We included a total of 308 participants, recruited from among the relatives/friends of patients attended at the neurology department of Hospital del Mar in Barcelona, and patients cared for at adult care centres of the city of Barcelona. Recruitment was conducted considering pre-specified groups (random sampling to divide participants according to sex, age, and level of education). All participants were white, and they all lived and were raised in Spain. The project was approved by the ethics committee of the medical research institute of Hospital del Mar, in Barcelona (Spain).

The following selection criteria were applied:

1) individuals giving informed consent; 2) men and women aged 18–95 years; 3) Spanish speakers with sufficient ability to read and write (reported during the initial interview and confirmed by a reliable history of at least one year of formal seducation); and 4) independent for the activities of daily living, according to the Interview for Deterioration of Daily Living Activities in Dementia (score < 37).25

The exclusion criteria were as follows: 1) history of central nervous system disease potentially causing neuropsychological deficits (e.g., stroke, epilepsy, traumatic brain injury, movement disorders, multiple sclerosis, brain tumours, etc.); 2) history of abuse of alcohol or other psychotropic substances; 3) presence of active or poorly controlled systemic disorders associated with cognitive impairment (e.g., diabetes mellitus, hypothyroidism, B12 deficiency); 4) history of severe psychiatric disorders (e.g., major depressive disorder, bipolar disorder, psychosis); 5) severe sensory deficits (vision and/or hearing loss) interfering with cognitive test performance; 6) scores < 25 points on the Mini-Mental State Examination (MMSE)26 (version proposed by Blesa et al.27) or < 5 points on the Memory Impairment Screen (MIS)28 (Spanish-language version29); and 7) any other reason that, in the authors’ judgement, should preclude inclusion (e.g., lack of motivation). Participants did not receive compensation for their participation in the study.

Tests were administered and scored according to the published manuals, with the exception of DT, which is an experimental task that was designed ad hoc. The research group translated the original instructions from English into Spanish, with the following methodology. First, a researcher drafted the first version of the instructions for each test. A consensus meeting was subsequently held with the rest of the clinical neuropsychologists, as well as 2 linguists, and a consensus version was proposed for each test. A behavioural neurologist with experience in the development of cognitive tests reviewed the instructions and approved the final version for each test. Due to the non-verbal nature of the tests, none of their elements required linguistic adaptation. All tests were administered by trained neuropsychologists who were native Spanish speakers.

The DK-DFT includes 3 conditions: basic, inhibition, and switching. For each condition, the examinee is given a sheet containing 35 boxes with a set of dots, and asked to create as many different designs as possible within 60 seconds, using only 4 straight lines to connect the dots in each box. Each line must be connected to the previous line by a dot, and lines can intersect. Designs do not need to be closed patterns, and they can be abstract.

In the basic condition (filled dots), each box contains 5 black-filled dots, and examinees are asked to create different designs by connecting these dots. In the inhibition condition (empty dots), each box contains 5 black-filled dots and 5 empty dots; participants are instructed to create different designs connecting the empty dots only, ignoring the black-filled dots (these are used in the previous condition). In the switching condition, each box contains 5 black-filled dots and 5 empty dots, but in this case participants are instructed to create different designs, switching from connecting filled dots or empty dots. Before each condition is administered, the participant completes 3 boxes as a practice exercise, with the examiner giving feedback on whether responses are correct. We gathered the total number of correct designs for each condition to establish normative data.

The CTT has 2 parts, CTT-1 and CTT-2, with both including a practice task. In CTT-1, the participant must draw a line to connect a series of circles, numbered 1 to 25, in ascending order, in the shortest time possible and without lifting the pen. In CTT-2, the participant is shown 2 circles for each number, one in yellow and the other in pink, and is instructed to connect the numbered circles, alternating between pink and yellow circles. In both parts of the CTT, the main variable is the time (in seconds) taken to complete the task.

The DT consists of 3 parts. The first 2 tasks (single-task condition) are relatively simple. In the third task, tasks 1 and 2 must be performed simultaneously (dual condition). The first 2 tasks consist of a digit span task (using the maximum verbal span) and a cancellation task. The worksheets are available upon request from the authors.

