Department of Mental Health and Aberdeen Centre for Trauma Research, University of Aberdeen
Correspondence: Dr Alastair Hull, Lecturer, Aberdeen Centre for Trauma Research, Bennachie, Royal Cornhill Hospital, Aberdeen AB25 2ZH, UK. E-mail: alhul{at}aol.com
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ABSTRACT |
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Aims To determine whether neuroimaging studies had identified structural and functional changes specific to PTSD.
Method A review of all functional and structural neuroimaging studies of subjects with PTSD was carried out. Studies were identified using general medical and specific traumatic stress databases and paper searches of current contents and other secondary sources.
Results The most replicated structural finding is hippocampal volume reduction, which may limit the proper evaluation and categorisation of experience. Replicated localised functional changes include increased activation of the amygdala after symptom provocation (which may reflect its role in emotional memory) and decreased activity of Broca's area at the same time (which may explain the difficulty patients have in labelling their experiences).
Conclusions Evidence from neuroimaging studies has suggested areas of the brain that may be damaged by psychological trauma. The clinical implications of these neuroimaging findings need to be investigated further because they challenge traditional therapeutic approaches.
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INTRODUCTION |
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This review examines structural and functional studies of the brain and also studies combining both modalities. Symptom and non-symptom provocation paradigms are examined in relation to functional studies, with case reports reviewed separately. Finally, the implications of these findings are discussed.
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METHOD |
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RESULTS |
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A number of studies have now demonstrated the involvement of the hippocampus in chronic PTSD. Two studies have examined the hippocampus without finding volumetric changes. The first study demonstrated the absence of hippocampal atrophy prior to the onset of PTSD (Bonne et al, 2001). Further, after single-event trauma, hippocampal abnormalities did not occur within 6 months. The second study (De Bellis et al, 1999) demonstrated smaller cerebral volumes and corpus callosum measures but no hippocampal changes in a group of maltreated children.
Possible reasons for the differences in the extent of volume reduction may be the study design (thickness of slices or whether or not the whole brain volume was calculated), the control group utilised, comorbid substance misuse, treatment effects or neurodevelopmental plasticity. In the main, researchers have performed comparative analyses to minimise the effect of other psychiatric disorders, including alcohol and substance misuse.
Sapolsky (1992) has described the sensitivity of hippocampal formation to severe, chronic traumatic stress and perhaps also to elevated glucocorticoids and/or excitatory amino acids, yet many other disorders such as bipolar disorder, schizophrenia, alcohol misuse and dementia are also associated with hippocampal atrophy (McEwen, 1997). Glucocorticoid-induced atrophy would appear to require prolonged or repeated bursts of glucocorticoid excess. However, basal glucocorticoid levels have been shown to be lower than normal in PTSD, perhaps due to enhanced adrenocortical sensitivity to feedback regulation (Yehuda et al, 1991, 1993).
The lateralisation of hippocampal damage has varied, with one possible explanation being changing vulnerability of the hippocampus to stress-induced damage at different developmental stages. The possibility that small hippocampi represent a predisposition to PTSD is not supported by the one study to examine acute PTSD (Bonne et al, 2001) because no change in volume was present acutely or within the first 6 months. Further, Bremner et al (1995) demonstrated no volume difference between early-onset (before age 8 years) and late-onset (age 8 years or later) abuse.
Canive et al (1997) have uniquely demonstrated focal white matter lesions (WMLs) in eight subjects within a sample of 42 male combat-exposed subjects. Most of the WMLs were identified using the fluid attenuated inversion recovery (FLAIR) imaging sequence, which is not employed in typical MRI studies. The FLAIR sequence causes suppression of the cerebrospinal fluid signal with WML remaining bright, and the absence of the FLAIR imaging sequence may explain why other studies have not replicated this finding.
Studies using proton magnetic resonance spectroscopy in patients with
PTSD
Proton magnetic resonance spectroscopy (MRS) can provide information about
alterations in N-acetyl aspartate (NAA) and choline-containing
compounds in the human brain without the radiation exposure of positron
emission tomography (PET) on single photon emission computed tomography
(SPECT) but with lower sensitivity. Two studies have utilised this technique
(Table 3) to measure NAA in
subjects with PTSD. Schuff et al
(1997) utilised both MRI and
proton MRS to measure hippocampal volume and changes in NAA. An 18% reduction
in right hippocampal NAA compared with a 6% reduction in right hippocampal
volume suggests that NAA is a more sensitive measure of neuronal loss than
volume changes. Although this study does not answer whether the NAA changes
were pre-existing or a consequence of trauma rather than PTSD per se,
the second study (Freeman et al,
1998) suggests that it correlated with PTSD. Decreased NAA has
been demonstrated in other disorders, such as early-onset schizophrenia
(Bertolino et al,
1996), temporal lobe epilepsy
(Ende et al, 1997)
and Alzheimer's disease (MacKay et
al, 1996).
