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Department of Diagnostic Imaging, St Joseph’s Health Care, Lawson Health Research Institute, Department of Medical Biophysics and Department of Psychiatry, University of Western Ontario, London, Ontario
Lawson Health Research Institute and Department of Psychiatry, University of Western Ontario, London, Ontario
Lawson Health Research Institute and Department of Medical Biophysics, University of Western Ontario, London, Ontario
Department of Diagnostic Imaging, St Joseph’s Health Care, Lawson Health Research Institute, Department of Medical Biophysics and Department of Psychiatry, University of Western Ontario, London, Ontario
Department of Psychiatry, University of Western Ontario, London, Ontario
Department of Psychiatry, McGill University, Montreal, Quebec
Department of Psychiatry, University of Western Ontario, London, Ontario
Departments of Medical Biophysics and Psychiatry, University of Western Ontario and Centre for Functional and Metabolic Mapping, Robarts Research Institute, London, Ontario
Departments of Psychology and Psychiatry, University of Western Ontario
Departments of Medical Biophysics, Psychiatry, and Anatomy and Cell Biology, University of Western Ontario, London, Ontario
Department of Diagnostic Imaging, St Joseph’s Health Care, London, Ontario
Lawson Health Research Institute and Department of Psychiatry, University of Western Ontario
Department of Psychiatry, University of Western Ontario
Lawson Health Research Institute and Departments of Psychiatry and Medical Biophysics, University of Western Ontario, London, Ontario, Canada
Correspondence: Dr Jean Théberge, St Joseph’s Health Care, Nuclear Medicine and MR, Room B5-233, 268 Grosvenor Street, London, Ontario N6A 4V2, Canada. Tel: +1 519 646 6100 (x65635); fax: +1 519 646 6399; e-mail: jtheberge{at}lawsonimaging.ca
Declaration of interest None. Funding detailed in Acknowledgements.
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMETHODRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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Aims To determine whether glutamatergic changes in patients with schizophrenia correlated with grey-matter losses during the first years of illness.
Method Left anterior cingulate and thalamic glutamatergic metabolite levels and grey-matter volumes were examined in 16 patients with first-episode schizophrenia before and after 10 months and 30 months of antipsychotic treatment and in 16 healthy participants on two occasions 30 months apart.
Results Higher than normal glutamine levels were found in the anterior cingulate and thalamus of never-treated patients. Thalamic levels of glutamine were significantly reduced after 30 months. Limited grey-matter reductions were seen in patients at 10 months followed by widespread grey-matter loss at 30 months. Parietal and temporal lobe grey-matter loss was correlated with thalamic glutamine loss.
Conclusions Elevated glutamine levels in never-treated patients followed by decreased thalamic glutamine and grey-matter loss in connected regions could indicate either neurodegeneration or a plastic response to reduced subcortical activity.
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INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMETHODRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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We predicted that patients experiencing a first episode of schizophrenia would have higher than normal glutamatergic metabolite levels on the basis of our previous studies (Bartha et al, 1997; Théberge et al, 2002). From a previous cross-sectional study of chronic schizophrenia showing lower than normal glutamine levels in the anterior cingulate (Théberge et al, 2003), glutamatergic metabolites levels and grey-matter volumes were expected to decrease after 30 months in patients experiencing a first episode of schizophrenia and to remain unchanged in healthy participants. Furthermore, we predicted that the effect of medication alone on glutamatergic metabolites and grey-matter volumes would be minimal and that disease-related reductions in these quantities would become apparent when comparing never-treated patients and patients treated for approximately 2.5 years (30 months), but these parameters would not decrease in healthy participants assessed 2.5 years apart. Finally, we expected that the longitudinal differences in glutamatergic metabolites in the anterior cingulate and thalamus would correlate with the grey-matter volume differences in functionally connected cortical areas, because glutamatergic losses in a given region can also be attributed to loss of glutamatergic afferents from another structure, in which case local reductions in glutamatergic metabolites could be obtained without local grey-matter losses and in response to remote grey-matter losses.
