Perinatal Buprenorphine Effects on Offspring Growth, Opioid Withdrawal, and Brain Morphology in Rats

Barnes, Parker

01 May 2024

Opioid use disorder (OUD) impacts 5.6 million people in the US. Buprenorphine (BUP) is a commonly prescribed opioid medication used to treat OUD, including in pregnant women. However, opioid use during pregnancy is associated with poorer infant outcomes including reduced fetal growth, neurodevelopmental deficits, and neonatal opioid withdrawal syndrome (NOWS). Recent clinical data suggests that providing mothers with a lower dose of BUP may result in fewer negative outcomes in infants. Here, a preclinical rodent model of low-dose perinatal BUP exposure was used to study offspring health outcomes in the neonate, juvenile, and adolescent offspring. Dams were given clinically relevant doses of BUP prior to and throughout gestation, and continuing through weaning to mimic human doses and exposure. Although the lowest BUP dose still elicited signs of NOWS in offspring, there were fewer negative effects on overall brain morphology across the early lifespan than that of the higher BUP dose compared to controls.

buprenorphine

opioid use disorder

neonatal opioid withdrawal syndrome

Animals

Behavioral Neurobiology

Developmental Neuroscience

Maternal and Child Health

Medical Neurobiology

Neuroscience and Neurobiology

Neurosciences

Obstetrics and Gynecology

Organisms

Public Health

Peripheral Hypoglycaemic Neuropathy in Type 1 Diabetic Rats : Morphologic and Metabolic Studies

Jamali, Reza

January 2006

Hyperglycaemia caused by insulin deficiency is believed to play a major role in the de-velopment of neuropathy in diabetic patients. The clinical and pathological features of diabetic neuropathy vary considerably, although sensory and autonomic dysfunctions are the most common characteristics. Normalisation of the blood glucose level by ef-fective insulin treatment decreases the incidence of diabetic neuropathy in patients. However, intensive insulin therapy may result in more frequent hypoglycaemic epi-sodes than are provoked by less ambitious diabetes control. Neuropathy might also be induced by severe hypoglycaemia in diabetes or insulinoma. Accordingly, it seems that the diversity in clinical symptoms of diabetic neuropathy may be due to the combined effects of hyperglycaemia and hypoglycaemia. Based on that assumption, the general aim of this project was to study the relationship between severe hypoglycaemia and pe-ripheral neuropathy in diabetic rats. To understand how the development of neuropathy is related to glycaemic control, we needed to be aware of the glucose dynamics in the animal model that we used. The aim was to ascertain whether the diabetic rats were similar to type 1 diabetic patients with regard to such dynamics. To achieve that goal, we used a MiniMed continuous glucose monitoring system (CGMS®) to measure sub-cutaneous glucose in freely moving rats over a period of 72 hours. The glucose monitor worked well, and it showed that the insulin-treated diabetic BB/Wor rats with a hyper-glycaemic insulin regimen have a glycaemic status similar to that of type 1 diabetic patients with poor glycaemic control. The diabetic rats with a hypoglycaemic regimen generally had low blood glucose levels. Prolonged hypoglycaemia led to axonal de- and regeneration of large myelinated fibres in vagus nerve destined to the laryngeal muscle. Axonal de- and regeneration was also observed in the gastrocnemius and sural nerves, although the frequency of degeneration was much lower in the sural nerve. Small myelinated and unmyelinated nerve fibres were normal in these nerves. These results suggest that hypoglycaemia preferentially damages muscle-related nerve fibres. In contrast, in the diabetic rats exposed to pro-longed hyperglycaemia, only the sural nerve exhibited decreased myelinated fibre diameter in the absence of obvious axonal degeneration. In situ glucose measurements by microdialysis showed that the glucose concentrations in blood and subcutaneous tissue were similar in healthy, diabetic hyperglycaemic, and diabetic hypoglycaemic rats. In the healthy and hyperglycaemic animals, the lowest glucose level was found in the peripheral nerve. Moreover, in controls, the glucose level was lower in muscle than in blood. In hypoglycaemic rats, there were no signifi-cant differences in glucose concentrations between different tissues.

