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Neurology. Charles H. ClarkeЧитать онлайн книгу.

Neurology - Charles H. Clarke


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late Professor MJ Turlough Fitzgerald, Emeritus Professor of Anatomy, National University of Ireland, Galway most generously provided all the neuroanatomy illustrations for Neurology a Queen Square Textbook Second & First Editions.

      1 Clarke C, Lemon R. Nervous system structure & function. In Neurology A Queen Square Textbook, 2nd edn. Clarke C, Howard R, Rossor M, Shorvon S, eds. John Wiley & Sons, 2016. There are numerous references.

      2 Champney TH. Essential Clinical Neuroanatomy, 1st edn. Wiley Blackwell, 2016.

      3 Fitzgerald’s Clinical Neuroanatomy and Neuroscience, 8th Edition. Mtui E, Gruener G, Dockerty P. Elsevier, 2020.

      4 Hopkins AP, Clinical Neurology: A Modern Approach. Oxford Medical Publications, 1993.

      Also, please visit https://www.drcharlesclarke.com for free updated notes, potential links and references. You will be asked to log in, in a secure fashion, with your name and institution.

      Many neurological diseases have aetiologies that require an understanding of genetics, immune mechanisms and the way neuronal cell membranes – and thus ion channels – react. This chapter considers these briefly.

      I have approached this in two ways. The first is to trace the embryological development of parts of the CNS – and here I have selected the spine and spinal cord, where genes have been identified that deal with either longitudinal or axial spinal development. The second is to illustrate how mutations and other abnormalities translate into neurological diseases. The basic genetics are summarised here, but picked up in the third section of this chapter – in channelopathies. I assume an understanding of Mendelian and mitochondrial inheritance, DNA, RNA, and chromosomes.

      Despite the major advances, genetics plays little part in the day‐to‐day neurology of headache, seizures and even conditions such as malignant neoplasms, MS and most cases of Parkinson’s. This may change in years to come.

      Essential Embryology of the Spine

      The adult spine is divided into the cranio‐cervical junction, cervical, thoracic, lumbar and sacro‐coccygeal spine. In early foetal life the ectodermal germ layer forms the primitive neural tube that gives rise to the entire nervous system. This tube closes by the end of the fourth intrauterine week; failure of this primary neurulation results in fusion defects such as anencephaly or spina bifida. By this time the brain vesicles are present – the forebrain, midbrain and hindbrain. By the end of the fifth intrauterine week mesoderm that lies around the neural tube completes segmentation into somite pairs, from the occiput to the coccyx. Epithelioid cells of these somite pairs transform rapidly and migrate towards the notochord where they differentiate into three cell lines: sclerotomes – connective tissue, cartilage and bone, myotomes – segmental muscle and dermatomes. In the sclerotomes, chondrification leads on to ossification – anterior and posterior centres for each vertebral body and two for each arch. This is largely complete by the 12th week of foetal life.

Schematic illustration of genetic control of spinal development – putative mechanisms.

      Source: Courtesy of Dr Simon Farmer.

      Genetic Control of Spinal Development

      Notch genes are involved in longitudinal segmentation. A second group of genes, the Hox (homeobox) family, specifies axial development and defines vertebral shape. In man there are four families of Hox genes (Hox A‐D). Abnormal expression has been demonstrated in mice: for example, mutation of HOXB4 results in duplication of the atlas – a second atlas replaces the axis vertebra. Large Hox mutations produce a severely disrupted body habitus incompatible with intrauterine life. From analysis of mouse and human malformations, many genes have been identified: HOXB4, Notch, PAX1, PAX2, MEOX1, Gli2, Uncx4.1, BMP‐7 and Jun.

      Chromosomal Abnormalities, Repeat Expansions and Mutations

      These are usually categorised by their mode of inheritance:

       autosomal dominant (AD)

       autosomal recessive (AR)

       X‐linked

       mitochondrial inheritance.

      Mechanisms typically comprise:

       Mutations or other gene defects that affect a protein or an ion channel

       Nucleotide repeat expansions such as in Huntington’s disease

       Abnormalities in chromosomes, such as trisomy 21 (Down’s)

       Digenic (two‐locus) inheritance, such as in some familial Parkinson’s cases

      Conditions where genes and environment appear to interact, in an unproven way, such as in MS are less clear.

      Autosomal Dominant Inheritance

      Huntington’s disease, neurofibromatosis type 1, tuberous sclerosis and myotonic dystrophy are typical examples. There is usually a family pedigree.

      Autosomal Recessive Inheritance

      Most recessive traits are rare and typically follow consanguinity.

      AR cerebellar ataxias (Chapter 17), neuropathies (Chapter 10), hearing loss (Chapter 15) and progressive external ophthalmoplegia (Chapter 14) are examples.


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