Introduction
Multiple sclerosis (MS) is a neurodegenerative pathology that affects the central nervous system, characterized by presenting heterogeneity of symptoms and progressive disability that impairs the quality of life of patients1.
Nowadays, various research studies2,3 show that MS is a demyelinating disease in which immune processes are altered, unknown etiology but involving an interplay between genetic and environmental factors.
MS is clinically characterized by relapses and/or progression4, being relapses or not associated with progression. Relapses refer to acute or subacute episodes of neurological dysfunction that may or may not be followed by a remission, spontaneously or after treatment, resulting in a partial or complete recovery. These relapses are the result of acute, monofocal or multifocal, inflammation, that is recurrent with the appearance of new injuries. Symptoms associated with a relapse include diplopia, dizziness and vertigo, paresthesia, optic neuritis, paraparesis, and pyramidal syndrome5. Progression is defined as a steadily increasing objectively documented neurological dysfunction/disability without unequivocal recovery (fluctuations and phases of stability may occur).
At present, several disease courses or phenotypes of MS have been identified6.
The clinical manifestations of MS, in both progression and relapses, include motor and sensory dysfunctions, accompanied by cognitive deficits and emotional, and/or psychiatric disorders7-9. Cognitive impairment has a high prevalence and has been reported in 43-70% of MS patients, and can occur at any stage of the disease10. This cognitive dysfunction is a manifestation of axonal injury11,12 that is widely distributed throughout the brain and manifests as neuropsychological deficits, in attention, memory, learning, executive function, and processing speed. Using magnetic resonance imaging (MRI) measures, Filippi et al.13 noted that cognitive impairment in MS is related to atrophy in the gray matter damage and Cruz-Gómez et al.14 suggest that low performance in episodic and declarative memory tasks is associated with reduced functional connectivity of the left hippocampus. Several studies15-18 show that cognitive deficits are present in the early stages of the MS, and the impairment include alterations in processes such as attention, memory, executive function, and processing speed. In the study carried out by Duque et al.11 they find the performance was worse for MS patients than for control participants in verbal memory tasks, working memory, and processing speed. Achiron et al.19 and Desousa et al.20 reported on cognitive disturbances in memory, verbal fluency, attention, and processing speed in patients with MS. More specifically, after studying cognitive impairment among phenotypes of MS, Huijbregts et al.21 suggest that patients with different forms of MS are associated with different cognitive impairment profiles. Along the same lines, Wachowius et al.22 find that patients with progressive form of MS show greater cognitive impairment than patients with recurrent form of MS, and exhibit lower performance in tasks of visual memory, processing speed, and attention. Macías-Islas et al.23 assert that patients with relapsing-remitting MS (RRMS) perform significantly better in working memory, processing speed, and attention tasks than patients with primary progressive MS (PPMS). In short, it is necessary to know the involvement of the neuropsychological processes of each type of MS, to provide an adequate, early, and optimal neuropsychological intervention with the aim of delaying neurological disability and improving the quality of life of patients. For this reason, the objective of this research is to verify the existence of statistically significant differences in some neuropsychological processes such as attention, memory, language, visuoperceptual processing, executive function, and processing speed between patients with RRMS and PPMS.
Methods
A non-experimental descriptive and inferential design were used with the aim of describing the values of the study variables and comparing differences between groups (RRMS and PPMS). It was adopted an ex post facto and cross-sectional design, using a quantitative information-gathering methodology. The participants in this study were 20 MS patients from patients from the Psyque Foundation in the City of Medellin, Colombia, between the ages of 22 and 52 (M = 37.40; DE = 8.56), both sexes, 12 women and eight men. The RRMS group consisted of 11 patients, seven women, and four were men, aged between 22 and 46 (M: 37.55; DE: 6.54). The PPMS group consisted of nine patients, five women and four were men, aged between 22 and 52 (M: 37.27; DE: 10.24). All participants were of legal age and signed informed written consent expressing their agreement with participation in the study. The sample was non-random and the criteria for inclusion were as follows: to have MS diagnoses according to the McDonald criteria of 2005 (collected in Polman et al.24), to have a diagnosis time of the disease < 1 year, to have at least one level of high school studies, and to belong to the Psyche Foundation of Medellin.
