Neurological soft signs are minor neurological abnormalities that are not believed to be part of a well-defined neurological syndrome. Reference Heinrichs and Buchanan1 Neurological soft signs are more severe in adults and adolescents with psychosis, including schizophrenia (treated and antipsychotic-naive), Reference Arango, Bartko, Gold and Buchanan2,Reference Karp, Garvey, Jacobsen, Frazier, Hamburger and Bedwell3 first-episode psychosis Reference Bombin, Arango and Buchanan4–Reference Zabala, Robles, Parellada, Moreno, Ruiz-Sancho and Burdalo6 and bipolar I disorder, Reference Negash, Kebede, Alem, Melaku, Deyessa and Shibire7 compared with age-matched healthy controls. Psychosis during adolescence is associated with structural brain abnormalities. Reference Arango and Kahn8 In adults with first-episode psychosis, decreased volumes of the basal ganglia structures, thalamus, heteromodal cortex and cerebellar grey matter have been associated with increased severity of neurological soft signs. Reference Bottmer, Bachmann, Pantel, Essig, Amann and Schad9–Reference Venkatasubramanian, Jayakumar, Gangadhar and Keshavan14 In adolescents with psychosis, to the best of our knowledge, no study has investigated the relationship between severity of neurological soft signs and volumes of specific brain structures. The current study used voxel-based morphometry and segmentation of anatomical structures to investigate whether increased severity of neurological soft signs predicted decreased brain volumes in adolescents (younger than 18 years of age) with first-episode psychosis (duration of positive symptoms less than 6 months). Considering the complex anatomical definition of some structures related to the severity of neurological soft signs, such as the heteromodal cortex, we chose to focus only on the thalamus, caudate and putamen because the segmentation algorithms used were deemed more reliable for these structures.
Method
Participants
Individuals were recruited from the two child and adolescent psychiatric in-patient units in Madrid (Hospital General Universitario Gregorio Marañon and Hospital Universitario Infantil Niño Jesus). The two units serve a population of approximately five million people. All patients consecutively seen at these facilities between April 2002 and November 2005 who fulfilled the inclusion criteria described below were invited to participate in the study. Seventy-four individuals agreed to participate. Of the 74, 3 individuals did not undergo a magnetic resonance imaging (MRI) scan because of fear. One participant was excluded because of insufficient image quality for neuroimaging analyses, thus leaving a sample of 70 individuals (51 males). The inclusion criteria for participants were: age between 7 and 18 years, and presence of positive psychotic symptoms (within a DSM–IV 15 diagnosis) for less than 6 months at the time of assessment on enrolment in the study. Exclusion criteria were: presence of a concomitant Axis I disorder, mental retardation, a pervasive developmental disorder, neurological diseases, a history of head trauma with loss of consciousness, and pregnancy. Individuals with substance use and/or dependence were excluded. Individuals with substance use were included only if positive symptoms remained present after 14 days of a negative urine screen. Prior treatment was not an exclusion criterion if positive symptoms persisted for more than 2 weeks after a negative urine drug screen. The study was approved by the institutional review boards of both participating clinical centres. After the study was thoroughly explained to all of the participants, written informed consent was obtained. All of the participants met MRI safety criteria.
Clinical assessment
All participants met DSM–IV criteria for a first episode of psychosis, assessed using the Kiddie – Schedule for Affective Disorders – Present and Lifetime Version (K–SADS–PL). Reference Kaufman, Birmaher, Brent, Rao, Flynn and Moreci16 Clinical diagnostic interviews were performed during the initial hospitalisation by four experienced psychiatrists trained in this interview. Diagnostic consensus was reached in cases where presence or absence of psychiatric diagnoses was in doubt. Baseline diagnoses were reassessed in a clinical interview at a 12-month follow-up visit; follow-up diagnoses were based on DSM–IV criteria. Three diagnostic categories were established: schizophrenia, n = 25 (19 males); bipolar I disorder, n = 20 (13 males); and ‘other psychoses’, n = 25 (19 males). The latter group included six individuals with schizoaffective disorder, five with schizophreniform disorder, three with major depression with psychotic features, nine with psychosis not otherwise specified, and two with brief psychotic episode.
