1. CHAPTER 13 Nervous Tissue COMMON COURSE OBJECTIVES: 1. Functions of the nervous system 2. Organization of the nervous system 3. Nerve tissue and nerve cell types 4. Structure of a typical neuron 5. Structure of a chemical synapse

2. Nervous Tissue Histology Composed of: Composed of: Neurons true conducting cells in nervous tissue Neurons true conducting cells in nervous tissue Neuroglial (supporting) cells Neuroglial (supporting) cells -Astrocytes-Schwann cells -Oligodendrocytes-Satellite cells -Microglia-Ependymal

3. The NERVOUS SYSTEM Defined: like the CPU of a computer, the nervous system is the master controlling system of the body. It is designed to constantly and rapidly adjust and respond to stimuli the body receives. It includes the brain, cranial nerves, spinal cord, and associated peripheral nerves. Defined: like the CPU of a computer, the nervous system is the master controlling system of the body. It is designed to constantly and rapidly adjust and respond to stimuli the body receives. It includes the brain, cranial nerves, spinal cord, and associated peripheral nerves.

4. Properties of Neurons 1. Excitability (irritability): ability to respond to environmental changes or stimuli. 2. Conductivity: respond to stimuli by initiating electrical signals that travel quickly to other cells at distant locations. 3. Secretion: Upon arrival of the impulse at a distant location the neuron usually secretes a chemical neurotransmitter at a synapse that crosses the synaptic gap and stimulates the next cell.

5. Functional Classes of Neurons Sensory (afferent) neurons – afferent neurons are specialized to detect stimuli and transmit the information to CNS. They begin in any organ in the body, but end in the brain or spinal cord. Sensory (afferent) neurons – afferent neurons are specialized to detect stimuli and transmit the information to CNS. They begin in any organ in the body, but end in the brain or spinal cord. Interneuron (association neurons): lie entirely in the CNS. They receive signals from many different neurons and perform an integrative function “decision making” to respond to the different stimuli. Interneuron (association neurons): lie entirely in the CNS. They receive signals from many different neurons and perform an integrative function “decision making” to respond to the different stimuli. Motor (efferent) neurons – efferent neurons transmit the appropriate response from the interneuron to an end organ (muscle and gland cells) to carry out the body’s response to the stimuli. Motor (efferent) neurons – efferent neurons transmit the appropriate response from the interneuron to an end organ (muscle and gland cells) to carry out the body’s response to the stimuli.

6. Functional Classification of Neurons Based on the direction of conduction Based on the direction of conduction Sensory or afferent conduct toward the CNS Sensory or afferent conduct toward the CNS Motor or efferent conduct away from the CNS Motor or efferent conduct away from the CNS Interneuron interposed between sensory and motor Interneuron interposed between sensory and motor

7. Organization of the Nervous System Two main divisions: The Central Nervous System (CNS) The Central Nervous System (CNS) - Consists of the brain and spinal cord with tracts and nuclei Nucleus = a collection of nerve cell bodies in the CNS. Tract = bundle of nerve fibers within the CNS The Peripheral Nervous System (PNS) The Peripheral Nervous System (PNS) -Consists of ganglia, cranial nerves, spinal nerves and peripheral receptors Ganglia = a collection of nerve cell bodies in the PNS Nerve = bundle of nerve fibers in the PNS

8. CNS = brain + spinal cord

9. Peripheral Nervous System (PNS) Composed of cranial nerves and spinal nerves and their branches, ganglia and sensory receptors. Composed of cranial nerves and spinal nerves and their branches, ganglia and sensory receptors. PNS is subdivided into sensory and motor divisions: PNS is subdivided into sensory and motor divisions: somatic nervous system (SNS) somatic nervous system (SNS) autonomic nervous system (ANS) and the autonomic nervous system (ANS) and the enteric nervous system (ENS) enteric nervous system (ENS)

10. Sensory or Afferent Division Somatic sensory = senses touch, pressure, pain, temperature, vibration and proprioception in skin, body wall and limbs. Somatic sensory = senses touch, pressure, pain, temperature, vibration and proprioception in skin, body wall and limbs. Visceral sensory = Autonomic sensory division- senses stretch, pain, temperature, chemical changes and irritation in viscera; nausea and hunger. Visceral sensory = Autonomic sensory division- senses stretch, pain, temperature, chemical changes and irritation in viscera; nausea and hunger.