Diabetes Mellitu

Hypoglycaemia

Neuropathy

Morphology

Microdialysis

Glucose level

Neurobiology

Neurobiologi

Role of Tbr2 in intermediate progenitors during cortical neurogenesis

Vasistha, Navneet A.

January 2013

During embryonic development neurons of the cerebral cortex are generated from various progenitor cells that have progressively restricted fate. Understanding the multiple regulatory pathways that regulate the cell cycle kinetics and the identity of neurons is crucial to comprehend the etiology of severe developmental defects such as microcephaly and polymicrogyria and also the evolutionary expansion of the mammalian cerebral cortex. Intermediate progenitors (IPCs) express the transcription factor Tbr2 (a T-box gene) and deletion of this gene causes a decrease in brain size and cortical thickness. However, little is known about the molecular mechanisms regulating behavior of IPCs. In this thesis, I studied the molecular mechanisms regulating cell division and cell fate choices in IPCs using an overexpression system. I show that Tbr2 controls the expression of key genes such as Cdk4, Aspm and Wnt5a by directly binding to upstream regulatory sequences. These downstream targets could explain the role played by Tbr2 in cell cycle, spindle assembly and Wnt signaling in intermediate progenitors. The interaction with Aspm also suggests a possible mechanism of self-renewal of IPCs leading to an expanded generation of cortical neurons and ultimately an increased cortical size. While the role of IPCs in cortical neurogenesis is undisputed, it is widely believed that they contribute only towards supragranular layers. Using a knock-in transgenic mouse line (Tbr2^Cre), I show that IPCs provide glutamatergic neurons (but not GABAergic neurons or GFAP+ astrocytes) towards all cortical layers in a significant proportion (20-40%). I also show that clonally generated neurons disperse within tangential dimension across the cortex significantly closer (142.1 ± 76.8 µm) than unrelated ones (294.9 ± 105.4 µm) though within the confines of a cortical column (300-600 µm). Finally, I describe the similarity in the germinal zones of a large-brained gyrencephalic rodent, agouti and a lissencephalic primate, marmoset. Both these species show similar germinal zone cytoarchitecture and distribution of various progenitors. Further, the number of IPCs is grossly expanded thus demonstrating the conserved role of IPCs in cortical expansion regardless of the folding status of the cortex in these two species.

573.8

Novel analgesic interventions in cancer-induced bone pain

Currie, Gillian Laura

January 2012

Cancer-induced bone pain (CIBP), due to bony metastases, is a major clinical problem, significantly reducing quality of life in cancer patients. Current therapies often provide inadequate analgesia or unacceptable side effects. The aim of this thesis was to characterise behaviours of a preclinical model of CIBP and test novel analgesic interventions in this model. A secondary aim was to investigate the involvement of the N-methyl-D-Aspartate (NMDA) receptors and TRP channels (TRPM8, TRPV1 and TRPV4) in CIBP. Investigation of CIBP in a preclinical model may lead to better pain management in CIBP patients. The results presented here demonstrate that this model of CIBP develops behaviours that may be indicative of mechanical allodynia, thermal sensitivity, movement-evoked pain, ongoing pain and spontaneous pain. This suggests that this model reflects the clinical condition of CIBP, where patients suffer from constant background pain with spontaneous and movement-related breakthrough pain. In this study it was found that radiotherapy significantly attenuated movement-evoked pain and thermal sensitivity to 20°C and 40°C. XRT also significantly reduced anxiety and risk assessment behaviours (grooming behaviour and number of protected stretch attends) compared to untreated CIBP. Duloxetine attenuated CIBP-induced mechanical allodynia, thermal sensitivity to 40°C and movement-evoked pain, whereas S,S-reboxetine attenuated thermal sensitivity to 40°C but did not effect CIBP-induced mechanical allodynia or movement-evoked pain. In addition, CB 65 attenuated movement-evoked pain and thermal sensitivity to 40°C. A single dose of gabapentin did not attenuate CIBP-induced mechanical allodynia, thermal sensitivity to 40°C or movement-evoked pain. These studies confirm that the CIBP model shows characteristics and pharmacological sensitivities consistent with known and predicted mechanisms and validate it as a useful model for assessing potential new treatments proposed for use in patients. Behavioural results suggest that NMDA receptors containing the NR2A subunit are involved in CIBP-induced movement-evoked pain. This suggests that NR2A antagonists may be useful for treating CIBP-induced movement-evoked pain. Additionally, results show that there is increased expression of NR2A in the laminae I, II and III in the dorsal horn of the spinal cord. XRT treated animals also showed increased expression of NR2A in laminae I and II. The selective involvement of NR2A in CIBP is different to other chronic pain states, for example, neuropathic pain states that appear to involve the NR2B subunit. The TRPV1 antagonist AMG 9810 did not attenuate mechanical allodynia, thermal sensitivity to 40°C or movement-evoked pain. Interestingly, the TRPM8 agonist icilin attenuated movement-evoked pain, which suggests that icilin might be useful in the treatment of movement-evoked pain. The TRPV4 antagonist RN 1734 attenuated mechanical allodynia, thermal sensitivity to 40°C and movement-evoked pain in CIBP. This suggests RN 1734 may be useful in the treatment of mechanical allodynia, thermal sensitivity to 40°C and movement-evoked pain in CIBP. Results show that the expression of TRPV4 is increased in DRG ipsilateral to the cancerbearing tibia. In conclusion, these results show that the preclinical model of CIBP investigated in this thesis is suitable for testing novel analgesic interventions. This thesis identified some useful targets for the analgesic treatment of CIBP and results suggest that many different mechanisms contribute to CIBP. A point to consider is that any robust effective treatment may need to target all (or at least several) of these mechanisms.

