Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT01723033 |
| Other study ID # |
BHMC-5200 |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
N/A
|
| First received |
November 5, 2012 |
| Last updated |
November 7, 2012 |
| Start date |
December 2012 |
Study information
| Verified date |
November 2012 |
| Source |
Beersheva Mental Health Center |
| Contact |
Doron Tudor, MD |
| Phone |
972-8-6401401 |
| Email |
doron.todder[@]pbsh.health.gov.il |
| Is FDA regulated |
No |
| Health authority |
Israel: Israeli Health Ministry Pharmaceutical Adminsitration |
| Study type |
Observational
|
Clinical Trial Summary
Comparison of the neurophysiological response of OCD and PTSD patients (both considered
anxiety syndromes) in error processing. The patients will perform three computerized tasks
while a net of electrodes (for EEG measurement) will be placed on their head. This data will
then be compared to a previously collected healthy control sample.
Description:
Scientific background Obsessive Compulsive Disorder (OCD) Obsessive Compulsive Disorder
(OCD) is a chronic mental disturbance classified as an anxiety disorder, which causes a
severe social and occupational damage. It is characterized with repetitive and intrusive
thoughts, and with the urge to perform reoccurring rituals. Illness' course is usually
chronic and is characterized with fluctuation in symptoms severity. Only a minority of
patients gain full relief, even following the appropriate treatment. There are two main
useful treatments, a behavioral therapy and a medicinal treatment using SSRI's. Even though
medicinal treatments are improving, large amount of patients are irresponsive to a variety
of medicinal treatment and about a third is classified as Refractory to Treatment. Of those
who will gain relief, relapse rate is high (Catapano et al., 2006).
Brain imaging studies demonstrate that the neurophysiological basis of OCD appears to be
abnormal functioning of frontal subcortical circuits and that illness' symptoms are related
to an increase in cortical activity of different areas: anterior cingulate gyrus (Saxena &
Rauch, 2000) orbitofrontal cortex, caudate nucleus, and thalamus. ERP studies provide a
number of indicators of cerebral abnormalities in OCD, during critical aspects of cognitive
processing (Clark et al., 2009). The sharp negative deflection associated with errors is
referred to as error-related negativity (ERN; Gehring, Coles, Meyer, & Donchin, 1995).
Gehring et al. (2000) found that OCD patients had an increased ERN amplitude which was
significantly associated with symptom severity. Johannes et al. (2001) using a visual
discrimination task also reported larger ERN amplitudes in OCD patients, whilst Hajcak and
Simons (2002) found increased ERN-like deflections to both incorrect and correct trials in
University under- graduates with high levels of obsessive compulsive characteristics.
From cognitive behavioral perspective, obsessive-compulsive disorder (OCD) has been
associated with impairments in stop-signal inhibition, a measure of motor response
suppression (Morein-Zamir, Fineberg, Robbins, & Sahakian, 2010). Another study has related
OCD to an attention bias shifting towards the right hemifield in a well-established visual
attention task (Maril, Hermesh, Gross-Isseroff, & Tomer, 2007). Furthermore this shift of
attention had been reported to be positively correlated with OCD symptoms as measured by the
Y-BOCS (e.g. less Y-BOCS score correlated with less shifting of attention).
Post-Traumatic Stress Disorder (PTSD) Posttraumatic stress disorder (PTSD) is associated
with increased rates of health complaints (Beckham et al., 1998) medical morbidity (Beckham
et al., 2003) health service utilization (Calhoun, et al., 2002), and mortality (Boscarino,
2006). The prevalence of PTSD in the general population is estimated to be between 7% and
12% (Breslau, 2009).
On the anatomical level reports vary with certain areas emerging as possibly implicated in
PTSD predisposition and pathology. The hippocampus, important in learning and memory, has
been shown to be reduced in volume in PTSD patients ( reviewed by Nutt & Malizia, 2004). Two
additional regions implicated in PTSD are the amygdale- involved in emotional behavior, and
the medial frontal cortex - important in regulation of the HPA axis ( reviewed by Nutt &
Malizia, 2004).The major shortcoming of these anatomical studies is their retrospective
nature, precluding the possibility of extracting causality. Thus the question of temporal
sequence remains to be resolved.
Data reviewed by Etkin et al. (2011) suggest a controlled conscious top-down regulation,
like emotional conflict regulation, uses ventral ACC and mPFC areas to inhibit negative
emotional processing in the amygdala, thus dampening task interference. The ventral ACC and
mPFC might thus perform a generic negative emotion inhibitory function that can be recruited
by other regions (e.g. dorsal ACC and mPFC and lateral PFC) when there is a need to suppress
limbic reactivity. One might speculate that a dysfunction in this circuit might contribute
to a PTSD dysfunction in regulating negative emotional conflict. Unable to regulate and
suppress emotional arousal related to trauma relevant information, the PTSD affected
individual might choose to avoid it all together. The limbic reactivity might contribute to
hyper vigilant responses, and affect memory processes leading to intrusion, as well. In
short, dysfunction in the ventral medial PFC structures and their connections might
contribute to all symptom clusters.
