Original article | artigO Original

Authors
Juliana Silva Siqueira2

Fabiane Valentini Francisqueti-
Ferron1

Jéssica Leite Garcia1

Carol Cristina Vágula de 
Almeida Silva1

Mariane Róvero Costa1

Erika Tiemi Nakandakare- Maia1

Fernando Moreto1

Ana Lúcia A. Ferreira1

Igor Otávio Minatel2

Artur Junio Togneri Ferron1

Camila Renata Corrêa1

1Universidade Estadual Paulista, 
Faculdade de Medicina, Botucatu, 
SP, Brasil.
2Universidade Estadual Paulista, 
Instituto de Biociências, Botucatu, 
SP, Brasil.

Submitted on: 08/04/2020.
Approved on: 10/12/2020.

Correspondence to:
Fabiane Valentini Francisqueti-Ferron.
E-mail: fabiane_vf@yahoo.com.br

Rice bran modulates renal disease risk factors in animals 
submitted to high sugar-fat diet

Farelo de arroz modula os fatores de risco de doença renal em 
animais submetidos a uma dieta rica em gordura e açúcar

DOI: https://doi.org/10.1590/2175-8239-
JBN-2020-0169

Introduction: Obesity, diabetes, and 
hypertension are common risk factors 
for chronic kidney disease (CKD). CKD 
arises due to many pathological insults, 
including inflammation and oxidative 
stress, which affect renal function and 
destroy nephrons. Rice bran (RB) is rich 
in vitamins and minerals, and contains 
significant amount of antioxidants. 
The aim of this study was to evaluate 
the preventive effect of RB on renal 
disease risk factors. Methods: Male 
Wistar rats (±325 g) were divided into 
two experimental groups to received a 
high sugar-fat diet (HSF, n = 8) or high 
sugar-fat diet with rice bran (HSF + RB, 
n = 8) for 20 weeks. At the end, renal 
function, body composition, metabolic 
parameters, renal inflammatory and 
oxidative stress markers were analyzed. 
Results: RB prevented obesity [AI (HSF= 
9.92 ± 1.19 vs HSF + RB= 6.62 ±  0.78)], 
insulin resistance [HOMA (HSF= 83 ± 8 
vs. HSF + RB= 42 ± 11)], dyslipidemia 
[TG (HSF= 167 ± 41 vs. HSF + RB=92 
± 40)], inflammation [TNF-α (HSF= 80 ± 
12 vs. HSF + RB=57 ± 14), IL-6 (903 ± 
274 vs. HSF + RB=535 ± 277)], oxidative 
stress [protein carbonylation (HSF= 3.38 
± 0.18 vs. HSF + RB=2.68 ± 0.29), RAGE 
(HSF=702 ± 36 vs. RSF + RB=570 ± 190)], 
and renal disease [protein/creatinine ratio 
(HSF=1.10 ± 0.38 vs. HSF + RB=0.49 
± 0.16)]. Conclusion: In conclusion, 
rice bran prevented renal disease by 
modulating risk factors.

AbstrAct

Keywords: Kidney Function Tests; Phy-
tochemicals; Inflammation; Oxidative 
Stress.

Introdução: Obesidade, diabetes e hipertensão 
arterial são fatores de risco comuns para 
doenças renais crônicas (DRC). A DRC surge 
devido a muitos insultos patológicos, incluindo 
inflamação e estresse oxidativo, que afetam a 
função renal e destroem os néfrons. O farelo 
de arroz (FA) é rico em vitaminas e minerais, 
e contém uma quantidade significativa de 
antioxidantes. O objetivo deste estudo foi 
avaliar o efeito preventivo do FA nos fatores 
de risco de doenças renais. Métodos: Ratos 
Wistar machos (±325 g) foram divididos em 
dois grupos experimentais para receber uma 
dieta rica em gordura e açúcar (DRGA, n = 8) 
ou uma dieta rica em gordura e açúcar com 
farelo de arroz (DRGA + FA, n = 8) por 20 
semanas. Ao final, foram analisados a função 
renal, composição corporal, parâmetros 
metabólicos, marcadores renais inflamatórios 
e de estresse oxidativo. Resultados: FA 
preveniu a obesidade [IA (DRGA= 9,92 
± 1,19 vs. DRGA + FA= 6,62 ± 0. 78)], 
resistência à insulina [HOMA (DRGA= 83 
± 8 vs DRGA + FA= 42 ± 11)], dislipidemia 
[TG (DRGA= 167 ± 41 vs. DRGA + FA=92 
± 40)], inflamação [FNT-α (DRGA= 80 ± 12 
vs. DRGA + FA=57 ± 14), IL-6 (903 ± 274 vs. 
DRGA + FA= 535 ± 277)], estresse oxidativo 
[carbonilação de proteína (DRGA= 3. 38 ± 
0,18 vs. DRGA + FA=2,68 ± 0,29), RAGE 
(DRGA=702 ± 36 vs. DRGA + FA=570 
± 190)], e doença renal [relação proteína/
creatinina (DRGA=1,10 ± 0,38 vs. DRGA + 
FA=0,49 ± 0,16)]. Conclusão: Em conclusão, 
o farelo de arroz preveniu doenças renais 
através da modulação dos fatores de risco.

