DOCSLIB.ORG

Thesis Comprises Only My Original Work Towards the Doctor of Philosophy Except Where Indicated in the Preface;

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Thesis Comprises Only My Original Work Towards the Doctor of Philosophy Except Where Indicated in the Preface; Development, prevalence and treatment of blood pressure abnormalities in spinal cord injury Min Yin Goh ORCID: 0000-0003-2517-7745 Doctor of Philosophy August 2019 Department of Medicine, Austin Health Faculty of Medicine, Dentistry and Health Sciences The University of Melbourne Submitted in total fulfilment of the requirements of the degree of Doctor of Philosophy Abstract Disorders of blood pressure control arise from disruption of the autonomic nervous system and result in symptomatic orthostatic hypotension and large fluctuations in blood pressure. Ambulatory blood pressure monitoring is used in the general population for assessment of blood pressure control and to detect episodes of hypotension. In spinal cord injury (SCI), impaired control of the sympathetic nervous system leads to orthostatic intolerance and autonomic dysreflexia. Smaller studies in restricted populations have examined ambulatory pressures in SCI and observed abnormalities in diurnal blood pressure variation in complete cervical SCI. Altered diurnal blood pressure is associated with abnormalities in diurnal urine production and orthostatic intolerance in autonomic failure. This triad may also occur in SCI to explain the orthostatic intolerance. A retrospective examination of ambulatory pressures of patients with SCI referred for clinically significant blood pressure disorders revealed a high prevalence of abnormalities in diurnal blood pressure and urine production in acute and chronic tetraplegia and in acute paraplegia. To characterise the course of diurnal blood pressure, urine production and orthostatic symptoms in SCI, two prospective studies were performed. First, consecutive patients admitted with acute SCI were screened for recruitment, and consenting volunteers were compared with immobilised and mobilising controls. In the second study, people with chronic SCI (>1 year) living in the community were compared with mobilising controls. Compared with mobilising and immobilised controls, there was a high prevalence of abnormal diurnal blood pressure variation in SCI. The abnormalities were most prevalent and marked in higher and earlier SCI. Abnormalities persisted over time in both complete and incomplete cervical SCI. Abnormalities in high paraplegia were no different to that of cervical SCI in early SCI, but were no different to that of controls in chronic SCI. Nocturnal hypertension occurred in the absence of day hypertension in i SCI, thus clinic pressures may miss elevation in blood pressures and ambulatory monitoring may be beneficial in assessment of blood pressure in SCI. Abnormalities in diurnal urine production were present and persisted over time in cervical SCI, but appeared to improve over time with thoracic SCI, mirroring changes in diurnal blood pressure. Orthostatic hypotension and orthostatic intolerance were more prevalent in SCI than in controls. Mild orthostatic intolerance is common in chronic SCI and a small proportion had more severe symptoms. A single centre study to investigate a drug treatment for orthostatic intolerance in the setting of a loss of diurnal blood pressure variation was unsuccessful due to low recruitment rates. As life expectancy increases in the SCI population, there is evidence of increased rates of cardiovascular disease. Similar to the general population, the loss of diurnal blood pressure variation and elevated nocturnal pressures may be a contributor to the increased cardiovascular disease in SCI, and thus a potential therapeutic target. Ambulatory blood pressure monitoring may be useful to detect these changes and examination of a larger SCI population with a longer duration of follow up for cardiovascular disease may help to determine this. ii Declaration This is to certify that: i. this thesis comprises only my original work towards the Doctor of Philosophy except where indicated in the preface; ii. due acknowledgement has been made in the text to all other material used; and iii. this thesis is fewer than 100,000 words in length, exclusive of tables, maps, bibliographies and appendices. _______________ Min Yin Goh iii Preface Studies in this thesis were conducted as part of a large project comprising many programs, funded by the Victorian Neurotrauma Initiative which supports research in traumatic brain and spinal cord injury (SCI). A/Prof Chris O’Callaghan and Ms Melinda Millard were responsible for the concept and design for Studies 2 and 3, with input from associate investigators, A/Prof Doug Brown, Prof David Berlowitz and Dr Edmund Wong. I provided input to protocol revisions. I set up Studies 1 and 4 together with A/Prof Chris O’Callaghan, Ms Melinda Millard and A/Prof Doug