12 Jul 2012: (2012) Correction: Fact or Factitious? A Psychobiological Study of Authentic and Simulated Dissociative Identity States. PLoS ONE 7(7): 10.1371/annotation/4f2000ce-ff9e-48e8-8de0-893b67efa3a4. doi: 10.1371/annotation/4f2000ce-ff9e-48e8-8de0-893b67efa3a4 | View correction
Dissociative identity disorder (DID) is a disputed psychiatric disorder. Research findings and clinical observations suggest that DID involves an authentic mental disorder related to factors such as traumatization and disrupted attachment. A competing view indicates that DID is due to fantasy proneness, suggestibility, suggestion, and role-playing. Here we examine whether dissociative identity state-dependent psychobiological features in DID can be induced in high or low fantasy prone individuals by instructed and motivated role-playing, and suggestion.
DID patients, high fantasy prone and low fantasy prone controls were studied in two different types of identity states (neutral and trauma-related) in an autobiographical memory script-driven (neutral or trauma-related) imagery paradigm. The controls were instructed to enact the two DID identity states. Twenty-nine subjects participated in the study: 11 patients with DID, 10 high fantasy prone DID simulating controls, and 8 low fantasy prone DID simulating controls. Autonomic and subjective reactions were obtained. Differences in psychophysiological and neural activation patterns were found between the DID patients and both high and low fantasy prone controls. That is, the identity states in DID were not convincingly enacted by DID simulating controls. Thus, important differences regarding regional cerebral bloodflow and psychophysiological responses for different types of identity states in patients with DID were upheld after controlling for DID simulation.
The findings are at odds with the idea that differences among different types of dissociative identity states in DID can be explained by high fantasy proneness, motivated role-enactment, and suggestion. They indicate that DID does not have a sociocultural (e.g., iatrogenic) origin.
Citation: Simone Reinders AAT, Willemsen ATM, Vos HPJ, den Boer JA, Nijenhuis ERS (2012) Fact or Factitious? A Psychobiological Study of Authentic and Simulated Dissociative Identity States. PLoS ONE 7(6): e39279. doi:10.1371/journal.pone.0039279
Editor: Jerson Laks, Federal University of Rio de Janeiro, Brazil
Received: March 5, 2012; Accepted: May 16, 2012; Published: June 29, 2012
Copyright: © 2012 Reinders et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: AATSR is supported by the Netherlands Organization for Scientific Research (www.nwo.nl), NWO-VENI grant no. 451-07-009. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Despite its inclusion in the Diagnostic Manual for Mental Disorders , the genuineness of dissociative identity disorder (DID) continues to be disputed. Supporters of the diametrically opposed trauma-related and non-trauma-related views have been engaged since decades in a passionate debate regarding its validity as a mental disorder, and whether it is related to traumatization or to fantasy proneness, suggestibility, suggestion, and simulation –.
The non-trauma-related position , , , –, also referred to as the sociocognitive model of DID –, holds that DID is a simulation caused by high suggestibility and/or fantasy proneness –, suggestive psychotherapy and other suggestive sociocultural influences (e.g., the media and/or the church). According to this model, “[t]he rules for enacting the [DID] role […] are as follows: (a) Behave as if you are two (or more) separate people who inhabit the same body. (b) Act as if the you I have been addressing thus far is one of those people and as if the you I have been talking to is unaware of the other coinhabitants. (c) When I provide a signal for contacting another coinhabitant, act as though you are another person. To the extent that patients behave in terms of these rules, the “classic” symptoms [of DID] follow by implication and do not have to be taught through direct instruction or further suggestion”, Spanos (p.239 ). Fantasy proneness and suggestibility are highly correlated , –, and dissociative symptoms were found to be correlated with fantasy proneness, heightened suggestibility, and susceptibility to pseudomemories , .
To date, the position that DID is caused by sociocultural factors and personal features such as fantasy proneness has not been tested in studies involving DID patients, and evidence that the complex phenomenology and psychobiology of DID can be created and sustained over time by these factors is lacking –. Despite this lack of empirical support, the sociocognitive and fantasy based model of DID is influential in contemporary psychiatry and there have been proposals to prevent the inclusion of DID in the DSM-V .
The trauma-related perspective entails that DID is related to a combination of factors that include chronic emotional neglect and emotional, physical, and/or sexual abuse from early childhood, insufficient integrative capacity, attachment disorder, and lack of affect-regulation by caretakers , –. In this view DID is thought to be at the far end of the spectrum of trauma-related psychiatric disorders, i.e. being a severe form of post-traumatic stress disorder (PTSD) , .
Holders of the trauma-related view acknowledge that: some features of dissociative identity states can be influenced by sociocultural factors , that false positive cases of DID have evolved in a treatment setting, and that some psychiatric patients imitate DID . However, they also note that there are differences between authentic and imitated DID and that there is no evidence that DID can (sub-)consciously be created by sociocultural factors . Furthermore, even if DID symptoms can be created iatrogenically or enacted  this does not mean that genuine trauma-related DID does not exist .
According to the DSM-IV , DID is characterized by, among others, the presence of two or more distinct `identities’ or `personality states’. Different proposed labels include `different emotional states’, `alters’, `dissociative parts of the personality’ , and `dissociative identity states.’ Following previously used descriptions and terminology ,  different types of dissociative identity states are indicated here as neutral identity states (NIS) and trauma-related identity states (TIS). These indicators are derived from the terms ‘apparently normal part of the personality (ANP)’ and ‘emotional part of the personality (EP)’ respectively, which are used in the theory of structural dissociation , . This theory defines dissociation as a division of personality into different types of subsystems, each with their own first-person perspective, that is, their own point of view as to who they are, what the world is like, and how they relate to that world . As NIS DID patients concentrate on functioning in daily life, commonly try to hide their pathology, and have not sufficiently integrated (e.g., have partial or complete amnesia) traumatic memories. That is, NIS fails to relate the trauma-related nature to its self . In contrast, TIS does have conscious access to these memories, recalls them as personal experiences and is bodily and emotionally affected by them. That is, as TIS the patients are fixated in traumatic memories and engage in defensive actions such as freeze and flight, when they are or feel threatened , , thereby activating fast subcortical response routes in the brain , . TIS who engage in active kinds of physical defence (e.g., freeze, flight, fight) would involve dominance of the sympathetic nervous system, whereas those who engage in total submission (i.e.,playing dead) would be primarily mediated by the dorsal vagal branch of the parasympathetic nervous system .
