2. Introduction
Millions of sensory neurons are delivering information to the CNS all the time
Millions of motor neurons are causing the body to respond in a variety of ways
Sensory and motor neurons travel by different tracts within the spinal cord 2

3. Organization and Patterns of Spinal Cord Tracts
Communication involves sensory and motor tracts
Ascending tract
Sensory (delivers information to the brain)
Descending tract
Motor (delivers information to the periphery)
All tracts involve the spinal cord and the brain 3

4. Organization and Patterns of Spinal Cord Tracts
Naming a tract often involves its origin and destination
Spinocerebellar tract
Origin is spinal cord and destination is cerebellum
Spinothalamic tract
Origin is spinal cord and destination is the thalamus 4

5. Organization and Patterns of Spinal Cord Tracts
Naming a tract often involves its origin and destination
Corticospinal tract
Origin is cerebral cortex and destination is spinal cord
Vestibulospinal tract
Origin is vestibular nuclei and destination is spinal cord 5

6. Sensory Tracts There are three major sensory tracts
The posterior column
The spinothalamic tract
The spinocerebellar tract
All three of these tracts are also called somatosensory tracts 6

7. Posterior spinocerebellar tract
Figure 15.1 A Cross-Sectional View Indicating the Locations of the Major Ascending (Sensory) Tracts in the Spinal Cord
Fasciculus gracilis
Posterior columns
Fasciculus cuneatus
Dorsal root
Dorsal root ganglion
Posterior spinocerebellar tract
Anterior spinocerebellar tract
Ventral root
Lateral spinothalamic tract
Anterior spinothalamic tract
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8. Sensory Tracts Posterior Column consists of: Fasciculus gracilis
Transmits information to the cerebrum coming from areas inferior to T6
Fasciculus cuneatus
Transmits information to the cerebrum coming from areas superior to T6 8

9. Sensory Tracts Posterior Columns (dorsal columns)
Transmits information such as:
Proprioception
Fine touch
Pressure
Vibration sensations 9

10. © 2015 Pearson Education, Inc.
Figure 15.3a The Posterior Column, Spinothalamic, and Spinocerebellar Sensory Tracts
Posterior Columns
Ventral nuclei in thalamus
Midbrain
Medial lemniscus
Nucleus gracilis and nucleus cuneatus
Medulla oblongata
Fasciculus cuneatus and fasciculus gracilis
Dorsal root ganglion
Fine-touch, vibration, pressure, and proprioception sensations from right side of body a
The posterior columns deliver fine-touch, vibration, and proprioception information to the primary sensory cortex of the cerebral hemisphere on the opposite side of the body. The crossover occurs in the medulla, after a synapse in the nucleus gracilis or nucleus cuneatus.
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11. Sensory Tracts The Spinothalamic Tract Transmits information such as:
Pain
Temperature
Crude sensations of touch and pressure 11

12. Anterior Spinothalamic Tract
Figure 15.3b The Posterior Column, Spinothalamic, and Spinocerebellar Sensory Tracts
Anterior Spinothalamic Tract
A Sensory Homunculus
A sensory homunculus (“little human”) is a functional map of the primary sensory cortex. The proportions are very different from those of the individual because the area of sensory cortex devoted to a particular body region is proportional to the number of sensory receptors it contains.
Midbrain
Medulla oblongata
Anterior spinothalamic tract
KEY
Axon of first-order neuron
Second-order neuron
Crude touch and pressure sensations from right side of body
Third-order neuron b
The anterior spinothalamic tract carries crude touch and pressure sensations to the primary sensory cortex on the opposite side of the body. The crossover occurs in the spinal cord at the level of entry.
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13. Lateral Spinothalamic Tract
Figure 15.3c The Posterior Column, Spinothalamic, and Spinocerebellar Sensory Tracts
Lateral Spinothalamic Tract
Midbrain
Medulla oblongata
Lateral spinothalamic tract
Spinal cord
Axon of first-order neuron
Second-order neuron
Pain and temperature sensations from right side of body
Third-order neuron c
The lateral spinothalamic tract carries sensations of pain
and temperature to the primary sensory cortex on the opposite side of the body. The crossover occurs in the spinal cord, at the level of entry.
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14. Sensory Tracts The Spinocerebellar Tracts
Transmits information such as:
Proprioception concerning muscles, tendons, and joints 14

