Symbol Digit Modalities Test: Normative data for the Latin American Spanish speaking adult population

2.1Participants

The sample consisted of 3,977 healthy individuals who were recruited from Argentina, Bolivia, Chile, Cuba, El Salvador, Guatemala, Honduras, Mexico, Paraguay, Peru, and Puerto Rico. The participants were selected according to the following criteria: a) were between 18 to 95 years of age, b) were born and currently lived in the country where the protocol was conducted, c) spoke Spanish as their native language, d) had completed at least one year of formal education, e) were able to read and write at the time of evaluation, f) scored ≥23 on the Mini-Mental State Examination (MMSE, Folstein, Folstein, & McHugh, 1975), g) scored ≤4 on the Patient Health Questionnaire–9 (PHQ-9, Kroenke, Spitzer, & Williams, 2001), and h) scored ≥90 on the Barthel Index (Mahoney & Barthel, 1965).

Participants with self-reported neurologic or psychiatric disorders were excluded due to a potential effect on cognitive performance. Participants were volunteers from the community and signed an informed consent form. Twelve participants were excluded from the analyses, with a final sample of 3965 participants. Socio-demographic and participant characteristics for each of the countries’ samples have been reported elsewhere (Guárdia-Olmos, Peró-Cebollero, Rivera, & Arango-Lasprilla, 2015). The multi-center study was approved by the Ethics Committee of the coordinating site, the University of Deusto, Spain.

2.2Instrument administration

The SDMT test consists of converting symbols with shaped geometric figures in numbers. This substitution can be applied orally or in writing. This study used normative data for the written form. When administrating the test, confirmation that the subject is marking the answers in the order given and without skipping any lines is necessary. The subject’s score is the number of correct substitutions made at an interval of 90 seconds.

2.3Statistical analyses

The detailed statistical analyses used to generate the normative data for this test are described in Guàrdia-Olmos et al. (2015). In summary, the data manipulation process for each country-specific dataset involved five-steps: a) t – tests for independent samples and effect sizes (r) were conducted to determine gender effects. If the effect size was larger than 0.3, gender was included in the model with gender dummy coded and female as the reference group (male = 1 and female = 0); b) A multivariable regression model was used to specify the predictive model including gender (if effect size was larger than 0.3), age as a continuous variable, and education as a dummy coded variable with 1 if the participant had >12 years of education and 0 if the participants had 1–12 years of education. If gender, age and/or education was not statistically significant in this multivariate model with an alpha of 0.05, the non-significant variables were removed and the model was re-run. Then a final regression model was conducted that included age (if statistically significant in the multivariable model), dichotomized education (if statistically significant in the multivariate model), and/or gender (if effect size was greater than 0.3) [y∧i=β0+(βAge·Agei)+(βEduc·Educi)+(βGender·Genderi)] ; c) residual scores were calculated based on this final model ( ei=yi-y∧i ); d) using the SD_e (residual) value provided by the regression model, residuals were standardized: z = e _i /SD _e , with SD _e (residual) = the standard deviation of the residuals in the normative sample; and e) standardized residuals were converted to percentile values (Strauss et al., 2006). Using each country’s dataset, these steps were applied to SDMT scores.

3.1Normative procedure

Norms (e.g., a percentile score) for the SDMT score test were established using the five-step procedure described above. To facilitate the understanding of the procedure to obtain the percentile associated with a score on this test, an example will be given. Suppose you need to find the percentile score for a Mexican woman, who is 25 years old and has 13 years of education. She has a score of 40 on the SDMT test. The steps to obtain the percentile for this score are: a) Check Table 1 to determine if the effect size of gender in the country of interest (Mexico) on this test and time point (SDMT) is greater than 0.3 by country. In this example, the effect size is 0.077, which is not greater than 0.3. For Mexican on this test, gender does not influence scores to a sufficient degree to take it into account when determining the percentile. b) Find Mexico in Table 2, which provides the final regression models by country for SDMT. Use the B weights to create an equation that will allow you to obtain the predicted SDMT score. The corresponding B weights are multiplied by the actual age and dichotomized education scores and added to a constant in order to calculate the predicted value. In this case, the predicted SDMT score would be calculated using the equation [y∧i=60.802+(-0.471Agei)+(6.229Dichotomized Educational Leveli)] (the values have been rounded for presentation in the formula).The subscript notation i indicates the person of interest. The person’s age is 25, but the education variable is not continuous in the model. Years of education is split into either 1 to 12 years (and assigned a 0) or more than 12 years (and assigned a 1) in the model. Since our hypothetical person in the example has 13 years of education, her educational level value is 1. Thus the predicted value is y∧i=60.802+(-0.471·25)+(6.229·1)=60.802-11.778+6.229=55.25 . c) In order to calculate the residual value (indicated with an e in the equation), we subtract the actual value from the predicted value we just calculated ( ei=yi-y∧i) . In this case, it would be e _i  = 40 - 55.25 = -15.25. d) Next, consult the SD _e column in Table 2 to obtain the country-specific SD _e (residual) value. For Mexico it is 12.012. Using this value, we can transform the residual value to a standardized z score using the equation (e _i /SD _e ). In this case, we have (-15.25)/12.012 = -1.269. This is the standardized z score for a Mexican woman aged 25 and 13 years of education and a score of 40 on the SDMT test. e) The last step is to use look-up the tables in the statistical reference books (e.g. Strauss et al., 2006) or use a trusted online calculator like the one available at http://www.measuringu.com/pcalcz.php. In the online calculator, you would enter the z score and choose a one-sided test and note the percent of area after hitting the submit button. In this case, the probability of -1.269 corresponds to the 10th percentile.

