Abstract

This study was conducted to test the significance of adding row and column factors in the frequentist and Bayesian models used in the evaluation of a population of Passiflora edulis, as well as selecting promising genotypes to form the next generation. The following parameters were evaluated: number of fruits, yield, fruit weight, transverse fruit diameter, longitudinal fruit diameter, pulp percentage, skin thickness and total soluble solids. For the Bayesian model, two priors were considered, namely, inverse gamma and a priori distribution with extended parameters. The model with a priori distribution with extended parameters showed lower root mean square error and higher correlation coefficient between observed and predicted values than the inverse gamma model. Furthermore, for a selection intensity of 37%, the mixed and Bayesian models selected practically the same progenies in both experiments. The use of the 5-fold cross-validation technique indicated that both tested models were efficient.

Keywords:
REML; prior; post-hoc blocking Row-Col

INTRODUCTION

Brazil is considered the world's largest passion fruit producer, generating 602 thousand tons of the fruit from a cultivated area of approximately 43,000 ha, which amounts to an average yield of 14 t ha^-1. These estimates indicate the production potential and the economic importance of this crop for the country. About 62% of national production comes from the northeast, followed by the southeast, south, north, and center-west regions. However, when it comes to yield, the south region is the leader, accounting for about 25% of domestic production (IBGE 2018IBGE - Instituto Brasileiro de Geografia e Estatística2018 Produção agrícola municipal. Available at <Available at https://sidra.ibge.gov.br/tabela/5457#resultado >. Accessed on January 29, 2021.
https://sidra.ibge.gov.br/tabela/5457#re... ).

The passion fruit yield in the state of Rio de Janeiro was 6,000 t ha^-1, which can be considered low compared with the 16,000 t ha^-1 of Bahia state, the largest producer. This low yield is due, among other factors, to the lack of high-yielding genotypes, large variability in commercial orchards, lack of improved cultivars adapted to the soil, and climatic and environmental conditions of the growing region (Gonçalves et al. 2007Gonçalves GM, Viana AP, Bezerra Neto FV, Pereira MG, Pereira TNS2007 Seleção e herdabilidade na predição de ganhos genéticos em maracujá-amarelo. Pesquisa Agropecuária Brasileira 42:193-198). In the current Brazilian scenario, yield and fruit quality, as well as disease control in passion fruit cultivation, have become extremely important issues to ensure the sustainability of this crop. Unfortunately, these factors have contributed to a reduction in average yield in recent years in Brazil. Given the complexity of this scenario, breeding programs have employed a variety of methods to address these challenges.

In the field of passion fruit breeding, several methods are used to deal with spatial variation problems, especially when it comes to experiments. An important example is the mixed model methodology (REML/BLUP), which plays a crucial role in this context (Viana and Resende 2014Viana AP, Resende MDV2014 Genética quantitativa no melhoramento de fruteiras. Interciência, Rio de Janeiro, 296p). This approach has become standard for estimating genetic parameters and predicting genotypic values, being widely adopted in several breeding programs. The work carried out by Santos et al. (2015Santos EA, Viana AP, Freitas JCO, Rodrigues DL, Tavares RF, Paiva CL, Souza MM2015 Genotype selection by REML/BLUP methodology in a segregating population from an interspecific Passiflora spp. crossing. Euphytica 204:1-11) with individuals from a segregating population from an interspecific cross of passion fruit showed that the REML/BLUP method was effective in identifying superior genotypes.

In turn, the Bayesian approach has advantages such as allowing the incorporation of previous distributions into the model, especially when the availability of information is limited (Silva et al. 2018Silva JL, Sanches A, Andrade ACB, Oliveira GHF, Mauro AOD2018 Bayesian approach, traditional method, and mixed models for multienvironment trials of soybean. Pesquisa Agropecuária Brasileira 53:1093-1100). In addition to these techniques, post-hoc blocking Row-Col emerges as another promising strategy to control the local effect. This approach involves superimposing a structure of rows and columns over the original layout, generated in estimates of model parameters with greater precision (Machado et al. 2020Machado RFC, Krause W, Silva CA, Fachi LR, Silva FHL, Viana AP2020 Implications of the post hoc blocking row-col technique on the intrapopulational improvement of the passion fruit. Euphytica 216:62).

