Neuropsychological evaluation is a complex task requiring different assessment methods adapted to the disease under study, to the evaluator's objectives, and to the patient's status. The length and thoroughness of a neuropsychological evaluation of cognitive function depends on the complexity of the studies and instruments used; ideographic studies, complex or simple test batteries, functional scales, and brief scales1 are the most frequent tools. The evaluator must also be familiar with the principles of neuropsychometric assessment and be able to apply them to the use of tools validated and normalised for the population under study. This task requires a multidimensional approach and is much more complex than simply administering a test.

The most frequently recommended method for neuropsychometric assessment of dementia is the use of a multidimensional test battery with psychometric properties including sensitive tests for each cognitive area.2 The assessment tools used in Spain include the Barcelona Test (Programa Integrado de Exploración Neuropsicológica-Test Barcelona), in both the originall,2 and short forms,3 and such other short test batteries as the Repeatable Battery for the Assessment of Neuropsychological Status (RBANS),4 the Mattis Dementia Rating Scale,5 and the Cambridge Cognitive Examination, included in the Cambridge Mental Disorders of the Elderly Examination,6 for the evaluation of cognitive impairment in different populations; and others specifically designed for evaluating people with dementia, such as the Alzheimer's Disease Assessment Scale7 and the Consortium to Establish a Registry for Alzheimer's Disease.8

The RBANS has several advantages over the other batteries. It is a multidimensional method and includes 4 alternative forms (forms A, B, C, and D) in order to avoid the learning effect in repeated evaluations. It is easy to administer; administration time ranges from 20 to 30minutes, and it is administered on a one-on-one basis.9 The RBANS has been translated into several languages and validated for different countries and continents, including Australia,10 Russia,11 Asia,12–14 Turkey,15 and Spain.16,17 A study providing normative data for the Spanish-language version of the RBANS (RBANS-E) has recently been published.16 The study presents normative data for patients aged 20-89 years, classified into 6 age groups (10-year age ranges, except for the 20-39 age group). However, normative data for individuals older than 60 years are based on small samples (ranging from 40 to 44 individuals). The purpose of this study was to provide new normative data for a larger number of age groups (3-year age ranges). To optimise the normative sample for each age group, we followed the methodology used in the NEURONORMA project.18

Application of the inclusion and exclusion criteria left a sample of 609 healthy individuals aged 20-89 years: 273 men (mean age [SD], 52.42 [19.49]; mean years of schooling [SD], 11.38 [5.63]) and 336 women (mean age, 50.51 [18.17]; mean years of schooling, 10.66 [5.40]). Right-handed individuals accounted for 96.7% of the sample; 2.1% were ambidextrous and 1.1% were left-handed. Table 1 describes the demographic characteristics of our sample.

Table 2 shows the correlation coefficients and the coefficients of determination for the different RBANS subtests and the sociodemographic variables age, sex, and years of schooling. All scores analysed shared over 5% of the variance with age, indicating the need for a different norm for each age group. Norms were corrected for years of schooling, as this variable also shared over 5% of the variance with all RBANS subtest scores, except for the “picture naming” subscale. Adjustment for sex was not necessary (Table 2).

Norms for some of the 20 age groups are shown in Tables 3–5.

Table 6 shows the corrections to be applied to RBANS scaled scores according to years of schooling. The values obtained in Table 6 must be added to the scaled values obtained in Tables 3–5. Let us assume, for example, that a person obtains a raw score corresponding to a scaled score of 5 for the “list learning” subscale. If that person had 5 years of schooling, the corrected scaled score would be 5+1=6. If the education level were 17 years of schooling, the corrected scaled score would be 5−1=4. Note that scaled values in the “picture naming” subtest are not corrected for years of schooling.

Regarding sociodemographic variables, age and education level had a statistically significant influence in all subtests; this was not true for patients with 9-13 years of schooling, however. Furthermore, in patients with 8 and 14 years of schooling, education level only influenced “coding” subscale scores.

This study provides new normative data for Spanish individuals aged 20-89 years. Our sample was selected using strict inclusion and exclusion criteria.

One of the limitations of our study is the selection of healthy participants. Firstly, given that some participants were related to patients with dementia, we may hypothesise that a genetic component may act as an uncontrolled bias, although we cannot be certain that the relatives had begun or were going to develop the disease, nor that they had cognitive alterations typical of the disease that may affect test performance.

Furthermore, the MMSE cut-off point used as an inclusion criterion (≥24, widely recognised as a highly sensitive cut-off point for differentiating between dementia and normal cognitive function19 and also used as an inclusion criterion in other Spanish normative studies29) may not be the most appropriate tool since it may not be sufficiently sensitive in differentiating between mild cognitive impairment and normal cognitive function. This underlines the importance of the remaining inclusion and exclusion criteria. The purpose of the selection criteria was to gather a sample with scores lying around the middle of the normal distribution (rather than at the extremes), which would ensure greater adaptation of the norms to the general population.

According to an observational analysis of the norms obtained for each subtest, some scores that would indicate cognitive impairment in other neuropsychological tests indicated normal cognitive function in our test. This was the case with the norms for the “list recall” subtest for ages over 70 years. For instance, a score of 0 on this subscale (inability to recall any word from the list) is normal for that age group in the RBANS-E but would be considered pathological in other memory tests, such as the Free and Cued Selective Reminding Test.29

This may be due to a sample bias for this subtest and age group, the small sample size, or this subscale's low sensitivity for detecting cognitive impairment in prodromal stages of the disease in patients aged over 70 years; future studies should include more patients in this age band.

Another relevant finding of our study, again related to the role of sociodemographic variables, revolves around establishing norms, and more specifically around the distribution of scores for each norm. The socioeconomic context of the study and our sample's characteristics may be responsible for the fact that some cells are underrepresented. As a result, scaled scores may vary depending on the test and the person's age, with many scores not being matched with raw scores.

These peculiarities and limitations require us to exercise caution in interpreting the findings for some age bands.

Cognitive assessment tools should be adapted to the reference population, normalised, and have good psychometric properties; new normative data from different versions of the RBANS would be extremely valuable. The validated normative RBANS-E scores presented here are intended to assist in the detection and diagnosis of cognitive impairment. Poor test performance alone does not indicate dementia; thorough examination should be performed to assess all the variables that define an individual's clinical profile.

The authors have no conflicts of interest to declare.