Quantitative sensory testing, obstructive sleep apnea and peripheral nervous lesions /

Hagander, Louise,

January 2006

Diss. (sammanfattning) Stockholm : Karol. inst., 2006. / Härtill 4 uppsatser.

Developing an Adeno-Associated Viral Vector (AAV) Toolbox for CNS Gene Therapy: A Dissertation

Choudhury, Sourav Roy

07 January 2016

Neurological disorders – disorders of the brain, spine and associated nerves – are a leading contributor to global disease burden with a sizable economic cost. Adeno-associated viral (AAV) vectors have emerged as an effective platform for CNS gene therapy and have shown early promise in clinical trials. These trials involve direct infusion into brain parenchyma, an approach that may be suboptimal for treatment of neurodegenerative disorders, which often involve more than a single structure in the CNS. However, overall neuronal transduction efficiency of vectors derived from naturally occurring AAV capsids after systemic administration is relatively low. We have developed novel capsids AAV-AS and AAV-B1 that lead to widespread gene delivery throughout the brain and spinal cord, particularly to neuronal populations. Both transduce the adult mouse brain >10-fold more efficiently than the clinical gold standard AAV9 upon intravascular infusion, with gene transfer to multiple neuronal sub-populations. These vectors are also capable of neuronal transduction in a normal cat. We have demonstrated the efficacy of AAV-AS in the context of Huntington's disease by knocking down huntingtin mRNA 33-50% after a single intravenous injection, which is better than what can be achieved by AAV9 at the particular dose. AAVB1 additionally transduces muscle, beta cells, pulmonary alveoli and retinal vasculature at high efficiency, and has reduced sensitivity to neutralizing antibodies in human sera. Generation of this vector toolbox represents a major step towards gaining genetic access to the entire CNS, and provides a platform to develop new gene therapies for neurodegenerative disorders.

Genetic Therapy

Genetic Vectors

Huntington Disease

Central Nervous System Diseases

Dependovirus

Dissertations, UMMS

Genetics

Molecular Genetics

Nervous System Diseases

Neurology

Therapeutics

Development and optimization of image-guided transcranial gene delivery to the brain with focused and theranostic ultrasound

Batts, Alec James

January 2025

Over 50 million people globally suffer from neurodegenerative disorders—a number that is steadily increasing as the general population ages. Yet, effective treatments for neurodegenerative disorders including Alzheimer’s disease (AD), Parkinson’s disease (PD), and Huntington’s disease (HD) remain limited, primarily due to the presence of a natural protective biological barrier lining cerebral blood vessels called the blood-brain barrier (BBB). The blood- brain barrier prevents passage of nearly 98% of small molecules from blood vessels to brain tissue, while most therapies designed for neurodegenerative disorders, such as gene therapies, are considered large-molecule drugs, making development of efficacious pharmacological treatments extremely challenging. Present strategies to bypass the BBB for drug delivery broadly fall into two categories: non-invasive but non-targeted methods, or targeted but invasive surgical procedures such as direct intracranial injection. Currently, the only method poised clinically to provide both non-invasive and targeted drug delivery to the brain is focused ultrasound (FUS). When combined with intravenously administered ultrasound contrast agents called microbubbles which oscillate within blood vessels in response to FUS pressure waves, FUS can safely and reversibly open the blood-brain barrier (BBB) in a highly targeted manner. This enhances drug delivery to brain regions affected by neurodegenerative disorders through a physical mechanism known as acoustic cavitation. A majority of FUS research to date has centered around development and clinical translation of stereotactic FUS guided by magnetic resonance imaging (MRI) for treatment monitoring, commonly referred to as MRgFUS. However, MRgFUS exhibits cost, accessibility, and portability barriers to implementation in medical centers globally. Alternatively, our group has developed cost-effective and accessible ultrasound-guided FUS (USgFUS) configurations, which have the potential to enable BBB opening and drug delivery treatment outside of an MRI with treatment guidance facilitated by neuro-navigation technology and cavitation monitoring. While most USgFUS systems developed prior to this dissertation achieve therapeutic opening of the BBB and cavitation monitoring with separate ultrasound transducers, this thesis focuses primarily on development and optimization of a single-transducer technique for both therapy and monitoring called theranostic ultrasound (ThUS). In Aim 1, we show that a repurposed diagnostic ultrasound array reprogrammed with focused imaging pulses can produce therapeutically relevant ultrasound energy through primate skulls, and can induce multi-site modulatory drug and gene delivery depending on the ThUS parameters applied. In Aims 2 and 3, we apply ThUS-mediated drug and gene delivery for pre-clinical neuroscience and therapeutic applications in PD, respectively. In Aim 2, we demonstrated non-invasive delivery of specialized genes and nanoparticles which together enable remote stimulation and recording of neuronal activity, a synergistic process which could enable remote brain-to-brain communication. In Aim 3, we leveraged ThUS-mediated gene therapy to restore degenerated neurons in a PD mouse model, achieving nearly 85% restoration of diseased dopaminergic neurons non-invasively. Finally, in Aim 4, we translated ThUS-mediated BBB opening to non-human primates (NHP) to determine initial feasibility of targeted gene expression facilitated by a low frequency, custom ThUS array. We demonstrated that both conventional USgFUS and ThUS configurations can safely induce targeted gene expression in brain regions implicated in PD in rhesus macaques, motivating translation of USgFUS for gene therapy in the clinic. The aims in this dissertation collectively underscore the growing number of pre-clinical applications which could benefit from ThUS technology, while propelling USgFUS methodologies as a whole to the brink of clinical translation for unprecedented access to efficacious non-invasive gene therapy for neurodegenerative disorders in the future.