To determine the maximum verbal span, we administered the Spanish-language adaptation of the digit span test30 according to the standard procedure described in the WAIS-III manual,31 that is, 2 trials are administered for each span length regardless of whether the examinee correctly completes the first trial. Subsequently, we administered the first part of the test (verbal single-task condition), in which the participant is given 60 seconds to repeat series of digits of the maximum span length achieved previously. As the number of series varies depending on span length and the time taken to repeat the series, performance is measured according to the proportion of digits repeated in the correct position (total number of digits repeated in the correct order divided by the total number of digits presented by the examiner), rather than the number of correct series.

In the cancellation task, 2 sheets containing a row of silhouettes (animals and fruits) are placed horizontally. The participant is given 60 seconds to mark with a pencil all silhouettes matching the object. The main variable is the total number of matching silhouettes marked in the allotted time.

Lastly, in the dual-task condition, participants must perform the digit span task (maximum span) and the cancellation task simultaneously for 60 seconds. The variables included in our normalisation study were number of digits repeated in the correct order and number of correctly identified silhouettes.

Proportional performance in the digit span task (P digits) was estimated by measuring the change between performance on the single-task condition (p single-task) and the performance on the dual-task condition (p dual-task) using the following formula, where p is the proportion of digits repeated in the correct order divided by the digit span presented by the examiner:

Formula for P digits:

Proportional performance on the cancellation task (P cancellation) was estimated by calculating the change in performance between the single-task condition (t single) and the dual-task condition (t dual, defined as the total number of silhouettes correctly identified), using the following formula:

Formula for P cancellation:

The proportional performance of the combination of both tasks (P dual), which is the main outcome variable considered in the normative data, was calculated with the following formula:

Formula for P dual:

All assessments were conducted in a single session, in which participants were informed about the study and gave written informed consent. After that, they underwent an initial interview and were screened for eligibility. The cognitive test battery was administered to individuals meeting all the inclusion criteria and none of the exclusion criteria. Assessment took approximately 2 hours.

Normative data were calculated according to the procedures described in the NEURONORMA project,1,2 although with slight variations, such as the use of semi-partial rather than univariate correlations to study associations with sociodemographic variables, and the use of the mean number of years of schooling of each group to adjust for level of education. To analyse the effect of sociodemographic variables on cognitive test performance, the sample was classified into 2 groups: individuals aged < 50 years (n = 118) and those aged ≥ 50 years (n = 190). This ensures the comparability of our data with those reported in previous normative studies within the NEURONORMA project, and achieves a more precise differentiation of the effect of ageing and level of education among younger and older adults.

We applied the overlapping interval strategy to maximise the number of participants included in each normative group.32 We considered 10 age groups for the creation of normative data (mid-points): 18–29 years (n = 41), 23–36 (n = 59), 30–43 (n = 48), 37–50 (n = 53), 44–57 (n = 61), 51–64 (n = 71), 58–71 (n = 83), 65–78 (n = 74), 72–85 (n = 68), and 79–92 (n = 40). We also established 10 new age ranges to study the applicability of normative data: 18–26, 27–33, 34–40, 41–47, 48–54, 55–61, 62–68, 69–75, 76–82, and 83–92.

Normative data were established according to the following procedure: 1) Descriptive analysis (mean, standard deviation, and percentages for the total sample and for each age group). 2) Determination of the effect of age, sex, and level of education with semi-partial correlations and the coefficient of determination (r2). 3) Creation of age-adjusted normative tables, assigning percentile ranks to NEURONORMA (age-adjusted) scaled scores (SS); this conversion resulted in a normal distribution of scores (range, 2–18; mean = 10; SD = 3). 4) For the purposes of adjusting data for level of education, we performed linear regression analyses between SS and level of education. We calculated the correlation coefficient (r) and the coefficient of determination (r2) of SS for each age group (< 50/≥ 50 years). When the explained variance was greater than 5% and β showed a significant effect (P < .05), data were corrected using the formula developed by Mungas et al.33 Age- and education-adjusted NEURONORMA SS were calculated using the formulae education-adjusted SS = age-adjusted SS – (β* [years of schooling – 13]), for the group of participants aged < 50 years, and education-adjusted SS = age-adjusted SS – (β* [years of schooling – 10]), for participants aged ≥ 50 years, with the values 13 and 10 being the mean number of years of schooling in each group. 5) To adjust for sex, we compared mean raw scores between men and women. When significant differences were found, a regression analysis was performed using age-adjusted or age- and education-adjusted SS as the dependent variable and sex as predictor; the criteria r2 ≥ 5% and β (P < .05) were used to decide whether adjustment for sex was needed. Thus, age-, sex-, and education-adjusted SS were calculated with the following formulae: Age- and education-adjusted SS – (β* sex), or age-adjusted SS – (β* sex), depending on which factors showed a significant association. Statistical analysis was completed using the Statistical Package for Social Sciences (SPSS) software, version 22.

