Clinical Correlates From Periphery to Spinal Cord PDF

Summary

This document presents clinical correlates from the periphery to the spinal cord, encompassing various neurological topics. It covers different diseases within the nervous system, such as myasthenia gravis, and details the causes and symptoms.

Full Transcript

Clinical Correlates from periphery
to spinal cord

~

Neuroscience
PHT 5200
Major sites where problems can occur

 Muscle (Clinical Path, ie Muscular Dystrophy)
 Neuromuscular junction
 Peripheral nerves
 Nerve roots
 Motor neuron
 Spinal cord
Extra-axial lesions
Intra-axial lesions
Tracts
Trauma
 select sites
 entire cross-section
Vascular
Definitions
 Motor unit: cell  Lower motor
body, axon, neuron: cell body
neuromuscular and axon
junction, and all the
http://www.baileybio.com/plogger/images/anatomy___physiology/05._powerpoint_-_muscular_system/motor_unit.jpg

skeletal muscle
fibers that it
innervates
 Diseases of chemical transmission at the
NM junction
Muscles can't contract

 Myasthenia gravis Postsynaptic
auto-immune disorder
antibodies produced against
nicotinic acetylcholine receptors
on the muscle
weakness affects cranial muscles
as well as limbs
manifestations vary from day to
day (NOT TYPICAL of other NM
diseases)
dive bomber response 2
temporarily reversed by drugs that
inhibit acetylcholinesterase
i
-keep
https://www.intechopen.com/chapters/43488

"breaks down

Ach in was
 Diseases of chemical transmission
at the NM junction
 Myasthenia gravis
clinical note - MSR’s typically https://encrypted-tbn0.gstatic.com/images?q=tbn:ANd9GcRYyzzVBmjxR9-Sw085cb-DteWrY3gKI6KJddlpN-HFT-4J3MmaY7DFvMkA

not affected, and nerve
conduction studies are
reasonably normal
Why?
What sensory deficits would be
found?
sensory deficits
No be we are

on
& the nerve is
the muscle
normal
Diseases of chemical transmission
at the NM junction
 Lambert-Eaton Presynaptic
antibodies to voltage
gated CA++ channels
presynaptic problem https://www.youtube.com/
watch?app=desktop&v=_aT
r58i5t3U
Weakness
repetitive stimulation
builds a response from
small to large (opposite of
enter
MG) more calcium can

NMS
present with some lung
cancer patients and a few
others

https://www.intechopen.com/chapters/43488
 Diseases of the peripheral nerve
 Nerve injuries - Seddon’s
classification system:
neuropraxia
 temporary block with preservation of the
axon
 Full recovery
axonotmesis
 disintegration and Wallerian
degeneration of distal axon
 endoneurial sheath is preserved
 axon regeneration is possible
neurotmesis
 entire continuity of the nerve trunk is
lost
 Recovery is less likely
What pattern of sensory loss would you
https://x.com/OrthoMScUCL/status/1202654795489824769 anticipate to find on sensory evaluation?

peripheral newe pattern
Not dermatomal
 Diseases of the peripheral nerve
 Wallerian degeneration Axonotmesis

PNS has limited ability to regenerate,
CNS very limited
atrophy of distal segment of the axon
(degeneration)
swelling of the proximal segment and
cell body
 site of protein synthesis
in presence of nerve growth factor,
schwann cells and macrophages
two forms of regeneration
itself
 Regenerative same aron regrows
-

 Collateral nearby aton regrows aror
-

proceeds approx 1 mm/day

https://www.nrronline.org/viewimage.asp?img=NeuralRegen
Res_2015_10_12_1945_172309_f1.jpg
 Factors influencing regeneration
 Intactness of the cell body
 Neurons do not have mitotic activity
 We do not have the ability to create more neurons
 Location of lesion in relation to the cell body
 Closer to cell body less likely to make a functional connection
 Further away from the cell body – slower the regrowth due to having
to transport so far for repair and growth
 Intactness of the endoneurium
 Guiding the nerve regrowth
 If not intact more difficult to make a functional connection
 Neurotrophic factors (growth factors, growth associated proteins)
 Timing of the repair – skill of the surgeon
 Status of end organ at the time of reinnervation
 Length of the injury zone
 CNS vs PNS
 CNS – much less likely to  Intrinsic theory –
have regeneration ◦ That CNS neurons are
 Why? intrinsically incapable of
 CNS is a network not regenerating – these
linear neurons cannot upregulate
 Barrier theory – blocked by growth associated proteins
scarring due to astrocytes (GAPs)
 A contributor, but does not
appear to be the entire
reason ◦ All probably have a role in
 Inadequacy of the blocking regeneration
environment
◦ CNS myelin has proteins
that inhibit growth
 Diseases of the peripheral NS
 Peripheral neuropathy
disease of the neuron
manifestations:
 glove and stocking pattern
due to impaired axonal transport or
dying back lack of blood supply to distal newes