Proponents of the sociocognitive view have argued that the different patterns of subjective, psychophysiological, and neural activity for NIS and TIS in response to a trauma-memory script that Reinders et al. ,  documented, might be due to fantasy proneness, suggestion and role-playing, and that they do not prove a traumagenic origin of DID. Obtaining independent proof of childhood traumatization in adulthood is most difficult. However, the claim that the previously reported results constitute effects of fantasy proneness, suggestion, and role-playing is open to test. Thus, the present study involves a psychobiological comparison between NIS and TIS engaging in active kinds of physical defence in DID patients (i.e., the DID identity states from Reinders et al. , ), and simulated NIS and TIS in high and low fantasy prone mentally healthy women who do not report a trauma history and who are instructed and motivated to role-play these different identity states (i.e., simulated identity states).
The a priori hypotheses of the current study were: (i) important previously found psychophysiological and neurobiological differences between NIS and TIS engaging in active kinds of physical defence in DID patients ,  are upheld when controlling for fantasy proneness, suggestion, and instructed and motivated role-playing, and (ii) the upheld psychophysiological and neurobiological differences for NIS and TIS in DID patients include higher sympathetic nervous system activation (e.g. higher heart rate and systolic bloodpressure) and subcortical activity (e.g. the amygdala and caudate nucleus) for TIS in DID, and (iii) hyperactivation of the cortical multimodal posterior association areas (e.g. the intraparietal sulcus and (pre-)cuneus) for NIS in DID when listening to personal trauma scripts.
Twenty-nine subjects participated in the brain imaging study: 11 patients with dissociative identity disorder (DID), 10 high fantasy prone DID simulating controls, and 8 low fantasy prone DID simulating controls. The controls were instructed to enact the two DID identity states: a neutral identity state (NIS) and a trauma-related identity state (TIS). Brain imaging data, autonomic (systolic and diastolic blood pressure, discrete heart rate and heart rate variability (HRV)) and subjective (controls’ subjective sensorimotor and emotional experiences) reactions were obtained. DID patients, as well as high fantasy prone and low fantasy prone controls were studied in the two different types of identity states during a memory script (MS) driven (neutral or trauma-related autobiographical texts) imagery paradigm. The brain imaging data of the three groups was statistically analyzed in SPM5 in a three-by-two-by-two factorial design which allows for the assessment of various effects, e.g., main effects and simple subtraction analyses (within and between identity state) within and between the three groups.
Autonomic and Subjective Reactions
Statistical results of the autonomic and subjective reactions analyses between the three groups are presented in Table 1. Mean values and the direction of the responses are depicted in Figure 1. Significant differences were found for most of the measured variables between the DID patients and both control groups (see for details Table 1) for dissociative identity state (DIS), DIS*group, MS, MS*group, DIS*MS, and DIS*MS*group.
Table 1. Between group: Subjective and autonomic reactions.doi:10.1371/journal.pone.0039279.t001
Figure 1. Graphical representation of averages and direction of subjective emotional experiences, subjective sensori-motor experiences, and cardiovascular responses.
The dashed line depicts the response of the neutral identity state (NIS) when listening to the neutral or trauma-related memory script (MS). The solid line depicts the response of the traumatic identity state (TIS) when listening to the neutral or trauma related MS. All three groups are presented per variable: the dissociative identity disorder patients (DID) in pink, the high fantasy prone DID simulating controls (CH) in cyan and the low fantasy prone DID simulating controls (CL) in blue. See Table 1 for the statistical values.doi:10.1371/journal.pone.0039279.g001
Regional Cerebral Blood Flow Changes
T-tests were used to test if a significant (p<0.05) difference in regional cerebral bloodflow (rCBF) variance between the DID and control groups was explained by the subjective or objective covariates (i.e. the principal components (PC), see below). No brain areas for which a significant difference was present between the DID patients and the high or low fantasy prone controls respectively were found.
Table 2. Main effects.doi:10.1371/journal.pone.0039279.t002
Comparing Simulated and Pathological Identity States
Main effects and conjunction analyses.
Results for the within DID group re-analyses and for the two between group comparisons of the dissociative identity states (DIS) main effects, both TIS and NIS, are given in Table 2. Significant differences in rCBF changes between the DID and both the high and low fantasy prone groups were found, i.e., text independent effects. These findings are shown in Figure 2. Commonalities in brain activation between patients and controls were found (data not shown).
Figure 2. “Glass brain” renderings showing the dissociative identity state main effects, both for the trauma-related identity state (TIS) and for the neutral identity state (NIS), for the dissociative identity disorder (DID) group (left) and the comparison of this group to the high (middle) and low (right) fantasy prone DID simulating controls (CH and CL respectively).
See Table 2 for the specific areas.doi:10.1371/journal.pone.0039279.g002
Trauma-related MS effects within identity state.
Trauma-related MS effects within both TIS and NIS are given in Table 3. TIS showed significant regionally specific increases and decreases in cerebral blood flow, when processing the trauma-related MS as compared to the neutral MS, between the DID and both the high and low fantasy prone control groups. These findings are depicted in Figure 3 and 4.
Table 3. Memory script effects within dissociative identity state.doi:10.1371/journal.pone.0039279.t003
Trauma-related MS effects between identity state.
Trauma-related MS effects between DIS are given in Table 4. Different rCBF patterns were found for NIS and TIS, when processing the trauma-related MS, between the DID and both the high and low fantasy prone control groups. These differential rCBF patterns are shown in Figure 5 and 6. The results indicate that, for some areas (e.g. the parahippocampal gyrus in the comparison NISt-TISt or the caudate nucleus in the comparison TISt-NISt), the difference in blood flow between patients and controls is larger than the difference between the DID identity states.
Figure 3. “Glass brain” renderings show differences in the processing of the trauma-related text (indicated with a small ‘t’) and the neutral text (indicated with a small ‘n’) within the trauma-related identity state (TIS).