Psychotic symptoms were assessed using the validated Spanish version of the Positive and Negative Syndrome Scale (PANSS). Reference Peralta and Cuesta17 Intraclass correlation coefficients for the four psychiatrists who administered the scale ranged from 0.72 to 0.96. Ratings on the Global Assessment of Functioning (GAF) scale were used as a measure of overall functioning. Sociodemographic data were collected, including parental socioeconomic level as measured by the Hollingshead–Redlich scale, Reference Hollingshead and Redlich18 and a physical examination (e.g. weight, height) was performed.
Neurological soft signs
All participants go through a comprehensive physical examination when they are admitted to hospital as part of our first-episode clinical guidelines. The severity of neurological soft signs was evaluated using the Neurological Evaluation Scale (NES), Reference Buchanan and Heinrichs19 a 26-item scale with four subscales: sensory integration, motor coordination, sequencing of complex motor acts, and an ‘other’ subscale that evaluates short-term memory, frontal release signs and eye movement abnormalities (see online supplement). Each item is rated from 0 to 2: 0, no abnormality; 1, mild, but definite impairment; and 2, marked impairment. The snout and suck reflexes are scored either 0 or 2. The severity for each subscale was calculated by summing the scores on that particular subscale. The NES was administered in its entirety, according to the original instructions of the instrument's developers, by three neuropsychologists. The intraclass correlation coefficients for the four NES subscales obtained by the examiners in an independent sample of ten individuals ranged from 0.80 to 0.99. The neurological assessment was performed when the participants were clinically stable. The mean duration between neurological assessment and scan acquisition was 15 days (s.d. = 22).
The age at onset of psychosis was defined as the age at which the individual experienced positive psychotic symptoms for the first time. This information was gathered during the K–SADS–PL interview with parents or legal guardians. Duration of psychosis was defined as the time between age at onset of psychosis and scan acquisition. Duration of treatment was defined as the time between initiation of antipsychotic treatment at enrolment in the study and scan acquisition.
Medication
At the time of the baseline assessment, all participants were on antipsychotic medication. Seventy-six per cent (n = 53) of the sample (n = 70) were receiving only one antipsychotic, whereas 24% (n = 17) were receiving two antipsychotics simultaneously. With the exception of two individuals, all participants were receiving a second-generation antipsychotic. The distribution of antipsychotic treatment was as follows: 54% (n = 38) risperidone, 34% (n = 24) quetiapine, 28% (n = 20) olanzapine, 4% (n = 3) ziprasidone, and 3% (n = 2) haloperidol. The chlorpromazine equivalent dose Reference Woods20 was calculated from the dose of antipsychotics received (Table 1). The mean daily antipsychotic dose in chlorpromazine equivalents was 290.0 mg (s.d. = 180.4 mg).
Adolescents with first-episode psychosis (n = 70) | |
---|---|
Gender, male/female: n (%) | 51/19 (72/27) |
Handedness, right/left/ambidextrous, n (%) | 63/6/1 (90/9/1) |
Age, years: mean (s.d.), range | 16.3 (1.7), 11-18 |
Height, cm: mean (s.d.)a | 168.4 (9.5) |
Weight, kg: mean (s.d.)a | 61.3 (11.8) |
Level of education, years: mean (s.d.) | 8.2 (2.1) |
Parental socioeconomic status: mean (s.d.) | 2.6 (1.4) |
Age at onset of psychosis, years: mean (s.d.), rangea | 15.3 (1.8), 10-17 |
Duration of psychosis, weeks: mean (s.d.), rangeb | 12.6 (10.1), 0-48 |
Duration of treatment, weeks: mean (s.d.), rangeb | 2.8 (3.4), 0-25 |
Chlorpromazine equivalents, mg: mean (s.d.), range | 290.0 (180.4), 3-920 |
Global Assessment of Functioning scale score: mean (s.d.) | 41.2 (15.8) |
Positive and Negative Syndrome Scale score: mean (s.d.) | |
Positive symptoms | 25.3 (5.6) |
Negative symptoms | 23.4 (7.2) |
General psychopathology | 48.2 (9.8) |
Cerebral grey matter, cc: mean (s.d.) | 750.4 (71.8) |
MRI acquisition
All participants were scanned on a 1.5-T Philips MRI scanner (Philips Gyroscan, Philips Medical Systems, Best, The Netherlands). Two MR sequences were obtained for all the participants: a T1-weighted, 3-dimensional, gradient-echo scan with 100 1.5-mm contiguous axial slices (echo time (TE) 4.6 ms; repetition time (TR) 9.3 ms; flip angle 30°; field of view (FOV) 256 mm; and in-plane voxel size 0.98 × 0.98 mm2) and a T2-weighted turbo spin echo scan with 3.5-mm contiguous axial slices (turbo factor 15; TE = 120 ms; TR = 5809 ms; FOV = 256 mm; and in-plane voxel size 0.98 × 0.98 mm2). Both T1-and T2-weighted images were used for clinical neurodiagnostic evaluation by an independent neuroradiologist. No participants showed clinically significant brain pathology.
