The impact of posttraumatic stress disorder on executive functioning

De Kock, Cornelius Johannes

January 2019

Background: Most of the neurocognitive research in Posttraumatic Stress Disorder (PTSD) thus far focused on impairment in learning and memory, neglecting the impact of PTSD on executive functioning processes. Therefore, this study specifically aims to investigate the impact of PTSD on frontal lobe executive functioning. Given the high prevalence rate for traumatic event exposure in South Africa, this study provides important findings on the role intact executive functioning plays in all areas of daily functioning, including the maintenance of good mental and physical health. Methods: Executive functions were assessed using an Executive Functioning Battery consisting of the three subtests of the Delis Kaplan Executive Functioning System (e.g., Trail Making Test, Colour-Word Interference Test, and Tower Test), as well as the Executive Functioning Index. The study sample consisted of 88 adult South African citizens who were divided into two groups (PTSD+; n = 44; PTSD–; n = 44) with different levels of trauma exposure. Results: PTSD was linked with impairment in executive functioning domains such as attention, cognitive flexibility, inhibition, working memory, and planning. Important gender differences were also reported in terms of empathy and organisation. In addition, education also appeared to affect frontal lobe executive functioning differently. Conclusions: The data suggest that overall, PTSD impaired executive functioning processes. It is therefore critical that assessment of executive functioning form part of a comprehensive treatment plan for individuals diagnosed with PTSD. / Mini Dissertation (MA)--University of Pretoria, 2019. / Psychology / MA / Unrestricted

UCTD

Posttraumatic Stress Disorder (PTSD)

Cognition

Executive Functions

Prefrontal Lobes

Neuropsychological Impairments

The Effects of Adolescent High Fat Diet on Adult Prefrontal Cortex-Dependent Behavior, Stress Responsivity, and Microglial Reactivity,

Lloyd, Kelsey

29 September 2021

No description available.

Neurology

Prefrontal Cortex

Stress Response

Adolesence

High Fat Diet

Obesity

Microglia

Procrastination as a form of Self-regulation Failure : A review of the cognitive and neural underpinnings

Fridén, Iselin

January 2020

The action of postponing an intended plan is often referred to as procrastination. Research on procrastination generally views the phenomenon as a form of self-regulation failure. Self-regulation refers to the conscious and non-conscious processes that enable individuals to guide their thoughts, feelings, and behaviors purposefully. Research indicates correlations between self-regulation and executive functions providing a fruitful integration. From a neuroscientific perspective, this integration generally associates the prefrontal cortex with top-down control whenever successful self-regulation is achieved. On the contrary, self-regulation failure appears to involve a bottom-up control, in which subcortical regions have greater influence on behavioral outcomes. Subcortical regions involved in emotional and rewarding processes, such as the amygdala and nucleus accumbens appears to lie at the coreof self-regulation failure, whereas cortical executive functions of regulating emotion and impulsive behaviors may contribute to successful self-regulation, thus overcoming procrastination. This thesis aims to obtain a deeper understanding of the mechanisms of procrastination, specifically investigating self-regulation failure and its relationship with executive functions and the neural underpinnings of self-regulation.

procrastination

self-regulation failure

executive functions

prefrontal cortex

nucleus accumbens

amygdala

Neurosciences

Neurovetenskaper

Exogenous Agmatine Has Neuroprotective Effects Against Restraint-Induced Structural Changes in the Rat Brain

Zhu, Meng Yang, Wang, Wei P., Cai, Zheng W., Regunathan, Soundar, Ordway, Gregory A.

01 March 2008

Agmatine is an endogenous amine derived from decarboxylation of arginine catalysed by arginine decarboxylase. Agmatine is considered a novel neuromodulator and possesses neuroprotective properties in the central nervous system. The present study examined whether agmatine has neuroprotective effects against repeated restraint stress-induced morphological changes in rat medial prefrontal cortex and hippocampus. Sprague-Dawley rats were subjected to 6 h of restraint stress daily for 21 days. Immunohistochemical staining with β-tubulin III showed that repeated restraint stress caused marked morphological alterations in the medial prefrontal cortex and hippocampus. Stress-induced alterations were prevented by simultaneous treatment with agmatine (50 mg/kg/day, i.p.). Interestingly, endogenous agmatine levels, as measured by high-performance liquid chromatography, in the prefrontal cortex and hippocampus as well as in the striatum and hypothalamus of repeated restraint rats were significantly reduced as compared with the controls. Reduced endogenous agmatine levels in repeated restraint animals were accompanied by a significant increase of arginine decarboxylase protein levels in the same regions. Moreover, administration of exogenous agmatine to restrained rats abolished increases of arginine decarboxylase protein levels. Taken together, these results demonstrate that exogenously administered agmatine has neuroprotective effects against repeated restraint-induced structural changes in the medial prefrontal cortex and hippocampus. These findings indicate that stress-induced reductions in endogenous agmatine levels in the rat brain may play a permissive role in neuronal pathology induced by repeated restraint stress.