15. Spinocerebellar Tracts
Figure 15.3d The Posterior Column, Spinothalamic, and Spinocerebellar Sensory Tracts
Spinocerebellar Tracts
PONS
Cerebellum
Medulla oblongata
Spinocerebellar tracts
Anterior spinocerebellar tract
Posterior spinocerebellar tract
Spinal cord
Proprioceptive input from Golgi tendon organs, muscle spindles, and joint capsules d
The spinocerebellar tracts carry proprioceptive information to the cerebellum. (Only one tract is detailed on each side, although each side has both tracts.)
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16. Sensory Tracts
The three major sensory tracts involve chains of neurons
First-order neuron
Delivers sensations from the periphery to the CNS
Second-order neuron
Decussates to the contralateral side and ascends to the thalamus
Third-order neuron
Transmits information from the thalamus to the cerebral cortex 16

17. Figure 15.2 Organization of Spinal Cord Tracts (1 of 4)
First-Order, Second-Order, and Third-Order Neurons in Ascending Tracts
Sensory tracts that deliver somatic sensory information to the sensory cortex of the cerebral or cerebellar hemispheres involve a chain of neurons.
Sensory homunculus on primary sensory
cortex of left cerebral hemisphere
Cerebral
Sensory
Cortex
KEY
First-order neuron
Second-order neuron
Third-order neuron
Thalamus 3
Third-Order Neuron
In tracts ending at the cerebral cortex, the second-order neuron synapses on a
third-order neuron in the thalamus. The axon
of the third-order neuron carries the sensory information from the thalamus to the appropriate sensory area of the cerebral cortex.
In most cases, the axon
of either the first-order or second-order neuron crosses over to the opposite side of
the spinal cord or brain stem
as it ascends. As a result of
this crossover, or decussation, sensory information from
the left side of the body is delivered to the right side of the brain, and vice versa.
Brain stem 2
Second-Order Neuron
The axon of the first-order neuron synapses on a second-order neuron. The second-order neuron’s cell body may be located in either the spinal cord or the brain stem.
Sensory tract in spinal cord 1
First-Order Neuron
Dorsal root ganglion
A first-order neuron is the sensory neuron that delivers the sensations to the CNS; its cell body is in a dorsal root ganglion or a cranial nerve ganglion.
Somatic sensations from right side of the body
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18. Sensory Tracts
Neurons in the sensory tracts are arranged according to three anatomical principles
Sensory modality
Medial–lateral rule
Somatotropic 18

19. Sensory Tracts Sensory Modality Medial–Lateral Rule Somatotopic
Fine touch sensations are carried in one sensory tract
Medial–Lateral Rule
Sensory neurons that enter a low level of the spinal cord are more medial within the spinal cord
Sensory neurons that enter at a higher level of the spinal cord are more lateral within the spinal cord
Somatotopic
Ascending tracts are arranged according to the site of origin 19

20. Figure 15.2 Organization of Spinal Cord Tracts (2 of 4)
Neuron Arrangement within Sensory Tracts
Neurons within the sensory tracts are not randomly arranged. Rather they are segregated, or arranged according to at least three anatomical principles:
MEDIAL
LATERAL 2
Medial-lateral rule
Most sensory nerves entering the spinal cord at more inferior levels travel more medially within a sensory tract than sensory nerves entering the cord at a more superior level. For instance, a sensory nerve that enters the cord at T11 (11th) thoracic spinal nerve) is located more medially within a sensory
tract than a nerve that enters at C4.
Lower limb
Upper limb
Hip
Trunk 1
Sensory modality arrangement
Sensory fibers are arranged within the spinal cord according to the type of sensory information carried by the individual neurons. In other words, information dealing with fine
touch will be carried within one sensory tract, while information dealing with pain will be carried within another.
Sensory fibers carrying fine touch, pressure, proprioception, and vibration
Sensory fibers carrying pain and temperature 3
Somatotopic arrangement
Ascending sensory fibers are arranged within individual tracts according to their site of origin within the body. Sensory fibers coming from a particular region of the body, such as the upper limb, form a tract containing organized bundles of sensory fibers from the hand, wrist, forearm, and arm.
Sensory fibers carrying crude touch
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21. Motor Tracts Motor Tracts
CNS transmits motor commands in response to sensory information
These are descending tracts
Motor commands are delivered by the:
Somatic nervous system (SNS)
Directs contraction of skeletal muscles
Autonomic nervous system (ANS)
Directs the activity of glands, smooth muscles, and cardiac muscle 21