Biomedical engineering

Ultrasonics in medicine

Nervous system--Diseases--Treatment

Blood-brain barrier

Brain--Magnetic resonance imaging

Nanoparticles

Traumatic brain injury and attention : postconcussion symptoms and indices of reaction time

Mureriwa, Joachim F. L.

07 1900

One of the consequences of traumatic brain injury is the postconcussion syndrome. The symptoms in this syndrome include headache, dizziness, poor memory, poor concentration, easy fatigue, drowsiness, irritability, sensitivity to light, sensitivity to noise, low alcohol tolerance, visual problems, auditory problems, nausea, vomiting, anxiety, and depression. Several factor analytic studies have shown that these symptoms load onto cognitive and noncognitive factors (Bohnen, Twijnstra, & Jolles, 1992). The aim of this study was to determine whether patients who report different symptoms also evidence differences in cognitive deficits, as indexed by reaction time. For this purpose 106 subjects (mean age 25.92 years; SD=6.05) of both sexes were tested on 8 reaction time tasks adapted from Shum, McFarland, Bain, and Humphreys (1990). There were 54 traumatic brain injury patients (mean age 26.40 years; SD=6.23) drawn from three Pretoria hospitals. They were heterogeneous with respect to diagnosis and severity of injury. For the controls (N=52), the mean age was 25.43 years (SD=5.88). The eight reaction time tasks constituted 4 task variables, each with 21evels. From these tasks, 36 reaction time indexes were derived. The indexes were classified into 4 groups, viz., reaction time (RT), movement time (MT), total reaction time (TT), and subtraction scores (SB, the difference between the 2 levels for each task variable). RT reflects the decision component and MT reflects the response execution component of reaction time. Partial correlation coefficients for all symptoms (p0,01) showed that some symptoms were most frequently associated with RT whilst others were most frequently associated with MT. On factor analysis with varimax rotation, symptoms loaded predominantly with SB scores. Symptoms also loaded with different task variablseuiggesting that they correlated with deficits on different stages of information processing. Taking into account possible methodological constraints that were discussed, these results confirm that different symptoms within the postconcussion syndrome correlate with different cognitive deficits. The correlations between symptoms and indices of reaction time are moderated by the characteristics of the symptoms (frequency & intensity), and the duration since injury. These findings have significance for understanding the aetiology of the postconcussion symptoms and for planning treatment. / Psychology / Ph. D. (Psychology)