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Studies of brain function in patients with PTSD
Most functional brain imaging studies in PTSD have used either PET or
SPECT, which involve the detection of radiation-emitting radioisotopes to
measure regional cerebral metabolism or blood flow. Functional MRI determines
regional brain activation by detecting changes in blood oxygenation level and
has a better spatial resolution than PET or SPECT.
The majority of studies employed a symptom provocation paradigm because measuring brain function at rest poses the problem of controlling the range of possible mental states. Studies have concentrated upon traumatic memory as a central component in PTSD because the presence of intrusive symptoms compellingly points to PTSD as the diagnosis. The one study to employ a non-symptom provocation paradigm (Lucey et al, 1997) used SPECT to study three groups with anxiety-related disorders: PTSD, obsessivecompulsive disorder (OCD) and agoraphobia with panic disorder (see Table 5). One study utilised a pharmacological challenge and is discussed separately below (Bremner et al, 1997b).
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Pharmacological challenge study
Bremner et al
(1997b) administered
the 2-antagonist yohimbine in a pharmacological challenge
symptom provocation paradigm (Table
4). Yohimbine has been shown to provoke an exaggerated behavioural
and biochemical responsiveness in subjects with PTSD
(Southwick et al,
1993) and panic disorder
(Charney et al,
1987a) but not in patients with other mental disorders
(Charney et al,
1987b; Glazer et
al, 1987; Rasmussen
et al, 1987; Heninger
et al, 1988). Bremner et al demonstrated that
yohimbine administration correlated with increased anxiety symptoms in
patients with PTSD but not in controls. Patients with yohimbine-induced panic
attack (approximately 60%) had significantly reduced hippocampal and
neocortical metabolism, suggesting enhanced noradrenaline release in subjects
with PTSD after yohimbine administration.
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Symptom provocation studies using PET
The majority of PET studies (six reports) provoked intrusive symptoms by
using personalised trauma scripts or trauma-related sounds or pictures
(Table 4), and one group
examined changes during the performance of cognitive tasks (Semple et
al, 1993,
1996,
2000).
Symptom provocation studies using SPECT
Only three SPECT studies have examined subjects with PTSD after symptom
provocation (Table 5). Liberzon
et al have conducted a SPECT study of subjects with combat-related
PTSD and reported key findings in two papers
(Liberzon et al,
1999; Zubieta et al,
1999) and one case report
(Liberzon et al,
1996/97). They report separately on a specific analysis of the
activity of the medial prefrontal cortex, which is thought to modulate the
fear response (Zubieta et al,
1999). An increased regional cerebral blood flow (rCBF) was found
in the medial prefrontal cortex in subjects with PTSD during provocation,
although no statistically significant association was found with peripheral
measures. The different findings may reflect the fact that the subjects were
from the same cohort but the region-of-interest analysis was derived from a
different cohort of normal controls. The anatomical region sampled for the
region-of-interest analysis was more rostral than the anterior cingulate
region examined by Liberzon et al
(1999).
Functional MRI studies
Rauch et al (2000)
conducted a functional MRI study applying a validated method for measuring
automatic amygdala responses to general threat-related stimuli using a masked
face paradigm (Whalen et al,
1998b). The magnitude of amygdala response distinguished
subjects with PTSD from those without PTSD with 75% sensitivity and 100%
specificity (Table 3).
Case reports involving functional neuroimaging
Levin et al (1999)
report on one subject from an ongoing SPECT study utilising the same
provocation paradigm as Rauch et al
(1996). Subjects were scanned
before and after successful treatment for PTSD. After treatment there were two
areas of increased activity: the anterior cingulate cortex and the left
frontal lobe. The treatment was eye movement desensitisation and reprocessing
(EMDR; Shapiro, 1996) but the
subject of this report was also on a selective serotonin reuptake inhibitor
throughout the study. The authors state that these changes were consistent
with summed data from four out of six subjects in their ongoing study.
Profound memory deficits were demonstrated in a case report of a man after a second traumatic event triggering memories of a fatal accident he witnessed as a child. A PET scan revealed hypoperfusion in memory-sensitive regions such as the hippocampal formation and temporal lobe (Markowitsch et al, 1998). Liberzon et al (1996/97) report one patient who experienced a flashback after provocation while being scanned. There was greater uptake in subcortical regions, especially the thalamus, in comparison with cortical regions.
