico das sementes
de Bixa orellana.
Phytogroup
EEBO
Tannins
Blue
Alkaloids
+
Carbohydrates
-
Reducing sugars
+
No
-
reducing sugars
-
Glycosides
-
Cardiac glycosides
-
Amino acids
+
Flavonoids
+
Phenolics
+
Phlobatannins
+
Phytosterols
+
Cholesterol
-
Terpinoids
+
Triterpinoids
-
Diterpenes
-
Lignins
-
Carotenoids
+
Quinones
-
Anthraquinones
-
Anthocyanins
-
Carboxylic acids
-
Coumarins
+
Emodins
-
Gums &
mucilages
-
Resins
-
Fixed oils & Fat
-
Volatile oils
-
Organic acids
+
Aliphatic & aromatic
Red
Polysaccharides
-
Proteins
+
Foamy saponin
-
Hemolytic saponin
+
Oxylates
-
Bixin
+
Norbixin
+
Note: EEBO: ethanolic extract of Bixa orellana seeds. (-) no detected.
(+) positive. Blue: hydrolyzable or gallic tannins. Red: aromatic
compounds. Source: Authors, 2023.
Nota: EEBO: extrato etanólico das sementes de Bixa orellana. (-) não
detectado. (+) positivo. Azul: taninos hidrolisáveis ou gálico.
Vermelho: compostos aromáticos. Fonte: Autores, 2023.
Extract from Bixa orellana L. seed: development of biodegradable packaging and biological activities
Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
262
3.2. Physicochemical characteristics of packaging
The control BP exhibited the lowest values of thickness,
while in the others, the higher the extract doses added to the
BP, the higher their thickness values (Table 2). Moisture
contents of BP depended directly on the amount of extract
that was added to them (Table 2). Control BP had
significantly higher in solubility due to the e -OH group
presence in starch, and thereby affecting the starch BP by its
hydrophilic nature. This consequently leads to higher
interaction with water molecules. Increasing the extract from
250 to 1000 µL has lowered the solubility. Basically, low water
solubility exhibits great water resistance (Table 2).
Concerning colors of BP under development, (Figure 1)
shows decrease in light transmittance rates of BP
incorporating different doses of extract in the visible and
ultraviolet region (from 200 to 850nm).
Table 2. Thickness, humidity and solubility of biodegradable
packages incorporated with ethanolic extract of Bixa orellana seeds.
Tabela 2. Espessura, umidade e solubilidade das embalagens
biodegradáveis incorporadas com extrato etanólico das sementes de
Bixa orellana.
Film
Thickness
(mm)
Moisture (%)
Solubility (%)
Control
0.24±0.01d
10.40±0.73c
50.43±3.30a
EESBO 250
0.26±0.01d
8,28±0.31d
40.88±3.82b
EESBO 500
0.32±0.01c
9.26±0.45cd
29.99±1.52c
EESBO 750
0.36±0.01b
12.92±1.02b
24.94±2.21c
EESBO 1000
0.43±0.01a
14.65±0.31a
22.95±4.48d
Note: Different letters in the column show statistical difference by the
Duncan’s test (P < 0.05) significance.
Nota: Letras diferentes na coluna apresentam diferença estatística pelo teste
de Duncan com (P < 0,05) de significância.
Figure 1. Transmission of UV-Vis light in biodegradable packaging
incorporated with ethanolic extract from Bixa orellana seeds. Source:
Authors, 2023.
Figura 1. Transmissão de luz UV-Vis em embalagens
biodegradáveis incorporadas com extrato etanólico das sementes de
Bixa orellana. Fonte: Autores, 2023.
Results showed that the use of extract increased BP
luminosity. The highest extract concentrations showed the
best luminosity results, being superior to the standard BP.
The control BP exhibited negative values of a* and b*
chromaticity and was green/blue. Biodegradable packaging
incorporating from 250 to 1000 µL extract exhibited positive
values of a* and b* chromaticity and were red and yellow
(Table 2).
3.3. Biodegradable activity
The lowest concentrations 500 and 250 µL mL-1 showed
the highest biodegradation capacity, showing no statistical
difference with the control (Figure 2). Although they have
shown potential, higher concentrations verified suggest that
they are toxic because they reduce biodegradability and
statistically longer time in the soil.
Table 2. Color parameters of biodegradable packages incorporated
with ethanolic extract from Bixa orellana seeds.
Tabela 2. Parâmetros de cor das embalagens biodegradáveis
incorporadas com extrato etanólico das sementes de Bixa orellana.
