2. Spinal Cord
• Runs through the vertebral canal
• Extends from foramen magnum to second
lumbar vertebra
• Regions
– Cervical
– Thoracic
– Lumbar
– Sacral
– Coccygeal
• Gives rise to 31 pairs of spinal nerves
– All are mixed nerves
• Not uniform in diameter
– Cervical enlargement: supplies upper limbs
– Lumbar enlargement: supplies lower limbs
• Conus medullaris- tapered inferior end
– Ends between L1 and L2
• Cauda equina - origin of spinal nerves
extending inferiorly from conus medullaris.
Brought to you by
3. Meninges
• Connective tissue membranes
– Dura mater: outermost layer; continuous with
epineurium of the spinal nerves
– Arachnoid mater: thin and wispy
– Pia mater: bound tightly to surface
• Forms the filum terminale
– anchors spinal cord to coccyx
• Forms the denticulate ligaments that attach the
spinal cord to the dura
• Spaces
– Epidural: external to the dura
• Anesthestics injected here
• Fat-fill
– Subdural space: serous fluid
– Subarachnoid: between pia and arachnoid
• Filled with CSF
Brought to you by
4. Cross Section
of Spinal Cord
• Anterior median fissure and posterior
median sulcus
– deep clefts partially separating left and
right halves
• Gray matter: neuron cell bodies,
dendrites, axons
– Divided into horns
• Posterior (dorsal) horn
• Anterior (ventral) horn
• Lateral horn
• White matter
– Myelinated axons
– Divided into three columns (funiculi)
• Ventral
• Dorsal
• lateral
– Each of these divided into sensory or
motor tracts
Brought to you by
5. Cross section of Spinal Cord
• Commissures: connections between left
and right halves
– Gray with central canal in the center
– White
• Roots
– Spinal nerves arise as rootlets then
combine to form dorsal and ventral
roots
– Dorsal and ventral roots merge
laterally and form the spinal nerve
Brought to you by
6. Organization of Spinal Cord Gray
Matter
• Recall, it is divided into horns
– Dorsal, lateral (only in thoracic region), and ventral
• Dorsal half – sensory roots and ganglia
• Ventral half – motor roots
• Based on the type of neurons/cell bodies located in each
horn, it is specialized further into 4 regions
– Somatic sensory (SS) - axons of somatic sensory neurons
– Visceral sensory (VS) - neurons of visceral sensory neur.
– Visceral motor (VM) - cell bodies of visceral motor neurons
– Somatic motor (SM) - cell bodies of somatic motor neurons
Brought to you by
8. White Matter in the Spinal Cord
• Divided into three funiculi (columns) – posterior, lateral, and
anterior
– Columns contain 3 different types of fibers (Ascend., Descend., Trans.)
• Fibers run in three directions
– Ascending fibers - compose the sensory tracts
– Descending fibers - compose the motor tracts
– Commissural (transverse) fibers - connect opposite sides of cord
Brought to you by
9. White Matter
Fiber Tract Generalizations
• Pathways decussate (most)
• Most consist of a chain of two or three
neurons
• Most exhibit somatotopy (precise spatial
relationships)
• All pathways are paired
– one on each side of the spinal cord
Brought to you by
11. Descending (Motor) Pathways
• Descending tracts deliver motor
instructions from the brain to the spinal
cord
• Divided into two groups
– Pyramidal, or corticospinal, tracts
– Indirect pathways, essentially all others
• Motor pathways involve two neurons
– Upper motor neuron (UMN)
– Lower motor neuron (LMN)
• aka ‘anterior horn motor neuron” (also, final
common pathway)
Brought to you by
12. Pyramidal (Corticospinal) Tracts
• Originate in the precentral gyrus of brain (aka, primary motor area)
– I.e., cell body of the UMN located in precentral gyrus
• Pyramidal neuron is the UMN
– Its axon forms the corticospinal tract
• UMN synapses in the anterior horn with LMN
– Some UMN decussate in pyramids = Lateral corticospinal tracts
– Others decussate at other levels of s.c. = Anterior corticospinal tracts
• LMN (anterior horn motor neurons)
– Exits spinal cord via anterior root
– Activates skeletal muscles
• Regulates fast and fine (skilled) movements
Brought to you by
13. Corticospinal
tracts
1. Location of UMN cell
body in cerebral cortex
2. Decussation of UMN
axon in pyramids or at
level of exit of LMN
3. Synapse of UMN and
LMN occurs in anterior
horn of s.c.