resumo

Descritores: Testes de Função Renal; Com-
postos Fitoquímicos; Inflamação; Estresse 
Oxidativo.

IntroductIon

Chronic kidney disease (CKD) is 
defined as changes in the kidney 

function or structure for more than 
three months, independent of the cause, 
which affect the health of an individual1. 

https://orcid.org/0000-0003-3172-2199
https://orcid.org/0000-0003-2910-4308
https://orcid.org/0000-0002-3670-243X
https://orcid.org/0000-0002-2004-3097
https://orcid.org/0000-0002-9922-2871
https://orcid.org/0000-0001-7089-3033
https://orcid.org/0000-0001-8493-5329


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Rice bran and renal disease risk factors

157

Epidemiological data show that CKD affects 10–16% 
of adults in the world2, being considered a global 
health problem. CKD diagnosis is usually established 
by the glomerular filtration rate (GFR). However, the 
reference GFR range does not exclude renal disease, 
since renal disease leads to decrease of renal function. 
Within this context, the National Kidney Foundation 
recommends proteinuria analysis for early stage 
detection and GFR estimations for assessing the 
progression of kidney disease3.

Obesity, diabetes, and hypertension are common 
risk factors for CKD4. CKD arises due to many 
pathological insults, including inflammation and 
oxidative stress, which affect the renal function and 
destroy nephrons. The literature reports an association 
between renal impairment and different mediators 
of inflammation including interleukin-6 (IL-6) and 
tumor necrosis factor-α (TNF-α) suggesting that CKD 
is a low-grade inflammatory process5,6.

Oxidative stress can be considered an imbalance 
in the reactive oxygen species (ROS) production/
degradation ratio. Excessive ROS levels can produce 
cellular damage by interacting with biomolecules 
(proteins, lipids, and nucleic acids) resulting in negative 
effects on tissue function and structure, including kidney. 
Studies show that increased oxidative stress markers, 
as malondialdehyde (MDA) and carbonylated protein 
are inversely correlated with kidney function5,7. As a 
result, the nephrons compensate the function of injured 
nephrons with hyperfiltration, leading to glomerular 
hypertension, proteinuria, and eventually loss of renal 
function overt time1.

Several mechanisms are associated with 
renal inflammation and oxidative stress. When 
activated, the receptor for advanced glycation end 
products (RAGE), a multi-ligand member of the 
immunoglobulin superfamily of cell surface receptors, 
leads to a signalling sequence with the activation 
of the nuclear factor kappa-B (NFκB) resulting in 
proinflammatory cytokines production, such as 
TNF-α, IL-6, and monocyte chemoattractant protein-1 
(MCP-1)8. RAGE activation can also directly induce 
oxidative stress by activating nicotinamide adenine 
dinucleotide phosphate (NADPH)-oxidase (NOX), 
especially NOX-4. Thus, RAGE activation is an 
interface between oxidative stress and inflammation, 
which are pillars for development of several diseases, 
especially in organs that express these AGE receptors, 
as brain, heart, and kidneys9.

