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Understanding Neurosurgical Operations & Axon Anatomy

Learn about the stages of a neurosurgical operation, the use of local anesthesia, and the anatomy of axons. Discover how nerve fibers work and their significance in various medical disciplines.

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Understanding Neurosurgical Operations & Axon Anatomy

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  1. A Neurosurgical Operation

  2. A neurosurgical operation has several stages • Induction of Anesthesia • Line Insertion – Local anesthesia • Induction – General anesthesia • Maintenance of anesthesia • Initiation of Neuromonitoring • The Operation • Termination of Anesthesia

  3. Line Insertion – Local Anesthesia Insertion of an arterial line for blood pressure monitoring Lidocaine HCL

  4. Local Anesthesia • Erythroxylon coca, a shrub growing high in the Andes mountains – appreciated for centuries by the Peruvian people. • The plant ash releases an alkaloid in a form that can be absorbed across mucous membranes. • The pure alkaloid of cocaine was isolated in 1880. • In 1884, cocaine was used clinically as a local anesthetic in ophthalmology, dentistry, and surgery. • In 1905, the first synthetic local anesthetic, procaine, was developed.

  5. Local Anesthesia • There are currently 16 chemical agents used in local anesthesia; lidocaine, bupivacaine, and tetracaine are the most commonly used in clinical practice. • Local anesthetics are used to decrease pain, temperature, touch proprioception, and skeletal muscle tone. • Used in a variety of clinical situations, from topical application to the skin or mucosa membranes to injectable agents used for peripheral, central, or spinal nerve block. • All work in approximately the same way

  6. Lidocaine – a localanesthetic All local anesthetics reversibly block nerve conduction by decreasing nerve membrane permeability to sodium. This decreases the rate of membrane depolarization, thereby increasing the threshold for electrical excitability.

  7. Lidocaine – a local anesthetic All nerve fibers are affected, albeit in a predictable sequence: autonomic, sensory, motor. These effects diminish in reverse order.

  8. Why we have to learn about axons, ion channels & how they work • Local anesthetics: an everyday example used in a variety of medical disciplines 2. Axons are the prototypical “nerve fiber”. Knowing how they work facilitates an understanding of much of neuroscience. 3. Axons are involved in a range of very common medical diseases that you will all see. 4. It will be on the exam.

  9. We’ll get back to the operation Once we can get the arterial line into the patient without them jumping off the table.

  10. Anatomy of the axon

  11. Anatomy of the axon

  12. Axons behave very differently from dendrites In Health (their physiological role) And in Disease (their pathological response)

  13. AxonAnatomy Axons are cables composed of a tube surrounded by a cell membrane +/- insulation (myelin). From: Li S, Mealing GA, Morley P, Stys PK J Neurosci 1999 Jul 15;19(14):RC16

  14. AxonAnatomy The tubes of large axons are wrapped with myelin

  15. Myelin is produced by oligodendrocytes AxonAnatomy

  16. Axon Anatomy Myelination:

  17. Axon Anatomy • The tube contains • A cytoskeleton used for • Transporting stuff (axoplasmic transport) • Maintaining structure • Trafficking and anchoring cytoplasmic and cell membrane components. • Organelles, and the stuff being transported (proteins, neuro-transmitters, etc…)

  18. Axoplasmic transport • Axonal transport controls the distribution of membranes and secretory proteins in the neuron • Transport is anterograde and retrograde • Both anterograde and retrograde transport have fast and slow components.

  19. Fast transport Fast anterograde transport depends on microtubules & MT-associated ATPases (kinesins) that move large components (e.g., organelles) at high rates > 100mm / day

  20. Other transport: • Slow anterograde transport serves to move smaller elements such as cytoskeletal and other proteins at 0.2-5 mm/day • Fast retrograde transport moves at ½ to 2/3 the rate of fast anterograde transport. Serves to recycle large elements back to the cell soma, and also to inform the body about what’s happening at the other end (e.g., retrograde transport of hormones, and other signaling molecules)

  21. Axon Anatomy- The Node

  22. Axon Anatomy ->Physiology

  23. More About the tube: • The tube & its membrane contain • The Cytoskeleton • Organelles • Ion Channels • Ion Exchangers/Transporters • Neurotransmitter Exchangers/Transporters • Enzymes

  24. To Understand How the Axon Works, we need to understand: • Ion Channels • Concepts of Diffusion • Basic Concepts of Electicity • How to Put 1-3 Together

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