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METHOD |
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TOPABSTRACTINTRODUCTIONMETHODRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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All participants were assessed by a psychiatrist using the Structured Clinical Interview for DSM–IV (SCID; First et al, 1997). Eleven participants were classified as having paranoid schizophrenia and five as having undifferentiated schizophrenia. The duration of untreated psychosis for participants with schizophrenia was evaluated and defined as the elapsed time between the first examination and the first appearance of positive symptoms. Symptoms of participants with schizophrenia were evaluated using the Scale for the Assessment of Negative Symptoms (SANS; Andreasen, 1983a) and the Scale for the Assessment of Positive Symptoms (SAPS; Andreasen, 1983b). The mean parental educational level of the most educated parent was rated on a four-point scale for all participants (level 1, grade 10 or below; level 2, grades 11–13; level 3, college 1–3 years; level 4, college 4 years or more). Handedness was assessed using a questionnaire (Bryden, 1977).
Four participants with schizophrenia received medications other than antipsychotics 1–10 days prior to their first scan (see Table 2). For patients receiving antipsychotic treatment, chlorpromazine equivalent dosages were calculated (Bezchlibnyk-Butler & Jeffries, 2002; Woods, 2003). At their second assessment, all patients were receiving atypical antipsychotics (not clozapine), with the exception of one patient who received haloperidol and two who did not receive antipsychotic medication but were judged to be clinically stable. At the final assessment two participants were taking clozapine and a third participant was no longer receiving medication.
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None of the participants had a history of head injury or of drug or alcohol misuse in the year before the scan, or a serious medical illness (according to SCID and anatomical MRI). Participants reported not using substances on the day of the scan; urinalysis was not always performed.
MRS and MRI
All MRI and MRS data were obtained using a 4.0 T Varian (Palo Alto,
California, USA)/Siemens (Erlangen, Germany) scanner with a Varian Unity Inova
console, Siemens Sonata gradients and a circularly polarised hybrid head
resonator (XLR Imaging Inc., London, Ontario, Canada). The methods of MRI data
acquisition and MRS data acquisition and data processing were identical to
those described in a previous report by Théberge et al
(2002). These procedures are
described briefly below.
After a manual adjustment of global magnetic field uniformity with first-
and second-order shims, a T1-weighted three-dimensional
imaging volume was obtained (three-dimensional magnetisation-prepared fast low
angle shot (MP-FLASH), inversion time (TI) 500 ms, time to repetition (TR)
11.4 ms, time to echo (TE) 6.2 ms, 
=30°, 64 slices, 2.75 mm thick,
field of view 20 cm, matrix 256x256) and used to prescribe MRS voxel
position, manually segment grey/white matter and cerebrospinal fluid (CSF)
within MRS voxels and perform voxel-based morphometry.
Localised short echo time 1H-MRS measurements (stimulated echo acquisition mode, STEAM; TR=2000 ms, TE=20 ms, mixing time (TM)=30 ms, acquisition time 1.5 s, dwell time 500 µs, size 10x10x15 mm3, eight-step eight-step phase cycle, averages: 256 water-suppressed, 16 unsuppressed) were obtained from voxels in the left anterior cingulate and left thalamus of each participant (retrospective description of average Talairach coordinates: anterior cingulate, –5.9, 46.7, 1.3 – Brodmann area (BA) 32; thalamus, –6.9, –14.3, 4.2). Voxels were positioned by the scanner operator (J.T. or N.A.) based on anatomical landmarks, as trained by our local neuroanatomy expert (N.R.). Local field uniformity and radio frequency pulse power were manually optimised for each voxel. The line shapes of the water-suppressed spectra were restored to a Lorentzian form using a combined QUALITY and eddy current correction (ECC) lineshape correction (QUECC; as in Bartha et al, 2000b). Residual water resonances between (4.2–6.2 ppm) were modelled using a Hankel–Lanczos singular value decomposition procedure and subtracted (Bartha et al, 1999). Before spectral quantification, the quality of every spectrum was evaluated using two visual scales to provide an index composed of a number from 1 to 10 (Visual Appreciation Scale) and a letter from A to E (Baseline and Artefact Scale). The combined scales allow a more structured determination of spectral quality and are used in the decision to discard a spectrum in cases of excessive voluntary or involuntary movement by the participant (further information about these scales is presented in Data Supplement 1 to the online version of this paper). In this study, we discarded spectra with a Visual Appreciation Scale rating lower than 5 and/or a Baseline and Artefact Scale rating poorer than B, and for which the spectral quantification procedure described below was unsuccessful (no metabolite level data produced). Quantification of the water-suppressed spectra was performed using the Lawson Health Research Institute Fitman spectral analysis suite (Bartha et al, 1999, 2000a), a software package developed by our group and used by us and by other international collaborators in more than 30 publications. Time domain fitting of the water-suppressed spectra used the first 1024 points acquired. The quantification model used a priori knowledge from 12 metabolite solutions and partial prior knowledge for three macromolecules and ten broad components as described by Bartha et al (1999, 2000a) (a complete list of the modelled spectral components can be found in the caption to Fig. 2). This quantification model using partial prior knowledge of broad spectral components is ideal for our short echo time STEAM-localised spectra acquired without outer-volume suppression (Bartha et al, 2000a). The water-unsuppressed spectra were lineshape corrected and fitted to a single Lorentzian model. Metabolite levels were obtained by normalising the metabolite amplitude by the corrected amplitude of the water-unsuppressed acquisition (further information is presented in Data Supplement 2 to the online version of this paper). Although other MRS studies present metabolite levels calculated in this fashion as ‘absolute’ concentrations in mol/l or mol/kgww, we present them as metabolite levels in arbitrary units owing to the arbitrary nature of the numerical values chosen for quantities such as temperature-dependent molecular weights and densities as well as the assumed water content of different brain tissues (grey matter 81%, white matter 71%, CSF 100%). These quantities were obtained from the literature rather than measured in each individual participant because of the time needed to obtain such measurements. Additional correction for relaxation weighting (T1, T2) and diffusion weighting of both metabolites and the water reference signals would be needed to claim absolute quantification; however, the magnitude of changes in these tissue parameters required to produce a significant change in metabolite levels is typically considered unlikely to be found in brains not affected by neoplasms, and thus these additional corrections are often ignored. The coefficients of variation of N-acetylaspartate, glutamate and glutamine metabolite levels using this technique (4.0 T, STEAM, TE=20 ms, 1.5 cm3 volume of interest) were 8%, 11% and 24% inter-individual and 7.3%, 8.9% and 16.9% intra-individual (Bartha et al, 2000a).
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For the two measurement period data (NT and 30M v. HPAR1 and
HPAR2) the overall layout entailed a 2x2 split-plot factorial design
with ‘measurement period’ being the two-level within-participant
factor and ‘participant group’ being the two-level
between-participant factor. With our directional hypotheses on the progression
of glutamate and glutamine levels, unidirectional statistical tests
(=0.05) were applied. Significant effects, however, met two-tailed
criteria throughout (Stevens,
1996). The time evolution of glutamate and glutamine levels for
participants with schizophrenia was tested separately from other metabolites
because of our directional hypotheses concerning these metabolites. Here, the
data layout entailed a three-level repeated-measures design using measurements
from NT, 10M and 30M. Spectroscopic data for which we had no a priori
hypotheses (macromolecular levels, the Glu/Gln ratio and the set of metabolite
levels residual to glutamate and glutamine) were examined using multivariate
analysis of variance (MANOVA) applied region-wise using the 2x2
(groupsxtime) split-plot factorial layout. For the patient group, the
above measures were subjected to a region-wise MANOVA using the aforementioned
three-level repeated-measures design. Constituent univariate analyses of
variance were applied to the individual variables of the multivariate set
pursuant to significant parent multivariate results (=0.05). Two-tailed
alphas of 0.05 (Hummel & Sligo,
1971; Stevens,
1996) were used for the follow-up univariate tests (e.g. the
statistical treatment in Jensen et
al, 2004).
Correlation between metabolite levels of participants with schizophrenia and symptoms scores (SANS and SAPS) as well as with length of illness and chlorpromazine equivalent dosage (30M only) were evaluated using the Pearson product-moment correlation coefficient (P<0.001).