In this context, an interest has emerged on the role 
of functional foods to prevent some diseases. Rice 
bran is one of the most abundant products produced 
in the rice milling industry that is rich in vitamins, 
including vitamin E, thiamin, niacin, and minerals 
like aluminum, calcium, chlorine, iron, magnesium, 
manganese, phosphorus, potassium, sodium, and zinc. 
It also contains a significant amount of antioxidants 
such as tocopherols, tocotrienols, and oryzanol. Rice 
bran also has proteins of high nutritional value and it 
is a good source of both soluble and insoluble dietary 
fiber10. Thus, considering that the consumption of 
high sugar-fat diet can lead to obesity and kidney 
disease risk factors development and the lack of 
studies regarding the effect of rice bran on these 
physiopathological aspects, the aim of this study was 
to evaluate the effect of rice bran on the modulation 
of renal disease risk factors in animals submitted to 
high sugar-fat diet.

mAterIAl And methods

animals and experimental prOtOcOl

In the present study, male Wistar rats (±325 g) from 
the Animal Center of Botucatu Medical School, 
Sao Paulo State University (UNESP, Botucatu, SP, 
Brazil), were divided into two experimental groups 
to receive high sugar-fat diet (HSF, n = 8) or high 
sugar-fat diet with rice bran (HSF + RB, n = 8) for 
20 weeks. The diets and water were provided ad 
libitum. The diet composition has been described in 
our previous study11. All the animals were housed in 
an environmentally controlled room (22±3 ºC, 12 h 
light-dark cycle and relative humidity of 60±5%). All 
of the experiments were performed in accordance with 
the Canadian Council on Animal Care (CCAC)12 and 
the procedures were approved by the Animal Ethics 
Committee of Botucatu Medical School (1305/2019). 
In order to confirm the effects of high sugar-fat diet on 
renal risk factors development in the HSF group, male 
Wistar (n=8, ±325 g, and same age), fed a standard 
diet, were used as reference group (baseline control 
group). At the end of the experiment, the animals 
were euthanized by decapitation after anesthesia with 
thiopental (120 mg/kg, intraperitoneal injection) and 
all efforts were made to minimize suffering. Blood 
from fasted animals was collected in tubes containing 
EDTA and centrifuged at 3500 rpm and the plasma 
was collected for analysis. Fat deposits and kidneys 
were collected for analysis.



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Rice bran and renal disease risk factors

158

rice bran dOse

Since rice bran contains antinutritionals components, 
such as lipases and trypsin inhibitors10, it was 
subjected to a stabilization process, which consisted 
of heating in an oven to 100ºC, for 4 minutes. After 
the stabilization process, it was mixed to the chow in 
a dose of 11% (w/w). The dose has been chosen based 
on previous studies13.

nutritiOnal parameters

The nutritional parameters evaluated were: chow 
intake, water intake, and caloric intake. Caloric 
intake was determined by multiplying the energy 
value of each diet (g × Kcal) by the daily food 
consumption plus the calories from water (0.25 × 4 
× mL consumed).

bOdy cOmpOsitiOn

Body composition was evaluated considering the final 
body weight (FBW), and adiposity index (AI). After 
euthanasia, fat tissues (visceral (VAT), epididymal 
(EAT), and retroperitoneal (RAT)) were used to 
calculate the AI by the following formula:

AI = VAT + EAT + RAT /FBW × 10014.

metabOlic analysis

After 8 h fasting, blood was collected and the plasma 
was used to measure the biochemical parameters. 
Glucose concentration was determined using a 
glucometer (Accu-Chek Performa, Roche Diagnostics 
Brazil Limited) and triglycerides were measured with 
an automatic enzymatic analyzer system (Chemistry 
Analyzer BS-200, Mindray Medical International 
Limited, Shenzhen, China). The insulin level was 
measured using the enzyme-linked immunosorbent 
assay (ELISA) method using commercial kits 
(EMDMillipore Corporation, Billerica, MA, USA). 
The homeostatic model of insulin resistance (HOMA-
IR) was used as an insulin resistance index, calculated 
according to the formula: HOMA-IR = (fasting 
glucose (mmol/L) x fasting insulin (µU/mL))/22.515.

systOlic blOOd pressure

Systolic blood pressure (SBP) was assessed in conscious 
rats by the noninvasive tail-cuff method with a 
Narco Bio-Systems® electrosphygmomanometer 
(International Biomedical, Austin, TX, USA). The 

animals were kept in a wooden box (50 × 40 cm) 
between 38 and 40°C for 4-5 minutes to stimulate 
arterial vasodilation16. After this procedure, a cuff 
with a pneumatic pulse sensor was attached to the 
tail of each animal. The cuff was inflated to 200 
mmHg pressure and subsequently deflated. The blood 
pressure values were recorded on a Gould RS 3200 
polygraph (Gould Instrumental Valley View, Ohio, 
USA). The average of three pressure readings was 
recorded for each animal.

