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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Stereotypical behaviour in the deer mouse (Peromyscus Maniculatus bairdii) : a pharmacological investigation of the frontal–cortico–striatal serotonergic system / Wolmarans D.

Wolmarans, Petrus De Wet January 2011 (has links)
Obsessive–compulsive disorder (OCD) is a psychiatric condition that is characterized by two main symptom cohorts, namely recurrent inappropriate thoughts (obsessions) and seemingly purposeless repetitive motor actions (compulsions). In 70% of cases, the condition only re–sponds to chronic, but not sub–chronic, high dose treatment with the selective serotonin reup–take inhibitors (SSRIs), such as fluoxetine and escitalopram. This indicates a role for hyposero–tonergic functioning in the primary brain areas involved in OCD, namely the components of the cortico–striatal–thalamic–cortical (CSTC) circuit which include the prefrontal cortex, the basal ganglia, and the thalamus. A number of studies have demonstrated a lower serotonin trans–porter (SERT) availability in OCD patients compared with healthy controls, supporting the hy–pothesis of a hyposerotonergic state in OCD. The current study focuses on the validation of the deer mouse (Peromyscus maniculatus bairdii) model of OCD and builds on previous work done in our laboratory. Deer mice that are bred and housed in confinement naturally develop two main forms of stereotypical behaviour, namely vertical jumping and pattern running. Furthermore, these behaviours can be catego–rized into various levels of severity, namely high (HSB), low (LSB) and non–stereotypic (NSB) cohorts. The seemingly purposeless and repetitive nature of these behaviours mimics the com–pulsions that characterize human OCD and constitutes the basis for the face validity of the model. However, although these two forms of stereotypy seem equally repetitive and persis–tent, stereotypical pattern runners do not complete the required number of cage revolutions per 30 minutes compared to the amount of jumps executed by stereotypical vertical jumpers. As only one set of criteria for the appraisal of the different topographies of deer mouse stereotypy has been applied in previous studies, the matter of whether pattern runners do in fact generate stereotypical behaviour of the same persistent and severe nature as opposed to the behaviour expressed by vertical jumpers, is problematic. Therefore, the first objective of the current study was to develop a new classification system for the appraisal of the different forms of behavioural topographies of deer mice and subse–quently to evaluate whether pattern runners can indeed be categorized into non–, low– and high stereotypical cohorts. After an eight–week behavioural assessment period, deer mice express–ing the two different behavioural topographies could be classified into non–, low– and high stereotypical cohorts (NSB, LSB, and HSB respectively), applying different criteria for each be–havioural topography. Based on the weekly mean stereotypy count generated during three 30–minute intervals of highest stereotypical behaviour over the course of a 12–hour assessment period, HSB pattern runners were found to execute on average 296 cage revolutions per 30 minutes, while HSB vertical jumpers executed an average of 3063 jumps per 30 minutes. This discrepancy between the generated numbers of the different topographies of stereotypy indi–cates that one classification system for the appraisal of both behavioural topographies is indeed inappropriate, and hence requires re–evaluation and validation. As patients with OCD present with a lower central SERT availability compared to healthy controls, the second objective of the study was to determine whether a decrease in SERT den–sity could be demonstrated in HSB animals compared to the NSB and LSB controls. After eight weeks of behavioural assessment, animals were sacrificed and frontal–cortical and striatal SERT binding was performed. HSB deer mice presented with significantly lower striatal, but not fron–tal–cortical SERT availability compared to the [NSB/LSB] control animals (p = 0.0009). As far as it concerns a lower SERT availability in HSB animals and involvement of the CSTC circuitry, this data is congruent with that demonstrated in human OCD and strengthens the construct validity of the model. Although previous studies undertaken in our laboratory demonstrated that deer mouse stereotypy is attenuated after chronic (21–day) fluoxetine administration, OCD only responds to chronic, but not sub–chronic treatment with the SSRIs. The lack of response of deer mouse