616.8

Post-concussion syndrome

Neuropsychology

Neuropsychiatry

Nervous system -- Diseases

Brain -- Concussion

Brain -- Wounds and injuries

Brain damage

HISTOLOGICAL AND BEHAVIORAL CONSEQUENCES OF REPEATED MILD TRAUMATIC BRAIN INJURY IN MICE

Bolton Hall, Amanda Nicholle

01 January 2016

The majority of the estimated three million traumatic brain injuries that occur each year are classified as “mild” and do not require surgical intervention. However, debilitating symptoms such as difficulties focusing on tasks, anxiety, depression, and visual deficits can persist chronically after a mild traumatic brain injury (TBI) even if an individual appears “fine”. These symptoms have been observed to worsen or be prolonged when an individual has suffered multiple mild TBIs. To test the hypothesis that increasing the amount of time between head injuries can reduce the histopathological and behavioral consequences of repeated mild TBI, a mouse model of closed head injury (CHI) was developed. A pneumatically controlled device with a silicone tip was used to deliver a diffuse, midline impact directly onto the mouse skull. A 2.0mm intended depth of injury caused a brief period of apnea and increased righting reflex response with minimal astrogliosis and axonal injury bilaterally in the entorhinal cortex, optic tract, and cerebellum. When five CHIs were repeated at 24h inter-injury intervals, astrogliosis was exacerbated acutely in the hippocampus and entorhinal cortex compared to a single mild TBI. Additionally, in the entorhinal cortex, hemorrhagic lesions developed along with increased neurodegeneration and microgliosis. Axonal injury was observed bilaterally in the white matter tracts of the cerebellum and brainstem. When the inter-injury interval was extended to 48h, the extent of inflammation and cell death was similar to that caused by a single CHI suggesting that, in our mouse model, extending the inter-injury interval from 24h to 48h reduced the acute effects of repeated head injuries. The behavioral consequences of repeated CHI at 24h or 48h inter-injury intervals were evaluated in a ten week longitudinal study followed by histological analyses. Five CHI repeated at 24h inter-injury intervals produced motor and cognitive deficits that persisted throughout the ten week study period. Based upon histological analyses, the acute inflammation, axonal injury, and cell death observed acutely in the entorhinal cortex had resolved by ten weeks after injury. However, axonal degeneration and gliosis were present in the optic tract, optic nerve, and corticospinal tract. Extending the inter-injury interval to 48h did not significantly reduce motor and cognitive deficits, nor did it protect against chronic microgliosis and neurodegeneration in the visual pathway. Together these data suggested that some white matter areas may be more susceptible to our model of repeated mild TBI causing persistent neuropathology and behavioral deficits which were not substantially reduced with a 48h inter-injury interval. In many forms of TBI, microgliosis persists chronically and is believed to contribute to the cascade of neurodegeneration. To test the hypothesis that post-traumatic microgliosis contributes to mild TBI-related neuropathology, mice deficient in the growth factor progranulin (Grn-/-) received repeated CHI and were compared to wildtype, C57BL/6 mice. Penetrating head injury was previously reported to amplify the acute microglial response in Grn-/- mice. In our studies, repeated CHI induced an increased microglial response in Grn-/- mice compared to C57BL/6 mice at 48h, 7d, and 7mo after injury. However, no differences were observed between Grn-/- and WT mice with respect to their behavioral responses or amount of axonal injury or ongoing neurodegeneration at 7 months despite the robust differences in microgliosis. Dietary administration of ibuprofen initiated after the first injury reduced microglial activation within the optic tract of WT mice 7d after repeated mild TBI. However, a two week ibuprofen treatment regimen failed to affect the extent of behavioral dysfunction over 7mo or decrease chronic neurodegeneration, axon loss, or microgliosis in brain-injured Grn-.- mice when compared to standard diet. Together these studies underscore that mild TBIs, when repeated, can result in long lasting behavioral deficits accompanied by neurodegeneration within vulnerable brain regions. Our studies on the time interval between repeated head injuries suggest that a 48h inter-injury interval is within the window of mouse brain vulnerability to chronic motor and cognitive dysfunction and white matter injury. Data from our microglia modulation studies suggest that a chronically heightened microglial response following repeated mild TBI in progranulin deficient mice does not worsen chronic behavioral dysfunction or neurodegeneration. In addition, a two week ibuprofen treatment is not effective in reducing the microglial response, chronic behavioral dysfunction, or chronic neurodegeneration in progranulin deficient mice. Our data suggests that microglia are not a favorable target for the treatment of TBI.

