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Neuroimaging and other neurobiological indices in schizophrenia: relationship to measurement of functional outcome

Published online by Cambridge University Press:  02 January 2018

John L. Waddington
John L. Waddington*
Affiliation:
Molecular and Cellular Therapeutics, Royal College of Surgeons in Ireland, St Stephen's Green, Dublin 2, and St Davnet's Hospital, Cavan-Monaghan Mental Health Service, Monaghan, Ireland. Email: [email protected]
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Abstract

Background

As understanding of the pathobiology of schizophrenia increases, the challenge is to relate such measures to outcome at a functional level

Aims

To consider our current understanding of how neurobiological variables relate to functional outcome and might constitute outcome measures in their own right

Method

Critical appraisal of recent evidence on structural and functional imaging, neurological evaluation, early neurodevelopmental indices, genomics, proteomics, metabolomics and apoptotic mechanisms in relation to outcome

Results

Studies conducted prospectively from the first episode of schizophrenia are generating more reliable findings but currently lack predictive power. Prediction of transition from ‘high-risk’ status to first episode has proved somewhat more fruitful, but the gain has been modest and circumscribed

Conclusions

Our current level of understanding does not yet allow the generation of predictive models on an individual patient basis. Genomic and metabolomic studies hold particular potential for generating clinically meaningful ‘biomarkers’ but considerable further work is necessary

Type
Review Articles
Information
The British Journal of Psychiatry , Volume 191 , Issue S50: Evolution of outcome measures in schizophrenia , August 2007 , pp. s52 - s57
Copyright
Copyright © Royal College of Psychiatrists, 2007 

Over recent decades our understanding of the pathobiology of schizophrenia has increased materially. The body of knowledge accumulated gives us some insight into: (a) aetiological factors, in terms of genetic risk variants (Reference Harrison and WeinbergerHarrison & Weinberger, 2005; Reference Owen, Craddock and O'DonovanOwen et al, 2005; Reference Karayiorgou and GogosKarayiorgou & Gogos, 2006) and environmental adversities, both biological and psychosocial (Reference van Os, Krabbendam and Myin-Germeysvan Os et al, 2005; Reference Spauwen, Krabbendam and LiebSpauwen et al, 2006); (b) putative pathophysiological processes, in terms of developmental disruption in critical neuronal networks (Reference Waddington, Lane and LarkinWaddington et al, 1999; Reference Waddington and MorganWaddington & Morgan, 2001; Reference Harrison and WeinbergerHarrison & Weinberger, 2005; Reference Stephan, Baldeweg and FristonStephan et al, 2006) and the role of these early events in ‘kick starting’ a lifetime-trajectory model of the disorder (Reference DeLisiDeLisi, 1999; Waddington et al, Reference Waddington, Lane and Larkin1999, Reference Waddington, Kingston, O'Tuathaigh, Carpenter and Thaker2007; Reference Baldwin, Hennessy, Morgan, Gattaz and HaffnerBaldwin et al, 2004); and (c) the relationship of such pathophysiology to aspects of psychopathology and cognitive deficit (Reference Flashman and GreenFlashman & Green, 2004).

However, it is important not to underestimate the superficiality of these insights. Studies are, in the main, cross-sectional in nature, often in people with an established illness, and thus fail to inform directly on the relationship of biological variables to subsequent course of illness at any level. A new generation of prospective studies, particularly those from the first psychotic episode (Reference Keshavan, Berger and ZipurskyKeshavan et al, 2005; Reference WaddingtonWaddington, 2005), now allows these relationships to be explored systematically, but have focused primarily on the conundrum of whether the biological variables themselves are static or progressive thereafter and how such biology might relate to the longitudinal characteristics of psychopathology and cognitive deficit.

Thus, a fundamental challenge remains: how do we relate cross-sectional and prospective studies of biological measures not just to psychopathology and cognition but also to functional outcome, even on a population basis. More specifically, in the present context the yet greater challenge is to relate specific neurobiological indices to their individual outcomes. The purpose of this article is to outline current understanding of the relationship between neurobiological variables and functional outcome, both on a population basis and in terms of the individual patient, and whether any neurobiological variables have potential for becoming outcome measures in their own right.

STRUCTURAL IMAGING

Magnetic resonance imaging

Magnetic resonance imaging (MRI) has established that subtle but widespread abnormalities of cortical and subcortical brain structure are present in schizophrenia on a population basis (Reference Lawrie and AbukmeilLawrie & Abukmeil, 1998; Reference Wright, Rabe-Hesketh and WoodruffWright et al, 2000; Reference Shenton, Dickey and FruminShenton et al, 2001; Reference Honea, Crow and PassinghamHonea et al, 2005). A related technique, diffusion tensor imaging (DTI), is a relatively new modality that can examine, through fractional anisotropy, the microstructure of white matter and, through fibre tractography, aspects of neuronal connectivity in the brain. The majority of a limited number of DTI studies to date (Reference Kanaan, Kim and KaufmannKanaan et al, 2005) have indicated reductions in white matter integrity which supports a broader interpretation of structural brain pathology in schizophrenia to involve cortical disconnectivity (Reference Stephan, Baldeweg and FristonStephan et al, 2006).