stereotypy to sub–chronic treatment has not been established and therefore the third study ob–jective was to assess the behavioural effects of sub–chronic (7–day) and chronic (28–day) SSRI treatment on expression of deer mouse stereotypy. Chronic, but not sub–chronic treatment with oral escitalopram (50 mg/kg/day) significantly increased the number of intervals over a 12–hour assessment period during which no stereotypical behaviour were expressed by HSB deer mice (p = 0.0241) and decreased the number of intervals during which high–stereotypical be–haviour were executed (p = 0.0054). Neither chronic, nor sub–chronic treatment significantly affected the behaviour of animals in the [NSB/LSB] cohort. The fact that the model demon–strates a lack of response to sub–chronic treatment with high dose SSRIs, positively contributes to the predictive validity of the deer mouse model of OCD. The results from the current study therefore strengthens the construct and predictive valid–ity of the deer mouse model of OCD and confirm the model’s status as a prominent animal model of OCD. Not only is hyposerotonergic functioning in the CSTC circuitry implicated in the behaviour of HSB animals, but the model also demonstrates selective response to chronic SSRI–treatment - two core characteristics of human OCD. / Thesis (M.Sc. (Pharmacology))--North-West University, Potchefstroom Campus, 2012.
2

Stereotypical behaviour in the deer mouse (Peromyscus Maniculatus bairdii) : a pharmacological investigation of the frontal–cortico–striatal serotonergic system / Wolmarans D.

Wolmarans, Petrus De Wet January 2011 (has links)
Obsessive–compulsive disorder (OCD) is a psychiatric condition that is characterized by two main symptom cohorts, namely recurrent inappropriate thoughts (obsessions) and seemingly purposeless repetitive motor actions (compulsions). In 70% of cases, the condition only re–sponds to chronic, but not sub–chronic, high dose treatment with the selective serotonin reup–take inhibitors (SSRIs), such as fluoxetine and escitalopram. This indicates a role for hyposero–tonergic functioning in the primary brain areas involved in OCD, namely the components of the cortico–striatal–thalamic–cortical (CSTC) circuit which include the prefrontal cortex, the basal ganglia, and the thalamus. A number of studies have demonstrated a lower serotonin trans–porter (SERT) availability in OCD patients compared with healthy controls, supporting the hy–pothesis of a hyposerotonergic state in OCD. The current study focuses on the validation of the deer mouse (Peromyscus maniculatus bairdii) model of OCD and builds on previous work done in our laboratory. Deer mice that are bred and housed in confinement naturally develop two main forms of stereotypical behaviour, namely vertical jumping and pattern running. Furthermore, these behaviours can be catego–rized into various levels of severity, namely high (HSB), low (LSB) and non–stereotypic (NSB) cohorts. The seemingly purposeless and repetitive nature of these behaviours mimics the com–pulsions that characterize human OCD and constitutes the basis for the face validity of the model. However, although these two forms of stereotypy seem equally repetitive and persis–tent, stereotypical pattern runners do not complete the required number of cage revolutions per 30 minutes compared to the amount of jumps executed by stereotypical vertical jumpers. As only one set of criteria for the appraisal of the different topographies of deer mouse stereotypy has been applied in previous studies, the matter of whether pattern runners do in fact generate stereotypical behaviour of the same persistent and severe nature as opposed to the behaviour expressed by vertical jumpers, is problematic. Therefore, the first objective of the current study was to develop a new classification system for the appraisal of the different forms of behavioural topographies of deer mice and subse–quently to evaluate whether pattern runners can indeed be categorized into non–, low– and high stereotypical cohorts. After an eight–week behavioural assessment period, deer mice express–ing the two different behavioural topographies could be classified into non–, low– and high stereotypical cohorts (NSB, LSB, and HSB respectively), applying different criteria for each be–havioural topography. Based on the weekly mean stereotypy count generated during three 30–minute intervals of highest stereotypical behaviour over the course of a 12–hour assessment period, HSB pattern runners were found to execute on average 296 cage revolutions per 30 minutes, while HSB vertical jumpers executed an average of 3063 jumps per 30 