Microglia

Neurodegeneration

Traumatic Brain Injury

Progranulin

Ibuprofen

Medical Physiology

Nervous System Diseases

Neurosciences

PRECLINICAL DEVELOPMENT OF PHYTOCANNABINOID- AND ENDOCANNABINOID- BASED PHARMACOTHERAPIES FOR THE TREATMENT OF ETHANOL-INDUCED NEURODEGENERATION

Liput, Daniel J

01 January 2013

Excessive ethanol consumption, characteristic of alcohol use disorders (AUDs), is associated with widespread neurodegeneration and cognitive and behavioral impairments that may contribute to the chronic and relapsing nature of alcoholism. Therefore, identifying novel targets that can afford neuroprotection will undoubtedly aid current treatment strategies for AUDs. The cannabinoids have been shown to provide neuroprotection in a variety of preclinical models of neurodegeneration; however minimal data is available regarding the use of cannabinoid-based pharmacotherapies for treating ethanol-induced neurodegeneration. Therefore, the current dissertation examined the overarching hypothesis: the cannabinoids are a therapeutic strategy to afford neuroprotection in the context of ethanol-induced neurodegeneration. Importantly, this overarching hypothesis was approached with translational considerations in mind. Specifically, the use of many cannabinoids in the clinic is hindered due to multiple unfavorable pharmacokinetic/pharmacodynamic profiles, including high first pass metabolism and untoward psychoactivity. Therefore, the studies herein were designed to circumvent these PK/PD obstacles. The first set of studies examined whether transdermal delivery of the phytocannabinoid, cannabidiol (CBD), could attenuate binge ethanol induced neurodegeneration. Transdermal CBD afforded neuroprotection in the entorhinal cortex and neuroprotection was similar in magnitude as intraperitoneal administration. The second set of studies found that binge ethanol treatment transiently down-regulated the main CNS cannabinoid receptor, CB1R. Interestingly, these changes were not accompanied by alterations in one of the major endogenous ligands, anandamide (AEA), or other related n-acylethanolamides (NAEs). The latter finding is in contrast to other literature reports demonstrating that endocannabinoid content is substantially elevated in response to a CNS insult. Nevertheless, studies were carried out to determine if administration of the AEA and NAE catabolism inhibitor, URB597, could attenuate binge ethanol induced neurodegeneration. URB597 failed to produce neuroprotection in the entorhinal cortex and dentate gyrus of the hippocampus. However, additional studies found that URB597 failed to elevate AEA in the entorhinal cortex, and in general the biological activity of URB597 was impaired by ethanol exposure. Therefore, with further drug discovery/development efforts, it may be feasible to optimize such treatment strategies. In conclusion, the studies within the current dissertation demonstrated the feasibility of using some cannabinoid-based agents to prevent ethanol-induced neurodegeneration.

Alcoholism

endocannabinoids

cannabidiol

ethanol-induced neurodegeneration

binge ethanol exposure

Nervous System Diseases

Pharmacy and Pharmaceutical Sciences

The combined application of 'H MRI and '19F MRS to the study of cerebroprotection

Haga, Kristin Kerr

January 2000

No description available.

610

Investigation of treatment related neurotoxicity following childhood cancer by proton magnetic resonance spectroscopy

Davidson, Anne

January 1999

No description available.