Voxel-based morphometry maps were obtained for each participant using SPM2
(Wellcome Department of Imaging Neuroscience, University College London, UK)
and the T1-weighted images. Images were spatially
normalised to the T1-weighted template provided by SPM2
(Montreal Neurological Institute brain) and segmented into grey/white/CSF
images with the modified model cluster analysis after correcting for intensity
non-uniformity (Ashburner & Friston,
2000). Images were then modulated by the Jacobian determinants
obtained in the normalisation step and finally smoothed using an isotropic
Gaussian kernel (12 mm full width at half maximum)
(Ashburner & Friston,
2001). The SPM2 general linear model produced maps of the
t statistic for grey-matter ‘concentration’ changes
between participants (NT v. HPAR1, 30M v. HPAR2) or within
participants (NT v. 10M, NT v. 30M, 10M v. 30M,
three-level repeated-measures analysis; HPAR1 v. HPAR2) with a
corrected < 0.05 and extent threshold k=5. Difference maps
of grey-matter concentrations (NT—30M) were used in simple correlations
with scanning, treatment and MRS variables. Uncorrected values of
0.001 and k=5 were set to explore the hypothesised correlation of
grey-matter loss and glutamine loss.
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RESULTS |
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TOPABSTRACTINTRODUCTIONMETHODRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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General 1H-MRS and VBM results
The proton MRS section of this study produced 152 spectra: 2 regions per
participanx((3 time pointsx16 participants with schizophrenia
– 3 missing time points) + (2 time pointsx16 healthy
participants–1 missing time point)). Six of these spectra, obtained from
participants with schizophrenia, were considered unusable because of excessive
voluntary or involuntary movements during the acquisition
(Table 1); no successful
quantification was obtained from these six spectra. Discarded spectra had
spectral quality ratings of 0E, 0E, 4C, 3E and 10D and one thalamic spectral
acquisition was abandoned before completion owing to breathing-induced phase
variations. All discarded spectra had been obtained from male participants
(anterior cingulate: two NT, one 10M; thalamus: one NT, two 10M) and their
handedness was as follows: anterior cingulate, right-handed participants
exclusively (two NT, one 10M); thalamus, two right-handed participants (one
NT, one 10M) and one left-handed participant (10M).
Mean metabolite levels for both regions and all groups are presented in Fig. 1 along with group standard deviations and statistics for significant differences (macromolecule levels for both regions and all groups are presented in Data Supplement 3, and group standard deviations of metabolite levels and minimum detectable percentage difference between groups in Data Supplement 4 to the online version of this paper). A typical spectrum from the anterior cingulate of a participant with schizophrenia is shown in Fig. 2, together with the spectral model and components. Fitted line widths of unsuppressed water signals and time domain N-acetylaspartate area signal-to-noise ratios are presented in Data Supplement 5 to the online version of this paper. The distribution of thalamic glutamine levels is presented in Fig. 3 for all participant groups.
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Statistical comparisons
Proton MRS and VBM data were compared between participants with
schizophrenia and healthy participants (between participants) and among
participants with schizophrenia at different time points (within
participants). A summary of all statistical comparisons is presented in Data
Supplement 6 and details of significant VBM findings are presented in Data
Supplements 7 and 8. Significant findings are presented below.
Between-participant comparisons
Anterior cingulate glutamine levels were significantly elevated among
participants with schizophrenia (NT) compared with healthy participants
(HPAR1) (see Fig. 1). This
predicted result was embedded in a significant main effect of groups pursuant
to the routine tests of the 2x2 split-plot factorial analysis
(F=4.67, d.f.=1,26, P=0.04). The 2x2 analysis revealed
a significant effect for group at the univariate level in metabolite levels of
N-acetylaspartate (see Fig.
1) and macromolecular levels M1.41 (F=4.773, d.f.=1,26,
P=0.038) and M1.30 (F=4.945, d.f.=1,26, P=0.035).
These group differences were not significant at the multivariate level of
analysis; although not ignored, they are presented with this associated
caveat.
Left thalamic glutamate and glutamine levels showed significantly higher glutamine in participants with schizophrenia (NT) than in healthy participants (HPAR1) (see Fig. 1), but no significant difference in glutamate levels. The predicted elevation in level of glutamine for the patients’ first measurement period was considered as embedded in a significant (routinely computed) groupxtime interaction (F=5.76, d.f.=1,27, P=0.024), and main effect of time (P=0.02). Univariate split-plot factorial analysis of thalamic metabolite levels residual to glutamate and glutamine, macromolecular levels and the Glu/Gln ratio showed a significant group effect for the metabolite level of taurine (see Fig. 1), whereby participants with schizophrenia had lower levels than healthy participants. Note that Levene’s test for equality of error variances disclosed no significant difference for anterior cingulate and thalamic glutamate and glutamine, a statistical bias consideration when comparing groups of unequal size (Box, 1953, 1954; Milligan et al, 1987).
