1. Chapter 12 The Central Nervous System Part A Shilla Chakrabarty, Ph.D.

2. Central Nervous System (CNS)
CNS consists of the brain and spinal cord
During the course of evolution, cephalization has occurred
Evolutionary development of the rostral (anterior) portion of the CNS
Increased number of neurons in the head
Highest level is reached in the human brain

3. Embryonic Development Of Neural Tube
The neural plate forms from surface ectoderm. 1
Head
Tail
Surface ectoderm
Neural plate
The neural plate invaginates, forming the neural groove, flanked by neural folds. 2
Neural folds
Neural groove
Neural fold cells migrate to form the neural crest, which will form much of the PNS and many other structures. 3
Neural crest
The neural groove becomes the neural tube, which will form CNS structures. 4
Neural tube

4. Embryonic Development Of Neural Tube
Neural plate forms from ectoderm
Neural plate invaginates to form a neural groove and neural folds
Neural groove fuses dorsally to form the neural tube
Neural tube gives rise to the brain and spinal cord (CNS)
Neural crest cells segregate and either move in a lateral direction to form melanocytes in skin (1), or move ventrally to form neurons and glial cells of PNS(2,3)

5. Embryonic Development Of Human Brain
Neural
tube
(b) Primary brain vesicles
Anterior
(rostral)
Posterior
(caudal)
Rhombencephalon
(hindbrain)
Mesencephalon
(midbrain)
Prosencephalon
(forebrain)
Anterior end of the neural tube gives rise to three primary brain vesicles
Prosencephalon—forebrain
Mesencephalon—midbrain
Rhombencephalon—hindbrain

6. Embryonic Development Of Human Brain
Primary vesicles give rise to five secondary brain vesicles
Telencephalon and diencephalon arise from procencephalon
Telencephalon  cerebrum (two hemispheres with cortex, white matter, and basal nuclei)
Diencephalon  thalamus, hypothalamus, epithalamus, and retina
Mesencephalon remains undivided
Mesencephalon  brain stem (midbrain)
Metencephalon and myelencephalon arise from rhombencephalon
Metencephalon  brain stem (pons) and cerebellum
Myelencephalon  brain stem (medulla oblongata)
Central canal of the neural tube enlarges to form fluid-filled ventricles

7. Embryonic Development Of Human Brain

8. Effect of Space Restriction on Brain Development
Metencephalon
Anterior (rostral)
Posterior (caudal)
Mesencephalon
Diencephalon
Midbrain
Cervical
Spinal cord
Flexures
Telencephalon
Myelencephalon
(a) Week 5
Cerebellum
Pons
Medulla oblongata
Cerebral hemisphere
Outline of diencephalon
(b) Week 13
Medulla
oblongata
Cerebral
hemisphere
(c) Week 26
Midbrain flexure and cervical flexure cause forebrain to move toward the brain stem
Cerebral hemispheres grow posteriorly and laterally
Cerebral hemisphere surfaces crease and fold into convolutions

9. Regions and Organization of the CNS
Adult brain regions
Cerebral hemispheres
Diencephalon
Brain stem (midbrain, pons, and medulla)
Cerebellum
Cerebellum
Diencephalon
Cerebral
hemisphere
(d) Birth
Brain stem
• Midbrain
• Pons
• Medulla oblongata

10. Development Of The Human Brain

11. Pattern Of Gray And White Matter In The CNS
Spinal cord
Central cavity surrounded by a gray matter core
External white matter composed of myelinated fiber tracts
Brain
Similar pattern with additional areas of gray matter
Both cerebral hemispheres and cerebellum have outer layer or “bark” of gray matter called a cortex
With descent through brain stem cortex disappears, scattered gray matter nuclei seen within white matter

12. Ventricles of the Brain
Connected to one another and to the central canal of the spinal cord
Lined by ependymal cells
Contain cerebrospinal fluid
Two C-shaped lateral ventricles in the cerebral hemispheres
Third ventricle in the diencephalon
Fourth ventricle in the hindbrain, dorsal to the pons, develops from the lumen of the neural tube

13. Ventricles of the Brain
Contain cerebrospinal fluid
Two C-shaped lateral ventricles in the cerebral hemispheres
Third ventricle in the diencephalon
Fourth ventricle in the hindbrain, dorsal to the pons, develops from the lumen of the neural tube

14. Lateral ventricle Septum pellucidum Anterior horn Posterior horn
Inferior
horn
Interventricular
foramen
Lateral
aperture
Median
aperture
Third ventricle
Inferior horn
Lateral
aperture
Cerebral aqueduct
Fourth ventricle
Central canal
(a) Anterior view
(b) Left lateral view
Figure 12.5