22. Figure 15.4a Motor Tracts in the CNS and PNS
Upper-motor neurons in primary motor cortex
BRAIN
Somatic motor nuclei of brain stem
Skeletal muscle
SPINAL CORD
Lower-motor neurons
Somatic motor nuclei of spinal cord
Skeletal muscle a
In the somatic nervous system (SNS), an upper-motor neuron in the CNS controls a lower-motor neuron in the brain stem or spinal cord. The axon of the lower-motor neuron has direct control over skeletal muscle fibers. Stimulation of the lower-motor neuron always has an excitatory effect on the skeletal muscle fibers.
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23. Figure 15.4b Motor Tracts in the CNS and PNS
Visceral motor nuclei in hypothalamus
BRAIN
Preganglionic neuron
Visceral Effectors
Smooth muscle
Autonomic nuclei in brain stem
Autonomic ganglia
Glands
Ganglionic neurons
Cardiac muscle
SPINAL CORD
Adipocytes
Autonomic nuclei in spinal cord
Preganglionic neuron b
In the autonomic nervous system (ANS), the axon of a preganglionic neuron in the CNS controls ganglionic neurons in the periphery. Stimulation of the ganglionic neurons may lead to excitation or inhibition of the visceral effector innervated.
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24. Motor Tracts There are two principal motor tracts
Corticospinal tract: Conscious control of skeletal muscles
Corticobulbar, lateral corticospinal, and anterior corticospinal tracts
Subconscious tract: Subconscious regulation of balance, muscle tone, eye, hand, and upper limb position
Vestibulospinal, tectospinal, reticulospinal, and rubrospinal tracts 24

25. Motor Tracts The Corticospinal Tracts
Consists of three pairs of descending tracts
Corticobulbar tracts
Conscious control over eye, jaw, and face muscles
Lateral corticospinal tracts
Conscious control over skeletal muscles
Anterior corticospinal tracts 25

26. Figure 15.5 The Corticospinal Tracts
Motor homunculus on primary motor cortex of left cerebral
hemisphere
KEY
Cerebral
Sensory
Cortex
Axon of upper-motor neuron
Lower-motor neuron
Corticobulbar tract
To skeletal muscles
Mesencephalon
Cerebral peduncle
Motor nuclei
of cranial nerves
To skeletal muscles
Medulla oblongata
Decussation of pyramids
Pyramids
Lateral corticospinal tract
Anterior corticospinal tract
To skeletal muscles
Spinal cord
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27. Figure 15.2 Organization of Spinal Cord Tracts (2 of 4)
Neuron Arrangement within Sensory Tracts
Neurons within the sensory tracts are not randomly arranged. Rather they are segregated, or arranged according to at least three anatomical principles:
MEDIAL
LATERAL 2
Medial-lateral rule
Most sensory nerves entering the spinal cord at more inferior levels travel more medially within a sensory tract than sensory nerves entering the cord at a more superior level. For instance, a sensory nerve that enters the cord at T11 (11th) thoracic spinal nerve) is located more medially within a sensory
tract than a nerve that enters at C4.
Lower limb
Upper limb
Hip
Trunk 1
Sensory modality arrangement
Sensory fibers are arranged within the spinal cord according to the type of sensory information carried by the individual neurons. In other words, information dealing with fine
touch will be carried within one sensory tract, while information dealing with pain will be carried within another.
Sensory fibers carrying fine touch, pressure, proprioception, and vibration
Sensory fibers carrying pain and temperature 3
Somatotopic arrangement
Ascending sensory fibers are arranged within individual tracts according to their site of origin within the body. Sensory fibers coming from a particular region of the body, such as the upper limb, form a tract containing organized bundles of sensory fibers from the hand, wrist, forearm, and arm.
Sensory fibers carrying crude touch
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28. Motor Tracts The Subconscious Motor Tracts
Consists of four tracts involved in monitoring the subconscious motor control
Vestibulospinal tracts
Tectospinal tracts
Reticulospinal tracts
Rubrospinal tracts 28

