Spinal Reflexes 2024 PDF - RCSI

Summary

This document provides an overview of spinal reflexes, including learning objectives and descriptions of different types. It covers the function and importance of spinal reflexes, including monosynaptic and polysynaptic reflexes. The document likely comes from a university or medical school.

Full Transcript

Spinal reflexes
Course Year 2 CNS module
Lecturer Prof David Henshall; Presented by Dr Ebrahim Rajab
Date 3rd November, 2024
Learning outcomes
Discuss the role of involuntary control of skeletal muscles
Define a reflex and describe its basic components
Explain the function of muscle sensory receptors in spinal reflexes
Describe a stretch reflex
Discuss the testing of stretch reflexes in neurological testing
Interpret an atypical knee jerk response
Explain the flexor withdrawal and cross extensor reflexes
Reflex
A reflex by definition is “Any response that occurs automatically
without conscious effort. Reflexes are rapid, automatic and
stereotyped responses to a specific stimulus”

A rapid, automatic and stereotyped* response to a specific stimulus
*Stereotyped: This means that the response does not vary and is therefore predictable

Example of a reflex,
100 people are asked to touch a metal plate with their index finger. Unknown to
them the plate is hot. Immediately the hand is withdrawn. The response is
predictable, similar in all, automatic and immediate.
Skeletal muscle and spinal cord reflexes (overview)

Skeletal muscle is under voluntary control from brain but,

Skeletal muscles can contract without conscious control in a
reflex manner in response to certain stimuli

There are varying degrees of complexity of these spinal reflexes
monosynaptic reflexes through to polysynaptic reflexes involving muscle
control on both sides of body
Functions of the Spine
Ventral side Dorsal side

1) Link for transmission of
information between
brain and remainder of
body

2) Integrate reflex activity
between afferent input and
efferent output without
involving the brain
From Physiology by Sherwood
Information “root” of spinal nerves
Afferent sensory fibres enter spinal cord
through dorsal root (their cell bodies are in
the dorsal root ganglion; DRG)

Cell bodies of efferent [motor] neurons
originate in grey matter, axons exit through
ventral route

-motor neurons (A axons
innervate skeletal muscle)

 motor neurons (A axons
innervate intrafusal fibres)

Dorsal horn: cell bodies of interneurons on which afferents Dorsal & ventral roots form spinal nerve
terminate Ventral horn: cell bodies of efferent motor
neurons [supply skeletal muscles] (of which there are 31 in total)
From Physiology by Sherwood
Spinal cord reflexes: why are they important?

Coordinate the rapid withdrawal responses to painful stimuli
Protect against over-stretching of muscles

Execute emptying pelvic organs
e.g. bladder contraction

Carry out purposeful muscle movement and contribute to proper
balance & movement (e.g. during walking)
Spinal reflexes coordinate skilled movements of the trunk and limbs and the often-taken-for-
granted activities of standing erect, walking, and running

Learned reflexes (e.g. somersaults in sports)
https://youtu.be/l59Hu4CiV1Q
Reflexes continued
A reflex response is the most basic form of integrated neural activity
Reflex responses occur in:

1. The somatic nervous system

2. The autonomic nervous system
 What are the Components of a reflex?
Reflex activity involves three
components and their connecting
neurons

The three components are:
1. Peripheral sensory receptors [&
sensory nerve]
2. Area for integration in the CNS
3. [Efferent nerve] & effectors

“Reflex arc” is the name for the
neural pathway that accomplishes
reflex activity.
 The sensory receptors
These receptors respond to changes in the periphery

1-Exteroceptors: (respond to external stimuli)

Information and temperature, pressure

2- Proprioceptors: (receptors in muscles, tendons, joints)
send information about position

3- Interoceptors: (internal organs)
- send information about pain, stretching internal organs
Area for integration in the CNS
This area is the brain or spinal cord

Receives, processes and integrates incoming sensory information sent
from the sensory receptors

Based on integration of incoming information, the CNS integration area
issues appropriate commands to effectors.