Film
L*
a*
b*
Control
14.59±0.24e
-
0.71±0.09e
-
0.91±0.05e
EESBO 250
17.41±0.11c
0.34±0.09d
9.03±0.13c
EESBO 500
15.48±0.02d
0.94±0.01c
10.19±0.05b
EESBO 750
19.67±0.03a
1.65±0.03b
8.29±0.03d
EESBO 1000
19.11±0.04b
3.53±0.01a
11.95±0.09a
Note: Different letters in the column show statistical difference by the
Duncan’s test with 5% significance. Source: Authors, 2023.
Nota: Letras diferentes na coluna apresentam diferença estatística pelo teste
de Duncan com 5% de significância. Fonte: Autores, 2023.
Figure 2. Biodegradability test in soil in natura in packages
incorporated with ethanolic extract of Bixa orellana seeds. Note:
Different letters in the column show statistical difference by the
Duncan’s test (P < 0.05) significance.
Figura 2. Ensaio de biodegradabilidade em solo in natura em
embalagens incorporadas com extrato etanólico das sementes de
Bixa orellana. Nota: Letras diferentes na coluna apresentam diferença
pelo teste de Duncan (P < 0,05) de significância.
3.4. Antifungal activity
The B. orellana seed extract incorporated into the BP
exhibited good antifungal potential on the three evaluated
strains. For S. sclerotiorum, no significant difference (P < 0.05)
was observed between the 1000 and 750 µL concentrations
with 58% inhibition. The same was observed for C.
gloeosporioides with inhibition above 25%. For C. acutatum
growth inhibition activity was above 30%.
Table 4. Antifungal activity of biodegradable packaging
incorporated with ethanolic extract of Bixa orellana seeds.
Tabela 4. Atividade antifúngica das embalagens biodegradáveis
incorporadas com extrato etanólico das sementes de Bixa orellana.
Strain
Inhibition Zone (%)
1000
750
500
250
1
58.75b
55.95b
32.83c
19.82d
2
31.91b
29.67bc
27.93c
22.57d
3
26.31b
23.92b
19.54c
15.62d
1 = Sclerotinia sclerotiorum. 2 = Colletotrichum acutatum. 3 = Colletotrichum
gloeosporioides. Standard 100a. Control 0.00e.
Note: Different letters in the line show statistical difference by the Duncan’s
test (P < 0.05) significance.
Nota: Letras diferentes na linha mostram diferença estatística pela
significância do teste de Duncan (P < 0,05).
Jatobá et al.
Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
263
4. DISCUSSION
The diversity of plants with a formidable source of active
compounds is extremely high (COSTA; FREIRE, 2018;
MENEZES FILHO et al., 2023). Here, our plant B. orellana
exhibit this potential through many of it's group having
important phytomolecules for several sectors such as
pharmaceutical, agricultural and food. Our findings
corroborate the study by Santos et al. (2022) where they
found results similar to ours for the phytochemistry of B.
orellana seed extract, although our results were more complex
for other phytochemical groups. According to Gutierrez-del-
Rio et al. (2021) and Stoll et al. (2023), some phytochemical
groups such as terpenoids (monoterpenes or carotenoids)
such as bixin and norbixin present in B. orellana seeds have
antioxidant action. Carotenoids can eliminate reactive species
of oxygen, nitrogen, superoxide, hydroxyl or peroxyl radicals.
In addition, when the extract is incorporated into the
polymeric matrix or directly into the product, it conserves
meat and other products by preventing lipid oxidation
(PACHECO et al., 2018).
Polymeric matrices based on natural starch have high
specificity, a characteristic of great importance in
incorporating extracts, essential oils, resinous oil, fixed oil,
among others. Among the various characteristics, we can
mention the physicochemical parameters such as the
intramolecular arrangement that undergoes changes, which
are positive mainly in the physicochemical parameters.
Increase in BP thickness were observed, and this may be
related to conformational changes in the starch chain by the
addition of B. orellana seed extract. Package thickness is an
important parameter that affects mechanical properties and
permeability to oxygen, carbon dioxide and water vapour. In
addition, the drying conditions and preparation methods are
factors that also influence the thickness of the packaging and
that must be verified (HOSSEINI et al., 2015).
Furthermore, denser BP were observed in this study due
to a greater distribution of carotenoids in the starch
polymeric matrix, retaining more moisture. It was observed
that B. orellana extract induces a high sensitivity to moisture
absorption, which can also affect the mechanical and thermal
properties of BP (THAKUR et al., 2019).