β-tubulin III

agmatine

arginine decarboxylase

hippocampus

prefrontal cortex

repeated restraint stress

Biomedical Sciences

Central neural correlates of generalized anxiety disorder : A systematic review

Rundström, Alexandra

January 2021

Generalized anxiety disorder (GAD) is a prevalent anxiety disorder that is characterized by persistent excessive worrying that is often difficult to control. The pathology of GAD has been associated with abnormal neural activity and functional connectivity. This systematic review has examined the central neural correlates of GAD which are the prefrontal cortex (PFC), the anterior cingulate cortex (ACC) and the amygdala and how activation and functional connectivity in these brain areas differ between patients with GAD and healthy controls. This review also investigated how abnormal functional connectivity and activation in these brain regions relates to worry which is the most prominent psychological symptom in patients with GAD. A systematic review was conducted and seven original functional magnetic resonance imaging (fMRI) studies were included after a literature search on PubMed, Scopus and, Web of Science. The main findings from this review revealed decreased activation in the PFC and ACC and enhanced activation in the amygdala during the viewing of negative stimuli in patients with GAD. Identifying the neural correlates of GAD and how it relates to worry may provide improved treatment in the future such as developing more effective psychotropic drugs or improved psychotherapy. GAD has been associated with lower well-being and life satisfaction and may even be a risk factor for suicidal thoughts. One of the limitations from this review is that several of the included studies recruited patients with comorbidities and for that reason results from these studies cannot be generalized and applied to individuals with GAD.

Generalized anxiety disorder

prefrontal cortex

anterior cingulate cortex

amygdala

worry

Neurosciences

Neurovetenskaper

Into the Multiverse: Methods for Studying Developmental Neuroscience

Bloom, Paul Alexander

January 2022

One major challenge in developmental neuroscience research is the sheer number of choices researchers face when addressing even a single research question. Even once data collection is complete, the journey from raw data to interpretation of findings may depend on numerous decisions. To address this issue, this dissertation explores “multiverse” analysis techniques for following many analytical paths at once in the same dataset. In chapter 1, multiverses are used to examine which analyses of age-related change in amygdala-medial prefrontal cortex circuitry are robust versus sensitive to researcher decisions. Chapter 2 uses multiverse analysis to identify optimal solutions for mitigating breathing-induced artifacts in resting-state functional magnetic resonance imaging data. Chapter 3 uses a variety of model specifications to characterize simultaneous reward learning strategies in youth contingent on both visual task cues and spatial-motor information. Despite varied approaches and goals, each of the three studies highlight the benefits of conducting multiple parallel analyses for both addressing questions in developmental neuroscience and deepening understanding of the methods used to address them.

Developmental psychology

Neurosciences

Amygdaloid body

Prefrontal cortex

Magnetic resonance imaging

Reward (Psychology) in children

"Isolation Stress" Revisited: Isolation-Rearing Effects Depend on Animal Care Methods

Holson, R. R., Scallet, A. C., Ali, S. F., Turner, B. B.

01 January 1991

Early reports of enhanced behavioral reactivity in isolation-reared rats attributed this syndrome to "isolation stress." In the studies reported here, this "isolation stress syndrome" was reliably obtained in adult rats reared from weaning in individual hanging metal cages. Such isolates showed behavioral and adrenocortical symptoms of profound fear during open-field testing, unlike group-housed controls or littermate isolates reared singly in plastic cages. Animals in hanging metal cages are never touched by human caretakers, whereas rats reared in plastic cages are picked up and put in clean cages twice weekly. Handling hanging-cage isolates twice weekly to model the handling associated with cage changes completely protected against this syndrome. Further, there was no hormonal, neurochemical or anatomical evidence of chronic stress even in hanging-cage isolates. Littermates housed in social groupings (three rats per plastic cage) also froze and defecated in the open field at rates comparable to hanging-cage isolates if they were the first animals to be tested from their social group cage. It is probable that odor cues from familiar cagemates in the open field protected socially reared animals tested subsequently from the same cage from this syndrome. It is concluded that isolates are not chronically stressed, and that rearing effects are the result of a complex interaction between prior handling, social experience and test conditions.

activity

corticosterone

early experience

emotionality

handling

isolation

open field

prefrontal cortex

stress

Progesterone Facilitates the Acquisition of Avoidance Learning and Protects Against Subcortical Neuronal Death Following Prefrontal Cortex Ablation in the Rat

Asbury, E. Trey, Fritts, Mary E., Horton, James E., Isaac, Walter L.