29. Motor Tracts The Subconscious Motor Tracts Vestibulospinal tracts
Send information from the inner ear to monitor position of the head
Vestibular nuclei respond by altering muscle tone, neck muscle contraction, and limbs for posture and balance 29

30. Motor Tracts The Subconscious Motor Tracts Tectospinal tracts
Send information to the head, neck, and upper limbs in response to bright lights and sudden movements and loud noises
The tectum area consists of superior and inferior colliculi
Superior colliculi: receives visual information
Inferior colliculi: receives auditory information 30

31. Motor Tracts The Subconscious Motor Tracts Reticulospinal tracts
Send information to cause eye movements and activate respiratory muscles
Rubrospinal tracts
Send information to the flexor and extensor muscles 31

32. Figure 15.6 Nuclei of Subconscious Motor Pathways
Motor cortex
Basal Nuclei
Thalamus
Caudate nucleus
Superior colliculus
Putamen
Globus pallidus
Inferior colliculus
Red nucleus
Cerebellar nuclei
Tectum
Reticular formation
Pons
Vestibular nucleus
Medulla oblongata
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33. Figure 15.2 Organization of Spinal Cord Tracts (4 of 4)
Descending Motor Tracts
Conscious and subconscious motor commands control skeletal muscles through descending motor tracts within the spinal cord.
Motor Tracts Carrying Subconscious Motor Commands
Motor Tracts Carrying Conscious Motor Commands
The rubrospinal tract automatically adjusts upper limb position and muscle tone during voluntary movements.
The anterior corticospinal tract contains axons that do not cross over (decussate) in the brain stem.
The reticulospinal tract originates in the reticular formation, a diffuse network of neurons in the brain stem. The functions of the tract vary depending on which area of the reticular formation is stimulated.
The lateral corticospinal tract contains the motor fibers that decussate within the brain stem.
The tectospinal tract controls reflexive changes in position in response to auditory or visual stimuli.
The vestibulospinal tract carries motor commands that reflexively control posture and balance.
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34. Levels of Somatic Motor Control
Somatic motor control involves:
Cerebral cortex
Basal nuclei
Cerebellum
Hypothalamus
Pons
Medulla oblongata
Brain stem and spinal cord
Thalamus 34

35. Figure 15.7a Somatic Motor Control
BASAL NUCLEI
CEREBRAL CORTEX
Modify voluntary and reflexive motor patterns at the subconscious level
Plans and initiates voluntary motor activity
HYPOTHALAMUS
THALAMUS AND MESENCEPHALON
Controls stereotyped motor patterns related to eating, drinking, and sexual activity; modifies respiratory reflexes
Control reflexes in response to visual and auditory stimuli
PONS AND SUPERIOR MEDULLA OBLONGATA
CEREBELLUM
Coordinates complex motor patterns
Control balance reflexes and more-complex respiratory reflexes
BRAIN STEM AND SPINAL CORD
INFERIOR MEDULLA OBLONGATA
Control simple cranial and spinal reflexes
Controls basic respiratory reflexes a
Somatic motor control involves a series of levels, with simple spinal and cranial reflexes at the bottom and complex voluntary motor patterns at the top.
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36. Levels of Somatic Motor Control
Summary of Somatic Motor Control
Cerebral cortex initiates voluntary movement
Information goes to the basal nuclei and cerebellum
These structures modify and coordinate the movements so they are performed in a smooth manner 36

37. Figure 15.7b Somatic Motor Control
Motor association areas
Cerebral cortex
Decision in frontal lobes
Basal nuclei
Cerebellum b
The planning stage: When a conscious decision is made to perform a specific movement, information is relayed from the frontal lobes to motor association areas. These areas in turn relay the information to the cerebellum and basal nuclei.
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38. Levels of Somatic Motor Control
Summary of Somatic Motor Control
Information goes from:
The basal nuclei and cerebellum constantly monitor position and muscle tone
Information goes back to:
The cerebral cortex
Reason:
Constantly monitor position and muscle tone 38