Cross-sectional relationship to outcome

Studies have sought to relate structural brain pathology on MRI to aspects of outcome on a cross-sectional basis, usually by subdividing patients retrospectively into ‘good’ v. ‘poor’ outcome groups and comparing them on various MRI measures at a single index assessment. For example, while patients of whatever outcome evidenced smaller thalamic volume relative to controls, those with poor outcome (i.e. hospitalised for more than 50% of the total duration of illness and continuously hospitalised over the past 3 years) evidenced enlargement of the lateral and third ventricles and reduced overall grey matter volume, particularly in the prefrontal cortex, whereas those hospitalised for less than 10% of total duration of illness and not hospitalised over the past year did not (Reference Staal, Hulshoff and SchnackStaal et al, 2001). Similarly, patients of whatever outcome evidenced an overall reduction in grey matter volume relative to controls, particularly in the frontal and temporal lobes, but those with poor outcome, ‘Kraepelinian’ schizophrenia (i.e. continuously hospitalised or completely dependent on others for basic needs, unemployed, with severe negative symptoms and severe thought disorder) evidenced reduced grey matter volume in the temporal and occipital but not in the frontal lobes relative to their good-outcome (i.e. non-‘Kraepelinian’) counterparts (Reference Mitelman, Shihabuddin and BrickmanMitelman et al, 2003).

However, such studies illustrate how the indirect nature and inconsistency of the relationship between MRI measures and retrospective, dichotomous indices of outcome, on a population basis, precludes the generation of a predictive model in relation to the individual patient. Such models can only be generated in longitudinal studies.

Longitudinal relationship to outcome over chronic illness

The putative utility of MRI measures as indices of outcome is associated with the enduring debate on the extent to which structural brain pathology in schizophrenia does or does not progress. The weight of evidence from longitudinal studies beginning at various stages of illness (Reference Pantelis, Yucel and WoodPantelis et al, 2005), together with incisive, pseudo-longitudinal analyses of cross-sectional studies (Reference Woods, Ward and JohnsonWoods et al, 2005), now suggests a small but significant acceleration in the loss of cortical grey matter volume with associated enlargement of cerebrospinal fluid (CSF) spaces in the long term. To the extent that one can generalise from very early-onset schizophrenia in children to the more typical presentation in young adulthood, there is initial evidence for dynamic tissue loss that progresses to frontal, but less so to cingulate and temporal cortex, in ‘waves’ along the anterior–posterior and dorsal–ventral axes (Reference Vidal, Rapoport and HayashiVidal et al, 2006).

Studies have related such longitudinal changes to aspects of outcome, usually in terms of MRI measures and assessments of clinical course made on two occasions at the beginning and end of a given period of follow-up. For example, over a mean interval of 3.6 years (range 0.6–7.5), patients who had been ill for a mean of 15.3 years (range 2.2–26.5) evidenced greater decline in cortical grey matter and greater increase in both frontal and temporal cortical sulcal and ventricular CSF volumes relative to controls. The rate of expansion in frontal sulci was associated with higher overall positive symptom scores and a longer percentage of time spent in hospital over follow-up; the rate of decrease in grey matter and of sulcal expansion in prefrontal cortex was associated with higher overall negative symptom scores and longer percentage of time spent in hospital; and the rate of decrease in grey matter and of sulcal expansion in temporal cortex was associated with higher overall negative symptom scores (Reference Mathalon, Sullivan and LimMathalon et al, 2001).

However, although such studies support the presence of some subtle but poorly understood neuroprogressive process in schizophrenia, they involve people with differing durations of chronic illness at the start of variable periods of longitudinal assessment who are assessed using a limited range of outcome measures, on a population basis. Thus, they are unable to generate a predictive model in relation to individual patients. Such models can only be generated in prospective studies from the first psychotic episode.

Prospective relationship to outcome from the first episode

It is now clear that some aspects of structural brain pathology evident on MRI in chronic schizophrenia, particularly reduction in whole brain and hippocampal volumes, together with enlargement of the third and lateral ventricles, are present at the time of the first psychotic episode and therefore pre-date onset of diagnostic symptoms (Reference Steen, Mull and McClureSteen et al, 2006; Reference Vita, De Peri and SilenziVita et al, 2006). Diffusion tensor imaging also indicates lower fractional anisotropy, consistent with white matter abnormalities at the first episode (Reference Szeszko, Ardekani and AshtariSzeszko et al, 2005). Thereafter, as considered above in the context of chronic illness, there is a small but significant acceleration in loss of cortical grey matter volume with associated enlargement of CSF spaces (Reference Pantelis, Yucel and WoodPantelis et al, 2005; Reference Whitford, Grieve and FarrowWhitford et al, 2006). The ‘anchor’ event of the first psychotic episode provides a frame of reference from which any relationships between MRI parameters and long-term outcome can be explored prospectively.

Studies have related such longitudinal change to prospective evaluation of outcome, usually in terms of MRI measures and assessments of clinical course made on two occasions: at the first episode and at variable periods of follow-up. For example, in a prospective study over 3 years, extent of ventricular enlargement during this period was associated with poor outcome as dichotomised in terms of remission of positive symptoms; extent of reduction in frontal lobe white matter volume and of increase in frontal lobe sulcal CSF volume were associated with greater negative symptom severity; extent of reduction in frontal lobe grey matter volume was associated with poorer executive functioning over follow-up (Reference Ho, Andreasen and NopoulosHo et al, 2003).