Differences in regional cerebral blood flow patterns for the dissociative identity disorder (DID) group (left) and the comparison of this group to the high (middle) and low (right) fantasy prone DID simulating controls (CH and CL respectively) are depicted. See Table 3 for the specific areas.doi:10.1371/journal.pone.0039279.g003
Figure 4. The brain areas indicated with the blue cross (i.e. the peak voxel) are (from top left to bottom right):
the left amygdala, the left insula, the left precuneus, and the right occipitotemporal sulcus. These areas have the most significant rCBF differences between the dissociative identity disorder patients and high and low fantasy prone DID simulating controls (CH and CL respectively) and is shown both in directionality, i.e. the bar graphs, and location, i.e. shown on a coronal overlay (left in the picture is left in the brain). Results show the differential processing of the trauma-related text versus the neutral text within the TIS, when comparing the DID groups to the high fantasy prone control group (left) and low fantasy prone control group (right).doi:10.1371/journal.pone.0039279.g004
The present study was performed to examine whether earlier reported results ,  for DID hold after correcting for potential iatrogenic and other sociogenic effects. To this end, we tested whether these findings can be simulated by motivated role-enactment and/or is facilitated by a high level of fantasy proneness  by re-investigating the patient population from Reinders et al. , . Results of a sub-study (see Methods and Supporting Information S1) show that DID patients have a fantasy proneness score of 9.83 (SD 5.25), which approximates the normal population, indicating that fantasy proneness might not play a major role in DID. This finding is consistent with the current psychobiological results. Neither high nor low fantasy prone healthy controls, instructed and motivated to simulate two different types of dissociative identity states in DID (i.e., NIS and TIS), mimicked previously observed psychophysiological and neural reactions that are associated with these identity states in DID , , which is supportive of our first a priori hypothesis.
Figure 5. “Glass brain” renderings show differences in the processing of the trauma-related text (indicated with a small ‘t’) between the trauma-related identity state (TIS) and the neutral identity state (NIS).
Differences in regional cerebral bloodflow patterns for the dissociative identity disorder (DID) group (left) and the comparison of this group to the high (middle) and low (right) fantasy prone DID simulating controls (CH and CL respectively) are depicted. See Table 4 for the specific areas.doi:10.1371/journal.pone.0039279.g005
Figure 6. The brain areas indicated with the blue cross (i.e. the peak voxel) are (from top left to bottom right): the right caudate nucleus (dorsal part) (2x), the left precuneus, and the right occipitotemporal sulcus.
These areas involve the most significant rCBF difference between the dissociative identity disorder patients and high and low fantasy prone DID simulating controls (CH and CL respectively) and is shown in both directionality, i.e. the bar graphs, and location, i.e. shown on a coronal overlay (left in the picture is left in the brain). Results show the differential processing of the trauma-related text between the TIS and the NIS, when comparing the DID groups to the high fantasy prone control group (left) and low fantasy prone control group (right).doi:10.1371/journal.pone.0039279.g006
From results shown in Figures 2, 3, and 5 a general feel of the effects can be obtained. Figures 2 and 5 and the top row of Figure 3 show that in the high fantasy prone control group more of the original DID rCBF patterns are apparent, while the low fantasy prone control group show less similarities with the original DID rCBF patterns, for example the disappearance of the left amygdala activation. Less similarities between patients only and patients versus controls means more overlap in rCBF patterns. In other words the less differences in the rCBF patterns between patients only and patients versus controls, the better the controls simulate DID. Thus, relatively speaking, low fantasy prone controls simulated the performance of DID patients better than high fantasy prone controls. This result is the opposite from the direction indicated by holders of the sociocognitive and fantasy based model of DID , –, . As patients and controls were scanned in a highly similar experimental setting and because controls were highly motivated to simulate DID, commonalities in brain activation between patients and controls were expected. Despite the overlap in brain activation between patients and controls important previously found psychophysiological and neurobiological differences between NIS and TIS in DID patients were upheld when controlling for fantasy proneness, suggestion, and instructed and motivated role-playing, which is supportive of our first a priori hypothesis.
The activated areas seem to be subdivided in two distinct neural networks, where the NIS activates areas in the cerebral cortex, while the TIS mainly activates subcortical areas (e.g., see Table 2 and Figure 2). The Tables show a detailed listing of all the brain areas involved. The brain areas marked with a II in the Tables are brain areas non-specific to DID as they disappear after comparing to a control group, i.e. these areas share commonalities between patients and controls. The brain areas marked with a III and IV in the Tables are brain areas specific to DID. The areas in the latter group are areas that were not reported earlier as they were “subtracted out” in the within group comparisons.
Our findings support the cortico-limbic inhibition model of trauma-related dissociative disorders , . Results of both the NISt-TISt comparison and the main effect of NIS show significant overlap with the activated network of brain regions during emotional memory suppression of unwanted memories in mentally healthy individuals , for example in frontal areas (BA 4/6/8/10/47), cingulate cortex (BA 32), and intraparietal sulcus (BA 7/40). Anderson et al.  did not find all of these brain areas. There is significant overlap between our study and their study, but the brain areas involved in the modulation of access to trauma-related memory in our patient population are of larger number. This might be an indication that, when functioning as NIS, in DID patients different cortical processes are involved that modulate conscious and subconscious perception of trauma-related information. These areas, e.g. (pre-)cuneus (BA 7/39, 18/19), fusiform gyrus (BA 18/19/37), lingual gyrus (BA 18), occipital gyrus (BA 18/19/37), and the parahippocampal gyrus (BA 35/36), are located in the posterior association areas (PAA) and have been indicated to be involved in multimodal ,  somato-sensory integration ,  of information, especially in relation to attention and perceptual awareness . Hyperactivation of cortical multimodal association areas for NIS in DID when listening to personal trauma scripts constituted our third a priori hypothesis. We thus propose that for emotional memory suppression, or NIS’ mental avoidance , of unwanted memories in DID the PAA fulfils a pivotal role.