 affects motor, sensory, and ANS
neurons
 Common neuropathies
diabetes
alcoholism
Guillain-Barre syndrome
Chemotherapy
https://www.atsdr.cdc.gov/csem/arsenic/phy
siologic_effects.html
Nerve Root involvement
 Compression of the
spinal nerve roots
 or mixed spinal
nerve
 Symptoms
Pain
Sensory loss
 Dermatomal pattern
Motor loss
 Myotomal pattern https://sportsmedicine.mayoclinic.org/condition/radiculopathy/
 Nerve Root involvement
 Dermatome
Area of skin, innervated
by a single nerve root
Dermatomes have
overlap, so complete
loss of a nerve root
rarely results in
complete loss of
sensation in an area
(except for CN V)
due to the overlap may
report decreased rather
than lost sensation Fig 46-3, Kandel & Schwartz, 3rd Edition
 Segmented
Root Major sensory area affected
C4 Clavicle
C8 Fifth finger
T4 Nipples
T10 Umbilicus
L1 Inguinal ligament
L3 Anterior surface of the thigh
L5 Great toe
S1 Lateral aspect of the foot

https://samarpanphysioclinic.com/dermatomes/
 Motor neuron disorders
http://neuromuscular.wustl.edu/pics/people/patients/anthornsm.jpg

 Motor neuron diseases
Polio
ALS
Amyotrophic lateral sclerosis (ALS)
 Amyotrophy - Neurogenic atrophy of
muscle
 Lateral sclerosis - Hardness of the lateral
SC on autopsy LCST lives here

Astrocyte proliferation
Scarring of lateral columns of SC
 Pathology

 Progressive degeneration
UMN in cortex
 Can affect corticospinal and/or corticobulbar
LMN (at level of brain stem and spinal cord)
 Some motor neurons are spared
Those supplying ocular muscles
Those involved in control of voluntary bowel
and bladder sphincters
ALS
http://library.med.utah.edu/WebPath/jpeg5/CNS103.jpg
Epidemiology
 1-4/100,000
 5-10% of people with the disease have a
family history.
 Cause is not known
heavy metal intoxication has been considered
Smoking
Serving in the military
History of brain trauma

 Males>females (slightly)
 Typical onset – age 40-mid 60’s
Symptoms
 Starts with painless weakness of
extremities
difficulty with fine hand movements
 using tools, writing, typing
 playing piano
Wasting of intrinsic hand and foot muscles
 Fasciculations of muscles in forearm or
upper arm
Symptoms
 Weakness spreads rapidly
 Hyperreflexia
 **Sensation is always normal motor neuron problem
 Does not affect autonomic motor neurons
 Usually no mental deterioration.
Aware of their own demise
 Night muscle cramps common
 Dysarthria and dysphagia (UMN-corticobulbar in
origin)
 Prognosis
 Patient becomes increasingly dependent
Usually WC dep. in 12-18 mo
 “ALWAYS” FATAL
Usually within 3 to 5 years
Usually secondary to compromise of respiratory
muscles or choking due to dysphagia
End of life ethical issues
 Variants of ALS
 Progressive Bulbar  Spinal Muscular
Palsy Atrophy
First symptoms are Only lower motor
restricted to muscles neurons are involved
innervated by cranial weakness, wasting,
nerves Fasciculation
Dysarthria, dysphagia Adult SMA probably =
Very rapid demise ALS
Autopsy - CST
involvement
Role of PT
 Patient/family education and support
Instruct family and caregiver in maintenance
stretching, transfers etc.
 Adaptive devices, wheelchairs,
environmental controls
 Heavy strengthening is contraindicated
 Did Lou Gehrig have Lou Gehrig’s
Disease?
 May have died from chronic
traumatic encephalopathy
Due to multiple concussions
and other forms of head injury
Identified by the presence of a
tau protein (TDP-43) in spinal
cord tissue (for CTE)
Since Lou Gehrig was
cremated, the controversy
will not be conclusively
resolved
 Polio
 Anterior horn cell/motor neuron disorder
 No sensory changes
 Muscle weakness
 Post-polio syndrome
 July 2022 – polio in US
 Post-polio
No heavy strengthening