Image processing
Voxel-based morphometry
Voxel-based morphometry processing Reference Ashburner and Friston21 was performed using the Statistical Parametric Mapping package (SPM5; The Wellcome Department of Imaging Neuroscience, University College London). In order to improve spatial normalisation, brain-extracted images were used as inputs. Reference Fein, Landman, Tran, Barakos, Moon and Di Sclafani22 Brain-extracted images were obtained using the Brain Extraction Tool (version 2) algorithm, Reference Smith23 and then manually edited to remove remaining non-intracranial tissue voxels with in-house software. The locally developed software is part of a Multimodality Workstation running on IDL (Interactive Data Language, Research Systems Inc, Boulder, Colorado, USA; http://www.ittvis.com/ProductService/IDL.aspx). This software incorporates modules for triplanar visualisation, manual tracing, automatic segmentation, multimodality registration, among other advanced image processing and quantification tools. Brain-extracted images were normalised and segmented into grey matter, white matter and cerebrospinal fluid, using the a priori template segments. Reference Ashburner and Friston24 To improve segmentation accuracy, a Markov random field estimate was applied to the grey matter segmentations. All brains were visually inspected to determine whether our image processing steps resulted in successful scan normalisation and segmentation. Registration with the template was consistent across the cohort in all brain regions.
Prior to entering the grey matter segmentations in the statistical analyses, the grey matter segmentations were modulated by the Jacobian determinants from the spatial normalisation. Modulation was done to account for the contraction and expansion of grey matter during normalisation. Reference Good, Johnsrude, Ashburner, Henson, Friston and Frackowiak25 After modulation, the voxel values represent grey matter volume. Finally, the modulated grey matter segmentations were smoothed using a 10-mm Gaussian kernel to ensure that the data were sufficiently normal to justify the application of Gaussian random field theory in the statistical calculations. Reference Salmond, Ashburner, Vargha-Khadem, Connelly, Gadian and Friston26
Segmentation of anatomical structures
The segmentation of anatomical structures was done using the Fmrib Integrated Registration and Segmentation Tool (FIRST) and the raw (not brain-extracted) T1-weighted images. Reference Smith, Jenkinson, Woolrich, Beckmann, Behrens and Johansen-Berg27 The FIRST is an automatic surface-based segmentation tool that relies on trained models of shape and intensity. It utilises a multivariate Gaussian model of shape (vertex coordinates). Shapes are fitted to new data by maximising the joint probability of shape and intensity, where the search space is limited to the principal components of the vertices. The sample used to train FIRST was composed of 317 manually segmented T1-weighted MR images, with an age range from approximately 4 to 87 years. The manual segmentations in the training data were based on previously described neuroanatomical criteria for manual segmentation. Reference Frazier, Chiu, Breeze, Makris, Lange and Kennedy28 The training data were composed of data on healthy controls as well as individuals diagnosed with schizophrenia and bipolar disorder. All segmentations were visually inspected to determine whether the segmentation process was successful.
Data analysis
Data were analysed in a two-step design. In step one, using voxel-based morphometry and small volume correction masks of the thalamus, caudate and putamen from the Wake–Forest University Pick Atlas, Reference Maldjian, Laurienti, Kraft and Burdette29 the association between the voxel-based volume in the three subcortical structures and the NES subscale scores (the NES subscale score represented the severity of neurological soft signs on that subscale) was examined. In step two, findings from step one were complemented by segmentation of those subcortical structures containing voxels that were significantly associated with NES subscale scores. After segmentation, the whole subcortical structure volume was calculated. Thereafter, the association between whole subcortical structure volume and NES subscale scores was examined.
Regression models: covariates
All analyses (in steps one and two) testing the association between voxel-based and whole subcortical structure volumes with the NES subscale scores were done using multiple regression in the context of the general linear model.