There are notable similarities in the patterns of brain activation for DID patients, as revealed in the main effect TIS and the TISt-NISt comparison, and mentally healthy individuals unsuppressed memory retrieval . Both groups had increased activation of the insula (BA 13) and parietal operculum (BA 40/43). We did not find the hippocampus to play a role in memory retrieval in DID patients, despite the fact that this area has been indicated in memory processing in mentally healthy individuals . Instead we found that the caudate nucleus was activated when DID patients listened to the trauma-memory scripts as TIS. Acute stress can be associated with a shift from hippocampal involvement to caudate nucleus involvement , . Thus, acute stress is linked with caudate nucleus-dependent stimulus-response type reactivity at the expense of hippocampal dependent spatial learning and memory . According to the theory of structural dissociation ,  listening to a description of a personal traumatic memory in an experimental setting constitutes a consciously experienced acute stressor for TIS, because as this dissociative identity state DID patients do not manage to mentally avoid the relevant memory. When DID patients as TIS are confronted with reminders of traumatic memories, they may initiate a caudate mediated reflex-like flight-fright-freeze response ,  which reaction is also supported by an accompanying amygdala activation , . Another, but compatible, explanation for increased caudate and amygdala activation in DID patients as compared to controls is a heightened memory sensitivity for negative valanced information . These findings for TIS are supportive of our second a priori hypothesis.
To date, experimental research of inter-identity amnesia in DID has produced mixed results. One study  demonstrated evidence for inter-identity amnesia, which is in line with the current findings. Other studies – found inter-identity transfer of newly learned non-autobiographical stimuli, even though the “amnestic” identity reported subjective amnesia for these stimuli. Several principles might explain the inconsistent findings: (i) Inter-identity amnesia may only exist for stimuli that have personal relevance for the “amnestic” identity. In the cited studies –, it was not assessed if or to what degree the applied stimuli had autobiographical meaning for the tested “amnestic” and “mnestic” dissociative identities. Our study included traumatic memories that were subjectively autobiographical for TIS but not for NIS, and found that NIS and TIS had different subjective, psychophysiological, and neural reactions to a description of the involved traumatic memories. We also found that as a NIS, DID patients did not relate these traumatic memories to themselves . These results indicate the importance of using autobiographical information when investigating inter-identity amnesia in DID. (ii) Inter-identity amnesia may predominantly exist between different types of dissociative identities, particularly between neural and trauma-related identity states.This has been clinically observed, theoretically proposed ,  and is in line with our results. Unfortunately, in most studies – it was not assessed what types of dissociative identities participated, e.g. NIS or TIS. Therefore, we strongly recommend that in future research in DID the types of dissociative identities are verified and reported and that test material is used that is subjectively autobiographical for one dissociative identity, but not for another.
The sociocognitive view of DID entails the idea that this disorder can be easily and readily created in motivated suggestible individuals and that few suggestions would suffice to generate the symptoms of DID  (see Supporting Information S2). Still, one might argue that the current brief practice of DID simulation is insufficient to simulate the psychobiological profiles of NIS and TIS. Even if years of practice could generate these profiles, our findings suggest that fantasy proneness is not the driving factor because low fantasy prone controls simulated the performance of DID patients better than high fantasy prone controls. This result is the opposite from the direction indicated by holders of the sociocognitive and fantasy based view. Therefore we feel that our study provides an important contribution to the etiology discussion.
For the first time, it is shown using brain imaging that neither high nor low fantasy prone healthy women, who enacted two different types of dissociative identity states, were able to substantially simulate these identity states in psychobiological terms. These results do not support the idea of a sociogenic origin for DID.
Mentally healthy females were recruited by local newspaper advertisements. Respondents were sent a letter in which the study was explained and in which they were invited to complete three questionnaires: (i) the Traumatic Experiences Checklist (TEC) , a self-report questionnaire assessing potentially traumatizing events such as physical abuse and emotional neglect, (ii) the Somatoform Dissociation Questionnaire (SDQ-20 –, a self-report questionnaire evaluating the severity of somatoform dissociative symptoms, e.g., analgesia, anesthesia, motor inhibitions), and (iii) the Creative Experiences Questionnaire (CEQ)  which measures fantasy proneness. Exclusion criteria were the presence of medical, neurological or psychiatric problems in the past or the present, the use of psychotropic medication 15 days prior to examination, participation in a positron emission tomography (PET) or other study that involved administration of radiation in the year prior to this study, and pregnancy. A total of 18 healthy controls participated in the study, which was approved by the Medical Ethical Committee of the University Medical Center Groningen.
After inclusion, written and oral information on dissociative identity states (i.e. NIS and TIS) in DID and instructions on how to simulate these dissociative identity states was given to the controls. It was checked whether the controls understood this information. A template for training themselves in switching between the simulated identity states was provided. Controls were then questioned about how they constructed the two identity states, whether they encountered difficulties and if so, they were given support to improve their roles as NIS and TIS. To help the controls simulate NIS and TIS, they were asked to recall two experiences they had had earlier in their life, an emotionally neutral experience and an emotionally painful experience. Controls were asked to provide their most painful memory to serve as an analogue for the patients’ personal trauma memories, as well as a neutral personal episodic memory. Controls were subsequently instructed how to write the autobiographical analogue neutral and “trauma” memory scripts. For the experiment they had to train themselves in being in a neutral state, the NIS who is unresponsive or under-responsive to the painful experience, and in being in a state in which they re-experience the painful memory, the TIS. The consecutive and final check on the capability to simulate the two different dissociative identity states consisted in checking whether their description of their neutral and painful experiences (that was to be casted in an audiotape recording) met the instructions on how to enact a DID patient.
In the two or more weeks preceding the PET scans, candidate control subjects practiced simulating NIS and TIS, as well as alternating between NIS and TIS using detailed role instructions. One of the investigators (H.V.) contacted the candidates per telephone during this preparatory phase to ensure that they followed the instructions and to offer further suggestions for optimizing their role performance. One candidate felt unable to simulate the roles satisfactorily, and was therefore excluded. Prior to the actual PET scanning, H.V. checked if the candidates experienced and judged that they were able to simulate the roles of NIS and TIS. During the actual scanning, he checked if they engaged in the requested simulations, and immediately after the role performances, he checked if the controls generally felt they had simulated the roles of NIS and TIS effectively. All controls passed these various checks. In addition, immediately after each text condition, H.V. administered a detailed questionnaire that inquired after the controls’ subjective sensorimotor and emotional experiences during their role performance. This questionnaire was identical to the one in the patient study , , which was administered by the patients’ therapist, and debriefed six subjective emotional experiences (fear, sorrow, sadness, anger, shame and disgust) and ten sensorimotor experiences (visual, kinesthetic, auditory, olfactory + gustatory reactions, pain, physical numbness, body stiffening, paralysis and restlessness) were debriefed. In addition, the presence of the identity state under investigation and the interference among identity states were also debriefed. Using this questionnaire, H.V. or the patients’ therapist could structurally evaluate if the intended NIS or TIS had been present during the experimental condition. Statistical analyses of the simulation performance in terms of their subjective experiences, i.e. the subjective sensorimotor perception and emotional response, during the scanning by the two control groups are provided in Supporting Information S2.
