Neuroanatomy Spinal Cord PDF

Summary

These notes provide an overview of neuroanatomy, focusing on the structure and function of the spinal cord. It details the anatomy of the spinal cord, its connections and function. The notes also explore aspects of medical conditions related to the nervous system.

Full Transcript

Neuroanatomy
Nick Hurst
 Neurological anatomy and physiology

Aims and To understand the structure of a nerve cell

objective Be able to explain how information is transmitted

To be able to explain the development of the
nervous system
Be able to explain the organisation of the nervous
system
Identify regions of the brain and spinal cord and
their functions
Investigate the central nervous system and
peripheral nervous system and how they relate to
medical conditions
Spinal cord
 Anatomy of the
spinal cord
Within Vertebral canal
Continues from brain stem
Receives info from, and controls trunk and limbs

Undifferentiated structure compared with the brain

Picture: https://neupsykey.com/introduction-and-overview/
irs 31 pairs of spinal nerves

H shape which are gray matter

als back and forward

Picture: http://dhamma4u.com/spinal-cord-images-anatomy/admirable-spinal-cord-images-anatomy/ Picture: https://neupsykey.com/introduction-and-overview/
 Intervertebral foramina

Cauda equina – lumbar and
sacral nerves

Spinal nerves end at L1/L2 disc
Why end here? Fused no column
for nerves because spincal cord
grows fasster later in development
than spinal column?

Nerves after lumbar spine coming out
can cause pressure?
Massive nerves coming out has no
protection which can easily get
damaged
Picture: http://aurorachiroplus.com/chiropractic-care-aurora-co-wellness/symptoms-disc-herniation-treat/
 Cauda equine Can squash nerves which causes symptoms of
bowel control loss

syndrome Numbness, weakness,

https://www.pinterest.com/pin/ http://pennstatehershey.adam.com/content.aspx?
 Picture: https://www.quora.com/Why-does-our-left-hemisphere-of-brain-control-our-right-side-of-our-body-and-the-right-our-left

Decussation is cross over of nerve

However……...
 - The olfactory system isn’t reversed at all.
- The visual system is only partly reversed; each eye sends some information to each side of the brain.
- Sounds are analysed on both sides of the lower portions of the brain but on only one side of the cortex.

https://www.quora.com/Does-olfactory-nerve-have-
https://www.pinterest.com/pin/ a-ganglion
 (only up)
to know Spinothalamic tract
Spinocerebellar tract and Dorsal columns Corticospinal tract

Picture: http://vanat.cvm.umn.edu/neurLab2/pages/SpThalTract.html

Picture: http://resizeme.club/picresize-212_12.html
 Ascending pathways
Dorsal column

1

2

Spinocerebellar tract

3

Spinothalamic tract
does the nervous sytem know youre in paina nd what it does?

How do we feel pain?
dins (inflammatory
hich released substance
rasnmitters)

s which activates the

get this pain since
es which don’t get along
 Alpha Beta Fibres Alpha-delta (aδ) fibres C-fibres (Visceral Pain)
(Touch) (Somatic Pain) Pain pressure ho

Large, mylelinated and fastest Small myelinated fibres which Smalleat diameter. Non- Cannot pin poin
conducting conduct rapidly myelinated fibres with low
conduction velocity
Eg: appendicitis
Carry information related to Sharp Pain Diffuse pain
touch/pressure Inflammed appe
Precisely located Precisely located Not distinctly localised
all over area as
fibres
Localised pain
 3 orders of neurons carrying action
potential signalling pain from periphery to
cerebral cortex.