Although, we observed an increase in moisture content;
the high concentration of carotenoids (bixin or norbixin) in
the extract can form hydrogen bonds within the starch
carbohydrate chain. Thus, this limits the bonding of the
hydrogen group with water. This can result in BP starch with
extract to not completely solubilized due to lack of affinity
for water molecules. It was observed that with increasing
concentration the solubility decreases. In the same sense Nor
Adilah et al. (2018) found lower solubility with the addition
of increasing concentrations of carotenoid-rich mango
extract.
Regarding the colors of the biodegradable packaging
developments, the transmission scan shows a decrease in the
light transmission rates of BP incorporating different doses
of EEBO in the ultraviolet and visible regions (from 200 to
850 nm). Our packages visually showed an increasing reddish
tone as a higher concentration of extract was added.
Additionally, luminosity increased as higher extract
concentrations were added. Chroma a* tended to reddish
tones and chroma b* to yellow. Similar results were observed
by Santos et al. (2020) for packaging incorporated with
Capsicum chinense extract using arrowroot as a polymeric
matrix.
Color is an important parameter to be evaluated, as it
influences product acceptance (ROMANI et al., 2018;
RAMBABU et al., 2019; SANTOS et al., 2022). The
biodegradable packaging used is usually transparent so that
the product can be seen. However, colored and opaque
packaging helps to protect foods exposed to UV-Vis light,
especially in foods with a high fat content, such as meat (beef,
pork, fish), thus preventing them from suffering oxidative
degradation (PRIYADARSHI et al., 2021; SANTOS et al.,
2022).
Packaging must have a short degradation time, thus
avoiding large volumes in landfills. That is why during the
development of a new package the biodegradability time
must be observed. In our study, the biodegradability of the
packages in soil in nature was performed to determine their
degradation time and confirm their potential as alternatives
to replace synthetic polymers, which require a long time for
degradation; greater than 500-1000 years. Biodegradation is
defined as the loss of mechanical properties, fragmentation
or chemical modifications due to the action of
microorganisms and enzymes present in the natural
microbiota of the soil or beach sand. According to Filipini et
al. (2020) biodegradability is influenced by the presence of
gases, humidity, light, temperature and natural biota.
Our biodegradability time is similar to studies that include
plant extracts in starch polymeric matrix or similar (RIAZ et
al., 2020). We noticed that higher concentrations of extract
become toxic to soil microorganisms, as we found that there
was a decrease in the percentage of biodegradability.
Antifungal and antibacterial activity is reported for B. orellana
extract in different extraction solvents, Jena; Bhatnagar
(2021) found inhibition activity on Aspergillus flavus and
Aspergillus niger for B. orellana extracts produced from n-
hexane solvents, chloroform, ethyl acetate and methanol;
Majolo et al. (2013) observed that the hydroethanolic extract
of B. orellana showed intense antibacterial activity on
Salmonella serovar Enteritidis, Escherichia coli, Staphylococcus
aureus, Enterococcus faecalis and Listeria monocytogenes, and on
Candida albicans by the ethanolic extract by Poma-Castillo et
al. (2019).
The antifungal effect is one of the bioactive
characteristics that enhance the use of a new active packaging
capable of inhibiting the development of deteriorating
microorganisms. Our results were encouraging and are
similar to other studies with extracts incorporated into a
natural polymeric matrix (FILIPINI et al., 2020; DEY et al.,
2021).
5. CONCLUSIONS
The phytochemical study showed richness in several
important groups that present biological activities, including
antifungal. The interaction between the Bixa orellana seed
extract and the arrowroot polymeric matrix showed potential
for the development of new biodegradable active packaging,
this statement was observed by the good results on the
physicochemical characteristics, high biodegradability and
antifungal potential on food phytopathogens.
Due to the satisfactory results obtained, new studies can
evaluate mechanical characteristics, in vitro and in vivo, and
Extract from Bixa orellana L. seed: development of biodegradable packaging and biological activities
Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
264
crystalline morphology of packages produced with the
ethanolic extract of Bixa orellana seeds.
6. REFERENCES
COSTA, R. M. C.; FREIRE, A. L. O. Efeito alelopático de
extratos aquosos de Prosopis juliflora (SW.) DC. na
emergência e no crescimento inicial de plântulas de
Mimosa tenuiflora (Willd.) Piret. Nativa, v. 6, n. 2, p. 139-
146, 2018. https://doi.org/10.31413/nativa.v6i2.4768
DEY, D.; DHARINI, V.; SELVAM, S. P.; SADIKU, E. R.;
KUMAR, M. M.; JAYARAMUDU, J.; GUPTA, U. N.
Physical, antifungal, and biodegradable properties of
celulose nanocrystals and chitosan nanoparticles for food
packaging application. Material Today: Proceedings, v.