Age showed a negative effect on DK-DFT performance. Scores were significantly lower in the group of older adults. These findings support the data presented by the authors of the test.10 Our results are consistent with those reported by previous studies on the effect of sociodemographic variables on other neuropsychological tests evaluating non-verbal fluency.4–15 Individuals with higher levels of education performed better on the test. This finding is also consistent with previous research on the effect of education on other tests for non-verbal fluency.8,9 In the group of younger adults, sex was found to have a discrete effect on one condition only (inhibition), with men performing better than women, as reported by Harter et al.34

As described in previous normative studies,16,35–39 age had a negative effect on the time taken to complete both CTT-1 and CTT-2 in the older group, but had no effect on CTT-1 performance in younger adults. Level of education had a moderate effect on CTT-2 performance but not on CTT-1 performance in both age groups, which suggests that completing the CTT-2 requires a higher educational level. No sex-related significant differences were found between groups; this is consistent with most published studies,16,36–39 with the sole exception of the study by Sant’Ana Rabelo et al.,35 who found that men scored higher in both parts of the CTT. In that study, which included nearly 2000 participants, only 19% of whom were men, the authors suggest that the higher level of education of men as compared to women may constitute a source of bias. In fact, this factor, together with the study’s great statistical power as a result of its large sample size, may explain why the researchers found significant sex differences despite the small effect sizes.

Despite the differences between the CTT and the TMT, it is interesting to compare our results on the CTT against those presented for the TMT in previous NEURONORMA studies.40,41 In general terms, the time taken to complete the CTT is similar, though slightly shorter than the time needed to complete the TMT (e.g., for scores around the median); for example, in the CTT-1, a scaled score of 10 corresponds to 35–40 seconds taken to complete the test in the 48–54 years age group, whereas in the TMT-A, the same scaled score corresponds to 36–46 seconds in individuals aged 50–56 years.40 The differences in test completion times are more apparent in the second, more complex, part of the CTT. According to normative data, participants consistently took less time to complete the CTT-2 than the TMT-B; for example, a scaled score of 10 corresponds to 66–84 seconds on the CTT-2 and 80–107 seconds on the TMT-B. Although these data are from different samples, which makes the tests only partially comparable, they suggest that the TMT-B is more complex than the CTT-2. We may therefore hypothesise that this added complexity is derived from the need to know the alphabet to complete the test and the fact that the TMT-B requires the examinee to alternate between numbers and letters, whereas in the CTT-2, the examinee must alternate between numbers and 2 colours. Regarding the effect of sociodemographic variables, both age and, especially, level of education had a greater impact on TMT performance40 than on CTT performance (for example, for individuals older than 50 years, the TMT-B showed a correlation with the education level of r = 0.52, compared to r = 0.35 in the case of the CTT-2). This further supports the superiority of the CTT for evaluating individuals with low levels of schooling or literacy.

As expected, our results revealed slightly poorer performance for the dual-task condition. As in previous studies, age was found to have no effect, which suggests that the skills evaluated with this paradigm are not affected by ageing.20,23,42,43 However, these results stand in contrast with those of other studies reporting poorer performance on dual tasks in older adults.44–46 Level of education was found not to influence test performance, whereas sex did have a small effect, with women performing slightly better; as a result, scores were adjusted in the group of men under the age of 50 years. This finding stands in contrast with those of previous studies23 reporting level of education to have a positive influence and sex to have no effect. This may be explained by differences in the nature of the tasks and the characteristics of the samples. The difficulty of the task used in this study is adjusted to the capacities of each participant, focusing on intraindividual differences between single- and dual-task performance; this is one of the strengths of our study and may explain the lack of differences in performance between age groups.