15. Cerebral Hemispheres Surface markings
Ridges (gyri), shallow grooves (sulci), and deep grooves (fissures)
Five lobes
Frontal
Parietal
Temporal
Occipital
Insula
Postcentral
gyrus
Central
sulcus
Precentral
Frontal
lobe
(a)
Parietal lobe
Parieto-occipital sulcus
(on medial surface
of hemisphere)
Lateral sulcus
Transverse cerebral fissure
Occipital lobe
Temporal lobe
Cerebellum
Pons
Medulla oblongata
Spinal cord
Cortex (gray matter)
Fissure
(a deep
sulcus)
Gyrus
Sulcus
White matter
Central
sulcus
(b)
Frontal lobe
Temporal lobe
(pulled down)
Gyri of insula

16. Surface Markings Of The Brain
Central sulcus
Separates the precentral gyrus of the frontal lobe and the postcentral gyrus of the parietal lobe
Longitudinal fissure
Separates the two hemispheres
Transverse cerebral fissure
Separates the cerebrum and the cerebellum

17. Cerebral Hemispheres Surface markings Central sulcus
Separates the precentral gyrus of the frontal lobe and the postcentral gyrus of the parietal lobe
Longitudinal fissure
Separates the two hemispheres
Transverse cerebral fissure
Separates the cerebrum and the cerebellum

18. Cerebral Cortex Thin (2–4 mm) superficial layer of gray matter
40% of the mass of the brain
Site of conscious mind: awareness, sensory perception, voluntary motor initiation, communication, memory storage, understanding
Each hemisphere connects to contralateral side of the body
There is lateralization of cortical function in the hemispheres
Three types of functional areas:
Motor areas—control voluntary movement
Sensory areas—conscious awareness of sensation
Association areas—integrate diverse information
Conscious behavior involves the entire cortex

19. Motor Areas Primary (somatic) motor cortex Premotor cortex
Broca’s area
Frontal eye field
Gustatory cortex
(in insula)
Primary motor cortex
Premotor cortex
Frontal eye field
Working memory
for spatial tasks
Executive area for
task management
Working memory for
object-recall tasks
Broca’s area
(outlined by dashes)
Solving complex,
multitask problems
(a) Lateral view, left cerebral hemisphere
Motor areas
Prefrontal cortex
Sensory areas and related
association areas
Central sulcus
Primary somatosensory
cortex
Somatosensory
association cortex
Somatic
sensation
Taste
Wernicke’s area
Primary visual
Visual
association
area
Vision
Auditory
association area
Primary
auditory cortex
Hearing
Motor association cortex
Primary sensory cortex
Sensory association cortex
Multimodal association cortex

20. Motor Areas: 1. Primary Motor Cortex
Toes
Swallowing
Tongue
Jaw
Primary motor
cortex
(precentral gyrus)
Motor
Motor map in
precentral gyrus
Posterior
Anterior
Large pyramidal cells of the precentral gyri
Long axons  pyramidal (corticospinal) tracts
Allows conscious control of precise, skilled, voluntary movements
Motor homunculi: upside-down caricatures representing the motor innervation of body regions

21. Motor Areas 2. Premotor Cortex 3. Broca’s Area 4. Frontal Eye Field
Anterior to the precentral gyrus
Controls learned, repetitious, or patterned motor skills
Coordinates simultaneous or sequential actions
Involved in the planning of movements that depend on sensory feedback
3. Broca’s Area
Anterior to the inferior region of the premotor area
Present in one hemisphere (usually the left)
A motor speech area that directs muscles of the tongue
Is active as one prepares to speak
4. Frontal Eye Field
Anterior to the premotor cortex and superior to Broca’s area
Controls voluntary eye movements

22. Sensory Areas Primary somatosensory cortex
Somatosensory association cortex
Visual areas
Auditory areas
Olfactory cortex
Gustatory cortex
Visceral sensory area
Vestibular cortex
Gustatory cortex
(in insula)
Primary motor cortex
Premotor cortex
Frontal eye field
Working memory
for spatial tasks
Executive area for
task management
Working memory for
object-recall tasks
Broca’s area
(outlined by dashes)
Solving complex,
multitask problems
(a) Lateral view, left cerebral hemisphere
Motor areas
Prefrontal cortex
Sensory areas and related
association areas
Central sulcus
Primary somatosensory
cortex
Somatosensory
association cortex
Somatic
sensation
Taste
Wernicke’s area
Primary visual
Visual
association
area
Vision
Auditory
association area
Primary
auditory cortex
Hearing
Motor association cortex
Primary sensory cortex
Sensory association cortex
Multimodal association cortex

