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    Unravelling the genetic basis for cortical plasticity in the human swallowing motor system

    Raginis-Zborowska, Alicja Iwona

    [Thesis]. Manchester, UK: The University of Manchester; 2016.

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    Abstract

    Swallowing is an important physiological function leading to nourishment of the organism, controlled by complicated interactions between the muscles, the cranial nerves and multiple brain structures. Swallowing impairments, also called dysphagia are a major health burden for patients with neurological diseases such as stroke, Parkinson’s disease as well as community dwelling elderly individuals. It has been shown that activation of undamaged swallowing motor cortex compensates for the initial lost swallowing function in stroke patients. Non-invasive brain stimulation provides a tool to explore excitability within the areas of the motor cortex responsible for swallowing muscles. Repetitive transcranial magnetic stimulation (rTMS) is one such technique, with defined frequency parameters, however the underlying reasons for the heterogeneity is responses to low (1Hz) and high (5Hz) frequencies is unclear. These physiological interactions affecting the neurological control of swallowing may be influenced by multiple genes and proteins. Insights into the molecular basis of swallowing through genetic interactions could provide a source of information which can be further used in understanding and treating swallowing impairments. Existing evidence is limited in terms of candidate proteins, genes and pathways which might drive the neural control of swallowing.The aim of my doctoral research was to explore genes which might be involved in swallowing neurophysiology and pathophysiology. My hypothesis is that swallowing due to its complicated physiology is most likely affected by multiple genes and interactions between genes and proteins.To study this hypothesis I used two experimentally distinct study designs. Firstly I explored a number of single nucleotide polymorphisms (SNPs) and potential candidate genes presented in the existing literature. Then, I performed a SNP- and gene-based Genome-Wide Association Study (GWAS) of self-reported swallowing impairments compared with over 500,000 single nucleotide changes. For GWAS I used a group of 555 community dwelling individuals from the Dyne Steel Cohort from the areas of Manchester and Newcastle. Further research involved replication of selected genes and SNPs from literature screening and GWAS using two rTMS paradigms on the largest to date cohort of healthy young volunteers. Forty one volunteers (were assessed for corticobulbar excitability after single-pulse TMS. Repeated measurements of motor evoked potentials from the pharynx and the hand were recorded after the interventions of 1Hz and 5Hz rTMS. The subjects’ individual responses were grouped according to multiple criteria and then associated with factors such as gender, ethnicity, time of day of the stimulation and individual genetic information.GWAS analysis for association with swallowing impairment identified one SNP rs17601696 which achieved genome-wide significance (P-value=5×10(-8)) within a non-coding region of chromosome 10. Gene-based analysis did not result in any genome-wide significant association. In replication of these findings and following a priori selected genes from the literature (BDNF, COMT, TRKB, APOE, DRD2, GRIN2B and GRIN1) from neurophysiological studies applying TMS, two main conclusions were formed. Firstly, rTMS paradigms showed high variability in responses which made the phenotype more complicated. Secondly the result from GWAS could not be confirmed. By contrast, SNP rs6269 from the COMT gene was associated with responsiveness of the pharyngeal MEPs after delivering 1Hz paradigm and rs1800497 from the DRD2 gene with responsiveness after 5Hz rTMS.Lack of replication of the findings between two experiments might be caused by high variability in responsiveness with complex molecular networks of swallowing control where multiple genes with small genetic effects are involved. Although our findings support the hypothesis that molecular markers can be associated with swallowing, more studies are needed to understand the individual factors that determine responsiveness and effectiveness of treatment therapies of swallowing impairments.

    Bibliographic metadata

    Type of resource:
    Content type:
    Form of thesis:
    Type of submission:
    Degree type:
    Doctor of Philosophy
    Degree programme:
    PhD Medicine 3yr (NEP)
    Publication date:
    Location:
    Manchester, UK
    Total pages:
    172
    Abstract:
    Swallowing is an important physiological function leading to nourishment of the organism, controlled by complicated interactions between the muscles, the cranial nerves and multiple brain structures. Swallowing impairments, also called dysphagia are a major health burden for patients with neurological diseases such as stroke, Parkinson’s disease as well as community dwelling elderly individuals. It has been shown that activation of undamaged swallowing motor cortex compensates for the initial lost swallowing function in stroke patients. Non-invasive brain stimulation provides a tool to explore excitability within the areas of the motor cortex responsible for swallowing muscles. Repetitive transcranial magnetic stimulation (rTMS) is one such technique, with defined frequency parameters, however the underlying reasons for the heterogeneity is responses to low (1Hz) and high (5Hz) frequencies is unclear. These physiological interactions affecting the neurological control of swallowing may be influenced by multiple genes and proteins. Insights into the molecular basis of swallowing through genetic interactions could provide a source of information which can be further used in understanding and treating swallowing impairments. Existing evidence is limited in terms of candidate proteins, genes and pathways which might drive the neural control of swallowing.The aim of my doctoral research was to explore genes which might be involved in swallowing neurophysiology and pathophysiology. My hypothesis is that swallowing due to its complicated physiology is most likely affected by multiple genes and interactions between genes and proteins.To study this hypothesis I used two experimentally distinct study designs. Firstly I explored a number of single nucleotide polymorphisms (SNPs) and potential candidate genes presented in the existing literature. Then, I performed a SNP- and gene-based Genome-Wide Association Study (GWAS) of self-reported swallowing impairments compared with over 500,000 single nucleotide changes. For GWAS I used a group of 555 community dwelling individuals from the Dyne Steel Cohort from the areas of Manchester and Newcastle. Further research involved replication of selected genes and SNPs from literature screening and GWAS using two rTMS paradigms on the largest to date cohort of healthy young volunteers. Forty one volunteers (were assessed for corticobulbar excitability after single-pulse TMS. Repeated measurements of motor evoked potentials from the pharynx and the hand were recorded after the interventions of 1Hz and 5Hz rTMS. The subjects’ individual responses were grouped according to multiple criteria and then associated with factors such as gender, ethnicity, time of day of the stimulation and individual genetic information.GWAS analysis for association with swallowing impairment identified one SNP rs17601696 which achieved genome-wide significance (P-value=5×10(-8)) within a non-coding region of chromosome 10. Gene-based analysis did not result in any genome-wide significant association. In replication of these findings and following a priori selected genes from the literature (BDNF, COMT, TRKB, APOE, DRD2, GRIN2B and GRIN1) from neurophysiological studies applying TMS, two main conclusions were formed. Firstly, rTMS paradigms showed high variability in responses which made the phenotype more complicated. Secondly the result from GWAS could not be confirmed. By contrast, SNP rs6269 from the COMT gene was associated with responsiveness of the pharyngeal MEPs after delivering 1Hz paradigm and rs1800497 from the DRD2 gene with responsiveness after 5Hz rTMS.Lack of replication of the findings between two experiments might be caused by high variability in responsiveness with complex molecular networks of swallowing control where multiple genes with small genetic effects are involved. Although our findings support the hypothesis that molecular markers can be associated with swallowing, more studies are needed to understand the individual factors that determine responsiveness and effectiveness of treatment therapies of swallowing impairments.
    Thesis main supervisor(s):
    Thesis co-supervisor(s):
    Language:
    en

    Institutional metadata

    University researcher(s):
    Academic department(s):

    Record metadata

    Manchester eScholar ID:
    uk-ac-man-scw:306466
    Created by:
    Raginis-Zborowska, Alicja
    Created:
    22nd December, 2016, 19:35:40
    Last modified by:
    Raginis-Zborowska, Alicja
    Last modified:
    6th January, 2017, 13:25:02

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