Brown. Screening and recruitment for all inpatients and some outpatients for Studies 2, 3 and 4 was done by Ms Melinda Millard and Ms Janette Alexander, the Spinal Research Liaison Coordinators, as there were several concurrent studies recruiting these patients. Ms Melinda Millard assisted with participant recruitment and assessment through the project. Dr Edmund Wong performed assessments in 2010 prior to my starting with the project. Dr Mariannick Le Guen assisted with data collection from a few participants who were also undertaking a research study she was conducting. Ms Samantha Lawford and Ms Stephanie Zhao assisted with patient list cleaning and telephone screening for Study 4. Mr Oliver Lukis assisted with data entry. I carried out participant assessments, and recruitment and screening of the outpatients not covered by the Spinal Research Liaison Co-ordinators; some of this was done in 2011 and 2012, prior to my enrolment towards the degree in 2013. Prof David Berlowitz, Dr Rachel Schembri and Dr Marnie Graco assisted with access to a database, database setup and maintenance, and a statistician during the studies. Statisticians Dr Steve Vander Hoorn provided guidance in data cleaning, manipulation and preliminary data analysis planning, and Dr Sue Finch provided guidance with data analysis. With this assistance, I set up and maintained the database, extracted information for data analysis, performed data cleaning, manipulation and analysis; data analysis and interpretation was conducted with A/Prof Chris O’Callaghan. iv Collaboration with other research programs run by Prof Mary Galea, Dr Jo Spong, Dr Mariannick Le Guen and Prof Ego Seeman facilitated participant recruitment. I collected data for the three publications included in this thesis, with help as described above, did the data cleaning, manipulation and analysis with guidance from statisticians as above, wrote initial drafts of all papers and revised manuscripts after feedback from all co-authors and reviewers. A/Prof Chris O’Callaghan helped with data interpretation for all papers. All co-authors as listed on the co-author authorisation forms were involved in manuscript revision. The three articles included in Chapters 3, 4 and 5 were published online in Spinal Cord on 11 November 2014, 28 June 2016 and 2 March 2018 respectively. Funding Funding for these studies was provided by the Victorian Neurotrauma Initiative (VNI) and Transport Accident Commission (TAC) (DP174). I was supported by a scholarship (Australian Postgraduate Award, APA) through the University of Melbourne and a stipend through the Spinal Research Institute. v Acknowledgements My heartfelt thanks to many for their support through these studies: A/Prof Chris O’Callaghan for continued and invaluable support, guidance, encouragement and patience; Prof Albert Frauman for advice and supervision; Prof Ingrid Scheffer and Dr Willian Korim as my advisory committee. Ms Jo Mayall, for help with university related queries. Ms Melinda Millard for all project related tasks and continued support; Ms Janette Alexander for co-ordinating participant recruitment and assessments. The Departments of Clinical Pharmacology and Medicine, especially Dr Edmund Wong, Ms Samantha Lawford, Ms Stephanie Zhao, Ms Lesa Marr, Dr Andrew Ellis, Ms Jenni Caulfield for help with research related tasks. Mr Oliver Lukis, for help with data entry. The Spinal Unit and the Spinal Research Institute (SRI), with special mention to A/Prof Doug Brown and Dr Andrew Nunn; staff at the Spinal Units for their help and patience with my repeated requests for urine collection and scheduling of monitors/interviews. Prof David Berlowitz, Dr Rachel Schembri, Dr Marnie Graco and the IBAS for access to a database, statistician and support. Dr Steve Vander Hoorn and Dr Sue Finch for statistics related guidance, and the former for introduction to the world of R. The SCI Autonomic Group and the VNI Program and other collaborators, for facilitating recruitment of participants - Prof John Furness, A/Prof James Brock, Prof Mary Galea, Dr Jo Spong, Dr Mariannick Le Guen, Prof Ego Seeman. Participants for their time and effort, and giving me a glimpse into life with SCI. Family, friends and rats, for being there for me. The Transport Accident Commission (TAC) and Victorian Neurotrauma Initiative (VNI) for project funding; APA scholarship through the University of Melbourne and the SRI for financial support. vi Table of Contents Abstract ........................................................................................................................ i Declaration ................................................................................................................. iii Preface ........................................................................................................................ iv Acknowledgements ...................................................................................................