Summary of functional findings
Many of the functional neuroimaging studies have suggested abnormalities of
limbic and paralimbic areas during symptom provocation and cognitive
activation studies. This supports the suggested role of these areas in
mediating emotional arousal in normal anxiety
(Benkelfat et al,
1996), across a range of disorders
(Rauch et al, 1995) and in trauma-exposed non-PTSD groups. These changes are therefore not
specific to PTSD. Hyperperfusion of limbic and paralimbic areas may be a
result of stress-induced long-term potentiation of the monosynaptic
N-methyl-D-aspartate (NMDA)-mediated pathway between the amygdala and
the periacqueductal grey (Davidson &
Sutton, 1995; Adamec,
1997). The NMDA receptors are thought to be activated to produce
long-term memories of events when sufficient glutamate is released as a result
of the stress (Glue et al,
1993).
Amygdalar activation may be detected more easily during the processing of fear-related stimuli (Breiter et al, 1996; Morris et al, 1996; Whalen et al, 1998a). Inconsistent findings of amygdala activation may reflect the nature of the trauma, and the greater emotional responsiveness to personal narratives of traumatic events (Rauch et al, 1996) rather than to generalised trauma-related pictures and images (Shin et al, 1997a,b) or to generalised combat sounds (Bremner et al, 1999a). For example, Shin et al (1997b) found increased activation of the amygdala in PTSD only during combat imagery, despite both the imagery and combat perception conditions being rated as of equal significance and causing equal arousal. In addition, the failure to demonstrate amygdalar activation may be due to its involvement in encoding an event's emotional significance but not in the recall of the event per se (Cahill et al, 1996).
The role of the amygdala was investigated in subjects with probable Alzheimer's disease who experienced the 1995 earthquake in Kobe, Japan (Ikeda et al, 1998; Mori et al, 1999; Kazui et al, 2000). Memories of the earthquake were examined as an index of emotional memory. Subjects remembered their personal experience rather than the context of the earthquake, and emotional memory correlated with normalised amygdalar volume (via MRI) irrespective of generalised brain atrophy and cognitive impairments.
Increased automatic amygdalar responsiveness to stimuli (cognitive activation or masked face paradigm) has been shown to be accompanied by decreased activity of the prefrontal cortex, which has a role in the encoding and retrieval of verbal memories. Lower benzodiazepine receptor binding in the prefrontal cortex might mean that PTSD causes a down-regulation of benzodiazepine receptor binding or that pre-trauma low levels of benzodiazepine receptor binding in the prefrontal cortex might increase the risk of developing PTSD after traumatic events (Bremner et al, 2000).
Although needing replication, the study by Levin et al (1999) suggests that successful treatment may not only reduce amygdala activity but also may involve activation of structures implicated in the modulation of fight/flight reactions to perceived threat, and perhaps the differentiation of real from imagined threat. Increased perfusion of the thalamus during a flashback (Liberzon et al, 1996/97) supports its suggested role in the generation of dissociative symptoms in PTSD (Krystal et al, 1995).
The absence of increased anterior cingulate activation over comparison groups may be associated with the inability of people with PTSD to extinguish fear. It is thought to play a major role in the assignment of motivational significance and is associated with non-specific anxiety states being activated in procaine-induced fear (Ketter et al, 1996), imagery of aversive stimuli (Kosslyn et al, 1996) and healthy individuals recollecting sad events (Whalen et al, 1998a). The increased activation of the posterior cingulate (Bremner et al, 1999b) may relate to its suggested role in the emotional processing of distressing material (Fischer et al, 1996).
A replicated finding has been the deactivation of Broca's area, the area of the brain thought to be responsible for applying semantic representations to personal experience to allow its communication or description (Rauch et al, 1996; Shin et al, 1997b). This would appear to be consistent with subjects with PTSD having difficulty in cognitively restructuring their traumatic experience.
The modality of re-experiencing phenomena will have a bearing on regional brain activation. The mental imagery in the study by Rauch et al (1996) was predominantly visual, causing increased rCBF in the secondary visual cortex, a finding not found by Shin et al (1997a,b, 1999) because the re-experiencing phenomena in their study were predominantly tactile. These findings serve to illustrate that different types of trauma cause different emotional reactions; trauma memories are not uniform and activation of brain regions will vary. Further, hypoperfusion of the left inferior frontal gyrus in PTSD (Shin et al 1997a,b, 1999) may reflect the nature of intrusive thoughts because the frontal regions are implicated in effortful recall (Schacter et al, 1996), whereas intrusive phenomena are effortless and may therefore lead to hypoperfusion.