minutes. This discrepancy between the generated numbers of the different topographies of stereotypy indi–cates that one classification system for the appraisal of both behavioural topographies is indeed inappropriate, and hence requires re–evaluation and validation. As patients with OCD present with a lower central SERT availability compared to healthy controls, the second objective of the study was to determine whether a decrease in SERT den–sity could be demonstrated in HSB animals compared to the NSB and LSB controls. After eight weeks of behavioural assessment, animals were sacrificed and frontal–cortical and striatal SERT binding was performed. HSB deer mice presented with significantly lower striatal, but not fron–tal–cortical SERT availability compared to the [NSB/LSB] control animals (p = 0.0009). As far as it concerns a lower SERT availability in HSB animals and involvement of the CSTC circuitry, this data is congruent with that demonstrated in human OCD and strengthens the construct validity of the model. Although previous studies undertaken in our laboratory demonstrated that deer mouse stereotypy is attenuated after chronic (21–day) fluoxetine administration, OCD only responds to chronic, but not sub–chronic treatment with the SSRIs. The lack of response of deer mouse stereotypy to sub–chronic treatment has not been established and therefore the third study ob–jective was to assess the behavioural effects of sub–chronic (7–day) and chronic (28–day) SSRI treatment on expression of deer mouse stereotypy. Chronic, but not sub–chronic treatment with oral escitalopram (50 mg/kg/day) significantly increased the number of intervals over a 12–hour assessment period during which no stereotypical behaviour were expressed by HSB deer mice (p = 0.0241) and decreased the number of intervals during which high–stereotypical be–haviour were executed (p = 0.0054). Neither chronic, nor sub–chronic treatment significantly affected the behaviour of animals in the [NSB/LSB] cohort. The fact that the model demon–strates a lack of response to sub–chronic treatment with high dose SSRIs, positively contributes to the predictive validity of the deer mouse model of OCD. The results from the current study therefore strengthens the construct and predictive valid–ity of the deer mouse model of OCD and confirm the model’s status as a prominent animal model of OCD. Not only is hyposerotonergic functioning in the CSTC circuitry implicated in the behaviour of HSB animals, but the model also demonstrates selective response to chronic SSRI–treatment - two core characteristics of human OCD. / Thesis (M.Sc. (Pharmacology))--North-West University, Potchefstroom Campus, 2012.
3

The effect of early-life exposure of rats to venlafaxine on behaviour and neurological markers of antidepressant action in adulthood / Renier Kruger

Kruger, Renier January 2014 (has links)
Major depression is a serious mood disorder affecting more than 120 million people worldwide, irrespective of their race or socio-economic status. This psychiatric disorder is predicted to become the second leading cause of disability by the year 2020, second only to heart diseases in the global population, without distinguishing differences in the incidence within defined age groups. Depression is known to affect people across all age groups, including children, adolescents, adults and geriatrics, although older age is associated with an increased susceptibility to major depression and other psychiatric conditions. Until the 1970‘s depression during childhood and adolescence was thought to be uncommon or non-existent. Recent epidemiological studies have demonstrated that there is a persistent escalation in the prevalence of depression in children and adolescents. Accordingly, the number of prescriptions for drugs to treat this disorder in juveniles has escalated significantly. With our current limited understanding of the safety and long-term effects of treatment with antidepressants, the clinician is left making decisions without sound evidence of safety. In addition, psychotropic drugs may affect neurodevelopment during childhood and adolescence and may consequently modulate susceptibility to psychiatric disorders later in life. The objective of the current study was to investigate the effects of early-life (pre-natal and postnatal) chronic treatment with venlafaxine, a dual action serotonin-noradrenalin reuptake inhibitor, during the developmental phase of the serotonin and norepinephrine pathways in stress-sensitive rats on measures of cognition, anxiety-like and depressive-like behaviour later in life. The study also investigated which age shows optimal