38, part. 2, p. 860-869, 2021.
https://doi.org/10.1016/j.matpr.2020.04.885
FILIPINI, G. S.; ROMANI, V. P.; MARTINS, V. G.
Biodegradable and active-intelligent films based on
methylcellulose and jambolão (Syzygium cumini) skins
extract for food packaging. Food Hydrocolloids, v. 109,
e106139, 2020.
https://doi.org/10.1016/j.foodhyd.2020.106139
GUTIERREZ-DEL-RIO, I.; LOPEZ-IBANEZ, S.;
MAGADAN-CORPAS, P.; FERNANDEZ-CALLEJA,
L.; PEREZ-VALERO, A.; TUNON-GRANDA, M.;
LOMBO, F. Terpenoids and polyphenols as natural
antioxidant agents in food preservation. Antioxidants, v.
10, n. 8, e1264, 2021.
https://doi.org/10.3390/antiox10081264
HIRKO, B.; GETU, A. Bixa orellana (Annatto Bixa): a review
on use, structure, extraction methods and analysis.
Journal of Agronomy, Technology and Engineering
Management, v. 5, n. 1, p. 687-696, 2022.
JENA, S.; BHATNAGAR, S. Antifungal activity of Bixa
orellana extract against Aspergillus flavus and Aspergillus niger.
World Journal of Pharmaceutical Research, v. 10, n.
14, p. 1148-1154, 2021.
https://doi.org/10.20959/wjpr202114-22366
LUIGGI, F. G.; PACHECO, P. D. G.; RACANICCI, A. M.
C.; MUYNARSK, E. S. M.; FASANARO, R.; SARTORI,
J. R. Uso de bixina na dieta de frangos de corte e seus
efeitos no desempenho zootécnico e qualidade da carne.
Archives of Veterinary Science, v. 25, n. 1, p. 95-108,
2020.
MAJOLO, C.; CARVALHO, H. H.; WIEST, J. M. Atividade
antibacteriana in vitrode diferentes acessos de urucum
(Bixa orellana L.) e sua relação com o teor de bixina
presente nas sementes. Boletim CEPPA, v. 31, n. 1, p.
115-124, 2013.
MENEZES FILHO, A. C. P.; VENTURA, M. V. A.;
ALVES, I.; CASTRO, C. F. S.; SOARES, F. A. L.;
TEIXEIRA, M. B. Extratos florais do domínio cerrado e
inibição da acetilcolinesterase. Nativa, v. 11, n. 2, p. 207-
211, 2023. https://doi.org/10.31413/nat.v11i2.14555
NAGAMANI, S.; GNANASOUNDARI, A.;
THANGAMATHI, P. Phytochemical analysis of Bixa
orellana seed extract. International Journal of Species,
v. 13, n. 41, p. 58-67, 2015.
NOR ADILAH, A.; JAMILAH, B.; NORANIZAN, M. A.;
NUR HANANI, Z. A. Utilization of mango peel extracts
on the biodegradable films for active packaging. Food
Packaging and Shelf Life, v. 16, p. 1-7, 2018.
https://doi.org/10.1016/j.fpsl.2018.01.006
PACHECO, S. D. G.; GARCIA, C. E. R.; ARLORIO, M.;
WAGNER, R.; STRAPASSON, G.; MASSON, M. L.;
OCAMPOS, F.; BARISON, A.; PASQUINI-NETTO,
H.; DECASTELLI, L.; BELLIO, A.; MIGUEL, O. G.
Antioxidant and effects of processing using bixin
potassium salt as a nitrite replacement in restructured
meat products. Visão Acadêmica, v. 19, n. 2, p. 4-23,
2018.
POMA-CASTILLO, L.; ESPINOZA-POMA, M.;
MAURICIO, F.; MAURICIO-VILCHEZ, C.;
ALVÍTEZ-TEMOCHE, D.; MAYTA-TOVALINO, F.
Antifungal Activity of ethanol-extracted Bixa orellana (L.)
(Achiote) on Candida albicans, at six different
concentrations. The Journal of Contemporary Dental
Practice, v. 20, n. 10, p. 1159-1163, 2019.
https://doi.org/10.5005/jp-journals-10024-2672
PRIYADARSHI, R.; KIM, S.-M.; RHIM, J-W.
Carboxymethyl cellulose-based multifunctional film
combined with zinc oxide nanoparticles and grape seed
extract for the preservation of high-fat meat products.