616.994

Study of adult neurogenesis and molecular mechanism underlying sexual behavior in male rats following induction of depression-like behaviorand pharmacological treatment

Lau, Wui-Man, Benson., 劉匯文.

January 2009

published_or_final_version / Anatomy / Doctoral / Doctor of Philosophy

Corticosterone.

Paroxetine.

Sexual behavior in animals.

Depression, Mental.

Developmental neurobiology.

DYNAMIC L-GLUTAMATE SIGNALING IN THE PREFRONTAL CORTEX AND THE EFFECTS OF METHYLPHENIDATE TREATMENT

Mattinson, Catherine Elizabeth

01 January 2012

The prefrontal cortex (PFC) is an area of the brain that is critically important for learning, memory, organization, and integration, and PFC dysfunction has been associated with pathologies including Alzheimer’s disease, schizophrenia, and drug addiction. However, there exists a paucity of information regarding neurochemical signaling in the distinct sub-regions of the PFC, particularly the medial prefrontal cortex (mPFC). The mPFC receives glutamatergic input from a number of brain areas, and functional glutamate signaling is essential for normal cognitive processes. To further understand glutamate neurotransmission, in vivo measurements of glutamate were performed in the cingulate cortex, prelimbic cortex, and infralimbic cortex of anesthetized rats using enzyme-based microelectrode array technology. Measurements of acetylcholine were also performed to examine the relationship between glutamate and other neurotransmitters in the mPFC. The described studies revealed a homogeneity of glutamate and acetylcholine signaling in the mPFC sub-regions, indicating somewhat uniform tonic and phasic levels of these two transmitters. In the infralimbic mPFC of awake freely-moving rats, rapid, phasic glutamate signaling events, termed “transients” were observed and in vivo glutamate signaling was successfully monitored over 24 hour time periods. The effects of methylphenidate (MPH), a stimulant medication with abuse potential that is used in the treatment of attention-deficit hyperactivity disorder, were measured in mPFC sub-regions of anesthetized rats. Data revealed similar tonic and phasic glutamate levels between chronic MPH-treated rats and controls in all sub-regions. Locomotor data from the chronic treatment period supported the behavioral sensitization effects of multiple MPH treatments. Significant effects were observed in locomotor activity, resting levels of glutamate, and glutamate uptake rates in the infralimbic mPFC of awake, freely-moving animals that received chronic MPH treatment. Taken together, this body of work characterizes glutamate signaling in the rat mPFC to a degree never before reported, and serves to report for the first time the effects of MPH on glutamate signaling in the mPFC.

glutamate

prefrontal cortex

microelectrode array

methylphenidate

Other Neuroscience and Neurobiology

Uncoupling Proteins : Regulation by IGF-1 and Neuroprotection during Hyperglycemia <i>in Vitro</i>