Age, gender and medication are known to influence severity of neurological soft signs as well as brain morphology. Reference Bombin, Arango and Buchanan4,Reference Giedd30 In addition, controlling for whole brain grey matter volume is advisable in voxel-based morphometry Reference Ridgway, Henley, Rohrer, Scahill, Warren and Fox31 to avoid the influence of inter-individual differences in whole brain grey matter volume when investigating local grey matter volume changes. Therefore we entered age, gender, whole brain grey matter volume and chlorpromazine equivalent dose as covariates in all analyses (in steps one and two).
The PANSS negative symptom score was also included as a covariate, because it was significantly positively associated with the sensory integration subscale score (P = 0.001), the sequencing of complex motor acts subscale score (P = 0.02) and the ‘other’ signs subscale score (P = 0.01). An association between negative symptom severity (as measured by the PANSS) and severity of neurological soft signs has been previously reported in adolescent psychosis. Reference Mayoral, Bombín, Zabala, Robles, Moreno and Parellada5 Moreover, this association has been replicated in numerous prior studies. Reference Compton, Bollini, McKenzie Mack, Kryda, Rutland and Weiss32,Reference Whitty, Clarke, McTigue, Browne, Gervin and Kamali33 It has been suggested that this association indicates that negative symptoms have a stronger neuropathological basis compared with positive symptoms. Following this rationale, an association between brain morphology and severity of neurological soft signs might be interpreted as an outcome of the underlying relationship between severity of negative symptoms and neurological soft signs. Hence, the PANSS negative symptom score was included as a covariate to ensure that the association between volumes and neurological soft signs remained significant regardless of its potential correlation with negative symptoms.
Step one
Four regression models, one for each NES subscale, tested whether voxel-based volume in the three subcortical structures could be predicted from the NES subscale score. First, a whole brain grey matter t-map was generated. The t-map was then thresholded at 3.23 (P<0.001). Thereafter, the small volume correction was applied. Within each small volume correction mask, a group of contiguous voxels (i.e. a cluster) of any size, containing one or more voxels with P<0.05, corrected for multiple comparisons at the voxel-level using the statistical parametric mapping family-wise error, Reference Worsley, Marret, Neelin, Vandal, Friston and Evans34 was considered significant. To facilitate interpretation, the coordinates of voxels with a corrected P<0.05 (‘local maxima’) were converted from normalised space to Talairach and Tournoux space, Reference Talairach and Tournoux35 using the icbm2tal transform. Reference Lancaster, Tordesillas-Gutierrez, Martinez, Salinas, Evans and Zilles36
Step two
After segmentation, regression models tested whether whole subcortical structure volume could be predicted from the NES subscale score. To examine the specificity of our findings, the volume of the hippocampus, which was assumed not to have a relationship with NES subscale scores, Reference Bombin, Arango and Buchanan4 was also estimated using FIRST. In all analyses, to ensure robustness of the findings, outliers (if any) were removed and analyses were re-done.
Results
The demographic and clinical characteristics of the participants are shown in Table 1 and the mean NES subscale scores are shown in Table 2. For the four voxel-based morphometry multiple regression analyses, significant findings were found for the sensory integration subscale and the sequencing of complex motor acts subscale.
Adolescents with first-episode psychosis (n = 70) | |||
---|---|---|---|
Neurological Evaluation Scale subscale scores | Mean | s.d. | Range |
Sensory integrationa | 4.9 | 2.3 | 0-11 |
Motor coordination | 3.8 | 2.1 | 0-11 |
Motor sequencing | 4.9 | 4.1 | 0-25 |
Other | 11.1 | 4.1 | 1-20 |
Sensory integration signs
A cluster comprising the left and right side of the anterior part of the thalamus showed a significant negative association with sensory integration subscale score, meaning that increased severity of sensory integration signs was associated with smaller volume in the anterior region of the thalamus after adjusting for age, gender, whole brain grey matter volume, negative symptom score and chlorpromazine equivalent dose (Talairach coordinates of the local maxima x, y, z: −3, −5, 13 mm; t-test = −4.1, cluster size 813 voxels; Fig. 1(a) and online Fig. DS1). Following the significant cluster located in the thalamus, the thalamus was segmented. Mean total (left + right) thalamus volume was 13.1 cc (s.d. = 1.5). There was a significant negative association between total thalamus volume and sensory integration subscale score, similar to the voxel-based morphometry analysis, (unstandardised regression coefficient, b = −0.15 cc (s.e.) = 0.06, t-test = −2.32, degrees of freedom (d.f.) = 62, P = 0.02), representing a 1% decrease in total thalamus volume per increment in sensory integration subscale score, after correction for age, gender, whole brain grey matter volume, negative symptom score and chlorpromazine equivalent dose (Fig. 1(b)).