As we did not have CEQ values for the patients (see also Supporting Information S1) we could not control for fantasy proneness by including a covariate. Therefore, the controls were divided into two groups based on their CEQ scores resulting in a high fantasy prone group (n = 10, age 38.2 (SD 10.9), TEC 0.7 (SD 1.3), SDQ-20 22 (SD 2.4)) with CEQ 13.7 (SD 3.2) and a low fantasy prone group (n = 8, age 42.5 (SD 10.1), TEC 0.4 (SD 0.5), SDQ-20 20.9 (SD 1.5)), with CEQ 3.9 (SD 1.6). A CEQ cut-off for high fantasy proneness of 10 was used, which the developers of the CEQ recommended for the current sample .
A detailed description of the DID patients can be found elsewhere , . In short: Eleven patients (all female, age 41.0, SD 6.1) participated: (i) whose treatment had progressed to Phase II , which involves therapeutic exposure to trauma-related memories, (ii) who met criteria for DID, as operationalized in the Structured Clinical Interview for DSM-IV Dissociative Disorders (SCID-D ), and (iii) had at least one TIS and one NIS that they could activate on demand  and (iv) the involved TIS had displayed signs of sympathetic nervous system dominance under perceived threat in clinical situations.
To establish the CEQ values in DID patients an independent and representative sample of DID patients (n = 42) completed the CEQ. Details regarding this substudy can be found in the Supporting Information S1.
During scanning, patients and controls listened to descriptions of the neutral episodic memories and memories of traumatizing or most painful events that only TIS experienced as a personal memory . These memories were cast, prior to the PET session, by the therapist or one of the principal investigators (H.V.) in terms of stimulus descriptions, and were subsequently audio-taped in a neutral tone of voice as 120 second scripts for playback during the PET investigation.
The PET (Siemens/CTI ECAT HR+) procedure for the controls was close to identical to the patients , . In contrast to patients the controls did not habituate to the PET environment prior to the investigation as anxiety levels were expected to be low. Approximately two hours prior to the PET investigation the continuous ECG registration was started, obtaining the five frequency and time domain variables , . No urine samples were obtained for the control groups, both medication and drugs use were verbally debriefed according to standard control research practice.
For the controls one extra set of the four conditions was added to increase statistical power. The scanning sequence was therefore NISn, NISt, TISn, TISt, TISn, TISt, NISn, NISt, TISn, TISt, NISn and NISt. The last minor character (n or t) denotes the content of the memory script (MS: neutral or trauma-related). For patient comfort considerations, i.e. minimizing the number of identity state switches, a fixed condition order was used, which was also used for the controls to minimize methodological differences.
Immediately following the end of each script, blood pressure (systolic and diastolic) and discrete heart rate frequency were measured and the six subjective emotional and ten sensorimotor experiences were debriefed. Finally, the presence of the identity state under investigation and the interference among identity states were also debriefed.
Image Acquisition and Data Processing
Data acquisition, reconstruction, attenuation correction, spatial transformation, spatial smoothing (isotropic Gaussian kernel of 12 mm) and global normalization were performed as usual , , . SPM5 (www.fil.ion.ucl.ac.uk/spm) was used for spatial transformation to the MNI template (using heavy regularization) ,  and statistical analysis  of both patient and control data.
Data Analysis: Autonomic and Subjective Reactions
Statistical analysis, missing value analysis and principal components (PC) analysis were performed with SPSS-PC 15.0 (2006) in an identical manner as was done for the patient data , . Results with p<0.05 are reported as significant. Within SPSS two two-by-two-by-two factorial design were defined with the first factor Group, consisting of the levels DID and the high fantasy prone controls or the low fantasy prone controls, a second factor identity state, consisting of the levels NIS and TIS, and the third factor was MS, consisting of the levels neutral and trauma-related. For one high fantasy prone and one low fantasy prone subject heart rate variability (HRV) data could not be obtained. In addition, the data, including the PET data, from two NISt conditions was removed as the control subjects reported not to be able to maintain as a NIS. One TISn condition was removed from the low fantasy prone data as the subject reported not to be able to maintain a TIS. Bonferoni correction to correct for multiple testing was applied.
Data Analysis: PET-data
The patient PET data included in the current study is identical to the data as included and described in our previous publications , . This study assessed various effects, e.g., main effects and simple subtraction analyses (within and between identity state) within the DID group using SPM99. This data was re-analyzed in SPM5 and is referred to as the “within DID only” analyses.
From the 10 high fantasy prone healthy controls the PET data of one subject was lost due to storage failure at the PET center. The data of the three groups was statistically analyzed in SPM5 in a three-by-two-by-two factorial design –. The general linear model (GLM) consisted of the three factor main effects, the four conditions and a group by condition interaction.
In addition, the subjective reactions and the autonomic reactions were included as group specific covariates of interest after PC analysis , . The variance in the subjective ratings could be described with the first two, six, and five PC for the DID, high and low fantasy prone groups respectively, explaining 64%, 68%, and 72% of the variance. The variance in the autonomic reactions could be described with the first three PC for each of the DID, high and low fantasy prone groups, explaining 85%, 82%, and 87% of the variance respectively. Finally, the global cerebral blood flow (CBF) was included as a nuisance covariate (AnCova by subject).
Previously reported significant findings were tested using a between group subtraction of the within group results (e.g. DID(TISt-NISt)-Control(TISt-NISt)). Commonalities in brain activation between patients and controls were tested using global null conjunction analyses .
Statistical Inference and Reporting
Our a priori hypothesis was that earlier findings would still hold after the correction for non-trauma-related factors. Both whole brain and a priori region of interest (ROI) multiple comparisons correction were performed on the basis of false discovery rate statistics . Statistical parametric maps were thresholded using an uncorrected threshold of p<0.001 ,  and explored for a priori hypothesized brain areas. If an a priori hypothesized brain area did not survive whole brain multiple comparison correction, multiple comparisons correction was performed within the a priori region of interest (ROI). For subcortical located ROI and ROI in the cerebellum a sphere with a volume of 3054 mm3  was used. For larger cortical a priori hypothesised ROI a sphere with a volume of 6108 mm3 was used. Note: in line with previously used statistical thresholds  voxels surviving significant levels only uncorrected for multiple testing for the whole brain, i.e. p<0.001 ,  were reported as well, but for comparison purposes only. Only clusters larger than eight voxels are reported taking into account the spatial resolution of the PET camera. In contrast to the earlier publication , this time all peak voxels are reported for a more accurate comparison between groups.