4. LMN axon exits via
anterior root
Brought to you by
14. Extrapyramidal Motor Tracts
• Includes all motor pathways not part of the pyramidal system
• Upper motor neuron (UMN) originates in nuclei deep in cerebrum (not in
cerebral cortex)
• UMN does not pass through the pyramids!
• LMN is an anterior horn motor neuron
• This system includes
– Rubrospinal
– Vestibulospinal
– Reticulospinal
– Tectospinal tracts
• Regulate:
– Axial muscles that maintain balance and posture
– Muscles controlling coarse movements of the proximal portions of limbs
– Head, neck, and eye movement
Brought to you by
15. Extrapyramidal
Tract
Note:
1. UMN cell body location
2. UMN axon decussates in pons
3. Synapse between UMN and LMN
occurs in anterior horn of sc
3. LMN exits via ventral root
4. LMN axon stimulates skeletal
muscle
Brought to you by
16. Extrapyramidal (Multineuronal) Pathways
• Reticulospinal tracts – originates at reticular formation of brain;
maintain balance
• Rubrospinal tracts – originate in ‘red nucleus’ of midbrain;
control flexor muscles
• Tectospinal tracts - originate in superior colliculi and mediate
head and eye movements towards visual targets (flash of light)
Brought to you by
17. Main Ascending Pathways
• The central processes of first-order neurons branch diffusely
as they enter the spinal cord and medulla
• Some branches take part in spinal cord reflexes
• Others synapse with second-order neurons in the cord and
medullary nuclei
Brought to you by
18. Three Ascending Pathways
• The nonspecific and specific ascending pathways
send impulses to the sensory cortex
– These pathways are responsible for discriminative touch
(2 pt. discrimination) and conscious proprioception (body
position sense).
• The spinocerebellar tracts send impulses to the
cerebellum and do not contribute to sensory
perception
Brought to you by
19. Nonspecific Ascending Pathway
• Include the lateral and anterior
spinothalamic tracts
• Lateral: transmits impulses
concerned with pain and temp.
to opposite side of brain
• Anterior: transmits impulses
concerned with crude touch and
pressure to opposite side of brain
• 1st order neuron: sensory neuron
• 2nd order neuron: interneurons
of dorsal horn; synapse with 3rd
order neuron in thalamus
• 3rd order neuron: carry impulse
from thalamus to postcentral
gyrus
Brought to you by
20. Specific and Posterior Spinocerebellar Tracts
• Dorsal Column Tract
1. AKA Medial lemniscal pathway
2. Fibers run only in dorsal column
3. Transmit impulses from receptors in
skin and joints
4. Detect discriminative touch and
body position sense =proprioception
• 1st
order neuron - a sensory neuron
• synapses with 2nd
order neuron in
nucleus gracilis and nucleus
cuneatus of medulla
• 2nd
order neuron.- an interneuron
• decussate and ascend to thalamus
where it synapses with 3rd
order
neuron
• 3rd-order (thalamic neurons)
•transmits impulse to somato-
sensory cortex (postcentral gyrus)
Spinocerebellar Tract
• Transmit info. about trunk and lower
limb muscles and tendons to cerebellum
• No conscious sensation Brought to you by
21. Spinal Cord Trauma and Disorders
• Severe damage to ventral root results in flaccid paralysis (limp and unresponsive)
• Skeletal muscles cannot move either voluntarily or involuntarily
• Without stimulation, muscles atrophy.
• When only UMN of primary motor cortex is damaged
• spastic paralysis occurs - muscles affected by persistent spasms and
exaggerated tendon reflexes
• Muscles remain healthy longer but their movements are no longer
subject to voluntary control.