Sequencing of complex motor acts
A cluster comprising the right caudate showed a significant negative association with sequencing of complex motor acts subscale score, meaning that increased severity of neurological soft signs on the sequencing of complex motor acts subscale was associated with smaller volume in this region (Talairach coordinates of the local maxima x, y, z: 13, −9, 20 mm; t-test = −4.0; cluster size 529 voxels, small volume correction corrected P<0.05; Fig. 1(c) and online Fig. DS1).
Subsequently, the right caudate was segmented. Mean right caudate volume was 2.4 cc (s.d. = 0.5). A negative relationship was found between right caudate volume and sequencing of complex motor acts subscale score (b = −0.03 cc (s.e. = 0.02), t-test = −2.1, d.f. = 63, P = 0.04), representing a 1% decrease in right caudate volume per increment in sequencing of complex motor acts subscale score, after correction for age, gender, whole brain grey matter volume, negative symptom score and chlorpromazine equivalent dose (Fig. 1(d)).
The outliers (motor sequencing subscale scores 11 and 25) did not change the results.
No significant associations were found between total hippocampus volume and sensory integration subscale score (P = 0.24) or sequencing of complex motor acts subscale score (P = 0.32). A post hoc exploratory analysis did not reveal any differences in severity of neurological soft signs or subcortical brain volumes between the diagnostic groups, suggesting that the relationship between neurological soft signs and brain volumes is similar for the three diagnostic groups.
Discussion
The major finding of this study is the localisation of specific neuroanatomical correlates of severity of neurological soft signs in adolescents with first-episode psychosis.
Sensory integration signs: thalamus
Increased severity of sensory integration signs was associated with decreased volume in an anterior part of the thalamus (i.e. after voxel-based morphometry analysis) and decreased total thalamus volume (i.e. after segmentation of the thalamus). Our results extend findings from a previous voxel-based morphometry study Reference Dazzan, Morgan, Orr, Hutchinson, Chitnis and Suckling11 by showing the negative association between severity of sensory integration signs and total thalamus volume in younger people with psychosis with a considerably shorter duration of illness (12.6 weeks v. 70.8 weeks). The thalamus functions as a central relay station of the brain by filtering and gating sensory inputs to the cerebral cortex. Reference Jones37 Sensory integration functions, such as audiovisual integration and stereognosis, require transfer of sensory information from subcortical regions to multimodal cortical brain areas. Our results may indicate that structural impairment of the thalamus affects this transfer and consequently decreases performance on the sensory integration subscale. Thalamic volume decrease has been associated with chronic schizophrenia, Reference Konick and Friedman38 first-episode psychosis Reference Jayakumar, Venkatasubramanian, Gangadhar, Janakiramaiah and Keshavan39 and increased genetic predisposition to schizophrenia. Reference Lawrie, Whalley, Abukmeil, Kestelman, Donnelly and Miller40 These findings, together with evidence of functional and post-mortem thalamic abnormalities, Reference Watis, Chen, Chua, Chong and Sim41 suggest that thalamic structure and function might be affected in psychosis. Reference Andreasen, O'Leary, Flaum, Nopoulos, Watkins and Boles Ponto42
Sequencing of complex motor tasks: right caudate
Increased severity of neurological soft signs on the sequencing of complex motor acts subscale was associated with volume decreases in the right caudate. Right and left caudate volume decreases have been associated with increased minor motor and cognitive neurological abnormalities, as measured by the NES, in adults with first-episode psychosis. Reference Keshavan, Sanders, Sweeney, Diwadkar, Goldstein and Pettegrew12 The caudate receives cortical projections from motor areas in the frontal lobe, and the received information is passed on to the putamen, globus pallidus and substantia nigra, which together with the caudate form the basal ganglia motor system. Reference Alexander and Crutcher43 Interestingly, decreased putamen volume and increased severity of neurological soft signs on the motor coordination subscale has been reported in adults with first-episode psychosis. Reference Dazzan, Morgan, Orr, Hutchinson, Chitnis and Suckling11 Therefore, a volume decrease in the caudate may point to suboptimal functioning of the basal ganglia motor system in people with first-episode psychosis.