However, using effective methods goes beyond that. It is necessary to consider the combination of appropriate approaches and techniques to face the specific challenges related to yield, fruit quality and disease control in passion fruit cultivation. This integration of methods, combined with a holistic approach, is key to driving progress in improving this crop and ensuring its long-term sustainability. In this context, the present study was conducted with the objective of estimating the components of variance, heritability and selection gain through the mixed model and Bayesian methods. In addition, we sought to evaluate the application of the post-hoc blocking Row-Col technique, using chi-square statistics, for real data variables from passion fruit breeding experiments.

MATERIAL AND METHODS

A total of 97 full-sib progenies from the fourth cycle of recurrent selection of the UENF breeding program were evaluated. These progenies were obtained by crossing 23 half-sib progenies selected by Cavalcante et al. (2019Cavalcante NR, Viana AP, Filho JEA, Pereira MG, Ambrósio M, Santos EA, Ribeiro RM, Rodrigues DL, Sousa CMB2019 Novel selection strategy for half-sib families of sour passion fruit Passiflora edulis (Passifloraceae) under recurrent selection. Genetics and Molecular Research 18:1-12). The experiment was conducted on Santo Antão farm, belonging to Instituto Federal Fluminense, in Cambuci - RJ, Brazil (lat 21° 34' S, long 41° 54' W, alt 35 m asl). The experiment was laid out in a randomized block design with two replicates, where each plot consisted of three plants (582 plants). To work with the post-hoc blocking Row-Col technique, a grid with 19 rows and 15 columns was implemented over the experimental layout.

The following variables were evaluated: number of fruits (NF), by counting the total number of fruits in each plot; total yield (YLD, kg plot^-1), determined by measuring the amount harvested during the experiment; fruit weight (FW, g), calculated as the arithmetic mean of the weight of 15 fruits sampled per plot; fruit longitudinal diameter (LGT, mm); fruit transverse diameter (TVS, mm); fruit pulp percentage (PP, %), obtained as the ratio between pulp weight and total fruit weight; peel thickness (PT, mm), determined in the median portion of fruits cut transversally, along the larger diameter; total soluble solids content (TSS, °Brix), determined with an ATAGO N1 digital handheld refractometer, with reading performed in the range from 0 to 95 °Brix in aliquots of pulp juice.

Models

To model the variables, two models were proposed. The first model used was a mixed linear model: $y=1\mathrm{\mu }+{Z_{1}u}_1+{Z_{2}u}_2+\epsilon$ , where $Y_{nx1}$ is the vector of phenotypic observations; 1_nx1 is a column matrix of ones; $u_1$ is the vector of random effects for blocks associated with incidence matrix Z₁, with probability distribution $u_1~N(0,{I\sigma }_{block}^2)$ ; $u_2$ is the vector of random effects for progeny associated with incidence matrix Z₂, with probability distribution $u_2~N(0,{I\sigma }_{progeny}^2)$ ; $\epsilon$ is the vector of random errors, with probability distribution $\epsilon ~N(0,{I\sigma }_{error}^2)$ , in which $\epsilon |{\sigma }_{error}^2~N\left(0,\mathrm{}{I\sigma }_{error}^2\right)$ ; and the joint distribution of the observed data is given by $E\left(y\right)~N(1\mathrm{\mu }+{Z_{1}u}_1+Z_2{u}_2,{I\sigma }_e^2$ ), here referred to as “reduced model”.