Between-group comparisons of grey-matter volume changes (VBM) showed
significant differences between the last assessment of healthy participants
and participants with schizophrenia (HPAR2>30M) but not in other
comparisons (HPAR1>NT, HPAR1<NT, HPAR2<30M) using corrected
t-statistics (=0.05, k=5). Two small regions of
significant grey-matter reduction were located in the left superior temporal
gyrus (BA 22, k=77) and the left caudate head (k=10).
Within-participant comparisons (three-level)
The three-level repeated-measures analysis of glutamine and glutamate
levels, in the anterior cingulate and thalamus respectively, yielded no
significant effect. There were insufficient residual degrees of freedom
(measure battery-to-participant ratio 
1) to perform a three-level
repeated-measures multivariate analysis of anterior cingulate metabolite
levels residual to glutamate and glutamine, macromolecular levels and Glu/Gln;
however, this was performed successfully with the corresponding thalamic
metabolite levels. Multivariate (thalamus only) and univariate three-level
repeated-measures analyses revealed no significant effect for any of these
measurements (the Huynh–Feldt non-sphericity correction was applied for
these tests) in both the anterior cingulate and thalamus.
The three-level within-group comparisons of VBM data from participants with
schizophrenia (NT, 10M, 30M) yielded significantly different regions for
NT>10M, NT>30M and 10M>30M (corrected =0.05, k=5,
d.f.=2,24). Figure 4 presents
the distribution of regions of reduced grey-matter volume (NT>30M)
superimposed on a cortical surface rendering. Regions with significant
grey-matter volume reductions (NT>30M) include cortical regions of the
frontal lobe (middle frontal gyrus: BA 46, 8 and 9; medial frontal gyrus: BA 6
and 8; inferior frontal gyrus: BA46, 9 and 44) bilaterally, the bilateral
temporal lobe (BA 38, 39, 42, 21 and 22), the bilateral parietal lobe (BA 7,
40, 31 and 39), the limbic lobe (BA 28 and 31 (posterior cingulate),
hippocampus and amygdala), the right caudate and right thalamus.
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The split-plot factorial MANOVA on thalamic metabolite levels residual to
glutamate and glutamine, macromolecular levels and Glu/Gln yielded no
significant effect. Univariate split-plot factorial analysis of the same
measurements nevertheless revealed a significant effect for time in two
macromolecular levels: both M1.50 (F=5.745, d.f.=1,27,
P=0.024) and M1.41 (F=7.123, d.f.=1,27, P=0.013)
decreased with time. Pursuant to the significant findings of the three-level
analysis of the VBM data, within-group two-level comparisons (NT>10M,
NT>30M, 10M>30M) were computed post hoc with a more exploratory
uncorrected =0.00001 and k=5 (d.f.=1,12). Significant
reductions in grey-matter volume were found in all three comparisons (results
are presented in Data Supplement 6).
Grouping of VBM data from participants with schizophrenia according to
subtype (paranoid v. undifferentiated) in a 2x2 split-plot
factorial design did not produce any significant effect for group using a
corrected =0.05 and k=5. Grey-matter loss across time (NT
v. 30M) was not significantly different between subtypes (corrected
P<0.05, k=5).
Based on the grey-matter, white-matter and CSF segmentation procedure performed on the anterior cingulate and thalamic MRS volumes of interest for the calculation of tissue content correction factors used in spectral quantification, a technique akin to traditional grey-matter volume measurements, the amount of grey-matter did not differ between the first and last scan of patients (anterior cingulate, P=0.58; thalamus, P=0.47; two-tailed paired t-test) and controls (anterior cingulate, P=0.98; thalamus, P=0.32; two-tailed paired t-test).