• Muscles commonly become permanently shortened.
• Transection (cross sectioning) at any level results in total motor and
sensory loss in body regions inferior to site of damage.
• If injury in cervical region, all four limbs affected (quadriplegia)
• If injury between T1 and L1, only lower limbs affected (paraplegia)
Brought to you by
22. Spinal Cord Trauma and Disorders
• Spinal shock - transient period of functional loss that follows the injury
• Results in immediate depression of all reflex activity caudal to lesion.
• Bowel and bladder reflexes stop, blood pressure falls, and all muscles
(somatic and visceral) below the injury are paralyzed and insensitive.
• Neural function usually returns within a few hours following injury
• If function does not resume within 48 hrs, paralysis is permanent.
• Amyotrophic Lateral Sclerosis (aka, Lou Gehrig’s disease)
• Progressive destruction of anterior horn motor neurons and fibers of the
pyramidal tracts
• Lose ability to speak, swallow, breathe.
• Death within 5 yrs
• Cause unknown (90%); others have high glutamate levels
• Poliomyelitis
• Virus destroys anterior horn motor neurons
• Victims die from paralysis of respiratory muscles
• Virus enters body in feces-contaminated water (public swimming pools)
Brought to you by
24. Dorsal Column (SC) -Medial Lemniscal (brain stem) System
• 1° sensory function – brings info from
sensory receptors in the periphery all the
way to the 1° somatic sensory cortex.
• Refer to the postcentral gyrus of parietal
lobe!
• Via the SC, brainstem, and thalamus.
• A 3-neuron-circuit (sites of synaptic
contact):
Brought to you by
25. Dorsal Column (SC) -Medial Lemniscal (brain stem) System
i. DRG cells – bipolar (pseudounipolar) neurons receive
info from peripheral sensory receptors and bring it to SC
and bs, where the info is 1st
processed (through dorsal
column). *synapse at relay nucleus in medulla: dorsal
column nucleus.
ii. Axons of these neurons from the dorsal column nucleus
cross over (decussate) here at the medulla and
continue as the medial lemniscus thalamus.
iii. These next thalamic neurons send their axons into the
internal capsule (white mattter underlying the cortex)
synapse at 1° somatic sensory cortex.
Brought to you by
26. Corticospinal Tract
• This pathway serves a 1° motor function –
bringing information down from the
primary motor cortex (where?) all the way
down to skeletal muscle in the periphery
(activating muscle contraction).
• This pathway contains only 1 synapse
(unlike the DCML system, which contains
__ (how many)?
Brought to you by
27. Corticospinal Tract
i. 1° motor cortical neuron (pre-central
gyrus of the frontal lobe) internal
capsule ventral surface of midbrain
pyramids on ventral surface of medulla.
These axons decussate at caudal medulla and
travel in the lateral column of the SC
synapse at motor neurons in the ventral
horn these axons travel to the spinal
nerve (through ventral nerve roots) to
synapse at the muscles. Brought to you by
28. Overview of SC Anatomy –as it relates to these
systems
• Gray matter:
- dorsal (sensory) and ventral (motor) horns.
- intermediate zone – integration of sensory and motor functions
(inter-neurons, reflexes), which serve direct spinal reflexes.
• White matter:
- nerve tracts (myelin)
- dorsal column (contains dorsal column)
- lateral column (contains motor descending axons)
- ventral column (will discuss later).
Many of the CNS slices we will view, such as this next slide, are myelin-
stained – so white mater appears dark.
Central canal – lowest component of ventricular system
Brought to you by
31. This platform has been started by Parveen
Kumar Chadha with the vision that nobody
should suffer the way he has suffered because
of lack and improper healthcare facilities in
India. We need lots of funds manpower etc. to
make this vision a reality please contact us. Join
us as a member for a noble cause.
Brought to you by
32. Our views have increased the mark
of the 20,000
Thank you viewers
Looking forward for franchise,
collaboration, partners. Brought to you by