Subsequently, the post-hoc blocking Row-Col method was applied on the reduced model by tracing a grid with 13 rows and 18 columns over the experimental layout, thus modifying the model, which was then termed “full model”: $y=1\mathrm{\mu }+{Z_{1}u}_1+Z_2{u}_2+{Z_{3}u}_3+{Z_{4}u}_4+\epsilon$ , where $Y_{nx1}$ is the vector of phenotypic observations; 1_{n x 1} is a column matrix of value 1; $u_1$ is the vector of random effects for blocks associated with incidence matrix Z₁, with probability distribution $u_1~N(0,{I\sigma }_{block}^2)$ ; $u_2$ is the vector of random effects for progeny associated with incidence matrix Z₂, with probability $u_2~N(0,{I\sigma }_{progeny}^2)$ ; $u_3$ is the vector of random effects for row associated with incidence matrix Z₃, with probability distribution $u_3~N(0,{I\sigma }_{row}^2);\mathrm{}{u}_4$ is the vector of random effects for column associated with incidence matrix Z₄, with probability distribution $u_4~N(0,{I\sigma }_{column}^2)$ ; $\epsilon$ is the vector of random errors, with probability distribution $\epsilon ~N(0,{I\sigma }_{error}^2)$ ; and the joint distribution of the observed data is given by $E\left(y\right)~N(1\mathrm{\mu }+{Z_{1}u}_1+Z_2{u}_2+{Z_{3}u}_3+{Z_{4}u}_4,{\mathit{I}\mathit{\sigma }}_e^2$ ). The models were compared by the likelihood ratio test (LRT) using chi-square statistics, adopting two degrees of freedom and a 5% probability level. After both models were tested under the frequentist approach, they were also tested under the Bayesian approach. The joint distribution of the data observed under this approach was obtained from the following distributions: $y|\mathrm{\mu },u_1,u_2,u_3,u_4,{\sigma }_{progeny}^2,{\sigma }_{block}^2,{\sigma }_{row}^2,{\sigma }_{column}^{\mathrm{}2},{\sigma }_{error}^2~N\left(1\mathrm{\mu }+Z_1{u}_1+Z_2{u}_2{+Z}_3{u}_3+Z_4{u}_4,\mathrm{}{\mathit{}\mathit{I}\sigma }_e^2\right)$ where $\mu ~N\left({\mu }_0,{\sigma }_0^2\right)$ ; ${u_1|\sigma }_{prog\mathrm{e}\mathrm{n}\mathrm{y}}^2\mathrm{}~\mathrm{}N\left(0,\mathrm{}{\mathit{I}\sigma }_{prog\mathrm{e}\mathrm{n}\mathrm{y}}^2\right);\mathrm{}{\sigma }_{progeny}^2\mathrm{}~IG\left(\nu ={\nu }_1,\mathrm{}V=V_1\right)$ ; ${u_2|\sigma }_{block}^2\mathrm{}~\mathrm{}N\left(0,\mathrm{}{\mathit{I}\sigma }_{block}^2\right);{\sigma }_{block}^2\mathrm{}~IG\left(\nu ={\nu }_2,\mathrm{}V=V_2\right)$ ; ${u_3|\sigma }_{column}^2\mathrm{}~\mathrm{}N\left(0,\mathrm{}{\mathit{I}\sigma }_{column}^2\right);{\sigma }_{column}^2\mathrm{}~IG\left(\nu ={\nu }_2,\mathrm{}V=V_3\right)$ ; ${u_4|\sigma }_{row}^2\mathrm{}~\mathrm{}N\left(0,\mathrm{}{\mathit{I}\sigma }_{row}^2\right)$ ; ${\sigma }_{row}^2\mathrm{}~IG\left(\nu ={\nu }_2,\mathrm{}V=V_4\right);$ and ${\sigma }_{error}^2\mathrm{}~IG\left(\nu ={\nu }_0,\mathrm{}V=V_0\right)$ . This was termed “full Bayesian model”. For the reduced model, as in the frequentist approach, only the effects of block, progeny, and error were maintained, with the same distributions of the variances described above. To improve the estimates in the Bayesian approach, two priors were defined for the parameters, here called Bayes I (ν=1; V=0.002; alpha.mu=0; alpha.V=0; Classification μ=Inverse Gamma (IG) N[0.10^8]) and Bayes II (ν=1; V=1; alpha.mu=0; alpha.V=252; Classification μ= Half-Cauchy (HC) N[0.10^8]).