3.2User-friendly normative data tables

The five-step normative procedures explained above can provide more individualized norms. However, this method can be prone to human error due to the number of required computations. To enhance user-friendliness, the authors have completed these steps for a range of raw scores based on small age range groupings (see Guàrdia-Olmos et al., 2015) and created tables so that clinicians can more easily use to obtain a percentile range associated with a given raw score on this test. These tables are available by country and type of test (SDMT) in the Appendix. In order to obtain an approximate percentile for the above example (converting a raw score of 40 for a Mexican women who is 25 years old and has 13 years of education) using the simplified normative tables provided, the following steps are recommended. (1) First, identify the appropriate table ensuring the specific country and test. In this case, the table for SDMT scores for Mexico can be found in Table A8. (2) Note if the title of the table indicates that it is only to be used for one specific gender. In this case, gender is not specified. Thus Table A8 is used for both males and females. (3) Next, the table is divided based on educational level (1 to 12 vs. more than 12 years of education). Since this woman has 13 years of education, she falls into the more than 12 years of education category. These data can be found in the top section of the table. (4) Determine the age range most appropriate for the individual. In this case, 25 falls into the column 23–27 years of age. (5) Read down the age range column to find the approximate location of the raw score the person obtained on the text. Reading down the 23–27 column, the score of 40 obtained by this Mexican woman corresponds to an approximate percentile of 10.

4.1Limitations and future directions

This study has several limitations, and as a result directions for future research. First, this study was subject to a number of sampling limitations. Participants had Spanish as their primary language, and SDMT performance could differ among people with various languages, bilingualism, or local dialects such as Quechua or Guaraní. A ripe area for future research is bilingualism and SDMT performance. Also, the data were collected in various regions of the countries in this study, as opposed to nationally. Although this study was the largest neuropsychological normative study in the history of Latin America, or of any global region, it is only a first step in conducting more rigorous, larger studies with nationally representative samples. Although many participants had fewer than 12 years of education, those who were unable to read or write were excluded; thus, the SDMT norms cannot generalize to illiterate populations. Similarly, all participants in the current study were healthy adults, so future studies need to include populations with neurological conditions, as well as children. Future research may also assess participants’ bilingualism, which was not controlled for or examined.

Second, clinicians should be cautious about using the norms of the SDMT from the current study in countries in Latin America beyond the 11 countries from which data were collected. In the future, it is important to establish SDMT norms in other countries such as Ecuador, Uruguay, Venezuela, and Panama. Nonetheless, the current SDMT norms may be more accurate in these countries than other norms from Spain or English-speaking countries that may currently be in use; future research should nonetheless investigate the generalizability of the current norms.

Third, despite the SDMT’s commonness in Latin America, many other assessments are also common and need to be normed in the same manner. It is important that future research examine the psychometric properties of common neuropsychological instruments in Latin America, even at the individual item level. Research should also examine whether neuropsychological assessments have good ecological validity, or develop instruments in those cultures with higher ecological validity. The SDMT was created in a Western culture that may be different from the various cultures in Latin America. Future research should develop more culturally sensitive assessments bound in local cultures, not solely translate and norm tests from other cultures and countries.

Despite these limitations and although previous studies have produced Spanish-language norms for the SDMT in Spain with healthy adults (Smith, 2002), the current study was the first to generate SDMT norms across 11 countries in Latin America with nearly 4,000 participants. This study was the largest and most comprehensive SDMT normative study to date in any global region, and its norms have the potential to affect the standard of neuropsychological assessment with the SDMT in Latin America unlike any study before it.