The coordinates were converted from MNI space to Talairach space  to be defined in Brodmann areas (BA) using both the Talairach atlas  and Deamon , . Activations in sulci was defined using Brain Tutor . The location was anatomically compared to and described using a second brain atlas .
Fantasy proneness in dissociative identity disorder.
How well are the dissociative identity disorder simulating healthy controls doing?
The authors are greatly indebted to all the participants: thank you for participating. They also would like to thank Margo Jongsma for her assistance and participant recruitment. Jaap Haaksma is thanked for the HRV data collection and Marc van Ekeren for help during data collection and pilot analyses. Finally, Borden Armstrong is thanked for psychophysiological data-analysis support and proof reading.
Conceived and designed the experiments: AATSR ATMW JAB ERSN. Performed the experiments: AATSR HPJV. Analyzed the data: AATSR ATMW. Wrote the paper: AATSR ATMW HPJV JAB ERSN.
- 1. Association AP, DSM-IV APATF on (2000) Diagnostic and statistical manual of mental disorders: DSM-IV-TR. American Psychiatric Pub. 996 p.
- 2. Piper A, Merskey H (2004) The persistence of folly: a critical examination of dissociative identity disorder. Part I. The excesses of an improbable concept. Can J Psychiatry 49: 592–600.
- 3. Piper A, Merskey H (2004) The persistence of folly: critical examination of dissociative identity disorder. Part II. The defence and decline of multiple personality or dissociative identity disorder. Can J Psychiatry 49: 678–683.
- 4. Coons PM (2005) Re: the persistence of folly: a critical examination of dissociative identity disorder. Can J Psychiatry 50: 813; author reply 814.
- 5. Fraser GA (2005) Re: the persistence of folly: a critical examination of dissociative identity disorder. Can J Psychiatry 50: 814; author reply 814.
- 6. Sar V (2005) Re: the persistence of folly: a critical examination of dissociative identity disorder. What are Dr Piper and Dr Merskey trying to do? Can J Psychiatry 50: 813; author reply 814.
- 7. Piper A, Merskey H (2005) The persistence of folly: A critical examination of dissociative identity disorder. Can J Psychiatry 50: 814.
- 8. Giesbrecht T, Lynn SJ, Lilienfeld SO, Merckelbach H (2008) Cognitive processes in dissociation: an analysis of core theoretical assumptions. Psychol Bull 134: 617–647.
- 9. Bremner JD (2010) Cognitive processes in dissociation: comment on Giesbrecht, et al. (2008). Psychol Bull 136: 1–6; discussion 7–11.
- 10. Giesbrecht T, Lynn SJ, Lilienfeld SO, Merckelbach H (2010) Cognitive processes, trauma, and dissociation–Misconceptions and misrepresentations: Reply to Bremner (2010). Psychol 136: 7–11.
- 11. Merckelbach H, Muris P (2001) The causal link between self-reported trauma and dissociation: a critical review. Behav Res Ther 39: 245–254.
- 12. Merckelbach H, Devilly GJ, Rassin E (2002) Alters in dissociative identity disorder. Metaphors or genuine entities? Clin Psychol Rev 22: 481–497.
- 13. Pope HG Jr, Barry S, Bodkin A, Hudson JI (2006) Tracking scientific interest in the dissociative disorders: a study of scientific publication output 1984–2003. Psychother Psychosom 75: 19–24.
- 14. Spanos NP (1994) Multiple identity enactments and multiple personality disorder: a sociocognitive perspective. Psychol Bull 116: 143–165.
- 15. Spanos NP (1996) Multiple Identities and False Memories: A Sociocognitive Perspective. American Psychological Association (APA). 371 p.
- 16. Lilienfeld SO, Lynn SJ, Kirsch I, Chaves JF, Sarbin TR, et al. (1999) Dissociative identity disorder and the sociocognitive model: recalling the lessons of the past. Psychol Bull 125: 507–523.
- 17. Merckelbach H, Rassin E, Muris P (2000) Dissociation, schizotypy, and fantasy proneness in undergraduate students. J Nerv Ment Dis 188: 428–431.
- 18. Merckelbach H, Horselenberg R, Muris P (2001) The Creative Experiences Questionnaire (CEQ): a brief self-report measure of fantasy proneness. Personality and Individual Differences 31: 987–995.
- 19. Giesbrecht T, Merckelbach H (2006) Dreaming to reduce fantasy? – Fantasy proneness, dissociation, and subjective sleep experiences. Personality and Individual Differences 41: 697–706.
- 20. Giesbrecht T, Merckelbach H, Kater M, Sluis AF (2007) Why dissociation and schizotypy overlap: the joint influence of fantasy proneness, cognitive failures, and childhood trauma. J Nerv Ment Dis 195: 812–818.
- 21. Rassin E, Merckelbach H, Spaan V (2001) When dreams become a royal road to confusion: realistic dreams, dissociation, and fantasy proneness. J Nerv Ment Dis 189: 478–481.
- 22. Silva CE, Kirsch I (1992) Interpretive sets, expectancy, fantasy proneness, and dissociation as predictors of hypnotic response. J Pers Soc Psychol 63: 847–856.
- 23. Braffman W, Kirsch I (1999) Imaginative suggestibility and hypnotizability: an empirical analysis. J Pers Soc Psychol 77: 578–587.
- 24. Poulsen BC, Matthews Jr WJ (2003) Correlates of imaginative and hypnotic suggestibility in children. Contemporary Hypnosis 20: 198–208.
- 25. Levin R, Spei E (2004) Relationship of purported measures of pathological and nonpathological dissociation to self-reported psychological distress and fantasy immersion. Assessment 11: 160–168.
- 26. Rauschenberger SL, Lynn SJ (1995) Fantasy proneness, DSM-III-R axis I psychopathology, and dissociation. J Abnorm Psychol 104: 373–380.