Load more

Recommended publications
  • METHODICAL GUIDANCE for the Lecture Academic Subject Human
    Ministry of Public Health of Ukraine Ukrainian Medical Stomatological Academy "Approved" at the meeting of the Department of Human Anatomy «29» 08 2020 Minutes № Head of the Department Professor O.O. Sherstjuk ________________________ METHODICAL GUIDANCE for the lecture Academic subject Human Anatomy Module No 3 "The heart. Vessels and nerves of the head, the neck, the trunk, extremities" Lecture No 15 Review of the autonomic nervous system, its central departments. The principles of the autonomic innervation of the organs Year of study ІI Faculty Foreign students' training faculty, specialty «Medicine» Number of 2 academic hours Poltava – 2020 1. Educational basis of the topic The autonomic division of peripheral nervous system regulates physiological processes of the human organism like blood circulation, respiration, digestion, excretion and general metabolism; also, it regulates tissue trophic processes. The autonomic division acts relatively independently from the cerebral cortex and the organs supplied act involuntarily as well. It is quite clear that that distinguishing of the somatic and the autonomic compartments is conditional and exact delimitation is not possible. Such impossibility appears due to common regulatory centers for both divisions and tight morphological and functional associations featured by them. The somatic neurons and the interneurons of PNS like those of CNS feature topographical and synaptic associations so a reflex arc may comprise both somatic (e.g. afferent) and autonomic neurons. Summarizing the aforesaid, the term ’autonomic nervous system’ will be applied to a specific compartment of PNS but not for a separate nervous system. 2. Learning objectives of the lecture: . to familiarize students with the autonomic division of CNS; .
    [Show full text]
  • Autonomic Nervous System
    AUTONOMIC NERVOUS SYSTEM PAGE 1 AUTONOMIC NERVOUS SYSTEM PAGE 2 AUTONOMIC NERVOUS SYSTEM PAGE 3 AUTONOMIC NERVOUS SYSTEM PAGE 4 AUTONOMIC NERVOUS SYSTEM PAGE 5 AUTONOMIC NERVOUS SYSTEM PAGE 6 AUTONOMIC NERVOUS SYSTEM PAGE 7 AUTONOMIC NERVOUS SYSTEM PAGE 8 AUTONOMIC NERVOUS SYSTEM PAGE 9 REVIEW QUESTIONS 1. The autonomic nervous system controls the activity of _?_. (a) smooth muscle (b) cardiac muscle (c) glands (d) all of these (e) none of these 2. All preganglionic and postganglionic autonomic neurons are _?_ neurons. (a) somatic efferent (b) visceral efferent (c) somatic afferent (d) visceral afferent (e) association neurons 3. Which neurotransmitter is released at the synapses between preganglionic and postganglionic autonomic neurons ? (a) epinephrine (b) norepinephrine (c) acetylcholine (d) serotonin (e) oxytocin 4. All preganglionic sympathetic neurons are located in: (a) the lateral horn of the spinal cord of spinal cord segments T1-L2 (b) brainstem nuclei (c) intramural (terminal) ganglia (d) paravertebral ganglia of the sympathetic chains (e) prevertebral ganglia 5. All preganglionic parasympathetic neurons are located in _?_. (a) prevertebral ganglia (b) the lateral horn of spinal cord segments T1-L2 (c) sympathetic chain ganglia (d) intramural ganglia (e) brainstem nuclei and spinal cord segments S2-S4 6. Prevertebral and paravertebral ganglia contain _?_. (a) preganglionic sympathetic neurons (b) preganglionic parasympathetic neurons (c) postganglionic sympathetic neurons (d) postganglionic parasympathetic neurons (e) all of these 7. The otic, ciliary, submandibular and pterygopalatine ganglia are located in the head region and contain _?_. (a) preganglionic sympathetic neurons (b) preganglionic parasympathetic neurons (c) postganglionic sympathetic neurons (d) postganglionic parasympathetic neurons (e) none of these 8.