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DISCUSSION |
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The triggers causing intrusive thoughts or flashbacks are personal and often idiosyncratic. Research provocation paradigms need to be able to reflect this and if they do not then researchers may be studying different phenomena. The similarity between generalised combat sounds and a self-generated narrative of a fatal motor vehicle accident in which an individual was at fault have little in common and may explain why there was a failure to show amygdalar activation when generalised combat sounds were used rather than personalised trauma scripts. To expect uniform activation of the brain in different trauma populations with varying provoking stimuli is to suggest that all traumas have similar effects and trigger the same symptoms.
The failure of studies to include control or comparison groups (of trauma-exposed subjects without PTSD) leaves the possibility that the observed changes are due to trauma exposure as opposed to PTSD itself. However, there are demonstrated biological changes following trauma exposure that are associated with PTSD and not simply with the trauma exposure per se (Yehuda & McFarlane, 1995). The neurobiology of PTSD is a progressive state of modification and a cross-sectional perspective cannot answer some of the fundamental questions. Could a pre-existing brain abnormality predispose to PTSD or to exposure to trauma, thereby identifying at-risk individuals? Alternatively, could the trauma exposure rather than PTSD be responsible for the demonstrated structural and functional changes (Sapolsky, 2000)? Only one study has examined neuroimaging changes in individuals with acute PTSD and this suggests that no abnormality existed prior to the development of PTSD (Bonne et al, 2001). Furthermore, are there identifiable trait effects (defining the underlying disease process) as opposed to state effects (reflecting the symptom severity)? Only the latter have been investigated so far in PTSD.
Other methodological issues would include the standardisation of image acquisition (and analysis) and a consensus on methodologies (e.g. type of trauma population, type of symptom provocation and method of diagnosis). In addition, studies controlling for past and current treatment and the presence or absence of comorbidity are needed to determine the relative contributions. This would allow the pooling of data or a meta-analysis that would compensate for individually small studies.
Neuroimaging studies in PTSD have suggested a number of brain regions meriting further attention. Key regional abnormalities, their replicability and the possible significance of each finding are described in Table 6. Findings to support the proposed right-hemisphere lateralisation of post-trauma symptoms are inconsistent, with no neuroimaging study in PTSD examining the role of dominance (studies have chosen to study dextrals) or gender on this proposed laterality. For example, gender differences have been demonstrated in studies of self-induced dysphoria (Whalen et al, 1998b), with bilateral activation in women and predominantly left-sided activation in men.
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Treatment implications
Neuroimaging findings suggest that after psychological trauma biological
changes are not restricted to dysregulation of neurochemical systems but
involve alterations in brain function and structure. The challenge for
clinicians is to employ therapies for patients with PTSD that prevent, halt or
reverse these changes. Functional brain changes after successful treatment
have been demonstrated in other conditions
(Schwartz et al,
1996) and preliminary data suggest that the same is true for
patients with PTSD (Levin et al,
1999). One possible target is the demonstrated hippocampal damage.
The hippocampus may be unique in the brain in its ability to regenerate
neurons (Gould et al,
1998), with agents such as phenytoin potentially able to reverse
stress-activated hippocampal atrophy
(Watanabe et al,
1992). Silver et al
(1991) have suggested that
anticonvulsants may reduce limbic kindling in PTSD, thereby preventing
progression of symptoms, but this has yet to be tested in clinical trials in
subjects with acute post-traumatic reactions.
Perhaps one of the least expected early findings is the hypoperfusion of Broca's area when trauma-related memories are provoked. Broca's area is necessary for the labelling of emotions, therefore its deactivation under symptom provocation would explain why patients with PTSD can experience intense emotions without being able to label and understand them. This marries clinically with survivors often describing an inability to put their experience into words it is, in effect, unspeakable. Therefore, the ability of psychological treatment, especially talking therapies, may be compromised during some phases of the disorder. Therapies incorporating exposure have proven efficacy for the treatment of PTSD (van Etten & Taylor, 1998) and this may be because they can target all sensory modalities and not just their semantic representations. Alternatively, their potency may be explained by the preclinical finding that the reactivation of memory allows its disruption (Nader et al, 2000). Importantly, the reactivation of memory does not require it to be put into communicable language
The strategies and findings of published neuroimaging studies in PTSD provide a framework for future research, not just in neuroimaging but for clinical trials of historically accepted treatments for trauma survivors. Future neuroimaging studies need to develop protocols to investigate state and trait effects in a range of traumatic events and to study treatment-naïve subjects. Pre- and post-treatment studies also need to be completed to assess the full effectiveness of clinical strategies.
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Clinical Implications and Limitations |
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LIMITATIONS
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ACKNOWLEDGMENTS |
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Received for publication October 18, 2001. Revision received March 12, 2002. Accepted for publication March 19, 2002.
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