Although this study addressed relationships between longitudinal changes in MRI parameters and outcome measures, a critical question is whether any cross-sectional MRI measure made at the first episode is predictive of subsequent outcome as assessed prospectively. In a prospective study over 2 years, total brain volume and volumes of cortical grey and white matter, third and lateral ventricles and cerebellum at the first or second episode failed to predict outcome in terms of positive or negative symptoms, social disability and need for care (Reference van Haren, Chan and Polvan Haren et al, 2003). Similarly, in a prospective study over 5 years, smaller temporal lobe grey matter volume at the first episode was associated with persistence of hallucinations; however, initial temporal and frontal lobe tissue and sulcal and ventricular CSF volumes were unrelated to negative symptoms, extent of hospitalisation or psychosocial outcome (quality of relationships, sexual activity, recreation and work performance) over follow-up (Reference Milev, Ho and ArndtMilev et al, 2003). In a further prospective study over 2 years, decreasing volume of the dorsolateral prefrontal cortex at the first episode was associated with poorer functional outcome, in terms of social and employment indices, at 1 but not at 2 years (Reference Prasad, Sahni and RohmPrasad et al, 2005).

However, although such studies further elaborate the presence of some subtle but poorly understood neuroprogressive process in schizophrenia, they indicate that MRI measures made at and following the first psychotic episode have only limited capacity to predict outcome on a patient population basis. Thus, they are unable to generate a predictive model in relation to individual patients. One potential confound in all such studies is an effect of long-term antipsychotic treatment on brain tissue volumes. Magnetic resonance imaging studies have indicated that volumes of the basal ganglia and pituitary are increased following exposure to typical but not atypical antipsychotics (Reference Lieberman, Toffefson and CharlesLieberman et al, 2005; Reference Pariante, Dazzan and DanesePariante et al, 2005). More extensive studies have indicated exposure to typical antipsychotics to be associated with some reduction in cortical grey matter volume, whereas atypical agents can be associated with some increase in this volume (Reference Dazzan, Morgan and OrrDazzan et al, 2005; Reference Garver, Holcomb and ChristensenGarver et al, 2005; Reference Lieberman, Toffefson and CharlesLieberman et al, 2005). Given the practical difficulties in conducting MRI studies during the first episode in a person with no antipsychotic treatment, especially in a clinical setting, these effects could clearly confound the search for relationships between MRI measures and outcome.

Prospective relationship to transition from high-risk/prodrome to first episode

Over the past several years there has emerged a yet earlier domain of outcome: that of transition v. non-transition from high-risk status (defined usually in terms of affected family member(s), attenuated or transient psychotic symptoms and functional decline) to first-episode psychosis.

In a novel and important MRI study over a prospective period of at least 1 year (Reference Pantelis, Velakoulis and McGorryPantelis et al, 2003), those high-risk participants who developed first-episode psychosis were characterised by a reduction in parahippocampal, fusiform and orbito-frontal cortex, and in cingulate gyri; for those who did not develop a first psychotic episode, no such longitudinal changes were evident. On addressing the critical question of whether any cross-sectional MRI measure made in the high-risk state is predictive of outcome as assessed prospectively, transition to a first psychotic episode was associated with reduced grey matter volume in the medial and lateral temporal, inferior frontal and cingulate cortex.

In a related study over a prospective period of 5 years, those high-risk participants who received two MRI scans at an interval of 2 years and subsequently received a diagnosis of schizophrenia were distinguished from those who did not receive this diagnosis by reduction in grey matter density in temporal gyrus, uncus and cerebellum between those two scans; cross-sectional MRI measures made in the high-risk state did not differ between those who did and did not go on to receive a diagnosis of schizophrenia (Reference Job, Whalley and JohnstoneJob et al, 2005). However, transition to psychosis, not just to schizophrenia but also particularly to psychotic depression, is associated with larger pituitary volume in the high-risk state, suggesting stress-related activation of the hypothalamic–pituitary–adrenal axis (Reference Garner, Pariante and WoodGarner et al, 2005). However, it is far from clear whether such findings, made on a patient population basis, allow generation of a predictive model in relation to individual patients.

FUNCTIONAL IMAGING

Functional magnetic resonance imaging

Functional magnetic resonance imaging (fMRI) accesses regional neuronal activation in terms of change in blood oxygenation. Although a variety of cross-sectional fMRI findings in schizophrenia have been reported (Reference Tost, Ende and RufTost et al, 2005), systematic, prospective studies from the high-risk state or the first psychotic episode in relation to outcome are in their infancy.

A recent cross-sectional study has examined frontal and cingulate cortex, thalamic and basal ganglia activation during executive processing in those at high risk and in both early-phase and patients with chronic illness in comparison with controls (Reference Morey, Inan and MitchellMorey et al, 2005). The findings indicate that prefrontal function begins to decline before the emergence of diagnostic symptoms and impairment in frontostriatal function is evident thereafter. Recently, a prospective study over a period of 5 years has examined activation during a sentence completion task (Reference Whalley, Simonotto and MoorheadWhalley et al, 2006). Cross-sectional fMRI measures made in the high-risk state indicated that those who went on to receive a diagnosis of schizophrenia were distinguished from those who did not by decreased activation of the anterior cingulate, increased activation of the parietal lobe and smaller increases in activation with increasing task difficulty. However, only four high-risk participants evidenced transition to schizophrenia over the follow-up period (Reference Whalley, Simonotto and MoorheadWhalley et al, 2006). The elaboration of such fMRI studies in those at high risk and first-episode patients on a prospective basis has the potential to provide important additional information on the prediction of long-term outcome. However, possible confounding effects of antipsychotic drugs on fMRI measures remain a cause for concern (Reference Davis, Jeste and EylerDavis et al, 2005).

Magnetic resonance spectroscopy

Magnetic resonance spectroscopy (MRS) also accesses functional processes, primarily the concentration of various brain metabolites, to provide more detailed information on regional cellular mechanisms.