Gustafsson, Helena

January 2004

<p>Diabetic neuropathy is believed to arise due to oxidative stress following hyperglycemic situations. Uncoupling proteins (UCPs) constitute a subgroup of mitochondrial transporter proteins with putative antioxidant properties. By dissipating the proton gradient over the mitochondrial inner membrane, these proteins reduce the mitochondrial inner membrane potential (MMP), and thereby, the mitochondrial production of reactive oxygen species (ROS) is decreased. In this thesis I have examined the regulation of UCP2, UCP3, and UCP4 by the neuroprotective hormone insulin-like growth factor type 1 (IGF-1). I have also investigated the possible involvement of UCP3 in IGF-1-mediated neuroprotection following high glucose treatments. All studies were performed using human neuroblastoma SH-SY5Y cells as an <i>in vitro</i> cell model. The major findings were as follows:</p><p>i. Native SH-SY5Y cells expressed UCP2, UCP3, and UCP4. </p><p>ii. UCP3 was upregulated by IGF-1 via activation of the IGF-1 receptor. IGF-1 increased UCP3 mRNA and protein levels primarily via activation of the “classical” anti-apoptotic phosphatidyl inositol 3 (PI3)-kinase signaling pathway, as shown by incubation with specific inhibitors of the PI3-kinase and mitogen activated protein (MAP) kinase signaling pathways. </p><p>iii. UCP2 and UCP4 protein levels were only marginally or not at all regulated by IGF-1. These UCPs are probably not involved in IGF-1-mediated neuroprotection.</p><p>iv. High glucose concentrations reduced the UCP3 protein levels in highly differentiated SH-SY5Y cells. Concomitantly, the MMP and the levels of ROS and glutathione increased, whereas the number of neurites per cell was reduced. This supports an antioxidant and neuroprotective role of UCP3 </p><p>v. IGF-1 prevented the glucose-induced reduction in UCP3 protein levels. In parallel, the effects on MMP, levels of ROS and glutathione, and number of neurites per cell were abolished or significantly reduced. These data suggest that UCP3 is involved in IGF-1-mediated neuroprotection.</p>

uncoupling protein

oxidative stress

diabetes

neuropathy

SH-SY5Y

Neurobiology

Neurobiologi

The development of resilience - a model

Maginness, Alison

January 2007

The impetus for this study grew from observations in clinical practice that many individuals survived all sorts of hardships with minimal distress, or with the ability to tolerate their distress, and move on with their lives in a positive manner. A review of the literature led to the conclusions that the research investigating resilience was making minimal inroads into understanding what made these people different, and that the richness of who they were was being lost in the scientific process. This dissatisfaction led to the decision to explore the construct from a phenomenological framework, and to try and discover the essential elements of resilience through analysis of the subjective experience of resilience. A qualitative study involving thirteen participants identified by their peers as resilient was undertaken and the underlying themes of their stories were analysed. This led to the development of a model of resilience that attempted to balance the need for parsimony with that of explanatory breadth, and which had the potential to tolerate the complexity and instability of the construct itself. The model developed identified three core elements that embraced the construct of resilience. These included the physiological capacity to be resilient, and from this basis the ability to be adaptive and the ability to maintain well-being emerge. Factors identified with these elements include individual reactivity to and recovery from adverse events, the ability to be effective and efficient in the management of adverse events, and the beliefs about the world and the self that promote well-being when exposed to adverse events. The model has a basis within neurobiology and is framed within the context of Dynamic Systems Theory. The theory itself is a culmination of clinical observations with what is known from within the current literature and the results of this study.

Resilience

developmental

model

neurobiology

dynamic systems theory

qualitative subjective experience

Protein Kinase Mzeta (PKM-ζ) Regulates Kv1.2 Dependent Cerebellar Eyeblink Classical Conditioning