    [Show full text]
  • Neuronal Types and Their Specification Dynamics in the Autonomic Nervous System
    From the Department of Medical Biochemistry and Biophysics Karolinska Institutet, Stockholm, Sweden NEURONAL TYPES AND THEIR SPECIFICATION DYNAMICS IN THE AUTONOMIC NERVOUS SYSTEM Alessandro Furlan Stockholm 2016 All previously published papers were reproduced with permission from the publisher. Published by Karolinska Institutet. Printed by E-Print AB © Alessandro Furlan, 2016 ISBN 978-91-7676-419-0 On the cover: abstract illustration of sympathetic neurons extending their axons Credits: Gioele La Manno NEURONAL TYPES AND THEIR SPECIFICATION DYNAMICS IN THE AUTONOMIC NERVOUS SYSTEM THESIS FOR DOCTORAL DEGREE (Ph.D.) By Alessandro Furlan Principal Supervisor: Opponent: Prof. Patrik Ernfors Prof. Hermann Rohrer Karolinska Institutet Max Planck Institute for Brain Research Department of Medical Biochemistry and Research Group Developmental Neurobiology Biophysics Division of Molecular Neurobiology Examination Board: Prof. Jonas Muhr Co-supervisor(s): Karolinska Institutet Prof. Ola Hermansson Department of Cell and Molecular Biology Karolinska Institutet Department of Neuroscience Prof. Tomas Hökfelt Karolinska Institutet Assistant Prof. Francois Lallemend Department of Neuroscience Karolinska Institutet Division of Chemical Neurotransmission Department of Neuroscience Prof. Ted Ebedal Uppsala University Department of Neuroscience Division of Developmental Neuroscience To my parents ABSTRACT The autonomic nervous system is formed by a sympathetic and a parasympathetic division that have complementary roles in the maintenance of body homeostasis. Autonomic neurons, also known as visceral motor neurons, are tonically active and innervate virtually every organ in our body. For instance, cardiac outflow, thermoregulation and even the focusing of our eyes are just some of the plethora of physiological functions under the control of this system. Consequently, perturbation of autonomic nervous system activity can lead to a broad spectrum of disorders collectively known as dysautonomia and other diseases such as hypertension.
    [Show full text]
  • Facsimile Del Frontespizio Della Tesi Di Dottorato
    Allma Mater Studiiorum – Uniiversiità dii Bollogna DOTTORATO DI RICERCA IN SCIENZE MEDICHE VETERINARIE Ciclo XXIX° Settore Concorsuale di afferenza: 07/H1 Settore Scientifico disciplinare: VET 01 The nervous system of Delphinidae: neurochemical studies on different central and peripheral regions Presentata da: Anna Maria Rambaldi Coordinatore Dottorato Relatore Chiar.mo Prof. Arcangelo Gentile Chiar.mo Prof. Cristiano Bombardi Esame finale anno 2017 The nervous system of Delphinidae: neurochemical studies on different central and peripheral regions INDEX ABSTRACT 1 INTRODUCTION 7 1 Cetaceans and general adaptations to aquatic environment 8 2 The nervous system of cetaceans 11 2.1 Evolution 11 2.2 The central nervous system 14 2.3 The peripheral nervous system 23 EXPERIMENTAL STUDIES 25 3 Distribution of calretinin immunoreactivity in the lateral nucleus of the 26 bottlenose dolphin (Tursiops truncatus) amygdala 4 Calcitonin gene-related peptide (CGRP) expression in the spinal cord and 41 spinal ganglia of the bottlenose dolphin (Tursiops truncatus) 5 Nitrergic and substance P immunoreactive neurons in the enteric nervous 58 system of the bottlenose dolphin (Tursiops truncatus) intestine 6 Preliminary study on the expression of calcium binding proteins and 72 neuronal nitric oxide synthase (nNOS) in different brain regions of striped dolphins (Stenella Coeruleoalba) affected by morbillivirus CONCLUSIONS 91 REFERENCES 94 ABSTRACT During the evolutionary path, Cetaceans experienced a return to waters and hence had to adapt many of their anatomical and physiological features to this new life. Many organs and systems present several modifications and specialisations, which make these mammals different from their mainland ancestors. The nervous system either displays peculiar features like an extremely large brain, in terms of both absolute and relative mass, a very high level of gyrification, a minimization, or in some cases a complete lack, of olfactory structures, and a poorly developed corpus callosum.