- 27. Gleaves DH (1996) The sociocognitive model of dissociative identity disorder: a reexamination of the evidence. Psychol Bull 120: 42–59.
- 28. Loewenstein RJ (2007) Dissociative Identity Disorder: Issues in the iatrogenesis controversy. In: Vermetten E, Dorahy M, Spiegel D, editors. pp. 275–299. Washington, D.C., USA: American Psychiatric Press.
- 29. Brown D, Frischholz EJ, Scheflin AW (1999) Iatrogenic Dissociative Identity Disorder - An Evaluation of the Scientific Evidence. J Psychiatry & L 27: 549.
- 30. Xiao Z, Yan H, Wang Z, Zou Z, Xu Y, et al. (2006) Trauma and dissociation in China. Am J Psychiatry 163: 1388–1391.
- 31. Gharaibeh N, Merskey H (2009) Removing DID/MPD from DSM-V: An email petition against the inclusion of DID in the DSM-V.
- 32. Putnam FW (1992) Multiple personality disorder. Br J Psychiatry 161: 415–416; author reply 418–420.
- 33. Hart O van der, Nijenhuis ERS, Steele K (2006) The Haunted Self: Structural Dissociation and the Treatment of Chronic Traumatization. 440 p.
- 34. Spiegel D (2006) Recognizing traumatic dissociation. Am J Psychiatry 163: 566–568.
- 35. Dell PF, O’Neil JA, editors (2009) Dissociation and the Dissociative Disorders: DSM-V and Beyond. Routledge. 898 p.
- 36. Spiegel D (1984) Multiple personality as a post-traumatic stress disorder. Psychiatr Clin North Am 7: 101–110.
- 37. Draijer N, Boon S (1999) Imitation of Dissociative Identity Disorder: Patients at Risk, Therapists at Risk, The. J Psychiatry & L 27: 423–458.
- 38. Elzinga BM, van Dyck R, Spinhoven P (1998) Three controversies about dissociative identity disorder. Clinical Psychology & Psychotherapy 5: 13–23.
- 39. Reinders AATS, Nijenhuis ERS, Paans AMJ, Korf J, Willemsen ATM, et al. (2003) One brain, two selves. Neuroimage 20: 2119–2125.
- 40. Reinders AATS, Nijenhuis ERS, Quak J, Korf J, Haaksma J, et al. (2006) Psychobiological characteristics of dissociative identity disorder: a symptom provocation study. Biol Psychiatry 60: 730–740.
- 41. Nijenhuis ERS, Van der Hart O, Steele K D’haenen HAH, Den Boer JA, Willner P, editors. (2002) The Emerging Psychobiology of Trauma-Related Dissociation and Dissociative Disorders. 2: 1079–1098. West Sussex: Wiley & Sons, LTD, Vol.
- 42. Nijenhuis ERS, van der Hart O (2011) Dissociation in trauma: a new definition and comparison with previous formulations. J Trauma Dissociation 12: 416–445.
- 43. Nijenhuis ERS, van der Hart O, Kruger K, Steele K (2004) Somatoform dissociation, reported abuse and animal defence-like reactions. Aust N Z J Psychiatry 38: 678–686.
- 44. LeDoux JE (2000) Emotion circuits in the brain. Annu Rev Neurosci 23: 155–184.
- 45. Nijenhuis ERS, Den Boer JA (2009) Psychobiology of traumatisation and trauma-related structural dissociation of the personality. In: Dell PF, O’Neil JA, editors. pp. 337–367. New York: Routledge.
- 46. Merckelbach, Giesbrecht T (2006) Subclinical dissociation, schizotypy, and traumatic distress. Personality and Individual Differences 40: 365–374.
- 47. Lanius RA, Vermetten E, Loewenstein RJ, Brand B, Schmahl C, et al. (2010) Emotion modulation in PTSD: Clinical and neurobiological evidence for a dissociative subtype. Am J Psychiatry 167: 640–647.
- 48. Anderson MC, Ochsner KN, Kuhl B, Cooper J, Robertson E, et al. (2004) Neural systems underlying the suppression of unwanted memories. Science 303: 232–235.
- 49. Driver J, Vuilleumier P (2001) Perceptual awareness and its loss in unilateral neglect and extinction. Cognition 79: 39–88.
- 50. Pavani F, Ládavas E, Driver J (2003) Auditory and multisensory aspects of visuospatial neglect. Trends Cogn Sci (Regul Ed) 7: 407–414.
- 51. Simeon D, Guralnik O, Hazlett EA, Spiegel-Cohen J, Hollander E, et al. (2000) Feeling unreal: a PET study of depersonalization disorder. Am J Psychiatry 157: 1782–1788.
- 52. Lanius RA, Williamson PC, Densmore M, Boksman K, Neufeld RW, et al. (2004) The nature of traumatic memories: a 4-T FMRI functional connectivity analysis. Am J Psychiatry 161: 36–44.
- 53. Schwabe L, Dalm S, Schächinger H, Oitzl MS (2008) Chronic stress modulates the use of spatial and stimulus-response learning strategies in mice and man. Neurobiol Learn Mem 90: 495–503.
- 54. White NM (2009) Some highlights of research on the effects of caudate nucleus lesions over the past 200 years. Behav Brain Res 199: 3–23.
- 55. Nijenhuis ER, Spinhoven P, Vanderlinden J, van Dyck R, van der Hart O (1998) Somatoform dissociative symptoms as related to animal defensive reactions to predatory imminence and injury. J Abnorm Psychol 107: 63–73.
- 56. Nijenhuis ER, Vanderlinden J, Spinhoven P (1998) Animal defensive reactions as a model for trauma-induced dissociative reactions. J Trauma Stress 11: 243–260.
- 57. Armony JL, LeDoux JE (1997) How the brain processes emotional information. Ann N Y Acad Sci 821: 259–270.
- 58. Hamilton JP, Gotlib IH (2008) Neural substrates of increased memory sensitivity for negative stimuli in major depression. Biol Psychiatry 63: 1155–1162.
- 59. Elzinga BM, Phaf RH, Ardon AM, van Dyck R (2003) Directed forgetting between, but not within, dissociative personality states. J Abnorm Psychol 112: 237–243.
- 60. Huntjens RJC, Peters ML, Postma A, Woertman L, Effting M, et al. (2005) Transfer of newly acquired stimulus valence between identities in dissociative identity disorder (DID). Behav Res Ther 43: 243–255.