11. Motor or Efferent Division Somatic motor Somatic motor -motor control to all skeletal muscles except pharyngeal muscles. Visceral Motor = Autonomic Nervous System – Four “F’s” Visceral Motor = Autonomic Nervous System – Four “F’s” -Sensory receptors convey information from visceral organs (e.g. heart, lungs, intestines, etc.) to the CNS for integration and interpretation. A motor response is initiated that conducts impulses from CNS to smooth muscle, cardiac muscle and/or glands for appropriate response

12. Autonomic Nervous System Two divisions of ANS (4 “F’s”) Two divisions of ANS (4 “F’s”) Sympathetic division – Fight or Flight Sympathetic division – Fight or Flight Parasympathetic division – Food or Sex Parasympathetic division – Food or Sex

13. CNS/PNS summary

14. Neurons Nerve cell proper Cell body (soma) Dendrites - TO Axons -FROM

15. Structural Classification of Neurons Neurons may be: Multipolar, Bipolar or Unipolar Neurons may be: Multipolar, Bipolar or Unipolar Determined by the number of processes attached to the cell body Determined by the number of processes attached to the cell body

16. Neurons Most (99%) neurons in the body are multipolar. Most (99%) neurons in the body are multipolar. Bipolar neurons are rare and occur in special sense organs of ear, nose and eye. Bipolar neurons are rare and occur in special sense organs of ear, nose and eye. Unipolar neurons begin as bipolar but processes fuse into one. They are primarily sensory neurons. Unipolar neurons begin as bipolar but processes fuse into one. They are primarily sensory neurons.

17. Neuroglia cells Found in CNS and PNS Found in CNS and PNS Perform a supporting function for neurons Perform a supporting function for neurons CNS PNS CNS PNS Oligodendroglialcytes Schwann cells Oligodendroglialcytes Schwann cells Astrocytes Satellite cells Astrocytes Satellite cells Ependymal cells Ependymal cells Microglia Microglia

19. Oligodendrogliocytes -CNS Form myelin sheath in CNS Form myelin sheath in CNS Fewer branches than astrocytes Fewer branches than astrocytes

20. Myelin Insulating layer around a nerve Insulating layer around a nerve Formed by oligodendrocytes in CNS and Schwann cells in PNS Formed by oligodendrocytes in CNS and Schwann cells in PNS Composed of a lipoprotein with phospholipids, glycolipids and cholesterol. Composed of a lipoprotein with phospholipids, glycolipids and cholesterol. Myelination is process of myelin formation Myelination is process of myelin formation

21. Astrocytes - CNS Star shaped Blood brain barrier Most numerous

22. Ependymal cells - CNS Epithelial cells that line ventricles and central cavities of brain and spinal cord-secrete CSF Epithelial cells that line ventricles and central cavities of brain and spinal cord-secrete CSF Ciliated to circulate CSF Ciliated to circulate CSF

23. Microglia - CNS Thorny bushes in appearance and the smallest glia Thorny bushes in appearance and the smallest glia Phagocytic function in CNS Phagocytic function in CNS Originate from monocytes Originate from monocytes

24. Schwann cells- PNS Form myelin sheath around peripheral axons Form myelin sheath around peripheral axons Look like jelly roll with neurolemma cover Look like jelly roll with neurolemma cover Node of Ranvier separate each Schwann cell Node of Ranvier separate each Schwann cell

26. Myelin and Unmyelinated fibers

27. Satellite cells -PNS Surround neuron cell bodies within ganglia Surround neuron cell bodies within ganglia

28. Synaptic ending Synapse – site where two nerves communicate with each other. Synapse – site where two nerves communicate with each other. Presynaptic neuron – neuron that is conducting information toward the next neuron Presynaptic neuron – neuron that is conducting information toward the next neuron Postsynaptic neuron – transmits information away from synapse Postsynaptic neuron – transmits information away from synapse Most synaptic communication is via chemical messengers (e.g. acetylcholine, serotonin, norepinephrine, dopamine, endorphins, GABA, glycine, glutamic acid, etc.) Most synaptic communication is via chemical messengers (e.g. acetylcholine, serotonin, norepinephrine, dopamine, endorphins, GABA, glycine, glutamic acid, etc.)

29. Synaptic terminals

30. Types of synapses Axodendritic = axon to dendrite Axodendritic = axon to dendrite Axosomatic = axon to cell body Axosomatic = axon to cell body Axoaxonic = axon to axon Axoaxonic = axon to axon Dendrodendritic = dendrite to dendrite Dendrodendritic = dendrite to dendrite Dendrosomatic = dendrite to cell body Dendrosomatic = dendrite to cell body

31. Types of Neuronal Circuits