Correlations
None of the anterior cingulate and thalamic metabolite levels,
macromolecular levels or Glu/Gln showed a significant correlation with SANS or
SAPS scores, length of illness or antipsychotic dosage (chlorpromazine
equivalents) (P>0.001). Correlation coefficients of glutamine
levels with SANS scores, SAPS scores, length of illness and antipsychotic
dosage were respectively 0.208 (P=0.186), 0.016 (P=0.920),
–0.259 (P=0.098) and –0.217 (P=0.168) in the
anterior cingulate, and 0.134 (P=0.398), 0.242 (P=0.123),
–0.137 (P=0.399) and 0.058 (P=0.714) in the thalamus.
Although these spectral components overlap in terms of chemical shift, there
was no significant correlation between anterior cingulate levels of glutamine
and M2.70 (r=0.056, P=0.637), M2.29 (r=0.203,
P=0.085), M2.05 (r=0.19, P=0.870),
gamma-amino-butyric acid (GABA) (r=0.196, P=0.097) or
N-acetylaspartylglutamate (NAAG) (r=–0.201,
P=0.088), or between thalamic levels of glutamine and M2.70
(r=–0.201, P=0.227), M2.29 (r=0.095,
P=0.426), GABA (r=0.036, P=0.763) or NAAG
(r=–0.027, P=0.818) as assessed with a two-tailed
Pearson–moment correlation in all groups combined (n=73).
Thalamic levels of glutamine did loosely correlate with M2.05
(r=–0.381, P=0.01, n=73) which is a
macromolecular level that was not included in the planned statistical analyses
(s.d.>75%). However, upon post hoc examination no significant
difference in M2.05 levels was found between any group of participants.
Correlation of grey-matter loss in participants with schizophrenia (NT
—30M) and antipsychotic dosage at 30M showed no significant results
using a corrected value of 0.05. However, significant correlation was
found in three areas of the brain using an exploratory uncorrected of
0.001: left frontal lobe (precentral gyrus, BA 6, x y z –50, 2,
28; P<0.001, t=8.38); left frontal lobe (superior gyrus,
BA 10, x y z –18, 64, 18; P<0.001,
t=6.59); right frontal lobe (inferior gyrus, BA 9, x y z=32,
16, 28; P<0.001, t=4.93).
Grey-matter loss (NT —30M) did not show any significant correlation
with the time elapsed between NT and 30M assessments using an uncorrected
of 0.001.
Correlation of grey-matter loss (NT —30M) assessed by VBM with
reduction in thalamic glutamine (NT —30M) was found in four areas of the
brain when using an uncorrected of 0.001 and n=14: right
parietal lobe (precuneus, BA 7, x y z 16, –44, 46;
P<0.001, t=6.28); left parietal lobe (angular gyrus, BA
39, x y z –30, –64, 30; P<0.001,
t=6.09); left temporal lobe (inferior gyrus, BA 20, x y z
–58, –36, –22; P<0.001, t=4.51); left
temporal lobe (superior gyrus, BA 41, x y z –44, –26, 12;
P<0.001, t=4.40). The correlation between left superior
temporal gyrus grey-matter concentration loss and left thalamic glutamine loss
is presented in Fig. 5
(r=0.741, n=14, P<0.001).
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Given the finding of positive correlation between thalamic glutamine loss and grey-matter volume loss from the VBM analysis, we expected a similar positive correlation between voxel grey-matter loss (first scan to last scan), as assessed during the grey/white/CSF segmentation procedure of the MRS analysis, and glutamine loss (first scan to last scan) in patients, and no correlation in controls. No significant correlation was found overall. In the anterior cingulate of patients (NT —30M) a trend towards a significant negative correlation was observed (r=–0.453, P=0.120, two-tailed, n=13), but no significant result was observed in controls (r=–0.149, P=0.597, two-tailed, n=15). No significant correlation was observed in the thalamus of patients (r=0.158, P=0.590, two-tailed, n=14) and controls (r=0.027, P=0.925, two-tailed, n=15).