behavioural changes later in life, following the above mentioned administration of venlafaxine. In addition we also determined the effects that the administration of venlafaxine has on the levels of monoamines l-norepinephrine (l-NE) and serotonin (5-HT) in the prefrontal cortex and the hippocampus. A number of translational animal models of psychiatric disorders have been described and validated, and is suitable for such investigations. For the current study we used stress-sensitive Flinders Sensitive Line (FSL) rats and their controls, Flinders Resistant Line (FRL) rats. Pregnant dams were injected subcutaneously for 14 days with 10 mg/kg venlafaxine or saline from pre-natal day 15 (ND-15) to ND-01. New-born pups were then injected subcutaneously with 3 mg/kg venlafaxine or saline for 14 days from postnatal day 3 (ND+03) to ND+17. These doses were determined from previous studies reported in literature. Four rat treatment groups of both FSL and FRL rats received injections during pre-natal + postnatal ages as follows: saline + saline, venlafaxine + saline, saline + venlafaxine and venlafaxine + venlafaxine. Following the drug treatments, all rat groups were housed under normal conditions until the indicated time to be subjected to a battery of behavioural tests, including the novel object recognition test (nORT), locomotor activity test (Digiscan®), elevated plus maze (EPM) and forced-swim test (FST), scheduled on either ND+35, ND+60 or ND+90. Separate treatment groups were used for each age group. After the behavioural tests animals were decapitated, the brains removed and the prefrontal cortex and hippocampus dissected out. These were analysed at a later stage using an HPLC with electrochemical detection to determine the levels of the monoamines l-NE and 5-HT. All animal procedures were approved by the Ethics Committee of the North-West University (approval number: NWU-00045-10-S5), and are in accordance with the recommendations of the National Institutes of Health guide for the care and use of laboratory animals. The data from the current study suggest that in general FRL rats were not influenced by the early-life treatment with venlafaxine, as observed in the nORT, EPM or FST on ND+35, ND+60 or ND+90. There was minimal changes seen in the immobile behaviour in the FST of FRL rats that received prenatal venlafaxine. As expected, depressive-like behaviour in the FST was significantly enhanced in FSL rats relative to corresponding FRL rat groups as observed at ND+35 and ND+60, but not ND+90. Importantly, depressive-like behaviour was reversed following pre- and postnatal treatment with venlafaxine in FSL rats at ND+60, relative to the corresponding FRL rat groups. Reversal of depressive-like behaviour in FSL rats were not observed at ND+35 or ND+90, suggesting a delayed response that is reversed later in adulthood. The data from the nORT, Digiscan® or EPM did not reveal any significant differences between the various FSL treatment groups, including at ND+60. The current study therefore demonstrated that the treatment regimen employed had a transient effect on depressive-like behaviour later in life and suggested that genetic susceptibility plays an important role in the treatment of depression. This was suggested by the venlafaxine-induced decrease in immobile behaviour exhibited by FSL rats at ND+60 in the FST, and the subsequent increase in immobile behaviour at ND+90. In general, the most significant venlafaxine-induced effects were seen in FSL rats, suggesting genetic susceptibility plays an important role. / MSc (Pharmacology), North-West University, Potchefstroom Campus, 2014
4

The effect of early-life exposure of rats to venlafaxine on behaviour and neurological markers of antidepressant action in adulthood / Renier Kruger

Kruger, Renier January 2014 (has links)
Major depression is a serious mood disorder affecting more than 120 million people worldwide, irrespective of their race or socio-economic status. This psychiatric disorder is predicted to become the second leading cause of disability by the year 2020, second only to heart diseases in the global population, without distinguishing differences in the incidence within defined age groups. Depression is known to affect people across all age groups, including children, adolescents, adults and geriatrics, although older age is associated with an increased susceptibility to major depression and other psychiatric conditions. Until the 1970‘s depression during childhood and adolescence was thought to be uncommon or non-existent. Recent epidemiological studies have demonstrated that there is a persistent escalation in the