The exclusion criteria were illiteracy, perceptual alterations that prevented evaluation and psychiatric disorders or another neurological disease in the anamnesis; to verify the latter, the diagnosis report was requested from participants, with no additional tests being performed for the assessment of depression and anxiety that are common in MS patients. To verify that the intellectual level of participants was not < 70, they were administrated K-BIT, which is an intelligence quotient (IQ) screening that verified that all patients had an IQ above 70, both the RRMS group (M: 76.22; SD: 16.81) and the PPMS group (M: 74.27; SD: 12.60).
The variables under study were attention, Wisconsin Cards Sorting test, Heaton, Chelune, Talley, Kay y Curtiss 31 this test evaluates cognitive flexibility. Memory, language, visuoperceptual processing, and executive function and processing speed, and the evaluation instruments for measuring them were, respectively: paced auditory serial addition test (PASAT) to evaluate auditory attention, symbol digit modalities test (SDMT) for auditory and visual attention, Rey Complex Figure Test (copy) for visual memory and visuoperceptual processing, Boston test to assess the naming abilities at a linguistic level and a verbal fluency test, the Wisconsin cards sorting test (WCST) to evaluate cognitive flexibility (one component of executive function), and Trail Making Test to assess processing speed.
The Paced Auditory Serial Addition Test (PASAT), Gronwall25 is a neuropsychological test used to assess divided attention; in this study the PASAT 3 version has been used.
The Symbol Digit Modalities Test (SDMT), Smith26 evaluates sustained attention and in the present research both versions (auditory and visual) have been used.
The Trail Making Test, Jarvis and Bart27 is used to assess attention and processing speed. In this study, only part B has been used and it has been registered the time spent performing the task.
Rey Complex Figure, Rey28 is a test that allows to assess the organization and visuospatial memory. In this study, the copy task is used to measure visuoperceptive ability and short-term visuospatial memory task.
The Boston test, Goodglass and Kaplan29 is used to assess naming abilities.
Verbal Fluency task, Ardila and Rosselli30 is a task of semantic verbal fluency.
Wisconsin Cards Sorting test (WCST), Heaton et al.31: this test evaluates cognitive flexibility.
Before the assessment, informed consents were requested from participants of the Psyque Foundation of the City of Medellin, both RRMS and PPMS patients. Subsequently, the tests were clinically administered, i.e., a single researcher and patient in a ward.
The neuropsychological assessment was organized into three sessions of approximately 40 min each and the order of the tests remained constant for all patients. Lighting and loudness conditions were controlled in each room to make them the most optimal possible. The study was conducted in accordance with established ethical standards. The research was approved by the Bioethics Committee of the Pampuri Foundation International NGO, in compliance with the ethical standards of the Helsinki Declaration of 2000.
The data were analyzed using the SPSS statistical program, version 20.0 for Windows. Descriptive statistics of the variables were calculated to represent the central tendency: mean, and standard deviation; and Students parametric t-test, and MannWhitneys non-parametric U-test (after analysis of the Shapiro normality test) were used to check for significative differences between groups in the variables under study with a significance level α = 0.05.
Results
The results of descriptive analyses of the attention, memory, language, visuoperceptual processing, executive function, and processing speed variables in the two EMRR and EMPP study groups are shown in table 1. The data in this table reveal a higher means for the variables sustained auditory attention, sustained visual attention, divided auditory attention, visual memory, denomination, and visuoperceptual processing in the patients RRMS. However, the mean of the variable cognitive flexibility is higher in PPMS. In processing speed RRMS patients used less time to finish the task. In the verbal fluency task, the performance of patients with RRMS and PPMS seems similar.