Although a variety of cross-sectional MRS findings in schizophrenia have been reported (Reference Keshavan, Berger and ZipurskyKeshavan et al, 2005), only one study to date has systematically applied this technique prospectively from the first psychotic episode in relation to outcome. Over a prospective period of 1.5 years, a lower N-acetylaspartate/creatine ratio, a putative index of neuronal integrity, at the first episode was associated with poorer outcome in terms of global assessment of functioning, social and occupational functioning and number of hospital admissions (Reference Wood, Berger and LambertWood et al, 2006). As for fMRI, the extension of MRS studies to those at high risk and first-episode patients on a prospective basis, to include assessments beyond transition to psychosis, has the potential to provide important additional information on prediction of long-term outcome. Similarly, as for fMRI, possible confounding effects of antipsychotic drugs on MRS measures remain a cause for concern (Reference Davis, Jeste and EylerDavis et al, 2005).

Emission tomography

Positron emission tomography (PET) and single-photon emission computed tomography (SPECT) are related techniques that access functional processes such as receptor availability, drug–receptor occupancies, transmitter biosynthesis/catabolism and cerebral metabolic activity. Although a variety of cross-sectional PET/SPECT findings in schizophrenia have been reported, only a few studies have systematically applied these techniques prospectively from the high-risk state or the first psychotic episode in relation to outcome. These relate primarily to contemporary versions of the long-standing dopamine hyperactivity model of psychosis, as recently elaborated (Reference Kapur, Mizrahi and LiKapur et al, 2005; Reference Seeman, Schwarz and ChenSeeman et al, 2006).

Over a prospective period of 2 years, higher SPECT binding of 123I-iodobenzamide to striatal D2 dopamine receptors at the first psychotic episode was associated with poorer social and occupational outcome among those who attained a follow-up diagnosis of schizophrenia but not among those who retained a diagnosis of schizophreniform disorder (Reference Corripio, Perez and CatafauCorripio et al, 2006). Recently, a PET study of striatal 18F-DOPA uptake has indicated dopamine overactivity in people in the high-risk state. These people are being followed prospectively to determine whether those who go on to evidence a first psychotic episode have raised 18F-DOPA uptake compared with those who do not (Reference Howes, Montgomery and AsselinHowes et al, 2006). Elaboration of such prospective PET/SPECT studies of those at high risk to include assessment of outcome beyond transition to psychosis has the potential to provide important additional information on prediction of long-term outcome. As for fMRI and MRS, possible confounding effects of antipsychotic drugs on PET/SPECT measures remain a cause for concern (Reference Davis, Jeste and EylerDavis et al, 2005).

NEUROLOGICAL EVALUATION

Electroencephalography

Although electroencephalography (EEG) has a history in biological psychiatry that long pre-dates the emergence of MRI, fMRI, MRS and PET/SPECT techniques, it has failed to match their impact. The recent introduction of techniques such as gamma synchrony has contributed to a new wave of incisive studies.

For example, a cross-sectional study in first-episode schizophrenia has reported decreased magnitude and delayed latency for frontal gamma 1 but not gamma 2 synchrony time-locked to target auditory stimuli, indicating disturbance in connectivity of neural activity in early sensory response to task-relevant stimuli, in a manner that may be modulated by antipsychotic drugs (Reference Symond, Harris and GordonSymond et al, 2005). The extension of such EEG studies to those at high risk and first-episode patients on a prospective basis has the potential to provide important additional information on prediction of long-term outcome.

Neurological soft signs

Neurological soft signs are non-localising abnormalities that cannot be related to impairment in a specific brain region and are not part of a well-defined neurological syndrome. They constitute evidence for otherwise unspecified brain dysfunction and have been shown consistently to occur to excess in schizophrenia (Reference Bombin, Arango and BuchananBombin et al, 2005).

Studies have indicated that the extent of neurological soft signs at the first episode has little relationship to long-term outcome, for example global or occupational functioning (Reference Bombin, Arango and BuchananBombin et al, 2005). Recently, in a study over a prospective period of 4 years from the first episode, improvement in neurological soft signs score was associated with better overall outcome over the same period (Reference Whitty, Clarke and McTigueWhitty et al, 2006). However, in a study over a prospective period of 1 year, extent of neurological soft signs at the first episode failed to predict outcome in terms of psychopathology or rate of relapse, defined as hospitalisation or unscheduled visit due to exacerbation, but did predict emergence of tardive dyskinesia (Reference Emsley, Turner and OosthuizenEmsley et al, 2005). Similarly, in a study over a prospective period of 3 years, extent of neurological soft signs at the first episode failed to predict outcome in terms of relapse or occupational functioning (Reference Chen, Hui and ChanChen et al, 2005). Thus, the findings to date do not indicate that neurological soft signs exert material prediction of long-term outcome.

EARLY NEURO-DEVELOPMENTAL INDICES

Minor physical anomalies are slight anatomical malformations of body regions that share the ectodermal origins of the brain. Their presence indicates adverse events acting over the first or second trimester (Reference Waddington, Lane and LarkinWaddington et al, 1999). Thus, although found reliably to be overrepresented in schizophrenia (Reference McNeil, Cantor-Graae and IsmailMcNeil et al, 2000), minor physical anomalies occur to excess in most disorders of early neurodevelopmental origin and therefore likely constitute a non-specific, qualitative indicator of early biological adversity that bears little specific relationship to outcome in schizophrenia.

Anthropometrics of craniofacial dysmorphogenesis

Aspects of dysmorphogenesis, particularly of craniofacial regions that bear the most intimate embryological relationship with early brain development, can be measured using classic anthropometric techniques (Reference Lane, Kinsella and MurphyLane et al, 1997). However, in a recent prospective study over a period of 5 years, cross-sectional measurement of hypertelorism made in the high-risk state did not distinguish those who went on to receive a diagnosis of schizophrenia from those who did not (Reference Johnstone, Ebmeier and MillerJohnstone et al, 2005).

