DEVELOPMENT OF CNS - PowerPoint PPT Presentation

About This Presentation
Title:

DEVELOPMENT OF CNS

Description:

DEVELOPMENT OF CNS Lecture 1 Formation of neural tube At the beginning of the third week of development, the ectodermal germ layer has the shape of a disc that is ... – PowerPoint PPT presentation

Number of Views:73
Avg rating:3.0/5.0
Slides: 38
Provided by: daactarbha
Category:

less

Transcript and Presenter's Notes

Title: DEVELOPMENT OF CNS


1
(No Transcript)
2
DEVELOPMENT OF CNS
  • Lecture 1

3
Formation of neural tube
  • At the beginning of the third week of
    development, the ectodermal germ layer has the
    shape of a disc that is broader in the cephalic
    than the caudal region .

4
  • Appearance of the notochord and prechordal
    mesoderm induces the overlying ectoderm to
    thicken and form the neural plate .

5
  • Appearance of the notochord and prechordal
    mesoderm induces the overlying ectoderm to
    thicken and form the neural plate .

6
(No Transcript)
7
By the end of the third week, the lateral edges
of the neural plate become more elevated to form
neural folds, and the depressed mid region forms
the neural groove
8
  • Gradually, the neural folds approach each other
    in the midline, where they fuse .

9
  • cells along the margin of the neural groove is
    called the neural crest
  • develop into sensory and sympathetic neurons and
    schwann cells

10
  • Fusion begins in the cervical region and proceeds
    cranially and caudally . As a result, the neural
    tube is formed. Until fusion is complete, the
    cephalic and caudal ends of the neural tube
    communicate with the amniotic cavity by way of
    the cranial and caudal neuropores, respectively

11
(No Transcript)
12
  • Neurulation is then complete, and the central
    nervous system is represented by a closed tubular
    structure with a narrow caudal portion, the
    spinal cord, and a much broader cephalic portion
    characterized by a number of dilations,
  • the brain vesicles

13
(No Transcript)
14
  • The wall of a recently closed neural tube
    consists of neuroepithelial cells.
  • These cells extend over the entire thickness of
    the wall and form a thick pseudostratified
    epithelium . Junctional complexes at the lumen
    connect them. During the neural groove stage and
    immediately after closure of the tube,they divide
    rapidly, producing more and more neuroepithelial
    cells. Collectively they constitute the
    neuroepithelial layer or neuroepithelium.

15
(No Transcript)
16
(No Transcript)
17
  • Once the neural tube closes, neuroepithelial
    cells begin to give rise to another cell type
    characterized by a large round nucleus with pale
    nucleoplasm and a dark-staining nucleolus. These
    are the primitive nerve cells, or neuroblasts.
    They form the mantle layer, a zone around the
    neuroepithelial layer . The mantle layer later
    forms the gray matter of the spinal
  • cord.

18
  • The outermost layer of the spinal cord, the
    marginal layer, contains nerve fibers emerging
    from neuroblasts in the mantle layer. As a result
    of myelination of nerve fibers, this layer takes
    on a white appearance and therefore is called the
    white matter of the spinal cord

19
(No Transcript)
20
(No Transcript)
21
BASAL, ALAR, ROOF, AND FLOOR PLATES
  • As a result of continuous addition of neuroblasts
    to the mantle layer, each side of the neural tube
    shows a ventral and a dorsal thickening.

22
  • The ventral thickenings, the basal plates, which
    contain ventral motor horn cells, form the motor
    areas of the spinal cord the dorsal thickenings,
    the alar plates, form the sensory areas .

23
  • A longitudinal groove, the sulcus limitans, marks
    the boundary between the two.

24
  • The dorsal and ventral midline portions of the
    neural tube, known as the roof and .floor plates,
    respectively, do not contain neuroblasts they
    serve primarily as pathways for nerve Fibers
    crossing from
  • one side to the other.

25
  • In addition to the ventral motor horn and the
    dorsal sensory horn, a group of neurons
    accumulates between the two areas and forms a
    small intermediate horn . This horn, containing
    neurons of the sympathetic portion of the
    autonomic nervous system, is present only at
    thoracic (T1T12) and upper
  • lumbar levels (L2 or L3) of the spinal cord.

26
HISTOLOGICAL DIFFERENTIATION
  • Nerve Cells
  • Neuroblasts, or primitive nerve cells, arise
    exclusively by division of the neuroepithelial
    cells. further development becomes the adult
    nerve cell or neuron.

27
  • Axons of neurons in the basal plate break through
    the marginal zone and become visible on the
    ventral aspect of the cord. Known collectively as
    the ventral motor root of the spinal nerve, they
    conduct motor impulses from the spinal cord to
    the muscles .

28
  • Axons of neurons in the dorsal sensory horn (alar
    plate) behave differently from those in the
    ventral horn. They penetrate into the marginal
    layer of the cord, where they ascend to either
    higher or lower levels to form association
    neurons.

29
(No Transcript)
30
(No Transcript)
31
  • Glial Cells
  • The majority of primitive supporting cells,
    the gliablasts, are formed by neuroepithelial
    cells and migrate from the neuroepithelial layer
    to the mantle and marginal layers. In the mantle
    layer, they differentiate into protoplasmic
    astrocytes and .fibrillar astrocytes
  • Another type of supporting cell possibly derived
    from gliablasts is the oligodendroglial cell.
    This cell, which is found primarily in the
    marginal layer, forms myelin sheaths around the
    ascending and descending axons in the marginal
    layer.

32
  • In the second half of development, a third type
    of supporting cell, the microglial cell, appears
    in the CNS.
  • Neural Crest Cells
  • During elevation of the neural plate, a group
    of cells appears along each edge (the crest) of
    the neural folds Crest cells migrate laterally
    and give rise to sensory ganglia (dorsal root
    ganglia) of the spinal nerves and other cell
    types

33
Spinal Nerves
  • Motor nerve fibers begin to appear in the fourth
    week, arising from nerve cells in the basal
    plates (ventral horns) of the spinal cord. These
    fibers collect into bundles known as ventral
    nerve roots and Dorsal nerve roots form as
    collections of fibers originating from cells in
    dorsal root ganglia (spinal ganglia).

34
Nerve cells in anterior gray column
  • nerve cells are large multipolar known as alpha
    which innervate skeletal muscle and gamma
    efferents which innervate intrafusal fibers of
    neuromucula spindles.

35
Nerve cells in posterior gray column
  • At apex-substantia gelatinosa
  • Nucleus prorius
  • Nucleus dorsalis-c8-L4

36
  • The dorsal region of the gray matter, called the
    dorsal or posterior horn, is associated with the
    incoming (afferent) dorsal root, and is thus
    related to sensory functions.
  • The cell body of these sensory fibers is
    located in the
  • dorsal root ganglion .
  • The dorsal horn is quite prominent in this
    region because of the very large sensory input
    to this segment of the cord from the upper limb,
    particularly from the hand.

37
  • The ventral gray matter, called the ventral or
    anterior horn, is the motor portion of the gray
    matter. The ventral horn has the large motor
    neurons, the anterior horn cells,which are
    efferent to the muscles . These neurons, because
    of their location in the spinal cord, which is
    below the brain, are also known as lower motor
    neurons.
Write a Comment
User Comments (0)
About PowerShow.com