The choice of prior was based on the smallest square root of the mean squared error and on the correlation between what was observed and predicted by the model, so prior II was chosen for presenting such more accurate metrics. It is noteworthy that the non-informative a priori models did not converge, as some variance components are low. The work included 5-fold cross-validation. The metrics root mean square error of the cross validation $\left(predictiveefficiencyPE=\sqrt{\frac{{\sum }_{i=1}^N{({\widehat{y}}_i-y_i)}^2}{N}}\right)$ and predictive ability coefficient $PC=100.\left(\frac{cov(y_{predicted};y_{observed})}{S_{ypredicted}.S_{yobserved}}\right)$ were considered as described by Silva al. (2018Silva JL, Sanches A, Andrade ACB, Oliveira GHF, Mauro AOD2018 Bayesian approach, traditional method, and mixed models for multienvironment trials of soybean. Pesquisa Agropecuária Brasileira 53:1093-1100). Bayes prior II was chosen because it showed more accurate metrics than prior I. The choice of prior distribution was based on the suggestion of Hadfield (2021Hadfield JD2021 MCMC methods for multi-response generalized linear mixed models: the MCMCglmm R Package. Journal of Statistical Software 33:1-22), adding the extension parameters alpha.mu and alphaV. The choice of the model (prior) under the Bayesian approach was made considering the smallest root mean square error (RMSE), based on the smallest value of Deviance Information Criterion (DIC) between the models. The models were considered equal when |Δ| < 2 between their DIC (Spiegelhalter et al. 2002Spiegelhalter DJ, Best NG, Carlin BP, Van der Linde A2002 Bayesian measures of model complexity and fit (with discussion). Journal of the Royal Statistical Society: Series B 64:583-639). The predictive ability of the model was also considered in a 5-fold cross-validation. In each fold, randomly, 80% of the data was used for modeling, and 20% of the data was used to observe the discrepancy with the model prediction when choosing the prior. Thus, the average correlation between the predicted dependent variables and those observed for the cross-validation folds was considered. This same model choice approach was repeated when the frequentist and Bayesian models were compared, by performing a new cross-validation, but comparing the models by predictive ability and mean square error.

To verify the effects of row and column factors, each model was fitted with and without the technique (post-hoc blocking row-column). The comparison between the models was performed using the likelihood ratio test (LRT) using the statistic $\mathrm{L}\mathrm{R}\mathrm{T}\mathrm{}=\mathrm{}2\left[\mathrm{I}\mathrm{n}\right(\mathrm{M}\mathrm{o}\mathrm{d}\mathrm{e}\mathrm{l}\mathrm{}\mathrm{o}\mathrm{f}\mathrm{}\mathrm{i}\mathrm{n}\mathrm{t}\mathrm{e}\mathrm{r}\mathrm{e}\mathrm{s}\mathrm{t})\mathrm{}-\mathrm{}\mathrm{I}\mathrm{n}(\mathrm{M}\mathrm{o}\mathrm{d}\mathrm{e}\mathrm{l}\mathrm{}\mathrm{u}\mathrm{n}\mathrm{d}\mathrm{e}\mathrm{r}\mathrm{}\mathrm{H}\mathrm{o}\left)\right]$ , where LRT under Ho has an approximate Chi-Square distribution with 2 (two) degrees of freedom. As for Bayesian models, the choice and comparison of models was made by the Deviance Information Criterion (DIC) with several iterations equal to 7000000, thinning = 20, burn-in = 200000. To evaluate the percentage (index) of coincidences of the selected progenies, the common percentage of progenies was selected by the two estimation methodologies for each of the three levels of selection intensity: 37%, 25% and 15%.

All statistical analyses were performed using the R software (R Core Team 2019R Core Team2019 R: A language and environment for statistical computing. Viena: R Foundation for Statistical Computing. Available at <Available at https://www.r-project.org />. Accessed on January 29, 2021.
https://www.r-project.org... ) using the Sommer (Covarrubias 2016Covarrubias PG2016 Genome-assisted prediction of quantitative traits using the R package sommer. PLOS ONE 11:e0156744, 2018Covarrubias PG2018 Software update: moving the R package sommer to multivariate mixed models for genome-assisted prediction. BioRxiv bioRxiv [Preprint] 10.1101/354639.), MCMCglmm (Hadfield 2010Hadfield JD2010 "MCMC methods for multi-response generalized linear mixed models: the MCMCglmm R package." Journal of Statistical Software 33:1-22, Hadfield and Nakagawa 2010Hadfield JD, Nakagawa PD2010 General quantitative genetic methods for comparative biology: phylogenies, taxonomies and multi-trait models for continuous and categorical characters. Journal of Evolutionary Biology 23:494-508) and Imer4 (Bates et al. 2014Bates D, Mächler M, Bolker B, Walker S2014 Fitting linear mixed-effects models using lme4. Journal of Statistical Software 67:1-48) libraries. The convergence of the MCMC chains was checked by the criterion of Geweke (1992Geweke J1992 Evaluating the accuracy of sampling-based approaches to the calculation of posterior moments. In Bernardo JM, Berger JO, Dawid AP and Smith AFM (eds) Bayesian statistics. Clarendon Press, Oxford, p. 169-193) using the Coda package (convergence diagnosis and output analysis for MCMC, Plummer et al. 2006Plummer M, Best N, Cowles K, Vines K2006 CODA: convergence diagnosis and output analysis for MCMC. R News 6:7-11) and the DCCPs were obtained according to Hadfield (2010).