 1st order neuron- cell bodies within the
dorsal root ganglion. Synapse with the 2nd
order neuron

 2nd order neuron- travels along the
spinothalamic tract- synapses in the
Thalamus

 3rd order neuron- sends fibres to the
somatosensory cortex (location)
Different pain will signal to d

This lets the body know its i
 Descending
pathway
 Responsible for pain inhibition

 Periaquaductal grey matter (PAG)

 Role in descending pathway and
pain modulation

 Enkephalin-releasing neurons
(like morphin makes you happy)

 Serotonin descends to the
dorsal horn of the spinal cord &
forms excitatory connections
with inhibitory interneurons

 Activated interneurons release
enkephalins or dynorphin that
bind to mu opioid receptors
Activation of Serotonergic (5-HT)
and Noradrenergic (NA) neurons to
prevent nociceptive
neurotransmitters

Serotonin binds to 5-ht and
blocks it to stop releasing
neurotransmitters to stop
signal pain
Endogenous and
exogenous Opioid
inhabitation of 1st order
neurone.

Morphine can be produced
interally and external (drug)

Blocks neurotrasnmitters to
not release pain signal

Pain still there but blocked to
feel
 Upper and lower motor neurones
Watch this- good explanation

https://www.youtube.com/watch?
v=ClXsS7O8seg&feature=youtu.be
UMN transmit signals from the brain to
brainstem and spinal cord.
-deal with higher most important parts

LMN transmit signals from the spinal cord to
the muscles.
Examples: pain in arm
Example
Want to move RIGHT thumb.

UMN arise from the LEFT Primary motor cortex

Pass through the internal capsule through the midbrain and brainstem (Medulla and
pons)

Majority of Neurons cross over to the opposite side of the body at the medulla.

Majority of UMN contained within the Lateral corticospinal tract through the spinal cord.

Once the UMN reaches the correct vertebral level (via the spinal cord) it will synapse
with the LMN at the anterior horn.

The LMN will then target the muscle responsible for the movement of that body part (ie
the muscles involved in the movement of the right thumb)
Causes of UMN Lesions Affected area: spinal cord
Signs of UMN lesions

Will still get some signals to move legs

But weaker
Causes of LMN Will get paralysis because there is no signal se

Lesions
Signs of LMN lesions
Lower and upper motor neurone
lesions
Upper motor neurone syndrome
Weakness or paralysis of specific movements (ie extension of upper limbs)
No wasting of muscles
Increased resistance to passive stretching muscles (spasticity)
Hyperactivity of deep tendon reflexes (hyperreflexia)
Emergence of extensor plantar response (Babinski reflex)
Loss of abdominal reflexes

Lower motor neurone syndrome
Weakness (paresis) or paralysis (plegia) of individual muscles (ie Bells Palsy, Bulbar palsy)
Wasting of muscles
Fasciculation (of muscles)
Reduced resistance to passive stretching (hypotonia)
Diminution of loss of deep tendon reflexes (hyporeflexia or areflexia)
 Blood supply to spinal cord
Anterior and Posterior
spinal artery
Requires additional
input from radicular
arteries

Picture: http://www.facts4u.co.in/blood-supply-of-spinal-cord-and-brain-anatomy/
 Spinal nerve control muscle Blood supply to spinal cord

Face: Trigeminal nerve
(cranial nerve)
 Blood supply most vulnerable in thoracic region and
anterior portion of cord
Occlusion of anterior spinal cord – paraplegia and incontinence
 Venous drainage
Anterior and posterior spinal vein
Via anterior and posterior radicular ve
into internal vertebral venous plexus

Ascends to:
Lumbar veins
Azygos
Hemiazygos veins

Picture: https://neupsykey.com/vasculature-of-the-central-nervous-system/
Ganglions
 A nerve cell cluster
Houses cell bodies of afferent and efferent nerve fibres
Made up of somata and dendritic structures
Can interconnect with other ganglia
Complex systems – “Plexus”

Function: provide relay points and intermediary connections
between different neurological structures
Dorsal root ganglia (Spinal ganglia) – sensory neurones
Cranial nerve ganglia – cell bodies of cranial neurones
Autonomic ganglia – cell bodies of autonomic nerves

Post and preganglionic fibres