    [Show full text]
  • Thesis Rests with the Author
    University of Bath PHD Studies on the alpha-bungarotoxin binding component in human brain. Whyte, J. Award date: 1985 Awarding institution: University of Bath Link to publication Alternative formats If you require this document in an alternative format, please contact: [email protected] General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal ? Take down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Download date: 10. Oct. 2021 i Ta \ D'--- V ^ STUDIES ON THE a-BUNGAROTOXIN BINDING COMPONENT IN HUMAN BRAIN submitted by J. Whyte for the degree of Ph.D. of the University of Bath 1985 COPYRIGHT Attention is drawn to the fact that the copyright of this thesis rests with the author. This copy of the thesis has been supplied on condition that anyone who consults it is under­ stood to recognize that its copyright rests with the author and that no quotation from the thesis and no information derived from it may be published without the prior written consent of the author.
    [Show full text]
  • Autonomic Nervous System
    Autonomic nervous System Regulates activity of: Smooth muscle Cardiac muscle certain glands Autonomic- illusory (convenient)-not under direct control Regulated by: hypothalamus Medulla oblongata Divided in to two subdivisions: Sympathetic Parasympathetic Sympathetic: mobilizes all the resources of body in an emergency Parasympathetic: maintains the normal body functions Complimentary to each other. ANS Activity expressed • Regulation of Blood Pressure • Regulation of Body Temperature • Cardio-respiratory rate • Gastro-intestinal motility • Glandular Secretion Sensations • General – Hunger , Thirst , Nausea • Special -- Smell, taste and visceral pain • Location of ANS in CNS: 1. cerebral hemispheres (limbic system) 2. Brain stem (general visceral nuclei of cranial nerves) 3. Spinal cord (intermediate grey column) ANS Anatomy • Pathway: Two motor neurons 1. In CNS -->Axon-->Autonomic ganglion 2. In Autonomic ganglion-->Axon-->effector organ • Anatomy: Preganglionic neuron--->preganglionic fibre (myelinated axon)--->out of CNS as a part of cranial/spinal nerve--->fibres separate & extend to ANS ganglion-->synapse with postganglionic neuron--->postganglionic fibre (nonmyelinated)-- >effector organ Sympathetic system Components • Pair of ganglionic sympathetic trunk • Communicating rami • Branches • Plexuses • Subsidiary ganglia – collateral , terminal ganglia Sympathetic trunk (lateral ganglia) • Paravertebral in position • Extend from base of skull to coccygeal • Both trunk unite to form – ganglion impar Total Ganglia • Cervical-3 • Thoracic-11
    [Show full text]
  • Pattern of Autonomic Innervation
    Pattern of Innervation of the Viscera The nerves supplying the viscera are derived from the autonomic nervous system – sympathetic and parasympathetic. The viscera of the thorax, abdomen and pelvis are supplied segmentally by branches of the sympathetic chain, and branches of the vagus nerve, as discussed below. The autonomic supply of structures in the head and neck follows a specific pattern that will be dealt with separately. The sympathetic chain: Communicates with the spinal nerves via white and grey rami communicantes The white rami communicantes: are present only at the levels of T1 to L2 spinal nerves convey all the sympathetic efferents from the spinal cord to the sympathetic chain consist of myelinated pre-ganglionic axons have their cell bodies in the lateral grey column of the spinal cord synapse in the sympathetic ganglia with postganglionic neurons NOTE: The cervical, lower lumbar and sacral ganglia have no white rami, and receive their sympathetic inflow from the thoracic and lumbar segments via ascending or descending axons in the sympathetic chain The grey rami communicantes consist of unmyelinated postganglionic neurons are the axons of postganglionic neurons distribute somatic branches via the cutaneous nerves to the arteries, sweat glands and arrectores pilorum in the skin, (where they are vasoconstrictor, secretomotor, and pilomotor respectively. are present in all spinal ganglia Visceral sympathetic branches are distributed to the viscera via autonomic nerve plexuses (listed in the table below) arise as
    [Show full text]
  • The Parasympathetic System
    DR MOUIN ABBOUD PR OF ANATOMY In faculity of medecin ( Damascus and Sham uneversities ) Specialist in respiratory diseases الدكتور معين عبود استاذ التشريح في كلية الطب البشري في جامعة دمشق وجامعة الشام الخاصة اختصاصي في أمراض جهاز التنفس DR MOUIN ABBOUD Abdominal viscera Innervation The Innervation Abdominal viscera are innervated by both : extrinsic ) visceral innervation ( involves : . receiving motor impulses from the central nervous system . and sending sensory information to, the central nervous system; and intrinsic components of the nervous system: involves the regulation of digestive tract activities by a generally self-sufficient network of sensory and motor neurons (the enteric nervous system). Visceral innervation The visceral innervation is transmited by Autonomic Plexuses )prevertebral plexus ). By which : these viscera send sensory information back to the central nervous system through visceral afferent fibers and receive motor impulses from the central nervous system through visceral efferent fibers. prevertebral plexus The abdominal prevertebral plexus receives: preganglionic parasympathetic and visceral afferent fibers from the vagus nerves [X]; preganglionic sympathetic and visceral afferent fibers from the thoracic and lumbar splanchnic nerves; preganglionic parasympathetic fibers from the pelvic splanchnic nerves. The Sympathetic Division The sympathetic division consists of the following: Preganglionic fibers in the lateral grey column of the thoracic and upper two lumbar segments of the spinal cord. Ganglionic neurons in : . Sympathetic chain ganglia, also called paravertebral, or lateral ganglia . Collateral ganglia, also known as prevertebral ganglia . Specialized neurons in the interior of the suprarenal gland Postganglionic fibers : to target organs Sectional Organization of the Spinal Cord The parasympathetic system The parasympathetic system is less neatly defined Preganglionic fibers .
