Recruitment methods and sample characteristics have already been described in another article. To summarise, we recruited 179 white subjects who had been educated in Spain and were either native Spanish speakers or bilinguals. The sample was stratified by age and educational level. None of the subjects presented cognitive impairment; scores on the Mini-Mental State Examination (MMSE)33,34 were ≥24 and scores on the Memory Impairment Screen (MIS)35,36 were ≥4.

We followed the neuropsychological protocol established for the NN project.8 All tests were administered according to the procedures described in their manuals.

We administered the initial screening test, followed by the 4 subtests selected for the NN test protocol:

Shape detection screening test: the patient is shown 20 stimulus cards, half of which display an embedded and degraded ‘X’ symbol. The subject is asked to determine whether or not the X is present.

Object decision: the subject is shown a series of 20 cards, each of which displays 4 black shapes; one is the silhouette of a real object and the other 3 are distractor shapes. The subject has to identify the real object without hearing its name. The total correct responses are counted, and the maximum score is 20.

Progressive silhouettes: this section uses 2 card series, one representing a pistol and the other, a trumpet. Cards display a silhouette, beginning at a maximum rotation; each silhouette progressively approaches the more familiar lateral view. Participants are asked to identify the object as early in the series as possible. We calculated the total number of cards the subject needed to identify each object (maximum of 20).

Position discrimination: 20 cards are presented, each of which contains two adjacent squares. A dot marks the exact centre of one square; in the other, it is off-centre. The subject identifies the square containing the centred dot. Correct responses were recorded; the maximum score is 20.

Number location: 10 cards are presented, each containing 2 squares, one above the other. The top square has the numbers 1 to 9 randomly spaced within it, and the other square has only a black dot. The patient is asked to identify the number that corresponds to the precise position of the black dot. The total number of correct responses was recorded; the maximum score is 10.

The test consists of 30 stimulus cards, each showing a different pair of angled lines at the top of the page. The subject matches those lines to those shown on a multiple choice reference card at the bottom of the page. The first 5 items are practice items. The total number of correct responses for both line segments is recorded; the maximum score is 30. Spontaneous corrections by the participant were accepted, since no guidelines about how to score answers were provided.

We completed the general statistical analysis procedure established in the NNy protocol since this project serves as a co-normalisation study. The procedure was as follows: (a) we converted raw scores into percentile ranks according to the distribution of cumulative frequencies. Percentile ranks were then converted to NSS (NEURONORMA Scaled Scores) ranging from 2 to 18. This conversion of raw scores produces an approximation of a normal distribution (mean±standard deviation: 10±3) that permits use of linear regression models. (b) Age, education, and sex effects were defined by calculating NSS correlation coefficients (r) and coefficients of determination (R2) with respect to the variables listed above. Variables were adjusted only in cases in which the explained variance exceeded 5% and where the regression coefficient was statistically significant. (c) The NSS was adjusted for age, education, and sex according to the following formula: SSA&E&S=SS−(β1* × [Age−35] + β2* × [Education−13] + β3* × Sex). The regression coefficient (β) from this analysis was used as the basis for adjusting for sociodemographic factors. The resulting value was truncated to the next lower integer.

Results from the current study reveal a slight education effect in all subtests of the VOSP. The low impact of this factor differed from findings in prior normative studies,7–9 which delivered evidence of a significant, although less pronounced, correlation between education and performance on these subtests. This discrepancy with regard to past findings could be explained by the fact that our sample contains no subjects with fewer than 8 years of education.

No significant age effects on performance were detected in any of the subtests in the test battery. These results do not coincide with those from prior normative studies,2,7–9 which suggest that age has a negative influence on performance. These discrepancies may be due to the fact that the age range of our sample differs from that included in all prior studies. This may indicate that younger adult subjects are not affected by the age-related decline in performance which begins to appear in middle age.

We did not find a significant sex effect on VOSP subtest scores. The results obtained in our study support those concluding that there is no sex effect on these subtests.7,11 However, they do not concur with those from a study that found differences in 5 of the 8 VOSP subtests.7

We cannot confirm the age effect on test performance compared to other studies of Spanish population samples.7,13 This may be due to the fact that the study samples have different age ranges and there is no age effect on the present study. Concerning education, this study does not corroborate the differences found by Herrera-Guzmán et al.7 in the object decision subtest.

The age effect on the progressive silhouettes subtest showed different results with respect to those from the NN study8 of subjects aged 50 and older. The sample containing older subjects revealed an age effect on performance which was not present in the sample of younger subjects. This finding might be explained by the characteristics of the test, which evaluates visuospatial abilities but also requires spatial rotation. Some authors state that these abilities are sensitive to the ageing process.37 A recent study revealed correlations of up to 70% between age and scores on a test of non-prototypical images in which the ability to rotate images was crucial for task completion.38 We also found differences regarding the education effect on performances on the same subtest; these differences are probably due to the fact that our younger sample contains no subjects with fewer than 8 years of education.

Results indicate a slight education effect on the JLO scores. This result coincides with those from prior normative studies, which suggest that education has a positive effect on task completion.3,14,15 The presence of a more marked education effect on JLO than on the VOSP spatial perception subtests may be related to JLO's more rigorous standards. These data indicate that JLO may be more sensitive for detecting visuospatial deficiencies.1

No age influence on test performance could be determined. This result does not coincide with data obtained from most earlier normative studies, which provide evidence of an age effect on scores for this test.3,12,13 These differences may also be explained by the hypothesis, confirmed by Benton et al.,3 that performance declines with normal ageing. These authors observed a curved relationship between age and scores on JLO in which scores rose progressively until reaching a maximum in subjects aged 13; they began declining in subjects aged 50.

A sex effect is reflected by the JLO; male subjects scored higher on the test than females. Our data agree with all relevant earlier studies that also found better performance by males on the long version of the test,3,8,16–20 the short version,14,21 and in studies of patients with stroke or Parkinson's disease matched to control group subjects.13,22

Regarding prior normalisation studies using Spanish population samples,7,13 the age effect on test performance has not been confirmed. This is probably due to the effect of the differences in age range in the samples and the lack of age-related impact on this study, as we mentioned before. Our results with regard to sex coincide with those found by Alegret et al.,13 but do not concur with the findings of Herrera-Guzmán et al.7

Compared to results from the NN study of subjects aged 50 and older,8 findings are similar with respect to the effects of education and sex on performance, but different with respect to the effect of age.

It is important to note that this is the first study to present data from both the JLO test and numerous VOSP subtests in the same sample of adults younger than 50. Furthermore, these are the first published normative data for either the JLO or the VOSP tests in a population of younger Spanish adults.

This article provides normative data from the JLO and selected VOSP subtests for the population mentioned above. Data have been processed for easier use in diagnostic tasks. The results we obtained confirm the effect of education and sex on the JLO test, but not on the VOSP subtests. They also indicate that age has a minimal impact on performance on both tests in the age range included in the study.