Neuropsychological variables | EMRR | EMPP | t | p | ||
---|---|---|---|---|---|---|
Mean | Standard deviation | Mean | Standard deviation | |||
Sustained visual attention | 21.18* | 6.86 | 15.66* | 7.63 | 1.700 | 0.10 |
Verbal fluency | 10.27* | 3.10 | 10.11* | 3.88 | 0.104 | 0.91 |
u | p | |||||
Sustained auditory attention | 9.90* | 6.73 | 7.77* | 5.99 | 0.456 | |
Divided auditory attention | 10.81* | 6.46 | 5.33* | 8.32 | 0.120 | |
Processing speed | 239.27* | 198.77 | 318.33* | 231.25 | 0.456 | |
Visual memory | 15.18* | 9.16 | 8.33* | 8.66 | 0.710 | |
Denomination | 51.18* | 8.48 | 44.88* | 13.89 | 0.331 | |
Visuoperceptual processing | 23.09* | 6.68 | 16.66* | 10.60 | 0.456 | |
Executive function: cognitive flexibility | 4.27* | 3.95 | 6.22* | 6.34 | 0.710 |
*Normal mean expected for the different tests: sustained auditory attention (48,38); sustained visual attention (42,97); divided auditory attention (48.3); processing speed (90.4); visual memory (14.1); denomination (44.2); verbal fluency (17.04); visuoperceptual processing (32); cognitive flexibility (5.7).
The results of the inferential analysis were obtained by Students parametric t-test and MannWhitneys non-parametric U-test with a significance level of 0.05, and show that there are no significant differences between EMRR and EMPP in any of the neuropsychological variables studied. Table 1 shows the results of the inferential analysis between RRMS and PPMS in all the neuropsychological measures.
To confirm the difference between MS patients and expected normal means, inferential statistics were in each of the neuropsychological tests with a significance level of 0.05. The results using the Mann-Whitney U test showed significant differences in sustained auditory attention (p = 0.000), divided auditory attention (p = 0.000), processing speed (p = 0.000) and naming (p = 0.000). The comparative analysis using the Student t-test found significant differences in verbal fluency (t = 8.212; p = 0.000) and sustained visual attention (t = 11.665; p = 0.000). No significant differences were found in visual memory (p = 0.108), visuoperceptual processing (p = 0.602) and cognitive flexibility (p = 0.602).
The differences between RRMS and PPMS were also analyzed based on age (t = 0.072; p = 0.944) intellectual level (IQ) (p = 0.421) and the schooling years (t = 1.201; p = 0.245), and no significant differences were found.
The estimated sample size to find a significant difference has been calculated for the two variables closest to statistical significance: sustained visual attention and divided auditory attention. The number of participants estimated to find significant differences between groups with a 95% CI is 52 for sustained visual attention and 40 for divided auditory attention, half of each subtype.
Discussion
The results of the present study show that there are no significant differences between RRMS and PPMS in the neuropsychological processes evaluated in this research such as: attention, processing speed, memory, language, visuoperceptual processing, and cognitive flexibility. These findings are in line with previous studies23 that found no significant differences in verbal fluency and executive function between RRMS and PPMS. However, these authors do find in their study that RRMS patients have better performance than PPMS patients in attention and processing speed tasks. In this same vein, Olivares et al.32 found significant differences between RRMS and PPMS in visual memory, attention, and processing speed tests. Johnen et al.33, in a meta-analysis of forty-seven empirical studies conducted with neuropsychological, found significant differences between PPMS and RRMS in favor of RRMS in IQ, speed processing, verbal learning, verbal memory, visual memory, working memory, cognitive fluency, visuoperception and executive function. These authors found that cognitive differences between MS subtypes persist regardless of clinical and demographic characteristics of the two subtypes, so they may be due to pathogenic differences or aspects related to the sample itself. In a systematic review of eighteen studies Vollmer et al.34 they highlight the relation between decreased brain volume with low scores on neuropsychological tests, suggesting that in PPSS there is a greater atrophy of the grey substance possibly generating decreased performance in neuropsychological tasks. Brochet y Ruet35 point out that the PPMS subtype presents more cognitive deficits than the RRMS subtype, specifically in tasks in memory, attention, processing speed, verbal fluency, executive functions, and working memory.