Three-dimensional surface imaging of craniofacial dysmorphogenesis

It is now possible to apply three-dimensional surface imaging technology and geometric morphometrics to the quantitative measurement of facial dysmorphology (Reference Hennessy, McLearie and KinsellaHennessy et al, 2005). Such techniques, which have been shown recently to distinguish people with schizophrenia from controls (Reference Hennessy, Baldwin and BrowneHennessy et al, 2007), might have greater potential for addressing any relationship between dysmorphogenesis and long-term outcome in schizophrenia.

Dermatoglyphics

Another index of dysmorphogenesis is dermatoglyphics; for example, a-b ridge count, a quantitative dermatoglyphic measure of the palm, is reduced in schizophrenia (Reference Bramon, Walshe and McDonaldBramon et al, 2005). However, in a recent prospective study over a period of 5 years, cross-sectional measurement of dermatoglyphics made in the high-risk state did not distinguish those who went on to receive a diagnosis of schizophrenia from those who did not (Reference Johnstone, Ebmeier and MillerJohnstone et al, 2005).

Postnatal MRI

Although brain MRI in the immediate postnatal period may have some utility in predicting neurodevelopmental outcome at 2 years (Reference Woodward, Anderson and AustinWoodward et al, 2006), any ability to predict schizophrenia as an outcome in young adulthood remains unexplored.

GENOMICS

Evidence accumulated over recent years indicates that schizophrenia is an oligogenic rather than a single-gene disorder, with several risk genes of small effect having been identified (Reference Harrison and WeinbergerHarrison & Weinberger, 2005; Reference Owen, Craddock and O'DonovanOwen et al, 2005; Reference Karayiorgou and GogosKarayiorgou & Gogos, 2006).

Studies of association between particular genetic risk variants and aspects of structural brain pathology on MRI in adult schizophrenia are now available (e.g. Reference Cannon, Hennah and van ErpCannon et al, 2005; Reference Gurling, Critchley and DattaGurling et al, 2006; Reference Ho, Milev and O'LearyHo et al, 2006). However, only recently are predictive studies emerging. For example, in a prospective study over a period of 5 years, neuregulin 1 and catechol-O-methyltransferase (COMT) genotypic variants assessed in the high-risk state each increased risk for developing psychotic symptoms of schizophrenia in association with abnormalities of brain structure and function on MRI and fMRI (Reference Hall, Whalley and JobHall et al, 2006; Reference McIntosh, Baig and HallMcIntosh et al, 2006). Such studies may be of considerable heuristic value in relation to prediction of outcome.

PROTEOMICS, METABOLOMICS AND APOPTOTIC MECHANISMS

Both proteomic and metabolomic studies in schizophrenia are in their infancy, with metabolomics (i.e. the study of the repertoire of biochemicals present in cells, tissue and body fluids as encoded by the genome and modified by environmental factors; Reference Kaddurah-DaoukKaddurah-Daouk, 2006) now being explored in the search for biomarkers for several aspects of schizophrenia.

In an initial study using nuclear magnetic resonance (NMR) spectra of CSF samples from antipsychotic-naive or minimally treated patients with first-episode schizophrenia, the glucoregulatory metabolic profile was characteristically altered relative to controls and showed some association with ‘normalisation’ with effective antipsychotic treatment (Reference Holmes, Tsang and HuangHolmes et al, 2006). As for genomics, such studies of metabolomics may be of considerable heuristic value in relation to prediction of outcome.

Apoptosis, a form of programmed cell death, is regulated by a complex cascade of pro- and anti-apoptotic proteins that may be altered in schizophrenia and might mediate subtle, progressive loss of cerebral grey matter, particularly over the early course, in the absence of evidence for any neurodegenerative process as currently conceptualised (Waddington et al, Reference Waddington, Lane and Larkin1999, Reference Waddington, Kingston, O'Tuathaigh, Carpenter and Thaker2007; Reference Glantz, Gilmore and LiebermanGlantz et al, 2006). Although a recent study noted apoptotic mechanisms in dermal fibroblasts to be anomalous in schizophrenia (Reference Catts, Catts and McGrathCatts et al, 2006), any ability to predict outcome remains unexplored. However, such indices join genomics and metabolomics in being of considerable heuristic value in relation to prediction of outcome.

CONCLUSIONS

On a population basis, neuroimaging and other neurobiological studies conducted prospectively from the first episode of schizophrenia have advanced rapidly. They hold out the prospect of more reliable findings with further experimental refinement, but currently lack predictive power.

Prediction of transition from ‘high-risk’ status to first episode has proved somewhat more fruitful, perhaps because of contemporary concentration of resources on this critical phase of illness and associated advances in the context of the potential of early intervention to ameliorate such transition, but the gain has been small. The greatest challenge is to relate specific neuroimaging and other neurobiological indices to outcome on an individual patient basis.

At this stage in our understanding of the biology of schizophrenia over its lifetime trajectory, the inconsistency and extent of variability in essentially all such measures still precludes generation of predictive models that are utilitarian for individual patients. Recent fMRI, MRS, genomic and metabolomic studies hold the greatest potential for identifying clinically meaningful ‘biomarkers’, but considerable further work is necessary.

Acknowledgements

The author's studies are supported by Science Foundation Ireland, the Health Research Board and the Health Service Executive - North Eastern Area.