Sustainable Material and Technologies, v. 29, e00325,
2021. https://doi.org/10.1016/j.susmat.2021.e00325
RAMBABU, K.; BHARATH, G.; BANAT, F.; SHOW, P. L.;
COCOLETZI, H. H. Mango leaf extract incorporated
chitosan antioxidant film for active food packaging.
International Journal of Biological Macromolecules,
v. 126, p. 1234-1243, 2019.
http://dx.doi.org/10.1016/j.ijbiomac.2018.12.196
ROMANI, V. P.; HERNÁNDEZ, C. P.; MARTINS, V. G.
Pink pepper phenolic compounds incorporation in
starch/protein blends and its potential to inhibit apple
browning. Food Packaging and Shelf Life, v. 15, p.
151-158, 2018.
http://dx.doi.org/10.1016/j.fpsl.2018.01.003
RIAZ, A.; LAGNIKA, C.; LUO, H.; DAI, Z.; NIE, M.;
HASHIM, M. M.; LIU, C.; SONG, J.; LI, D. Chitosan-
based biodegradable active food packaging film
containing chinese chive (Allium tuberosum) root extract
for food application. International Journal of
Biological Macromolecules, v. 150, p. 595-604, 2020.
https://doi.org/10.1016/j.ijbiomac.2020.02.078
SANTOS, R. S.; MENEZES FILHO, A. C. P.; BATISTA-
VENTURA, H. R. F.; CASTRO, C. F. S.; VENTURA,
M. V. A. Prospecção fitoquímica, teor de bixina e
atividade alelopática de extratos de Bixa orellana L.
Brazilian Journal of Science, v. 1, n. 12, p. 96-107,
2022. https://doi.org/10.14295/bjs.v1i12.243
SANTOS, L. S.; FERNANDES, C. C.; SANTOS, L. S.;
DEUS, I. P. B.; SOUSA, T. L.; MIRANDA, M. L. D.
Ethanolic extract from Capsicum chinense Jacq. Ripe fruits:
phenolic compounds, antioxidant activity and
development of biodegradable films. Food Science and
Technology, v. 41, n. 2, p. 497-504, 2021.
https://doi.org/10.1590/fst.08220
SHAIKH, S.; YAQOOB, M.; AGGARWAL, P. An overview
of biodegradable packaging in food industry. Current
Research in Food Science, v. 4, p. 503-520, 2021.
https://doi.org/10.1016/j.crfs.2021.07.005
STOLL, L.; MAILLARD, M-N.; LE ROUX, E.; FLÔRES,
S. H.; NACHTIGALL, S. M. B.; RIOS, A.; DOMENEK,
S. Bixin, a performing natural antioxidant in active food
packaging for the protection of oxidation sensitive food.
Jatobá et al.
Nativa, Sinop, v. 11, n. 2, p. 259-265, 2023.
265
LWT Food Science and Technology, v. 180, e114730,
2023. https://doi.org/10.1016/j.lwt.2023.114730
TONGNUANCHAN, P.; BENJAKUL, S.; PRODPRAN,
T. Structural, morphological and thermal behaviour
characterisations of fish gelatin film incorporated with
basil and citronella essential oils as affected by surfactants. Food
Hydrocolloids, v. 41, p. 33-43, 2014.
https://doi.org/10.1016/j.foodhyd.2014.03.015
Acknowledgments: We thank Goiano Federal Institute, Rio
Verde, Goiás, Brazil; to the Technological Chemistry, Plant
Products Post-Harvest and Water and Effluent Laboratories, and to
the Master's and Doctorate in Agrochemistry.
Author Contributions: L.A.J. - oriented, writing (original draft),
investigation and data collection and final writing; A.C.P.M.F. - co-
advisor, conceptualization, study design, methodology, submission,
final corrections and publication; P.S. - Experimental validation and
translation; C.F.S.C., M.B.T. and F.A.L.S. - acquisition of funding;
M.V.A.V. - advisor, conceptualization, study design, supervision,
statistical analysis. All authors read and agreed to the published
version of the manuscript.
Funding: Goiás Research Support Foundation (FAPEG) for the
doctoral scholarship for the second author; National Council for
Scientific and Technological Development (CNPq); Financier of
Studies and Projects (FINEP), and Higher Education Personnel
Improvement Coordination (CAPES).
Institutional Review Board Statement: Not applicable.
Informed Consent Statement (Ethics Committee of the area):
Not applicable.
Data Availability Statement: Study data can be obtained by
request to the corresponding the second author, via e-mail.
Conflicts of Interest: There are no conflicts of interest between
the authors. Supporting entities had no role in the design of the
study; in the collection, analysis, or interpretation of data; in the
writing of the manuscript, or in the decision to publish the results.