renal inflammatiOn

Renal tissue (±150 mg) was homogenized (ULTRA-
TURRAX® T 25 basic IKA® Werke, Staufen, Germany) 
in 1.0 mL of phosphate-buffered saline (PBS) pH 7.4 
in cold solution and centrifuged at 800 g at 4°C for 
10 min. The supernatant (100 μL) was used in the 
analysis. TNF-α and IL-6 levels were measured using 
the ELISA method with commercial kits from R&D 
System, Minneapolis, USA. The supernatant (100 μL) 
was used for analysis, and the results were corrected 
by the protein amount.

renal malOndialdehyde levels (mda)

MDA level was used to evaluate the lipid peroxida-
tion. Briefly, 250 µL of epididymal adipose tissue su-
pernatant was used plus 750 µL of 10% trichloroa-
cetic acid for precipitation of proteins. Samples were 
centrifuged (3000 rpm, for 5 minutes; Eppendorf® 
Centrifuge 5804-R, Hamburg, Germany) and the su-
pernatant removed. Thiobarbituric acid (TBA) was 
added 0.67% in ratio (1:1) and the samples heated 
for 15 minutes at 100°C. MDA reacts with TBA in 
the 1:2 (MDA:TBA) ratio. After cooling, the reading 
at 535nm was performed on Spectra Max 190 mi-
croplate reader (Molecular Devices®, Sunnyvale, CA, 
USA). The MDA concentration was obtained by the 
molar extinction coefficient (1.56 x 105 M-1·cm-1) and 
the absorbance of the samples and the final result re-
ported in nmol/g protein17.

renal prOtein carbOnylatiOn

Carbonylated proteins were measured by an unspecific 
method that uses DNPH (2,4-dinitrophenylhydrazine 
derivatizing agent) and photometric detection of any 
modified protein by carbonylation. Carbonylated 
protein levels are reported in nmol of DNPH/mg of 
protein18.



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Rice bran and renal disease risk factors

159

rage levels

Renal tissue (±150 mg) was homogenized (ULTRA-
TURRAX® T 25 basic IKA® Werke, Staufen, 
Germany) in 1.0 mL of phosphate-buffered saline 
(PBS) pH 7.4 in cold solution and centrifuged at 800 
g at 4°C for 10 min. The supernatant (100 µL) was 
used in the analysis. RAGE levels were measured with 
ELISA method using commercial kits from R&D 
System, Minneapolis, USA. The results were corrected 
according to the protein amount.

renal functiOn

At 24 hours, urine was collected from the metabolic 
cages to measure the excretion of creatinine and the total 
protein. All analyses were performed with an automatic 
enzymatic analyzer system (biochemical analyzer BS-
200, Mindray, China). The glomerular filtration rate 
(GFR = (urine creatinine × flux)/plasma creatinine) and 
proteinuria (protein/creatinine ratio) were also calculated.

statistical analysis

The data were submitted to Kolmogorov-Smirnov 
normality test. Parametric variables were compared 
by Student’s t-test and the results are reported as 
mean ± standard deviation. Non-parametric variables 
were compared by Mann-Whitney test and the results 
are reported as median (interquartile range (25-75)). 
Pearson correlation was used to assess the association 
among parameters. Statistical analyses were 
performed using Sigma Stat for Windows Version 3.5 
(Systat Software Inc., San Jose, CA, USA). A p value < 
0.05 was considered statistically significant.

results

rice bran effect On nutritiOnal parameters

The nutritional parameters are presented in the Figure 
1. It is possible to note the chow, water, and caloric 
intake in the HSF and HSF + RB groups. The HSF 
+ RB showed lower final body weight and adiposity 
index than the HSF group.

rice bran effect On renal cardiOmetabOlic risk 
factOrs

Renal cardiometabolic risk factors are presented in 
the Figure 2. It is possible to verify reduced HOMA-
IR and triglycerides in the HSF + RB group compared 
to HSF. No rice bran effect was observed on systolic 
blood pressure.

rice bran effect On renal inflammatiOn

Kidney inflammation parameters are presented 
in the Figure 3. Rice bran was effective to reduce 
inflammation, since the HSF + RB showed lower 
TNF-α and IL-6 levels compared to HSF.

rice bran effect On renal Oxidative stress

Figure 4 shows the oxidative stress parameters. 
The group HSF + RB presented lower protein 
carbonylation and RAGE level compared to the HSF. 
No difference was observed for the MDA levels.

