Version B was created based on the original Spanish-language version of the FCSRT.11 This parallel version used the same semantic categories as version A. In version A, words from each category were chosen based on their lexical frequency according to the study of categories and norms of the Spanish language published in 1994 by Soto et al.12 All words were within the second third of word frequency. The 16 words used in version B were selected based on lexical frequency, prototypicality, and practicality. A basic principle for tests providing category cues is to avoid selecting prototypical words for each category, in order to minimise the number of correct responses given by chance. The word list was created by 2 linguists and 2 clinical researchers specialising in neuropsychology. They first determined updated frequencies of the words included in version A using the Royal Spanish Academy’s Reference Corpus of Contemporary Spanish (CREA, for its Spanish initials: http://web.frl.es/CREA). The researchers then created groups of new words for each semantic category and determined their frequencies to select words with similar frequencies to those included in version A. The analysis of lexical frequency was performed using the subcorpus specific to Spain. Researchers then reached a consensus on which words to include in version B, avoiding polysemic words or those that are difficult to read or pronounce (Table 1).

The test was administered according to the administration instructions, which were adapted from the original instructions11 developed for the NEURONORMA project.13 The task includes 6 different phases: (1) reading and identification of words, (2) interference, (3) free recall, (4) cued recall, (5) selective recall of non-recalled words, and (6) delayed free and cued recall 30minutes later. Phases 2–5 are repeated 3 times during the learning process. The examiner gives the following instructions: “You are going to memorise 16 words. Each word belongs to a different category. I am going to tell you the names of the categories, and I want you to tell me which word belongs to each category. After that, I want you to say as many words as you can remember; it does not matter what order you say them in. When you have finished, I am going to remind you of the categories to help you remember any word that you may have left out. After that, I will tell you any words that you may have forgotten and you will try to memorise them again. You have 3 attempts to memorise all the words.” (1) Reading and identification of words: a card with the first 4 words is placed in front of the examinee, who is asked to read them aloud. The examinee is then provided with the name of each category; he or she must indicate which word belongs to which category. The same procedure is repeated for the remaining 3 cards. If the examinee is unable to identify all categories, the task is interrupted. (2) Interference: after identification, the examinee is asked to perform a serial subtraction task (eg, counting backwards from 100 by serial threes) for 20seconds to prevent subvocal repetition. (3) Free recall: the examinee is asked to say as many words as he or she can remember, in any order, with a time limit of 90seconds. The task is interrupted if the examinee is unable to say any word for 15seconds. Before the second and third free recall trials, the examinee is asked to complete the interference task described above, only changing the starting number (e.g., 99). (4) Cued recall: immediately after each free recall trial, the examinee completes a cued recall task for the items that he or she was unable to recall spontaneously. The examiner provides a category cue for each word the examinee was unable to recall. (5) Selective recall: the examiner provides the items that were not recalled with cues. The selective recall task is only completed in the first 2 trials. (6) Delayed recall: approximately 30minutes (±5) later, the examinee completes another free and cued recall trial. After completing the 3 learning trials, the examinee is informed that he or she will have to recall the words at a later time.

Data are obtained for 6 variables: free recall trial 1 (FR1; range 0–16), total free recall (TFR; sum of the number of words recalled in all 3 free recall trials; range, 0–48), total recall (TR; sum of the total number of words recalled freely and after cueing in all 3 trials; range, 0–48), delayed free recall (DFR; range, 0–16), total delayed recall (TDR; sum of the number of words recalled freely and after cueing in the delayed recall trial; range, 0–16); and retention index (RI; TDR/total recall in the third trial; range, 0–1). Our study includes data for the first 5 variables.

Due to the differences observed in the equivalence study, we created normative tables for version B, following the NEURONORMA model. The procedure is summarised below. We used the overlapping age group approach,14 in which individuals provide data to more than one norm group. Ten age ranges were established (18-26 years, 27-33, 34-40, 41-47, 48-54, 55-61, 62-68, 69-75, 76-82, and 83-91). For each age group, we created tables of cumulative percentages, to which we assigned NEURONORMA age-adjusted scaled scores (NSSA), ranging from 2 to 18; the data followed a nearly normal distribution, with a mean of 10 (standard deviation, 3). These distributions were used for the linear regression analysis, with years of schooling and sex as predictors to make adjustments where necessary. As with previous analyses of the NEURONORMA project, the sample was split into 2 groups for the linear regression study: individuals younger than 50, and those aged 50 and older. The reason for this division is the difference in education level between young adults and older individuals. We adjusted the scaled scores when the percentage of variation explained by the predictor variable (r2) exceeded 5% and the B coefficient was significant (P<.05). Sex was not found to have a significant effect on any variable according to this criterion. Education, on the contrary, did show an effect. To adjust for education level, we applied the following formulas, using each group’s mean number of years of schooling for adjustment: NSSA&E = NSSA − (B1×[educ − 10]) for individuals aged 50 years and older, and NSSA&E=NSSA − (B2×[educ − 13]) in those younger than 50, with B representing the value of the coefficient obtained in the regression. In all cases, corrections were truncated to the next lowest integer.