References

Baldwin, P., Hennessy, R. J., Morgan, M. G., et al (2004) Controversies in schizophrenia research: the ‘continuum’ challenge, heterogeneity vs homogeneity, and lifetime developmental-‘neuroprogressive’ trajectory. In Search for the Causes of Schizophrenia (eds Gattaz, W. & Haffner, H.), pp. 394409. Steinkopff.Google Scholar
Bombin, I., Arango, C. & Buchanan, R. W. (2005) Significance and meaning of neurological signs in schizophrenia: two decades later. Schizophrenia Bulletin, 31, 962977.CrossRefGoogle ScholarPubMed
Bramon, E., Walshe, M., McDonald, C., et al (2005) Dermatoglyphics and schizophrenia: a meta-analysis and investigation of the impact of obstetric complications upon a-b ridge count. Schizophrenia Research, 75, 399404.CrossRefGoogle ScholarPubMed
Cannon, T. D., Hennah, W., van Erp, T. G. M., et al (2005) Association of DISCI/TRAX haplotypes with schizophrenia, reducedprefrontal gray matter, and impaired short-and long-term memory. Archives of General Psychiatry, 62, 12051213.CrossRefGoogle Scholar
Catts, V. S., Catts, S. V., McGrath, J. J., et al (2006) Apoptosis and schizophrenia: apilot studybased on dermal fibroblast cell lines. Schizophrenia Research, 84, 2028.Google Scholar
Chen, E. Y. H., Hui, L. M. C., Chan, R. C. K., et al (2005) A 3-year prospective study of neurological soft signs in first-episode schizophrenia. Schizophrenia Research, 75, 4554.Google Scholar
Corripio, I., Perez, V., Catafau, A. M., et al (2006) Striatal D2 receptor bindingas amarker of prognosis and outcome in untreated first-episode psychosis. Neurolmage, 29, 662666.CrossRefGoogle Scholar
Davis, C. E., Jeste, D. V. & Eyler, L. T. (2005) Review of longitudinal functional neuroimaging studies of drug treatments in patients with schizophrenia. Schizophrenia Research, 78, 4560.Google Scholar
Dazzan, P., Morgan, K. D., Orr, K., et al (2005) Different effects of typical and atypical antipsychotics on grey matter in first episode psychosis: the AESOP Study. Neuropsychopharmacology, 30, 765774.CrossRefGoogle ScholarPubMed
DeLisi, L. E. (1999) Regional brain volume change over the life-time course of schizophrenia. Journal of Psychiatric Research, 33, 535541.Google Scholar
Emsley, R., Turner, H. J., Oosthuizen, P. P., et al (2005) Neurological abnormalitiesin first-episode schizophrenia: temporal stability and clinical and outcome correlates. Schizophrenia Research, 75, 3544.Google Scholar
Flashman, L. A. & Green, M. F. (2004) Review of cognition and brain structure in schizophrenia: profiles, longitudinal course, and effects of treatment. Psychiatric Clinics of North America, 27, 118.Google Scholar
Garner, B., Pariante, C. M., Wood, S. J. et al (2005) Pituitary volume predicts future transition to psychosis in individuals at ultra-high risk of developing psychosis. Biological Psychiatry, 58, 417423.Google Scholar
Garver, D., Holcomb, J. A. & Christensen, J. D. (2005) Cerebral cortical gray expansion associated with two second-generation antipsychotics. Biological Psychiatry, 58, 6266.CrossRefGoogle ScholarPubMed
Glantz, L. A., Gilmore, J. H., Lieberman, J. A., et al (2006) Apoptotic mechanisms and the synaptic pathology of schizophrenia. Schizophrenia Research, 81, 4763.Google Scholar
Gurling, H., Critchley, H., Datta, S. R., et al (2006) Genetic association and brain morphology studies and the chromosome 8p22 pericentriolar material I (PCMI) gene in susceptibility to schizophrenia. Archives of General Psychiatry, 63, 844854.CrossRefGoogle Scholar
Hall, J., Whalley, H. C., Job, D. E., et al (2006) A neuregulin I variant associated with abnormal cortical function and psychotic symptoms. Nature Neuroscience, 9, 14771478.CrossRefGoogle ScholarPubMed
Harrison, P. J. & Weinberger, D. R. (2005) Schizophrenia genes, gene expression, and neuropathology: on the matter of their convergence. Molecular Psychiatry, 10, 4068.CrossRefGoogle ScholarPubMed
Hennessy, R. J., McLearie, S., Kinsella, A., et al (2005) Facial surface analysis by 3D laser scanning and geometric morphometricsin relation tosexual dimorphism in cerebral-craniofacial morphogenesis and cognitive function. Journal of Anatomy, 207, 283296.Google Scholar
Hennessy, R. J., Baldwin, P. A., Browne, D. J., et al (2007) Three-dimensional laser surface imagingand geometric morphometrics resolve frontonasal dysmorphology in schizophrenia. Biological Psychiatry, 61, 11871194.Google Scholar
Ho, B.-C., Andreasen, N. C., Nopoulos, P., et al (2003) Progressive structural brain abnormalities and their relationship to clinical outcome. Archives of General Psychiatry, 60, 585594.Google Scholar
Ho, B.-C., Milev, P., O'Leary, D. S., et al (2006) Cognitive and magnetic resonance imaging brain morphometric correlates of brain-derived neurotrophic factor Val 66 Met gene polymorphism in patients with schizophrenia and healthy volunteers. Archives of General Psychiatry, 63, 731740.CrossRefGoogle Scholar