- 61. Huntjens RJC, Peters ML, Woertman L, Bovenschen LM, Martin RC, et al. (2006) Inter-identity amnesia in dissociative identity disorder: a simulated memory impairment? Psychol Med 36: 857–863.
- 62. Huntjens RJC, Peters ML, Woertman L, van der Hart O, Postma A (2007) Memory transfer for emotionally valenced words between identities in dissociative identity disorder. Behav Res Ther 45: 775–789.
- 63. Huntjens RJC, Postma A, Hamaker EL, Woertman L, van der Hart O, et al. (2002) Perceptual and conceptual priming in patients with dissociative identity disorder. Mem Cognit 30: 1033–1043.
- 64. Huntjens RJC, Postma A, Peters ML, Woertman L, van der Hart O (2003) Interidentity amnesia for neutral, episodic information in dissociative identity disorder. J Abnorm Psychol 112: 290–297.
- 65. Huntjens RJC, Postma A, Woertman L, van der Hart O, Peters ML (2005) Procedural memory in dissociative identity disorder: when can inter-identity amnesia be truly established? Conscious Cogn 14: 377–389.
- 66. Reinders AATS (2008) Cross-examining dissociative identity disorder: neuroimaging and etiology on trial. Neurocase 14: 44–53.
- 67. Nijenhuis ERS, Van der Hart O, Kruger K (2002) The psychometric characteristics of the traumatic experiences checklist (TEC): first findings among psychiatric outpatients. Clinical Psychology & Psychotherapy 9: 200–210.
- 68. Nijenhuis ER, Spinhoven P, Van Dyck R, Van der Hart O, Vanderlinden J (1996) The development and psychometric characteristics of the Somatoform Dissociation Questionnaire (SDQ-20). J Nerv Ment Dis 184: 688–694.
- 69. Nijenhuis ER, Spinhoven P, van Dyck R, van der Hart O, Vanderlinden J (1997) The development of the somatoform dissociation questionnaire (SDQ-5) as a screening instrument for dissociative disorders. Acta Psychiatr Scand 96: 311–318.
- 70. Tsar V, Kundakci T, Kiziltan E, Bakim B, Bozkurt O (2001) Differentiating Dissociative Disorders from Other Diagnostic Groups Through Somatoform Dissociation in Turkey. Journal of Trauma & Dissociation 1: 67–80.
- 71. Feb. 2008 Giesbrecht T, Merckelbach H (n.d.) Personal written email communication on the 11th of.
- 72. Brown D, Scheflin AW, Hammond DC (1998) Memory, trauma treatment, and the law. New York: Norton. p.
- 73. Steinberg M (1993) Structured Clinical Interview for DSM-IV Dissociative Disorders (SCID-D). Washington DC: American Psychiatric Press.
- 74. Casada JH, Amdur R, Larsen R, Liberzon I (1998) Psychophysiologic responsivity in posttraumatic stress disorder: generalized hyperresponsiveness versus trauma specificity. Biol Psychiatry 44: 1037–1044.
- 75. Haaksma J, Brouwer J, Mulder LJM, Mulder G, Crijns HJGM, et al. (1994) Heart Rate Dependent Changes in Spectral Analysis. Computers in Cardiology 1994. IEEE Computer Society Press (Los Almalitos). pp. 45–48.
- 76. Malik M (1996) Standards of measurement, physiological interpretation, and clinical use. Eur 17: 354–381.
- 77. Reinders AATS, Willemsen ATM, Georgiadis JR, Hovius M, Paans AMJ, et al. (2002) Interscan Displacement-Induced Variance in PET Activation Data Is Excluded by a Scan-Specific Attenuation Correction. NeuroImage 17: 1844–1853.
- 78. Friston KJ, Ashburner J, Frith CD, Poline J -B, Heather JD, et al. (1995) Spatial registration and normalization of images. Human Brain Mapping 3: 165–189.
- 79. Talairach J, Tournoux P (1988) Co-planar stereotaxic atlas of the human brain: 3-dimensional proportional system: an approach to cerebral imaging. Thieme. 145 p.
- 80. Friston KJ, Holmes AP, Worsley KJ, Poline J-P, Frith CD, et al. (1994) Statistical parametric maps in functional imaging: A general linear approach. Human Brain Mapping 2: 189–210.
- 81. Friston KJ, Price CJ, Fletcher P, Moore C, Frackowiak RS, et al. (1996) The trouble with cognitive subtraction. Neuroimage 4: 97–104.
- 82. Price CJ, Moore CJ, Friston KJ (1997) Subtractions, conjunctions, and interactions in experimental design of activation studies. Hum Brain Mapp 5: 264–272.
- 83. Price CJ, Friston KJ (1997) Cognitive conjunction: a new approach to brain activation experiments. Neuroimage 5: 261–270.
- 84. Karl J F (1997) Imaging cognitive anatomy. Trends in Cognitive Sciences 1: 21–27.
- 85. Genovese CR, Lazar NA, Nichols T (2002) Thresholding of statistical maps in functional neuroimaging using the false discovery rate. Neuroimage 15: 870–878.
- 86. Friston KJ, Frith CD, Liddle PF, Frackowiak RS (1991) Comparing functional (PET) images: the assessment of significant change. J Cereb Blood Flow Metab 11: 690–699.
- 87. Reinders AATS, den Boer JA, Büchel C (2005) The robustness of perception. Eur J Neurosci 22: 524–530.
- 88. Brett M (2006) The MNI brain and the Talairach atlas. Available. http://imaging.mrc-cbu.cam.ac.uk/imaging/MniTalairach.
- 89. Lancaster JL, Rainey LH, Summerlin JL, Freitas CS, Fox PT, et al. (1997) Automated labeling of the human brain: a preliminary report on the development and evaluation of a forward-transform method. Hum Brain Mapp 5: 238–242.
- 90. Lancaster JL, Woldorff MG, Parsons LM, Liotti M, Freitas CS, et al. (2000) Automated Talairach atlas labels for functional brain mapping. Hum Brain Mapp 10: 120–131.
- 91. Goebel R (2011) Brain Innovation: Home of the BrainVoyager Product Family. Available. http://www.brainvoyager.com/.
- 92. Mai JK, Assheuer JK, Paxinos G (1997) Atlas of the Human Brain. Academic Press Inc. 336 p.