    [Show full text]
  • Gen Anat-Nervous System
    Nervous system • Controlling & Coordinating System Functions • Regulates all activity (Voluntary & Involuntary) • Adjust Acc. to changing external and internal environment Nervous System Subdivisions CNS (Central Nervous System) PNS( Peripheral Nervous System) ANS (Autonomic Nervous system CNS Brain ( Encephalon) Spinal Cord ( Sp. Medulla) Parts • Cerebrum • Cerebellum •Brain Stem -Mid Brain -Pons -Medulla PNS ( Peripheral Nervous system) Two Components 1. Somatic ( Cerebrospinal) ---12 Pair Cranial Nerves ----31 pair Spinal Nerves 2. Visceral ( Autonomic Nervous System – ANS) ----Visceral or Splanchnic nerves two – subdivisions i) Sympathetic ii) Parasympathetic Somatic Component • Deals with any change in external environment – Extroceptive or Proprioceptive General Sensations like • Pain , Touch , Temp. --- From Skin • Sensations from muscles , bones , joints, limbs Special Sensations like • Vision • Hearing • Balancing – Through vestibular receptors Cranial Nerves 1. OLFACTORY 7. FACIAL 2. OPTIC 8. VESTIBULO-COCLEAR 3. OCCULOMOTOR 9. GLOSSOPHARYNGEAL 4. TROCHLEAR 10. VAGUS 5. TRIGERMINAL 11. ACCESSORY 6. ABDUCENT 12. HYPOGLOSSAL 31 Pairs Spinal Nerves Includes Cervical -8 (C1 ----C8) Thoracic -12 (T1-T12) Lumbar – 5 (L1-L5) Sacral - 5 (S1– S5) Coccyx – 1 (Co -1) Spinal Nerve Joining of ant. and Post. nerve roots Spinal Segment Length of the spinal cord originating rootlets of one spinal nerve Spinal Nerve Dorsal Root & Ventral Root Join to form trunk of spinal nerve At intervertebral foramina divide into Dorsal and ventral ramus Dorsal ramus runs posteriorly and divide in Medial and Lateral Branches to supply muscles of back, and give cut. Branches Ventral ramus runs anteriorly and give lateral cutaneous branch which further subdivide into: Ant and post branches Rest continue as ant. cutaneous Br. Ventral Rami of Cervical, Lumbar.
    [Show full text]
  • Pruritus: a Review
    Acta Derm Venereol 2003, Suppl. 213: 5–32 Pruritus: A Review ELKE WEISSHAAR1,2, MICHAEL J. KUCENIC1 AND ALAN B. FLEISCHER JR.1 1Department of Dermatology, Wake Forest University School of Medicine, Winston-Salem, North Carolina, USA and 2Department of Social Medicine, Occupational and Environmental Dermatology, University of Heidelberg, Germany The history, neurophysiology, clinical aspects and treat- could be considered that there are systemic or central as- ment of pruritus are reviewed in this article. The dif- pects of pruritus in dermatological diseases and of course ferent forms of pruritus in dermatological and systemic that there are dermatological factors causing pruritus in diseases are described, and the various aetiologies and systemic diseases. Pruritus can also occur without visible pathophysiology of pruritus in systemic diseases are dis- skin symptoms (3), and in systemic diseases can result from cussed. Lack of understanding of the neurophysiology a specific dermatological disease or infiltrate directly re- and pathophysiology of pruritus has hampered the de- lated to the underlying disease, e.g. cutaneous infiltrates velopment of adequate therapies. Nevertheless, the dis- in Hodgkin’s disease. This always needs to be considered covery of primary afferent neurons and, presumably, in the setting of pruritus in systemic diseases and has to be second-order neurons with typical histamine responses ruled out by the experienced dermatologist using the nec- mediating pruritic sensations can be regarded as a essary diagnostic tools, e.g. skin biopsy. Pruritus may also breakthrough in our understanding of the mechanisms occur in dermatological and systemic diseases not directly behind pruritus. The number of experimental and related to specific dermatoses or infiltrates.