Holmes, E., Tsang, T. M., Huang, J. T.-J., et al (2006) Metabolic profiling of CSF: eviidencethat early intervention may impact on disease progression and outcome in schizophrenia. PLoS Medicine, 3, e327.Google Scholar
Honea, R., Crow, T. J., Passingham, D., et al (2005) Regional deficits in brain volume in schizophrenia: a meta-analysis of voxel-based morphometry studies. American Journal of Psychiatry, 162, 22332245.Google Scholar
Howes, O. D., Montgomery, A. J., Asselin, M. C., et al (2006) The pre-synaptic dopaminergic system in subjects with at risk mental states: initial results from an ongoing [18F]-dopa PET study. Journal of Psychopharmacology, 20 (suppl. 5), A69.Google Scholar
Job, D. E., Whalley, H. C., Johnstone, E. C., et al (2005) Grey matter changes over time in high risk subjects developing schizophrenia. Neuro Image, 25, 10231030.Google Scholar
Johnstone, E. C., Ebmeier, K. P., Miller, P., et al (2005) Predicting schizophrenia: findings from the Edinburgh High-Riisk Study. British Journal of Psychiatry, 186, 1825.Google Scholar
Kaddurah-Daouk, R. (2006) Metabolic profiling of patients with schizophrenia. PLoS Medicine, 3, e363.Google Scholar
Kanaan, R. A. A., Kim, J. S., Kaufmann, W. E., et al (2005) Diffusion tensor imaging in schizophrenia. Biological Psychiatry, 58, 921929.Google Scholar
Kapur, S., Mizrahi, R. & Li, M. (2005) From dopamine to salience to psychosis-linking biology, pharmacology and phenomenology of psychosis. Schizophrenia Research, 79, 5968.CrossRefGoogle ScholarPubMed
Karayiorgou, M. & Gogos, J. A. (2006) Schizophrenia genetics: uncovering positional candidate genes. European Journal of Human Genetics, 14, 512519.CrossRefGoogle ScholarPubMed
Keshavan, M. S., Berger, G., Zipursky, R. B., et al (2005) Neurobiology of early psychosis. British Journal of Psychiatry, 187 (suppl. 48), s8s18.Google Scholar
Lane, A., Kinsella, A., Murphy, P., et al (1997) The anthropometric assessment of dysmorphic features in schizophrenia as an index of its developmental origins. Psychological Medicine, 27, 11551164.CrossRefGoogle ScholarPubMed
Lawrie, S. M. & Abukmeil, S. S. (1998) Brain abnormality in schizophrenia. A systematic and quantitative review of volumetric magnetic resonance imaging studies. British Journal of Psychiatry, 172, 110120.CrossRefGoogle ScholarPubMed
Lieberman, J. A., Toffefson, G. D., Charles, C., et al (2005) Antipsychotic drug effects on brain morphology in first-episode psychosis. Archives of General Psychiatry, 62, 361370.Google Scholar
Mathalon, D. H., Sullivan, E. V., Lim, K. O., et al (2001) Progressive brain volume changes and the clinical course of schizophrenia in men. Archives of General Psychiatry, 58, 148157.CrossRefGoogle ScholarPubMed
McIntosh, A. M., Baig, B. J., Hall, J., et al (2006) Relationship of catechol-O-methyltransferase variants to brain structure and function in a population at high risk of psychosis. Biological Psychiatry, Epub ahead of print.Google Scholar
McNeil, T. F., Cantor-Graae, E. & Ismail, B. (2000) Obstetric complications and congenital malformation in schizophrenia. Brain Research Reviews, 31, 166178.Google Scholar
Milev, P., Ho, B.-C., Arndt, S., et al (2003) Initial magnetic resonance imaging volumetric brain measurements and outcome in schizophrenia: a prospective longitudinal study with 5-year follow-up. Biological Psychiatry, 54, 608615.Google Scholar
Mitelman, S. A., Shihabuddin, L., Brickman, A. M., et al (2003) MRI assessment of gray and white matter distribution in Brodmann's areas of the cortex in patients with schizophrenia with good and poor outcomes. American Journal of Psychiatry, 160, 21542168.Google Scholar
Morey, R. A., Inan, S., Mitchell, T. V., et al (2005) Imaging frontostriatal function in ultra-high risk, early, and chronic schizophrenia during executive processing. Archives of General Psychiatry, 62, 254262.CrossRefGoogle ScholarPubMed
Owen, M. J., Craddock, N. & O'Donovan, M. C. (2005) Schizophrenia: genes at last? Trends in Genetics, 21, 518525.Google Scholar
Pantelis, C., Velakoulis, D., McGorry, P. D., et al (2003) Neuroanatomical abnormalities before and after onset of psychosis: a cross-sectional and longitudinal MRI comparison. Lancet, 361, 281288.CrossRefGoogle ScholarPubMed
Pantelis, C., Yucel, M., Wood, S. J., et al (2005) Structural brain imaging evidence for multiple pathological processes at different stages of brain development in schizophrenia. Schizophrenia Bulletin, 31, 672696.Google Scholar
Pariante, C. M., Dazzan, P., Danese, A., et al (2005) Increased pituitary volume in antipsychotic-free and antipsychotic-treated patients of the/Esop first-onset psychosis study. Neuropsychophamacology 30, 19231931.Google Scholar
Prasad, K. M., Sahni, S. D., Rohm, B. R., et al (2005) Dorsolateral prefrontal cortex morphology and short-term outcome in first-episode schizophrenia. Psychiatry Research, 140, 147155.CrossRefGoogle ScholarPubMed
Staal, W. G., Hulshoff, H. E., Schnack, H. G., et al (2001) Structural brain abnormalities in chronic schizophrenia at the extremes of the outcome spectrum. American Journal of Psychiatry, 158, 11401142.Google Scholar