The lack of significant differences between RRMS and PPMS encountered in this research is not consistent with the expression of the two clinical profiles of MS. Several studies4 indicate that the progressive form of MS is more affected cognitively from the early stages of the disease than the recurrent form of MS, and therefore should be expected worse performance in neuropsychological tasks in those patients with PPMS since the onset of the disease.
However, the results of this research, conducted with a sample diagnosed less than a year ago, indicate that there are no differences in the first stage of the disease between patients with RRMS and PPMS in cognitive impairment in neuropsychological processes such as attention, processing speed, visual memory, language, visoperceptual processing, and executive function. The results suggest that in early moments, despite anatomical differences due to cortical loss and pathogenic factors typical of each subtype of MS, the performance of patients in neuropsychological tests is not affected, specifically, no significant differences were found among the patient group versus normal values in cognitive flexibility, visual memory and visuoperception tasks. This finding goes in the opposite direction than the results of the study conducted by Ruet et al.36, who found worse performance in patients with MS, both PPMS and RRMS subtypes, compared to control group, with more severe cognitive deficits in PPMS than in RRMS, due to pathogenic factors inherent in PPMS. In relation to language (naming), attention, processing speed, verbal fluency and IQ, the performance of patients diagnosed with MS is significantly lower than the mean of the normal population. These results are in line with those found by other studies33,37, suggesting that some cognitive domains are more impaired than others in the first months of the disease. It is true that the data obtained in the present study are conditioned by the sample size, due to the difficulty in finding participants who met the inclusion criteria, especially among patients who were diagnosed at most in 1 year, since the objective of the study was to check for differences between groups in neuropsychological impairment the onset of the disease. In addition, in this study, an attempt has been made to control the effect of the educational level, selecting patients with the same educational level (high school), since several studies38-40 have shown the effect of this factor on the performance of neuropsychological tests in patients with MS. Regarding the intellectual level (IQ), there are no significant differences between the MS subtypes, in the opposite direction to the results found in other studies33,34,36. The present study raises the possibility that there are no different profiles of cognitive dysfunction in the execution of neuropsychological tests between RRMS and PPMS in patients with less than one year of symptoms. It is possible that the specific moment of the disease in the participants and the heterogeneity of measures of assessment of cognitive functioning used in the different studies may be influencing the results obtained.
This work has certain limitations: the size of the sample and lack of assessment of other variables that may affect the association of the clinical profile of MS and the cognitive impairment, such as cortical volume loss or white matter observed with MRI and the assessment of functional status or disability, preventing conclusion with a neuropsychiatric deterioration factor.
The results of this study may help the clinician in taking preventive decisions regarding the design and development of the neuropsychological rehabilitation plan of MS patients. The location of neuropsychological deficits in MS is essential to design intervention strategies for each MS subtype. In this study, despite having found no significant differences, the PPMS profile has a worse performance in neuropsychological tasks except for cognitive flexibility, which suggests the early need for more specialized treatment than the RRMS profile. It could be considered whether an early cognitive intervention in the first months could decrease the difference in terms of cognitive impairment in patients with PPMS versus the RRMS subtype.
Conclusion
In short, this study provides information on the neuropsychological differences between RRMS and PPMS in the initial phase of the disease and about the early neuropsychological profile of both types of MS.
Overall, RRMS patients have better scores on all neuropsychological measures (except cognitive flexibility), although the differences do not become significant in the sample under study. These results may indicate that RRMS/PPMS patients do not differ significantly from each other in the execution of neuropsychological processes in the 1st year after diagnosis. It is important to highlight that the participants of the two groups of MS subtypes in this study are both in the initial stage of the disease (diagnosed for less one year), and they have similar educational level, age, years of schooling and IQ. This data can help by providing information on the status of early-stage cognitive processes of both phenotypes and clinical forms of MS, as an indicator of prognosis and to suggest therapeutic and follow-up strategies in patients with RRMS/PPMS.
As a proposal for future research, it is important to increase the size of the sample and select patients with RRMS and PPMS with more years of disease evolution so that it can be compared the differences between the two types of MS patients in neuropsychological decline, with the passage of time and the effect of medication.