Malondialdehyde (nmom/mg protein); C, RAGE 
(pg/g protein). Comparison by Student’s t-test 
or Mann-Whitney test. p < 0.05 was considered 
significant. NS: not significant.

renal functiOn parameters

Figure 5 presents the renal function parameters. It 
is possible to verify the proteinuria presence in the 
HSF group while the HSF + RB was protected. No 
difference was observed for the glomerular filtration 
rate between HSF and HSF + RB groups.

cOrrelatiOn amOng the parameters

A positive correlation was found between proteinuria 
and caloric intake, adiposity index, triglycerides, 
HOMA, and carbonylation. Regarding the GFR, 
there was a positive correlation with MDA and a 
negative correlation with TNF-α (Figure 6).

dIscussIon

The study aimed to evaluate the effect of rice bran 
on the modulation of renal damage risk factors. 
Kidney disease has a major effect on global health, 
both as a direct cause of morbidity and mortality 
and as an important risk factor for cardiovascular 
disease. Moreover, CKD is preventable and treatable 
and deserves greater attention in global health policy 
decision making19. Thus, the discovery of natural 
products, as rice bran, able to prevent this condition 
is extremely relevant. In the present study, a beneficial 
effect of rice bran was observed on the main renal 
disease risk factors. At the same time, the HSF group 
showed proteinuria and several risk factors for kidney 
injury, among them: obesity, dyslipidemia, insulin 
resistance, inflammation, and oxidative stress4.

The literature is scarce of studies with rice bran 
and CKD. One study published by our research group 



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Rice bran and renal disease risk factors

160

Figure 1. Nutritional parameters. A, Chow fed (g/day); B, Water intake (mL/day); C, Caloric intake (kcal/day); D, Final body weight (g); E, Adiposity 
index (%). Comparison by Student’s t-test or Mann-Whitney test, n=8 animals/group. p < 0.05 was considered significant. HSF: high sugar-fat diet; 
RB: rice bran. NS: not significant.

found that γOz, the main bioactive compound of rice 
bran, was effective to recover obesity-induced kidney 
disease after 10 weeks of treatment in Wistar rats20. 
Another experimental study by Al-Okbi et al.21 found 
that γ-oryzanol (γ-O) and rice bran oil/γ-O mixture 
(RBO/γ-O) had protective effects on cardiovascular 
diseases and cardiorenal syndrome, similar to 
Francisqueti et al.22, which found a protective effect 
of γOz on cardiorenal metabolic syndrome.

Obesity has been identified as one of the main 
cause of kidney disease since it is associated with 
hemodynamic, structural, and histopathological 
alterations in the kidney, as well as metabolic and 

biochemical alterations that predispose to kidney 
disease23,24. The animals that received rice bran 
presented the same chow, water, and caloric intake, 
however lower final body weight and adiposity 
index than the HSF group. Although the mechanism 
by which rice bran protects against obesity is not 
clarified, the literature confirms this antiobesogenic 
effect and attributes the benefits to dietary fiber, 
oligosaccharides, hemicelluloses, and non-starchy 
polysaccharides as well as some water-soluble 
phytochemicals present in the rice bran25.

Obesity is the main risk factor for the development 
of chronic diseases, such as type 2 diabetes and 



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161

Figure 2. Renal cardiometabolic risk factors. A, Systolic blood pressure (mmHg); B, HOMA- IR; C, Triglycerides (mg/dL). Comparison by Student’s 
t-test or Mann-Whitney test, n=8 animals/group. p < 0.05 was considered significant. HSF: high sugar-fat diet; RB: rice bran. NS: not significant.