Genetic parameters

Some genetic parameters were estimated by both approaches, using the full or reduced model, according to their fit for each variable. If the full model was significantly different from the reduced model for a given variable, this full model was used to estimate the genetic parameters. Broad-sense heritability ( ${\widehat{\mathit{h}}}^2$ ) was estimated as shown below: ${\widehat{h}}^2=\frac{{\widehat{\sigma }}_{progeny}^2}{{\widehat{\sigma }}_{progeny}^2+{\widehat{\sigma }}_{block}^2+\mathrm{}{\widehat{\sigma }}_{column}^2+{\widehat{\sigma }}_{row}^2+{\widehat{\sigma }}_{error}^2}$ , where ( ${\widehat{\sigma }}_{error}^2$ ) is the estimate of residual variance; ( ${\widehat{\sigma }}_{block}^2$ ) is the estimate of variance due to the block factor; ( ${\widehat{\sigma }}_{column}^2$ ) is the estimate of variance due to the column factor; ( ${\widehat{\sigma }}_{row}^2$ ) is the estimate of the variance due to the row factor; and ${\widehat{\sigma }}_{progeny}^2$ is the estimate of genotypic variance.

Confidence intervals for heritability were obtained for the frequentist approach (CI- ${\widehat{h}}^2$ ) and the credible interval for heritability was obtained for the Bayesian approach. At the end, a ranking was created by selecting 30 individuals for which selection gain was obtained by the delta method, based on: $G_s=100.\left(\frac{{\stackrel{-}{X}}_{30}-{\stackrel{-}{X}}_G}{{\stackrel{-}{X}}_G}\right)$ , where selection gain is relative to the overall mean ( ${\stackrel{-}{X}}_G$ ) and the mean of the first 30 (thirty) progenies selected $\left({\stackrel{-}{X}}_{30}\right)$ .

RESULTS AND DISCUSSION

The significance of the factors (RCB + Row-Col) was tested by the likelihood ratio test (LRT) using chi-square statistics (Table 1). The full model was significant only for the production variables (NF and YLD), indicating that it had a better fit for these two variables (p<0.05). On the other hand, the Deviance Information Criterion (DIC) (Table 2) shows that the full model had a better fit for all variables, except PT and TSS.

With respect to the mixed-model approach, Silva et al. (2016Silva FHL, Muñoz PR, Vincent CI, Viana AP2016 Generating relevant information for breeding Passiflora edulis: genetic parameters and population structure. Euphytica 208:609-619) found the same results when the post-hoc blocking Row-Col technique was added to the model, that is, only the YLD and NF variables showed significance (p<0.05). Because both variables result from the total sum of the plot and are not sampled in fruits with a replicate, a variance was captured by Row-Col, which was not necessary when there were more observations in the other variables. Gezan et al. (2006Gezan SA, Huber DA, White TL2006 Post hoc blocking to improve heritability and precision of best linear unbiased genetic predictions. Canadian Journal of Forest Research 36:2141-2147) and Machado et al. (2020Machado RFC, Krause W, Silva CA, Fachi LR, Silva FHL, Viana AP2020 Implications of the post hoc blocking row-col technique on the intrapopulational improvement of the passion fruit. Euphytica 216:62), compared the efficiency of Row-Col with the randomized block design and obtained more accurate estimates of heritability using the former. However, in general, the randomized block design is efficient when the variability within the replicates is relatively small. This is a rare occurrence when a high number of genotypes is evaluated, especially in large-scale experiments, as is the present case. In this study, the post-hoc blocking Row-Col technique was more efficient to estimate genetic parameters, since when the observations were modeled via Bayesian models, only the variables TVS, PT, and TSS showed no significance for the RCB + Row-Col factor.

In this case, as it is the fourth cycle of recurrent selection, the estimates of genetic parameters (Tables 3 and 4) reveal that the greatest selection gains were obtained for YLD and NF. By the frequentist method, they also reveal the non-existence of genetic variability (or not captured by the model) and little selective potential among the passion fruit progenies under study, which is confirmed by the frequentist confidence intervals for heritability containing zero. This result could also be due to high environmental variation. This makes it difficult to fit a model properly, especially when this environmental variation results in data with a large standard deviation. Thus, the passion fruit breeder who sporadically may face high environmental variability, such as long periods of drought, high temperatures, and presence of diseases like CABMV, can opt for a model that, although more complex and computationally costly, will provide more accurate estimates.