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DISCUSSION |
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TOPABSTRACTINTRODUCTIONMETHODRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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Glutamine levels did not significantly decrease in the left thalamus in participants with schizophrenia whose symptoms were stabilised with medication for 10 months, suggesting that medication or clinical status did not affect the findings. The absence of significant correlation between medication levels or clinical assessments and glutamine levels also suggest that these variables do not explain the findings. Decrease in thalamic glutamine within a period of 30 months in participants with schizophrenia could be explained by an excitotoxic process. However, glutamine levels did not decrease below healthy levels in either regions of interest. This contrasts with lower-than-normal glutamate and glutamine levels found in the anterior cingulate of patients with chronic schizophrenia (duration of illness 15 years) (Théberge et al, 2003). If excitotoxicity is responsible for glutamine decreases from elevated first-episode levels to lower than normal levels in patients with chronic illness, this study suggests that more than 30 months must elapse for its manifestation. This result also contrasts with the higher than normal thalamic levels of glutamine found in patients with chronic schizophrenia (Théberge et al, 2003); however, the majority of these patients were being treated with conventional rather than atypical antipsychotics for 10 years or more, which might account for the difference.
Anterior cingulate glutamine levels in never-treated participants with schizophrenia did not significantly decrease upon follow-up, suggesting that glutamatergic activity remains elevated in this region for at least 30 months. As expected, no significant difference in glutamine levels was observed between the initial and follow-up examination in healthy participants, suggesting that ageing does not affect normal glutamatergic activity over a period of 30 months. We did not observe any significant difference in N-acetylaspartate levels between participants with schizophrenia and healthy participants at first assessment or follow-up, which is consistent with studies using the same (Bartha et al, 1997; Théberge et al, 2002, 2003) or similar methods (short echo time MRS and spectral analysis without non-physical baseline modelling).
Volumetric alterations
Voxel-based morphometry uncovered no significant grey-matter volume
difference in the anterior cingulate and thalamus when comparing never-treated
participants with schizophrenia and healthy participants. This suggests that
significant differences in glutamine levels observed in never-treated
participants compared with healthy participants are unlikely to be secondary
to a programmed loss of neuropil (Selemon et al, 1999) prior to onset
of symptoms or to other neurodevelopmental processes involving early
grey-matter loss. However, elevated levels of glutamine in the early stages of
untreated schizophrenia suggest a pre-existing dysregulation of the limbic
basal ganglia–thalamocortical pathway
(Alexander et al,
1990), the origin of which is not apparent from this study. No
grey-matter volume difference was detected between the two healthy participant
assessments 30 months apart. This suggests that grey-matter reductions related
to normal ageing are unlikely to play a part in our findings.
Both the 10-month and 30-month assessments of participants with schizophrenia showed significant reductions in grey matter compared with the first (never-treated) assessment. After 10 months of treatment and stabilisation of symptoms, only a small cluster of voxels showed significantly reduced grey-matter volume in the left precuneus. After 30 months of treatment the significant reductions were widespread and had expanded to include regions of the frontal, temporal, parietal and limbic lobes. These observations are similar to those of previous studies (Shenton et al, 2001; Thompson et al, 2001; Gogtay et al, 2004; Honea et al, 2005), particularly those looking at patients with first-episode disorder. Even after a short period of treatment (10 months) and stabilisation of symptoms, grey-matter volume reductions were observed, which suggests that antipsychotic medication might be partly responsible for the losses. However, the progressive nature of the grey-matter losses demonstrated at the 30-month assessment, when both clinical status and antipsychotic treatment had remained practically unchanged, suggests that the additional losses are disease-related. Late effects of antipsychotic medication on cortical volume are also a possibility.
Excitotoxicity or plasticity?
It is curious that no grey-matter loss was observed in regions where
elevated glutamine was detected in never-treated participants with
schizophrenia; this was expected, assuming the action of a glutamatergic
excitotoxic process. It is possible that the use of a 12 mm smoothing kernel
in the VBM analysis reduced our sensitivity to grey-matter changes in small
structures (White et al,
2001) within the MRS regions of interest. However, traditional
grey/white/CSF segmentation performed on the MRS volume of interest only also
did not detect significant grey-matter loss in the anterior cingulate and
thalamus. Detected regions of grey-matter loss, such as the dorsolateral
prefrontal cortex and superior temporal gyrus, are closely connected with both
the thalamus and the anterior cingulate. Interestingly, the posterior
cingulate – one of the regions demonstrating significant reduction in
grey matter at the 30 months assessment – is one of the first regions to
incur excitotoxic damage after an acute administration of glutamate
N-methyl-D-aspartate receptor antagonist in the rat model
of schizophrenia of Olney & Farber
(1995). Other schizophrenia
models have proposed that regions of the dorsolateral prefrontal cortex and
temporal lobe cortex regulate the limbic basal ganglia–thalamocortical
circuit which includes the anterior cingulate and thalamus
(O’Donnell & Grace,
1998). Thus a programmed loss of neuropil in these cortical
regions prior to the onset of symptoms could be associated with a secondary
excitotoxic process in the limbic basal ganglia–thalamocortical circuit.