https://www.theguardian.com/global/2020/nov/15/the-defeat-of-
polio-proved-that-immunisation-saved-lives-but-theres-a-sting-to-
the-tale
Disorders of the Spinal Cord
 Spina Bifida
 Complete transection of the cord
 Anterior spinal artery syndrome
 Posterior spinal artery syndrome
 Brown Sequard
 Central Cord
 Congenital deformations of the
lower spinal cord
 Spina bifida  Spina bifida oculta
failure to close the  Meningocele
neural tube during
 Myelomeningocele
development

Figure 5-5, Haines
 Spina Bifida
 Occulta
http://img.tfd.com/dorland/thumbs/spina_bifida-occulta.jpg

vertebrae only
Meninges and cord are
not impacted
Usually tuft of hair over
the area
Incidental findings on
x-ray
No functional deficits
 Spina bifida
 Meningocele Bulging of the

meninges
Meningo= meninges
Cele = tumor, swelling or
hernia
THUS – defect of the neural
arch permits extension of the
meninges and CSF, forming
the tumor
Typically repaired at birth
No functional deficits since
cord is not involved

https://www.cdc.gov/spina-bifida/about/index.html
 Spina bifida
http://www.georgiahealth.edu/medicine/neurosurgery/images/myelomeningocele.jpg

 Myelomeningocele
Myelo – involves cord
THUS – defect of the neural
arch permits extension of the
cord, meninges and CSF –
http://body-disease.com/wp-content/uploads/2012/03/Neural-tube-defects.png

May be paraplegic and loss of
sensation below level
Bowel and bladder problems
Incidence: 5 per 100,000
Can do surgical repair in utero
to minimize long term damage
Complete Transection of Cord
 Complete transection of the spinal
cord
Spinal shock – initial flaccid
Later manifestations - UMN
 spasticity
 hyper-reflexia
 present Babinski
 clonus
 loss of B/B
If above C3, breathing is affected
Incomplete is more common than
complete
Loss of all sensory modalities below
lesion
Autonomic dysreflexia
increased BP due
to vasoconstriction
◦ with complete lesions above T6
◦ response is a reflex response to
noxious stimuli below the level
of the lesion
◦ noxious stimulus results in ANS
initiating vasoconstriction
◦ body can’t compensate since
normal message to vasodilate
cannot pass the level of the
lesion
◦ message to heart to slow thru
Vagus is received
https://www.researchgate.net/figure/Diagram-illustrating-how-
autonomic-dysreflexia-occurs-in-a-person-with-spinal-
cord_fig1_9038493
 Autonomic Dysreflexia
 Symptoms
◦ pounding, severe HA (due
to blood pressure)
◦ Increased BP
◦ Flushing above the level of
the lesion
◦ Shivering, goose pimples
◦ Bradycardia
 Treatment
◦ Have patient sit
◦ Relieve the noxious stimuli
https://www.researchgate.net/figure/Diagram-illustrating-how-
autonomic-dysreflexia-occurs-in-a-person-with-spinal-
cord_fig1_9038493
Lesion Question #1
 A 27 y o male was thrown from a horse, landing on a
concrete planter with the bulk of the force
distributed to his back. X-rays revealed a bilateral
fracture of the pars interarticularis of T12/L1,
with a functional grade IV spondylolisthesis.
 A. Extent of injury?
 B. Type of injury (UMN or LMN)?
 C. Signs and symptoms expected?
 D. How would you describe the functional level?
 E. What is the prognosis?
 Brown-Sequard Syndrome
 Hemisection of the spinal cord
ipsilateral to LESION
 loss of 2 pt discrimination, light
touch, vibration, and
proprioception
 loss of voluntary motor (UMN
manifestations)
contralateral to LESION
 loss of nocioception, temperature
and crude touch
may have some ipsilateral LMN
involvement – only at the level of
the lesion
may have ipsilateral Horner’s if
cervical or T1-T2
 Horner’s
Losing sympathetics
 Sympathetic involvement
 Ptosis, meiosis, anhidrosis lack of
Droopy
eyes pupillaryconstriction
sweat
 Lesion in the Getting info from
hypothalamus
Upper segments of the IML (T1-T2)
Hypothalamus drives
fibers descending to the IML from
the hypothalamus in the lateral
brainstem
Extra axial lesion of the cervical
sympathetic chain/superior cervical
ganglion
Anywhere in the circuit
Brainster , servical ,
Horner’s
 anhidrosis  meiosis
 must be lesioned
↑ pathway
to see loss below the lesion