610

Design, Synthesis, and Biological Screening of Selective Mu Opioid Receptor Ligands as Potential Treatments for Opioid Addiction

Obeng, Samuel

01 January 2017

Today, more Americans die each year because of drug overdoses than are killed in motor vehicle accidents. In fact, in 2015, more than 33,000 individuals died due to an overdose of heroin or prescription opioids. Sadly, 40-60 % of patients on current opioid addiction treatment medications relapse. Studies have shown that the addiction/abuse liability of opioids are abolished in mu opioid receptor (MOR) knock-out mice; this indicates that the addiction and abuse liability of opioids are mainly mediated through MOR. Utilizing the “message-address concept”, the our laboratory reported a novel non-peptide, reversible MOR selective ligand 17-cyclopropylmethyl-3,14β-dihydroxy-4,5α-epoxy-6α (isoquinoline-3-carboxamido)morphinan (NAQ). Molecular modeling and mutagenesis studies revealed that the selectivity of NAQ for MOR is because of the π-π stacking of the isoquinoline ring of NAQ with W318. Therefore, other heterocyclic ring systems were explored to obtain a diverse library of compounds with similar or different molecular interactions and pharmacologic characteristics as NAQ. The newly designed compounds were indole analogs of 6α/β-naltrexamine. The compounds were synthesized and the affinity and selectivity for MOR determined using the radioligand binding assay while the functional activity at MOR was determined using the [35S]GTPγS binding assay. The indole analog of 6α-naltrexamine substituted at position 7 (compound 6) was found to be very potent and had the lowest efficacy in the [35S]GTPγS functional assay while the indole analog of 6β-naltrexamine substituted at position 2 (compound 10) was identified as a MOR agonist and had the greatest efficacy. In vivo studies were conducted using the warm-water immersion assay to find whether the synthesized compounds had antinociceptive effects and/or blocked the antinociceptive effects of morphine. Not surprisingly, compound 10 was identified as an opioid agonist while compound 6 almost completely blocked morphine’s antinociceptive effects. The opioid antagonist effect of compound 6 was found to be dose dependent with an AD50 of 2.39 mg/kg (0.46-12.47). An opioid withdrawal assay was conducted on compound 6 using morphine-pelleted mice. Compound 6 produced significantly less withdrawal symptoms at 50 mg/kg than naltrexone at 1 mg/kg. Therefore, compound 6 has the potential to be used in opioid addiction and withdrawal treatment.

Opioid addiction

mu opioid receptor

antagonist

naltrexone

NAQ

withdrawal

Medicinal and Pharmaceutical Chemistry

Nervous System Diseases

Axon Initial Segment Stability in Multiple Sclerosis

Thummala, Suneel K

01 January 2015

Multiple sclerosis (MS) is an autoimmune disease of the central nervous system characterized by inflammation and demyelination. In addition to these hallmark features, MS also presents with axonal pathology, which is likely responsible for the signs and symptoms of the disease. Although prominent in MS, axonal pathology is frequently considered a consequence of demyelination and not a primary event. This conclusion is consistent with demyelination inducing the loss of specific axonal domains, known as the nodes of Ranvier that are responsible for the propagation of action potentials along the axon. In contrast, we propose that axonal pathology associated with MS is a primary pathological event, independent of demyelination, and not a product of it. In support of our hypothesis, we have analyzed a different axonal domain known as the axon initial segment. Whereas a single axon has numerous nodes of Ranvier uniformly distributed along the axon, each axon contains only a single axon initial segment that is positioned immediately distal to the neuronal cell body. The axon initial segment is responsible for action potential generation and modulation, and hence is essential for normal neuronal function. Background studies conducted by our lab, employing a murine model of demyelination/remyelination, revealed no correlation between axon initial segment stability and myelin integrity. Here we investigate the fate of the axon initial segment in human multiple sclerosis. While not statistically significant, we provide data demonstrating an apparent 40% reduction in AIS numbers in MS. We further provide qualitative evidence that AIS integrity in MS is not dependent on myelination suggestive that axonal pathology may be a primary event in MS, independent of demyelination. Our current findings are intriguing, but unfortunately this study is underpowered, and more samples will be required to determine whether this apparent reduction is statistically significant.

Multiple Sclerosis

Axon initial segment

demyelination

myelin

MS

AIS

Medical Neurobiology

Nervous System Diseases

Neurology

Neurosciences