Figure 3. Renal inflammation parameters. A, Tumor necrosis factor alpha (TNF-α, pg/g protein); B, Interleukin-6 (IL-6, pg/g protein). Comparison by 
Student’s t-test or Mann-Whitney test. p < 0.05 was considered significant. NS: not significant.

cardiovascular diseases, which increases the risk for 
CKD26. Hyperglycemia increases the non-enzymatic 
reaction of glucose and other glycating compounds 
derived both from glucose and from increased 
fatty acid oxidation, which generates advanced 
glycation end products in complication-prone cell 
types, including kidney cells27. The HSF group not 
only developed obesity but also insulin resistance. 
However, the animals that received rice bran did not 

present insulin resistance, which can be explained 
by the protection against obesity in the HSF + RB 
group. An excessive adipose tissue is associated with a 
chronic low-grade inflammation that may explain the 
development of the obesity-related pathologies, such 
as type 2 diabetes mellitus28,29.

Hypertension is a major risk factor for renal 
disease30. Multiple mechanisms are involved in 
determination of renal damage in hypertension, 



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162

Figure 4. Renal oxidative stress parameters. A, Protein carbonylation (nmol/mg protein) B, Malondialdehyde (nmom/mg protein); C, RAGE (pg/g 
protein). Comparison by Student’s t-test or Mann-Whitney test. p < 0.05 was considered significant. NS: not significant.

Figure 5. Renal function evaluation. A, Protein/creatinine ratio; B, Glomerular filtration rate (GFR, mL/min). Comparison by Student’s t-test or Mann-
Whitney test. p < 0.05 was considered significant. NS: not significant.

such as the renin-angiotensin-aldosterone system 
(RAAS), oxidative stress, endothelial dysfunction, 
and inflammation31. In the present study, no effect 
of rice bran was observed on systolic blood pressure. 
However, the HSF + RB group presented protection 
against kidney damage, which can be explained by 
the effect on inflammation and oxidative stress. The 

main bioactive compound in RB is gamma-oryzanol, 
which has demonstrated antioxidative and anti-
inflammatory effects25,32 also in kidneys of obese 
animals20.

The upregulation of pro-inflammatory cytokines, as 
IL-6 and TNF-α, mediated by AGE/RAGE and NFκB, 
increase oxidative stress, which leads to local and 



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Rice bran and renal disease risk factors

163

Figure 6. Pearson correlation among the variables. Red values indicate negative significant difference, gray values indicate non-significant difference, 
and blue values indicate positive significant correlation.

systemic inflammation, glomerular and tubular lesions, 
and proteinuria. Among cytokines, TNF-α is known to 
cause direct cytotoxicity and apoptosis of renal cells33,34. 
Oxidized molecules reflect the damage mediated by 
oxidative stress in cells and tissues, and their measurement 
can be indicative of oxidative stress in a specific disease, 
as well as the potential efficacy of clinical treatments. 
Some of these modifications, as carbonylation, are 
irreversible and can lead to altered protein expression 
and activity, resulting in organ impairment35. Confirming 
the antioxidant and anti-inflammatory effect of rice 
bran, the HSF + RB animals showed reduced TNF-α, 
IL-6, RAGE, protein carbonylation, and proteinuria 
compared to the HSF group.

In summary, rice bran was able to prevent obesity, 
insulin resistance, dyslipidemia, inflammation, 
oxidative stress, and renal disease. These findings 
provide important information about the use of 
bioactive compounds as alternative therapeutics for 
preventing renal disease and associated risk factors. 
However, since the main limitation of this study was 
not evaluating the pathways involved in the positive 
effects of rice bran, more studies are necessary. 
Therefore, we concluded that rice bran was able to 
prevent renal disease by modulating risk factors.

Authors' contrIbutIon

Conceptualization: Siqueira, JS; Garcia JL; 
Francisqueti- Ferron FV; Minatel IO; Correa CR. 
Data curation: Francisqueti-Ferron FV; Garcia JL; 
Ferron AJT; Siqueira, JS; Nakandakare-Maia ET; 
Silva, CCVA; Costa MR; Moreto F. Formal analysis: 
Francisqueti-Ferron FV; Minatel IO; Ferron AJT; 

Ferreira ALA; Correa CR; Funding acquisition: 
Correa CR. Methodology: Francisqueti-Ferron FV; 
Garcia JL; Ferron AJT; Silva CCVA; Siqueira JS. 
Project administration: Francisqueti-Ferron FV; 
Correa CR. Writing original draft: Francisqueti-
Ferron FV; Minatel IO; Correa CR.

conflIct of Interest

The authors declare no conflict of interest.

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