Summary Taken together the described neurophysiological and neuropsychological findings, it
is compelling to further investigate antinational and response inhibition mechanisms in OCD
patients compared to PTSD patients by tapping on performance in cognitive paradigms
sensitive to the activity in medial prefrontal brain structures.
Study goal This study's main goal is to compare OCD and PTSD which are both considered an
anxiety syndrome by means of the patient's performance and neurophysiologic response while
engaged in an error detection task.
Design For the primary goal of the study, we will use a cross section design by comparing
PTSD sample to the OCD sample. Cognitive and electrophysiological data from the clinical
population will be compared to a previously collected healthy student's data.
Protocol After an explanation of the required procedure, all subjects will be kindly asked
to sign an informed consent version that can be found on the ethics committee application
form. Depicted in Figure 1, psychiatric and neurocognitive assessments will be taken at the
clinical neurophysiology department at the Beer-Sheva Mental Health Institute and cognitive
tasks while recording electrophysiology data will take place at the Cognitive
Neurophysiology Lab at Ben Gurion University of the Negev.
Figure 1
In order to evaluate the error processing in a domain general perspective, the
electrophysiological research will include three computerized tasks. In all three procedures
the subjects will be asked to perform a task, while a net of electrodes for EEG acquisition
will be placed on their head. During all tasks a number of within task breaks are inserted
in order to reduce the discomfort of the subjects as much as possible. The total procedure,
including all tasks, breaks within and in between tasks, will require approximately 2 hours.
Task description:
1. The Attention network test (Fan, McCandliss, Sommer, Raz, & Posner, 2002) has been
previously implemented in studying of clinical disorders (Posner & Rothbart, 2007). In
this task subject will be presented with five horizontal arrow stimuli and will be
asked to identify the direction of the centrally presented arrow by pressing a button
with the index finger. The procedure will require approximately 30 minutes.
2. In the Stroop with misspelled words task (Mesika & Berger, in preparation) subjects
will be asked to name the color of the word presented, while avoiding its meaning. On
some trials, spelling errors will be inserted in the presented words, while in others
no spelling errors will be present. This procedure will require approximately 30
minutes.
3. The Arithmetic verification task is a modified version of the task which Tzur and
colleagues have used previously (Tzur, Berger, Luria, & Posner, 2010; Tzur & Berger,
2007). The subjects participating in the task will be presented with either correct
(e.g. 3X6=18) or incorrect (e.g. 3X6=21) arithmetical equations, and will be asked to
decide each trial whether the equation presented is correct or incorrect. This
procedure will require approximately 45 minutes.
Three weeks after the initial examination, all subjects will be invited to participate in a
follow-up session at the Cognitive Neurophysiology Lab at Ben Gurion University of the Negev
regardless of the treatment they were participating in during this period. At this point all
subjects will be kindly asked to sign a new informed consent so that there will be no
obligatory relationship been participating at the first phase and at follow-up of the
experiment. Also, the subject's treatment between the sessions will be determined by the
patients attending physician without the intervention of the research team.
Patients will be evaluated using several widely used rating scales adminstered by a trained
psychiatrist.
Neurocognitive assessment
1. Raven's Progressive Matrices (Raven, 2000) - a measure of fluid intelligence; a factor
which may be relevant to PTSD development. This will also allow better control for
differences between patients normal population.
2. MindStreams®: neurocognitive assessment battery. Regularly used for diagnostic purposes
in the center.
All cognitive assignments are computerized and will take place at the Clinical
Neurophysiology department at the Beer-Sheva Mental Health center. The patient will either
read the instructions on the computer monitor or a trained experimenter will read the task
instruction for him.
Electrophysiology data acquisition
EEG recordings will take place at both the initiation and at the end of the research
protocol. We will use the EGI Geodesic Sensor net (128 electrodes) and system for data
acquisition (Electrical Geodesics, Oregon, USA). All equipment and materials that will be
used are FDA approved for clinical and research use and are been routinely applied on
patients, children and infants therefore can be considered safe. During all procedures the
use of the equipment will be according to the manufacturer's instructions only.
Before applying the net, subject's head will be measured in order to determine the
appropriate net size for EEG recording. Afterwards, using a soft and wide edged china
marker, a small mark will be drawn on the scalp to indicate the midpoint of the head. While
measuring the head, the electrode net will be dipped in electrolyte solution, composed of
purified water, salt and baby shampoo. The solution then will be warmed up to body
temperature to minimize the discomfort which could be caused by wetting the subject's head.
During net application procedure no scraping of the scalp is required. Preparation process
should take no more than 20 minutes and will cause no distress to the subject.
Statistics
Behavioral data will be collected as reaction time (in milliseconds) and accuracy (in
proportion) for each condition for each task, and will be analyzed using analysis of
variance (ANOVA) method for between subject analyses. Within subject analyses will be
performed using the repeated measures ANOVA on the same variables.
EEG data will be analyzed using the event related potentials (ERP) method, extracting the
amplitude (in microvolt) and latency (in milliseconds) of electrophysiological components.
In the statistical analysis ANOVA and repeated measures ANOVA will be implemented
accordingly.