prevalence of depression in children and adolescents. Accordingly, the number of prescriptions for drugs to treat this disorder in juveniles has escalated significantly. With our current limited understanding of the safety and long-term effects of treatment with antidepressants, the clinician is left making decisions without sound evidence of safety. In addition, psychotropic drugs may affect neurodevelopment during childhood and adolescence and may consequently modulate susceptibility to psychiatric disorders later in life. The objective of the current study was to investigate the effects of early-life (pre-natal and postnatal) chronic treatment with venlafaxine, a dual action serotonin-noradrenalin reuptake inhibitor, during the developmental phase of the serotonin and norepinephrine pathways in stress-sensitive rats on measures of cognition, anxiety-like and depressive-like behaviour later in life. The study also investigated which age shows optimal behavioural changes later in life, following the above mentioned administration of venlafaxine. In addition we also determined the effects that the administration of venlafaxine has on the levels of monoamines l-norepinephrine (l-NE) and serotonin (5-HT) in the prefrontal cortex and the hippocampus. A number of translational animal models of psychiatric disorders have been described and validated, and is suitable for such investigations. For the current study we used stress-sensitive Flinders Sensitive Line (FSL) rats and their controls, Flinders Resistant Line (FRL) rats. Pregnant dams were injected subcutaneously for 14 days with 10 mg/kg venlafaxine or saline from pre-natal day 15 (ND-15) to ND-01. New-born pups were then injected subcutaneously with 3 mg/kg venlafaxine or saline for 14 days from postnatal day 3 (ND+03) to ND+17. These doses were determined from previous studies reported in literature. Four rat treatment groups of both FSL and FRL rats received injections during pre-natal + postnatal ages as follows: saline + saline, venlafaxine + saline, saline + venlafaxine and venlafaxine + venlafaxine. Following the drug treatments, all rat groups were housed under normal conditions until the indicated time to be subjected to a battery of behavioural tests, including the novel object recognition test (nORT), locomotor activity test (Digiscan®), elevated plus maze (EPM) and forced-swim test (FST), scheduled on either ND+35, ND+60 or ND+90. Separate treatment groups were used for each age group. After the behavioural tests animals were decapitated, the brains removed and the prefrontal cortex and hippocampus dissected out. These were analysed at a later stage using an HPLC with electrochemical detection to determine the levels of the monoamines l-NE and 5-HT. All animal procedures were approved by the Ethics Committee of the North-West University (approval number: NWU-00045-10-S5), and are in accordance with the recommendations of the National Institutes of Health guide for the care and use of laboratory animals. The data from the current study suggest that in general FRL rats were not influenced by the early-life treatment with venlafaxine, as observed in the nORT, EPM or FST on ND+35, ND+60 or ND+90. There was minimal changes seen in the immobile behaviour in the FST of FRL rats that received prenatal venlafaxine. As expected, depressive-like behaviour in the FST was significantly enhanced in FSL rats relative to corresponding FRL rat groups as observed at ND+35 and ND+60, but not ND+90. Importantly, depressive-like behaviour was reversed following pre- and postnatal treatment with venlafaxine in FSL rats at ND+60, relative to the corresponding FRL rat groups. Reversal of depressive-like behaviour in FSL rats were not observed at ND+35 or ND+90, suggesting a delayed response that is reversed later in adulthood. The data from the nORT, Digiscan® or EPM did not reveal any significant differences between the various FSL treatment groups, including at ND+60. The current study therefore demonstrated that the treatment regimen employed had a transient effect on depressive-like behaviour later in life and suggested that genetic susceptibility plays an important role in the treatment of depression. This was suggested by the venlafaxine-induced decrease in immobile behaviour exhibited by FSL rats at ND+60 in the FST, and the subsequent increase in immobile behaviour at ND+90. In general, the most significant venlafaxine-induced effects were seen in FSL rats, suggesting genetic susceptibility plays an important role. / MSc (Pharmacology), North-West University, Potchefstroom Campus, 2014

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