    [Show full text]
  • The Neurophysiological Basis of the Divergent Sympathetic Responses to Long-Lasting Experimental Muscle Pain in Humans
    THE NEUROPHYSIOLOGICAL BASIS OF THE DIVERGENT SYMPATHETIC RESPONSES TO LONG–LASTING EXPERIMENTAL MUSCLE PAIN IN HUMANS Sophie Kobuch (BA, BMedRes) School of Medicine Western Sydney University Supervisor: Professor Vaughan Macefield Co-supervisor: Associate Professor Luke Henderson Co-supervisor: Doctor Rachael Brown A thesis submitted to Western Sydney University in fulfilment of the requirements of Doctor in Philosophy 2018 Acknowledgments The list of people who have encouraged me throughout my PhD is endless. Family, friends, partner, supervisors, colleagues, participants, you name it. These few words do not reflect the least of their help. Thank you to all participants, most of whom were my friends and colleagues, who have endured sitting or lying still for hours while being in pain. Thank you to the University of Sydney Neuroimaging lab for being a fun group to be around, and for including me in your team. Andrew, thanks for teaching me all the very basics of neuroimaging, you deserve a double PhD with all the time and effort you have devoted to helping me. I look forward to the next-generation “Macefield-Henderson!” Emily, thank you for all the nerdy chats, coffee breaks, climbing sessions, it’s been so fun! Flav, you have become one of my closest friends. I thank you for all the discussions – whether they were science based, political, or other. Your knowledge and work ethic have made me a better person and a better scientist. Zeynab, thank you for the great discussions, fun times, and lunches. Noemi and Kasia, thanks for making the windowless office a fun place to work in.
    [Show full text]
  • POLYTECHNIQUE MONTRÉAL Clustering of the White Matter
    POLYTECHNIQUE MONTRÉAL affiliée à l’Université de Montréal Clustering of the White Matter Tracts in the Rat Spinal Cord Based on Quantitative Histology HARRIS NAMI Institut de génie biomédical Mémoire présenté en vue de l’obtention du diplôme de Maitrise ès sciences appliquées Génie biomédical Août 2019 © Harris Nami, 2019. POLYTECHNIQUE MONTRÉAL affiliée à l’Université de Montréal Ce mémoire intitulé : Clustering of the White Matter Tracts in the Rat Spinal Cord Based on Quantitative Histology présenté par Harris NAMI en vue de l’obtention du diplôme de Maitrise ès sciences appliquées a été dûment accepté par le jury d’examen constitué de : Jean PROVOST, président Julien COHEN-ADAD, membre et directeur de recherche Nikola STIKOV, membre et codirecteur de recherche Samuel KADOURY, membre iii DEDICATION I would like to dedicate this thesis to my family, whom without their unwavering support I would not be where I am today. iv ACKNOWLEDGEMENTS I would like to acknowledge all my fellow colleagues at the NeuroPoly lab that have helped me throughout my 2 years in the lab. In particular, I would like to thank Agah, Aldo, Alexandru, Ariane, Atef, Charley, Christian, Gabriel, Maxime, Nibardo, Ryan, Tanguy, and Tommy for all of their help, interactions and useful discussions the past 2 years. I would like to thank my supervisor and co-supervisor Julien and Nikola for being very supportive and insightful with every project I worked on. They are amongst the most intelligent people I have had the pleasure of working under and truly learnt a lot from them. v RÉSUMÉ La matière blanche de la moelle épinière est vraiment importante pour la transmission de l’information entre le corps et le cerveau et vice-versa.
    [Show full text]