Seeman, P., Schwarz, J., Chen, J-F., et al (2006) Psychosis pathways converge via D2High dopamine receptors. Synapse, 60, 319346.Google Scholar
Shenton, M. E., Dickey, C. C., Frumin, M., et al (2001) A review of MRI findings in schizophrenia. Schizophrenia Research, 49, 152.Google Scholar
Spauwen, J., Krabbendam, L., Lieb, R., et al (2006) Impact of psychological trauma on the development of psychotic symptoms: relationship with psychosis proneness. British Journal of Psychiatry, 188, 527533.Google Scholar
Staal, W. G., Hulshoff, H. E., Schnack, H. G., et al (2001) Structural brain abnormalities in chronic schizophrenia at the extremes of the outcome spectrum. American Journal of Psychiatry, 158, 11401142.CrossRefGoogle ScholarPubMed
Steen, R. G., Mull, C., McClure, R., et al (2006) Brain volume in first-episode schizophrenia. Systematic review and meta-analysis of magnetic resonance imaging studies. British Journal of Psychiatry, 188, 5105188.CrossRefGoogle ScholarPubMed
Stephan, K. E., Baldeweg, T. & Friston, K. J. (2006) Synaptic plasticity and dysconnection in schizophrenia. Biological Psychiatry, 59, 929939.CrossRefGoogle ScholarPubMed
Symond, M. B., Harris, A. W. F., Gordon, E., et al (2005) “Gamma Synchrony” in first-episode schizophrenia: a disorder of temporal connectivity? American Journal of Psychiatry, 162, 459465.Google Scholar
Szeszko, P. R., Ardekani, B. A., Ashtari, M., et al (2005) White matter abnormalities in first-episode schizophrenia or schizoaffective disorder: a diffusion tensor imaging study. American Journal of Psychiatry, 162, 602605.CrossRefGoogle ScholarPubMed
Tost, H., Ende, G., Ruf, M., et al (2005) Functional imaging research in schizophrenia. International Review of Neurobiology, 67, 95118.Google Scholar
van Haren, N. E. M., Chan, W., Pol, H. E. H., et al (2003) Brain volumes as predictor of outcome in recent-onset schizophrenia: a multi-center MRI study. Schizophrenia Research, 64, 4152.Google Scholar
van Os, J., Krabbendam, L., Myin-Germeys, I., et al (2005) The schizophrenia envirome. Current Opinion in Psychiatry, 18, 141145.Google Scholar
Vidal, C. N., Rapoport, J. L., Hayashi, K. M., et al (2006) Dynamically spreading frontal and cingulate deficits mapped in adolescents with schizophrenia. Archives of General Psychiatry, 63, 2535.Google Scholar
Vita, A., De Peri, L., Silenzi, C., et al (2006) Brain morphology in first-episode schizophrenia: a metaanalysis of quantitative magnetic resonance imaging studies. Schizophrenia Research, 82, 7588.Google Scholar
Waddington, J. L. (2005) What have we learned from the new generation of prospective studies on first episode psychosis? Schizophrenia Bulletin, 31, 623.Google Scholar
Waddington, J. L. & Morgan, M. G. (2001) Pathobiology of schizophrenia. In Comprehensive Care of Schizophrenia (eds J. A. Lieberman & R. M. Murray), pp. 2835. Martin Dunitz.Google Scholar
Waddington, J. L., Lane, A., Larkin, C., et al (1999) The neurodevelopmental basis of schizophrenia: clinical clues from cerebro-craniofacial dysmorphogenesis, and the roots of a lifetime trajectory of disease. Biological Psychiatry, 46, 3139.Google Scholar
Waddington, J. L., Kingston, T. & O'Tuathaigh, C. M. P. (2007) Longitudinal studies on course of illness in schizophrenia: a lifetime trajectory perspective. In The Year in Schizophrenia (Vol. 1) (eds Carpenter, W. T. & Thaker, G.). Clinical Publishing (in press).Google Scholar
Whalley, H. C., Simonotto, E., Moorhead, W., et al (2006) Functional imaging as a predictor of schizophrenia. Biological Psychiatry, 60, 454462.Google Scholar
Whitford, T. J., Grieve, S. M., Farrow, T. F. D., et al (2006) Progressive grey matter atrophy over the first 2–3 years of illness in first-episode schizophrenia: atensor-based morphometry study. Neuro Image, 32, 511519.Google Scholar
Whitty, P., Clarke, M., McTigue, O., et al (2006) Diagnostic specificity and predictors of neurological soft signs in schizophrenia, bipolar disorder and other psychoses over the first 4 years of illness. Schizophrenia Research, 86, 110117.Google Scholar
Wood, S. J., Berger, G. E., Lambert, M., et al (2006) Prediction of functional outcome 18 months after a first psychotic episode. Archives of General Psychiatry, 63, 969976.CrossRefGoogle ScholarPubMed
Woods, B. T., Ward, K. E. & Johnson, E. H. (2005) Meta-analysis of the time-course of brain volume reduction in schizophrenia: implications for pathogenesis and early treatment. Schizophrenia Research, 73, 221228.Google Scholar
Woodward, L. J., Anderson, P. J., Austin, N. C., et al (2006) Neonatal MRI to predict neurodevelopmental outcomes in preterm infants. New England Journal of Medicine, 355, 685694.Google Scholar
Wright, I. C., Rabe-Hesketh, S., Woodruff, P. W., et al (2000) Meta-analysis of regional brain volumes in schizophrenia. American Journal of Psychiatry, 157, 1625.CrossRefGoogle ScholarPubMed
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