01 December 1998

Following a cortical injury, neurons in areas near and connected to the site of injury begin to degenerate. The observed neuronal death may contribute to the severity of the observed behavioral impairments. The purpose of the present study was to examine if progesterone, a hormone known for its effectiveness at reducing cerebral edema, could protect against secondary neuronal death and facilitate the acquisition of an avoidance learning task in an ablation model of cortical injury. Rats served as sham controls or received bilateral ablation of the medial prefrontal cortex followed by a 10-day regimen of progesterone (4 mg/kg) or oil vehicle (1 ml/kg) beginning 1 h after cortical lesions. Progesterone-treated lesion rats showed a significant facilitation of avoidance learning compared to oil- treated lesion controls. In addition, progesterone-treated lesion animals did not differ from either progesterone- or oil-treated sham controls in avoidance learning. Anatomical analysis revealed that progesterone treatment decreased the amount of neuronal death seen in the striatum and the mediodorsal nucleus of the thalamus. The findings are consistent with the notion that progesterone is an effective neuroprotective agent and suggest that the hormone can reduce the behavioral impairments associated with frontal cortical ablation injury.

avoidance learning

medial prefrontal cortex

mediodorsal thalamic nucleus

neuroprotection

progesterone

striatum

subcortical degeneration

Cortical Dopaminergic Neurotransmission in Rats Intoxicated With Lead During Pregnancy. Nitric Oxide and Hydroxyl Radicals Formation Involvement

Nowak, Przemysław, Szczerbak, Grazyna, Nitka, Dariusz, Kostrzewa, Richard M., Jośko, Jadwiga, Brus, Ryszard

01 September 2008

It is well established that low level Pb-exposure is associated with a wide range of cognitive and neurobehavioral dysfunctions in children. In fact, Pb-induced damage occurs preferentially in the prefrontal cerebral cortex, hippocampus and cerebellum - the anatomical sites which are crucial in modulating emotional response, memory and learning. Previously it was also shown that nitric oxide (NO) signaling pathway as well as glutamatergic neurotransmission are both involved in brain development, neurotoxicity and neurodegeneration processes whereas Pb2+ interfere with both. For this reason we investigated the effect of ontogenetic Pb2+ exposure on dopaminergic neurotransmission in the medial prefrontal cortex (mPFC) of rats after amphetamine (AMPH) and/or 7-nitroindazole (7-NI) administration. Furthermore, the possible role of oxidative stress in Pb2+-induced neurotoxicity in prenatally Pb2+-treated rats was explored in the content of hydroxyl radical (HO•) species in mPFC after AMPH and/or 7-NI injection, assessed by HPLC analysis of 2.3-dihydroxybenzoic acid (2.3-DHBA) - spin trap product of salicylate. As shown, the results of this study suggest that Pb2+ exposure during intrauterine life did not substantially affect cortical dopaminergic neurotransmission in adult offspring rats evaluated by means of microdialysis of mPFC and the content of the cortical HO•. It is likely that striatum, nucleus accumbens or other dopamine rich brain areas are more intricately associated with Pb2+ precipitated behavioral, dopamine - dependent impairments observed in mammalians.

dopamine

hydroxyl radicals

lead

medial prefrontal cortex

microdialysis

nitric oxide

prenatal

Biomedical Sciences

Chronic Treatment With Glucocorticoids Alters Rat Hippocampal and Prefrontal Cortical Morphology in Parallel With Endogenous Agmatine and Arginine Decarboxylase Levels

Zhu, Meng Yang, Wang, Wei Ping, Huang, Jingjing, Regunathan, Soundar

01 December 2007

In the present study, we examined the possible effect of chronic treatment with glucocorticoids on the morphology of the rat brain and levels of endogenous agmatine and arginine decarboxylase (ADC) protein, the enzyme essential for agmatine synthesis. Seven-day treatment with dexamethasone, at a dose (10 and 50 μg/kg/day) associated to stress effects contributed by glucocorticoids, did not result in obvious morphologic changes in the medial prefrontal cortex and hippocampus, as measured by immunocytochemical staining with β-tubulin III. However, 21-day treatment (50 μg/kg/day) produced noticeable structural changes such as the diminution and disarrangement of dendrites and neurons in these areas. Simultaneous treatment with agmatine (50 mg/kg/day) prevented these morphological changes. Further measurement with HPLC showed that endogenous agmatine levels in the prefrontal cortex and hippocampus were significantly increased after 7-day treatments with dexamethasone in a dose-dependent manner. On the contrary, 21-day treatment with glucocorticoids robustly reduced agmatine levels in these regions. The treatment-caused biphasic alterations of endogenous agmatine levels were also seen in the striatum and hypothalamus. Interestingly, treatment with glucocorticoids resulted in a similar change of ADC protein levels in most brain areas to endogenous agmatine levels: an increase after 7-day treatment versus a reduction after 21-day treatment. These results demonstrated that agmatine has neuroprotective effects against structural alterations caused by glucocorticoids in vivo. The parallel alterations in the endogenous agmatine levels and ADC expression in the brain after treatment with glucocorticoids indicate the possible regulatory effect of these stress hormones on the synthesis and metabolism of agmatine in vivo.

β-tubulin III

agmatine

arginine decarboxylase

glucocorticoids

hippocampus

medial prefrontal cortex