However, in our study no lower than normal grey-matter volume consistent with
loss of neuropil was observed at the initial assessment in those cortical
regions. Thalamic input has an important role in directing the neuroplastic
processes during cortical development
(Jafari et al, 2007)
and probably has a significant role in adult cortical plasticity
(Weinberger, 1995). The
reciprocal connections between the thalamus and cortical regions are a
potential conduit by which decreasing thalamic activity (evidenced in this
study by a progressive reduction in glutamine) could lead to a plastic
response. The finding of significantly correlated superior temporal lobe
grey-matter loss and thalamic glutamine loss supports this interpretation.
Limitations
Some limitations should be acknowledged. Proton MRS measurements of
glutamate and glutamine reflect the combined intra- and extraneuronal
concentration within a somewhat coarse region of interest despite the use of
high-field systems. Increases in glutamine concentration may not reflect
increases in glutamatergic activity if a problem exists with the conversion of
glutamine to glutamate in the astrocytic compartment of the
glutamate–glutamine cycle. However, there is no consistent evidence for
such enzymatic abnormality in schizophrenia. Glucose metabolism also
influences glutamatergic neurotransmission by synthesising 15–20% of the
glutamate entering the glutamate–glutamine cycle
(Hertz et al, 1999).
The single-voxel MRS localisation technique used produced high-quality data
from the anterior cingulate and thalamus yet did not permit the acquisition of
MRS data from other regions of the brain potentially implicated in
schizophrenia within a reasonable examination time. Macromolecular signals
have been hypothesised by some to potentially influence glutamate and
glutamine measurements. However, post hoc correlations of glutamine
levels and overlapping macromolecular levels do not show a significant link,
with the exception of thalamic glutamine levels and macromolecular level M2.05
which show a loose association. This association is not sufficient to explain
significant findings in thalamic glutamine. Correlation with a greater number
of overlapping components would have been necessary in order to explain the
glutamine findings because of the fairly wide spread in chemical shift of
glutamine’s gamma and beta multiplets. Such a quantification artefact
would probably have occurred in anterior cingulate data as well, yet no
correlation was found between glutamine and macromolecular levels in this
region. The number of participants in this study is fairly small owing to the
complexity of following them up over several years. Steen et al
(2005) suggest that 39
patients and 29 controls are needed to obtain 80% statistical power to detect
a 10% difference in N-acetylaspartate. Consequently, the number of
participants might not have been sufficient to detect differences in
metabolites such as N-acetylaspartate. The VBM technique may have
limited ability to detect grey-matter volume differences in certain parts of
the brain, and the use of large smoothing kernels may render the analysis
sensitive to partial volume effects. Future studies should verify the observed
progressive loss of grey matter with more conventional but time-consuming
volumetric techniques.
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ACKNOWLEDGMENTS |
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TOPABSTRACTINTRODUCTIONMETHODRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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Received for publication November 28, 2007. Revision received March 8, 2007. Accepted for publication April 30, 2007.
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-aminobutyric acid,
creatine and phosphocreatine, choline-containing compounds, taurine,
myo-inositol, scyllo-inositol, aspartate,
N-acetylaspartylglutamate, glucose ß and other components
accounting for glutamate’s and glutamine’s 2CH
multiplets, creatine’s 2CH2 resonance and residual
water peaks); (c) macromolecular spectral components; 13 unidentified broad
resonances(top to bottom: M3.15, M3.00, M2.70, M2.29, M2.05, M1.75, M1.70,
M1.50, M1.41, M1.30, M1.22, M0.90, M0.60; naming is based on seeded chemical
shift in ppm).