Table 1 shows both word lists (versions A and B) and the corresponding semantic categories and the base 10 logarithms of the frequency per million words + 1 according to data from the CREA corpus (we added 1 to avoid negative values). Cumulative (A=11.45; B=10.99) and mean frequencies (A=0.72; B=0.69) were similar in both lists, as were the total number of syllables and letters (A: 45 syllables and 113 letters; B: 50 syllables and 116 letters).

Table 2 shows descriptive data from sociodemographic variables and screening tests. It includes data from the total sample and the subgroup of individuals used in the equivalence study. The latter group presented a lower mean age than the total sample, although the difference was not significant (52.4 vs 55.3 years), and included more women (70% vs 53.4%; P<.05). The remaining cognitive and sociodemographic variables showed no significant differences between the total sample and the subgroup used in the equivalence study. FCSRT results are shown in Table 3. In the total sample, the mean total recall score was 43.21, which is equivalent to free or cued recall of 90% of information (maximum score of 48). All variables showed significant negative correlations (P<.05) with age (FR1, r=−0.45; TFR, r=−0.56; TR, r=−0.43; DFR, r=−0.50; TDR, r = −0.36) and positively correlated with education level (FR1, r=0.31; TFR, r=0.39; TR, r=0.32; DFR, r=0.39; TDR, r=0.30). No significant correlations were observed with sex. Normative data tables for each variable are shown in Supplementary Tables S1 to S5; adjustments for education are shown in Supplementary Tables S6 to S11.

Intraclass correlation coefficients for the relationship between both versions of the FCSRT were as follows: TR, 0.89 (95% CI, 0.79-0.94); TFR, 0.82 (95% CI, 0.66-0.91); TDR, 0.75 (95% CI, 0.56-0.87); DFR, 0.8 (95% CI, 0.64-0.90); and FR1, 0.57 (95% CI, 0.29-0.76). In the equivalence study, participants performed better in version A than B for free recall (P<.05). The mean difference between versions was 2.63 words for TFR, 0.97 words for FR1, and 0.93 words for DFR; accounting for the pooled standard deviation, this is equivalent to an effect size (Cohen’s d) of 0.37, 0.42, and 0.32, respectively. However, no significant differences were observed when data for cued recall were included (TR, TDR).

We developed the word list for version B based on lexical frequency, prototypicality, and practicality. Although frequency is an objective means of assessing difficulty recalling a word, this approach is not without limitations. Some values did not coincide with the perceived frequency and difficulty of the words in spoken language. This is probably because frequencies were calculated using the CREA corpus, which is based on written texts only, and the differences between written and spoken language are not accounted for. Other psycholinguistic aspects not considered in our study, such as familiarity or age at language acquisition, may also affect an individual’s ability to recall words. Word length and number of syllables are also relevant factors; both versions of the FCSRT showed similar values overall.

We studied the performance of 232 healthy individuals in the FCSRT version B, and its correlation with sociodemographic variables. According to our results, older age has a negative effect on test performance, whereas years of schooling are positively correlated with FCSRT scores. Our results are similar to those reported by the NEURONORMA study for FCSRT version A. The sample used for version A (n=517; 340 individuals > 50 years and 177 individuals < 50 years) showed similar performance to that used in version B (FR1: 6.91 [2.63]; TFR: 26.77 [8.05]; TR: 41.59 [5.95]; DFR: 10.30 [3.56]; TDR: 14.37 [2.15]; data not published), supporting the equivalence between versions. Likewise, correlations with sociodemographic variables were similar in both versions, though they were slightly stronger in version A (version A [n=517]; age: FR1, r=−0.57; TFR, r=−0.67; TR, r=−0.55; DFR, r=−0.64; TDR, r=−0.49; education: FR1, r=0.39; TFR, r=0.45; TR, r=0.43; DFR, r=0.42; TDR, r=0.40; data not published).

The equivalence study showed high intraclass correlation coefficients (ranging from 0.8 to 0.9) for the main variables. Scores in free recall tasks were significantly higher in version A than in version B. This suggests that free recall of version A items is easier, possibly due to greater familiarity or actual frequencies of the words included (irrespective of CREA data). In diagnosis of AD, the phenomenon showing greatest specificity is the inability to use semantic cues or recognition during memory tasks,15 which is reflected by total recall in the FCSRT; it has been suggested that free recall may be more sensitive in early stages of the disease.16 Version B may be regarded as equivalent to version A in terms of total recall scores after cueing; equivalence is less clear for free recall scores. Our intention for this parallel version was to demonstrate its equivalence to version A, with a view to obtaining normative data that may be applied to either of the 2 versions. However, in view of our results and pending further information on the equivalence of both versions, we provide normative data for FCSRT version B, based on the NEURONORMA methodology (Supplementary Tables S1-S11). To use this data for version A, we recommend adjusting data before conversion to scaled scores (+2 points for TFR and +1 point for DFR). Adjusting scores for different versions of neuropsychological instruments is common practice, especially in such widely used screening test batteries as the Repeatable Battery for the Assessment of Neuropsychological Status.17