23. Sensory Areas 2. Somatosensory Association Cortex
Genitals
Intra-
abdominal
Primary somato-
sensory cortex
(postcentral gyrus)
Sensory
Sensory map in
postcentral gyrus
Posterior
Anterior
1. Primary Somatosensory Cortex
In the postcentral gyri
Receives sensory information from the skin, skeletal muscles, and joints
Capable of spatial discrimination: identification of body region being stimulated
2. Somatosensory Association Cortex
Posterior to the primary somatosensory cortex
Integrates sensory input from primary somatosensory cortex
Determines size, texture, and relationship of parts of objects being felt

24. Sensory Areas 3. Visual Areas Primary visual (striate) cortex
Extreme posterior tip of the occipital lobe
Most of it is buried in the calcarine sulcus
Receives visual information from the retinas
Visual association area
Surrounds the primary visual cortex
Uses past visual experiences to interpret visual stimuli (e.g., color, form, and movement)
Complex processing involves entire posterior half of the hemispheres

25. Sensory Areas 4. Auditory Areas 5. Olfactory Cortex
Primary auditory cortex
Superior margin of the temporal lobes
Interprets information from inner ear as pitch, loudness, and location
Auditory association area
Located posterior to the primary auditory cortex
Stores memories of sounds and permits perception of sounds
5. Olfactory Cortex
Medial aspect of temporal lobes (in piriform lobes)
Part of the primitive rhinencephalon, along with the olfactory bulbs and tracts
(Remainder of the rhinencephalon in humans is part of the limbic system)
Region of conscious awareness of odors

26. Sensory Areas 6. Gustatory Cortex 7. Visceral Sensory Area
In the insula
Involved in the perception of taste
7. Visceral Sensory Area
Posterior to gustatory cortex
Conscious perception of visceral sensations, e.g., upset stomach or full bladder
8. Vestibular Cortex
Posterior part of the insula and adjacent parietal cortex
Responsible for conscious awareness of balance (position of the head in space)

27. Sensory areas and related association areas Primary motor cortex
Motor areas
Central sulcus
Sensory areas and related
association areas
Primary motor cortex
Primary somatosensory
cortex
Premotor cortex
Somatic
sensation
Frontal eye field
Somatosensory
association cortex
Broca’s area
(outlined by dashes)
Gustatory cortex
(in insula)
Taste
Prefrontal cortex
Working memory
for spatial tasks
Wernicke’s area
(outlined by dashes)
Executive area for
task management
Working memory for
object-recall tasks
Primary visual
cortex
Visual
association
area
Vision
Solving complex,
multitask problems
Auditory
association area
Hearing
Primary
auditory cortex
(a) Lateral view, left cerebral hemisphere
Primary motor cortex
Motor association cortex
Primary sensory cortex
Sensory association cortex
Multimodal association cortex
Figure 12.8a

28. Primary somatosensory cortex
Cingulate
gyrus
Primary
motor cortex
Premotor cortex
Central sulcus
Corpus
callosum
Primary somatosensory
cortex
Frontal eye field
Parietal lobe
Somatosensory
association cortex
Prefrontal
cortex
Parieto-occipital
sulcus
Occipital
lobe
Processes emotions
related to personal
and social interactions
Visual
association
area
Orbitofrontal
cortex
Olfactory bulb
Olfactory tract
Primary
visual cortex
Fornix
Temporal lobe
Uncus
Calcarine sulcus
Primary
olfactory cortex
Parahippocampal
gyrus
(b) Parasagittal view, right hemisphere
Primary motor cortex
Motor association cortex
Primary sensory cortex
Sensory association cortex
Multimodal association cortex
Figure 12.8b

29. Multimodal Association Areas
Receive inputs from multiple sensory areas
Send outputs to multiple areas, including the premotor cortex
Allow us to give meaning to information received, store it as memory, compare it to previous experience, and decide on action to take
Three parts
Anterior association area (prefrontal cortex)
Posterior association area
Limbic association area

30. Multimodal Association Areas
Anterior Association Area (Prefrontal Cortex)
Most complicated cortical region
Involved with intellect, cognition, recall, and personality
Contains working memory needed for judgment, reasoning, persistence, and conscience
Development depends on feedback from social environment
Posterior Association Area (Prefrontal Cortex)
Large region in temporal, parietal, and occipital lobes
Plays a role in recognizing patterns and faces and localizing us in space
Involved in understanding written and spoken language (Wernicke’s area)

31. Limbic Association Area
Part of the limbic system
Provides emotional impact that helps establish memories