No significant differences in caudate volume between first-episode psychosis or minimally treated individuals and healthy controls have been reported. Reference Glenthoj, Glenthoj, Mackeprang, Pagsberg, Hemmingsen and Jernigan44 In people with chronic schizophrenia, enlarged caudate volumes have been reported, possibly as a result of treatment with first-generation but not second-generation antipsychotics. Reference Corson, Nopoulos, Miller, Arndt and Andreasen45 In the current study, we cannot rule out effects of antipsychotics on brain morphology; however, we studied a sample of adolescents with first-episode psychosis with a mean duration of treatment of less than 3 weeks. We thus deem it unlikely that treatment with primarily second-generation antipsychotics affected our results. Indeed, we included chlorpromazine equivalent dose as a covariate in our analyses and still found an association between severity of sequencing of complex motor acts and right caudate volume.
Brain morphology and clinical diagnosis
Schizophrenia and bipolar disorder overlap in clinical symptoms and in genetic and epidemiological risk factors. Reference Thaker46 In previous MRI studies of adolescents with psychotic bipolar disorder or schizophrenia, grey matter deficits have been found in medial frontal areas in both patient groups. Reference Janssen, Reig, Parellada, Moreno, Graell and Fraguas47 Furthermore, these frontal cortical regions have been associated with increased genetic susceptibility to adult-onset schizophrenia and bipolar I disorder, Reference McDonald, Bullmore, Sham, Chitnis, Wickham and Bramon48 suggesting that both disorders share underlying neuropathology. The results from MRI studies in early-onset bipolar disorder investigating subcortical structures such as the thalamus and basal ganglia are conflicting. Reference Dasari, Friedman, Jesberger, Stuve, Findling and Swales49,Reference Wilke, Kowatch, DelBello, Mills and Holland50
Few studies have examined the relationship between severity of neurological soft signs and brain morphology in people with first-episode psychosis. Our study has extended the sparse previous findings to a younger patient sample with a shorter duration of psychosis. Our findings thus point to an association between increased severity of neurological soft signs and volume decreases in the thalamus and the right caudate in adolescents with recent-onset first-episode psychosis. If replicated, these findings may be of interest for clinicians as assessment of neurological soft signs in these individuals may serve as an easy-to-obtain marker of structure-specific brain alterations.
Limitations
Our results should be interpreted in view of the limitations of this study. First, the clinical heterogeneity and small sample size of diagnostic subgroups can be considered a limitation and should be taken into account when extrapolating our findings to different psychotic disorders. However, the current sample allows for the study of a phenotypic marker of psychosis, which is the trait that all participants have in common. Severity of neurological soft signs as well as subcortical brain volumes were not different between diagnostic groups, which suggests a shared marker for psychosis rather than one specific to schizophrenia or bipolar I disorder. This may also have relevance for future diagnostic criteria (e.g. DSM–V) as some biological markers may be consistent with a dimensional approach rather than a marker for a specific diagnosis. Second, we used voxel-based morphometry to assess the relationship between voxel-based grey matter volumes and severity of neurological soft signs. The effect size of the associations that we found is rather small and our results should be interpreted with caution, considering the limitations of MRI processing. Specifically, methodological issues regarding voxel-based morphometry have been discussed in the literature. Reference Bookstein51 Third, for methodological reasons we did not formulate an a priori hypothesis about the heteromodal cortex and cerebellar grey matter, although they have been related to severity of neurological soft signs. Reference Dazzan, Morgan, Orr, Hutchinson, Chitnis and Suckling11–Reference Thomann, Wustenberg, Santos, Bachmann, Essig and Schroder13
Future directions
Future longitudinal studies should combine follow-up assessments of neurological soft signs and neuroimaging to investigate whether neurodevelopmental changes in various neuroanatomic structures, including the heteromodal cortex and cerebellum, correlate with neurological soft signs changes and whether this association is diagnosis-specific. Our group is currently conducting such studies.
Funding
This study is supported by CIBER07/09, CIBER de Salud Mental (CIBERSAM), the Spanish Ministry of Health, Instituto de Salud Carlos III, ‘Fondo de Investigación Sanitaria’ G03/032, CIBER CB06/01/0079, CDTEAM Programa CéNIT, the Spanish Ministry of Industry and Programa Juan de la Cierva of the Spanish Ministry of Education and Science.
Acknowledgements
The authors thank the participants and their families.
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