Syringomyelia
 tumor on the inside of the spinal
cord (formation of cysts)
 typically, initial fibers affected
are ALS at the crossing of the
ventral white commissure – Fig 46-5, Kandel & Schwartz(Third Edition)
bilateral loss of At that
nociception/temp level

 sensory loss can be unilateral
 can also have UMN or LMN
involvement, depending on the
extent of the cyst

https://www.mayoclinic.org/diseases-conditions/syringomyelia/symptoms-causes/syc-20354771
 compression incomplete
,
lesion

Central Cord syndrome
◦ Symptoms
 UE involvement more than
somatotopic
due to

LE involvement organization

 Sensory loss and motor
loss
 Bladder control may be
lost
 Usually due to trauma or
narrowing with age
Medial So impacted more than

lateral
 intermittent daudication is
differential diagnosis

Spinal Stenosis
SC compression

 Spinal Stenosis
mechanical problem
due to narrowing of the spinal canal
usually bilateral pain
pain decreased when walking uphill forward flexion relieves pressure

occurs in back, buttocks, thighs, calves, and feet
normal pulses unlike intermittent daudication
-

peaks in 7th decade, affects men more than women
Anterior Spinal Artery Syndrome
 Anterior Spinal Artery
supplies the anterior
2/3rds of the spinal cord
medullary arteries
reinforce the ASA
 artery of Adamkiewicz
(most common at L2)

Signs and
Symptoms?

UMN problem be tracts are
impacted
LMN problem at that level
Posterior Spinal Artery Syndrome

 Deficits?
DCML same side below
Cauda equina syndrome
Below vertebral level L2
Symptoms
 Saddle sensory loss
 LMN loss
 Bowel and Bladder difficulties
 Pain – low back and radiating

 LMN problem be there's no

cord
spinal.

Dermational sensory loss

Fig 46-2a, Kandel & Schwartz
(Third Edition)
Spinal cord syndromes

https://clinicalgate.com/paraplegia-and-spinal-cord-syndromes/
 Systemic Problems that affect the spinal
cord

 Subacute combined  Tabes Dorsalis -
degeneration of the SC ◦ Syphilitic myelopathy
◦ Pernicious anemia, vitamin ◦ Locomotor ataxia
B12 deficiency in alcoholics
-

seen
◦ Demyelination of the dorsal
◦ Patchy losses of myelin in columns
the dorsal column and
↳ DCML
◦ Loss of DCML modalities
lateral column ◦ Sensory ataxia,
↳ Lost
◦ Also can have peripheral ◦ incoordination, wide based,
neuropathy high steppage gait with foot
◦ Symptoms: proprioceptive slap
loss, numbness, spastic ◦ Loss of reflexes
paresis, urinary ◦ *Sir Arthur Conan Doyle completed his
dissertation on Tabes Dorsalis in 1885
incontinence, clumsy gait,
incoordination
https://www.youtube.com/watch?v=-rRNdGJ3LxI
Friedreich’s Ataxia
genetic condition
tracts involved:
 *DSCT unconscious proprioception
-

 LCST motor to limbs
-

 DCML conscious proprioception
-

ataxia uncoordinated
-

spastic paralysis in legs
loss of proprioception loss of motor
-

reflexes
present Babinski
BUT, loss of KJ and AJ
(may be due to cerebellar
involvement)
https://www.youtube.com/watch?v=JampkXmVEg4
Questions?