For example, by comparing the estimates between the frequentist model (which is relatively simpler and less costly) against the Bayesian model, one can see that the highest posterior density (HPD) values had smaller amplitudes when compared to the confidence interval (CI) (Tables 3 and 4). This occurs due to the parametric space assumed by prior II. However, it is important to note that the selection gain estimates were very similar to those of the frequentist method, so it is the responsibility of the breeder to choose which parameters are of interest to him in order to choose which model will provide an approximate estimate, and a more accurate one.

Under the mixed-model approach, heritability estimates ranged from 0.05 to 0.26, with PT showing the highest value (0.26). Using the same experimental design, Silva et al. (2016Silva FHL, Muñoz PR, Vincent CI, Viana AP2016 Generating relevant information for breeding Passiflora edulis: genetic parameters and population structure. Euphytica 208:609-619) obtained divergent estimates in full-sib families of the same crop, describing values that ranged from 0.14 to 0.53. Selection gain ranged from -6.54% to 6.06%, with the highest results achieved by NF and YLD (6.06% and 5.89%, respectively). Under the Bayesian approach, these heritability estimates ranged from 0.04 to 0.11 and selection gain from -6.27% to 6.06%. Overall, the magnitude of the heritability estimates did not coincide between the two estimation methods, but selection gain estimates were close. The heritability estimates found for all traits are much lower than those described in the literature, which may be due to high environmental/experimental management influence or the polygenic nature of these variables. Heritability estimates were also lower than those reported by Viana et al. (2004Viana AP, Pereira TNS, Pereira MG, Amaral Júnior AT, Souza MM, Maldonado JFM2004 Parâmetros genéticos em populações de maracujazeiro-amarelo. Revista Ceres 51:545-555), which is explained by the fact that this is the fourth cycle of recurrent selection, when the variables are homogeneous for the desirable traits.

The analysis of the ranking of the first 30 selected progenies, according to Table 5, reveals consistency between the two winning methods. Differences in the selection of these progenies were not compatible. The coincidence rate between the progenies selected by the two methods ranged from 88.33% to 100%. When analyzing the 30 best progenies selected for each characteristic, progenies 89, 98, 92, 72, 58, 40, 4, 3, 100, 90, 59, 41, 23 and 9 form a set that shows a high genetic probability of being the best progenies in all evaluated traits. It is noteworthy that these results differ from those found by Silva et al. (2020Silva FA, Viana AP, Corrêa CCG, Carvalho BM, de Sousa CMB, Amaral BD, Ambrósio M, Glória LS2020 Impact of Bayesian inference on the selection of Psidium guajava. Scientific Reports 10:1-9) in guava crop, for which distinct sets of individuals were selected through the methodologies employed.

To evaluate the accuracy, reliability, and efficiency of the models, the study included the investigation of some statistics (metrics) that provide information on the selective and predictive accuracies of the models by the 5-fold method. Overall, the predictive ability (PA) and predictive efficiency (RMSE) metrics for each variable (Table 6) have practically the same magnitude by the two models, i.e., both have the same generalization ability. In the validation and training stages of cross-validation (5-fold), the models exhibited similar predictive ability for all variables, except FW PP, and TSS. The predictive ability of the models for the variables ranged from 6% to 40%.

CONCLUSION

From the standpoint of the frequentist and Bayesian models, the post-hoc blocking Row-Col technique captured the existing variability for the variables yield and number of fruits, for which it had a direct impact on experimental precision.

The tested models select practically the same individuals, which shows that the two estimation methods are equivalent for this structure of observations.

Overall, the parameterization of priors reduced the root mean square error, increased the correlation between observed and predicted values, and decreased the deviance information criterion for the models, compared with prior distribution I (Inverse Gamma).

FUNDING

The present study was supported by the Coordination for the Improvement of Higher Education Personnel - Brazil (CAPES) - Finance Code 001 and the Carlos Chagas Filho Foundation for Research Support of the State of Rio de Janeiro (Faperj).

REFERENCES

Publication Dates

History