Chihabi, Kutibh

01 January 2017

Learning and memory has been a topic that has captured the attention of the scientific and public communities since the dawn of scientific discovery. Without the faculty of memory, mammals cannot experience nor function in the world; among homosapiens specifically, language, relationships, and personal identity cannot be developed (Eysenck, 2012). After all, some philosophers such as John Locke argued we are nothing but a collection of past memories in which we have developed and improved upon (Nimbalkar, 2011). Understanding the cellular mechanisms behind learning, and the subsequent formation of memory, has been a topic that has garnered scientific interest for many decades. One particular kinase that has been at the center of attention in the last decade is the serine/threonine kinase PKM-ζ, an N-terminal truncated form of PKC-ζ that renders it constitutively active (Hernandez et al., 2003). PKM-ζ has long been implicated in a cellular correlate of learning, long-term potentiation (LTP). Inhibition of PKM-ζ with Zeta-inhibitory peptide (ZIP) has been shown in many brain structures to disrupt maintenance of AMPA receptors, irreversibly disrupting numerous forms of learning and memory that have been maintained for weeks. The voltage-gated potassium channel Kv1.2 is a critical modulator of neuronal physiology, including dendritic excitability, action potential propagation, and neurotransmitter release. While expressed in various mammalian tissues, Kv1.2 is most prevalent in the cerebellum where it modulates both dendritic excitability of Purkinje cells (PCs) and basket cell (BC) inhibitory input to PCs. Because PCs are the main computational unit of the cerebellar cortex and provide its sole output (Napper et al., 1988; Harvey et al., 1991), regulation of synaptic Kv1.2 is predicted to have a major role in cerebellar function. Pharmacological inhibition of Kv1.2 in cerebellar PC dendrites increases excitability (Khavandgar et al., 2005), while its inhibition in BC axon terminals increases inhibition to PCs (Southan & Robertson, 1998). Interestingly, two prior studies have demonstrated that PKC-ζ, an atypical Protein Kinase C, is able to phosphorylate and bind cerebellar Kvβ2, a Kv1.2 auxiliary subunit. (Gong et al., 1999; Croci et al., 2003). Delay eyeblink conditioning (EBC) is an established model for the assessment of cerebellar learning. Despite being highly expressed in the cerebellum, no studies have examined how regulation of cerebellar PKM-ζ may affect cerebellar-dependent learning and memory nor have they examined the possible effect PKM-ζ may have on Kv1.2. The goal of this dissertation was to determine whether PKM-ζ could modulate EBC in a Kv1.2 dependent manner. Through the use of microscopy techniques we have shown that PKM-ζ is highly expressed in the cerebellar cortex, primarily in the PC, and by the use of pharmacological manipulations, it was found that PKM-ζ has an important role in regulating the acquisition of EBC. Through the use of biotinylation, flow cytometry, and behavioral manipulations, it was determined that PKM-ζ regulates Kv1.2 during eyeblink conditioning. These studies provided the first evidence that PKM-ζ has a role for learning and memory in the cerebellum, and the first evidence of PKM-ζ regulating a voltage-gated ion channel rather than a ligand-gated ion channel such as AMPA receptors.

Cerebellum

Kv1.2

Learning

Memory

PKC

PKM-Zeta

Neuroscience and Neurobiology

Psychology

The Influence Of Prenatal Stress On Behaviors Associated With Schizophrenia And Autism Spectrum Disorder.

Bauerle, Harold

01 January 2015

Disorders such as schizophrenia (SCZ) and austism spectrum disorder (ASD) have long been associated with prenatal stress. In these three experiments, we attempted to correlate stress during gestation with behaviors considered to have good facial validity with SCZ and ASD in both juvenile and adult animals. To differentiate the effects of prenatal stress (PS) from the effects of early life stress due to a dam's behavior (MS), half of offspring animals were cross fostered to dams treated in the alternative condition as the offspring during pregnancy in experiments 2 and 3. In experiment 1, but not in 2 or 3, maternal animals that did not receive stress during pregnancy retrieved pups later than those that did. Our results in experiment 1 indicate that movement in a novel open field is dependent upon PS in a manner influenced by animal sex. In experiment 2, where cross fostering was considered, PS was a significant influence in females, while MS had considerable effect in males. Additionally, in males, animals treated by both PS and MS moved more than other male animals. Experiment 3 showed distinctions in male animals due to MS, but in startle amplitude, not open field movement. Overall, these experiments show the influence of PS and MS upon animals in juveniles and adults, but effects may be somewhat occluded due to litter effects.

autism

maternal

prenatal

schizophrenia

stress

Neuroscience and Neurobiology

Psychology