Integration in the CNS
depends on the activity of neurons known as interneurons which are
responsible for the distribution of sensory information and co-ordination of
commands within the CNS

Interneurons can have excitatory or inhibitory effects
The effectors

i.e. executing the response.

In the somatic nervous system, the effectors are skeletal muscles.

In the autonomic nervous system, the effectors are cardiac muscle,
smooth muscle and gland cells.
Spinal reflexes of the somatic nervous system

These reflexes provide involuntary control of the skeletal
muscular system.

The area for integration is in the spinal cord.

Spinal reflexes can be influenced and modified by higher centres in the CNS.

There are two types of reflexes in the somatic nervous system
Monosynaptic
Polysynaptic
 Monosynaptic reflexes
Only one synapse between afferent and
efferent nerves in CNS

The only monosynaptic reflexes which occur in the body are the stretch (myotactic)
reflexes.

A stretch reflex is elicited in a skeletal muscle by briefly stretching the muscle.
The reflex response is a brief contraction of that muscle
This reflex functions to oppose sudden changes in length of the muscle

The components of the stretch reflex are
1. Sensory receptor = muscle spindles
2. Area for integration = spinal cord
3. Effector = the skeletal muscle that is stretched
Muscle sensory receptors
Proper control of muscle function requires continuous feedback of sensory information from
muscle to spinal cord

What is length? What is tension? How rapidly is length/tension changing?

Muscles & their tendons have two main sensory receptors
Muscle spindles (length/rate of change in length)
Golgi tendon organs (tension/rate of change of tension) Both are types of
proprioceptor
Muscle spindle

Muscle spindle consists of:
1a
1. Fibrous capsule
2. Intrafusal muscle fibers wrapped
by nerve ending
3. Group Ia sensory axons (Primary
fibre/endings)
Large diameter
Fast conduction
Detect stretch and rate of
length change
4. Group II sensory axons
(secondary fibre/endings)
Detect stretch only
Muscle spindle
(force-generating)

Co-activation of

See animation of spindles functioning on VLE
 Neuronal connections involved in a stretch reflex
All skeletal muscles will respond to a brief stretch with a brief contraction
i.e. a stretch reflex

Note. one synapse only between
N.B. Muscle spindle sensory information
afferent and efferent nerves.
also conveyed to brain (e.g. cerebellum)
Muscle spindles and their role in muscle tone
Muscle spindles are important for muscle tone (residual muscle tension):
Muscles are always at least partially contracted resting muscle tension

Why? If muscles relaxed completely (no resting tone), they would over-lengthen,
and too much time would be required to take up slack when a contraction was
called for.

On the other hand, too much tone would not allow for sufficient rest and
recovery.
Muscle tone
Muscle tone is ultimately controlled by impulses from the brain, but
muscle spindles are the principal regulator

Under normal conditions, activity of -motoneurons is maintained at the level
needed to keep the muscle spindles under proper tension while the muscles are
relaxed

Undue relaxation is prevented by stretch and activation of the spindles thus, tone
is regulated by the stretch reflex and is not a characteristic of the muscle itself

Mechanism produces normal resting muscle length and state of tension or muscle
tone
muscle spindles keep the
brain and particularly the
cerebellum continually
informed of even slight
changes in muscle tone.
Interruption of the reflex arc controlling muscle tone leads
to immediate loss of muscle tone

https://youtu.be/gLZoYLxdXCQ
 Golgi tendon organ
Encapsulated sensory receptor inside muscle
tendon

Detects muscle tension

10-15 muscle fibres connected

↑ muscle tension → Ib sensory nerves
transmit signals to spinal cord (and brain)

Inhibits motor neuron

Prevents too much tension on muscle
controls force within muscles and the
stiffness of particular joints

see animation of Golgi tendon on VLE
 Golgi tendon organ pathway

N.B. Recent studies suggest GTO may not directly initiate reflexes
The knee jerk response: a The response to stretch of the quadriceps (the
stretch reflex which is knee jerk) or of the gastrocnemius (the ankle
jerk) may be demonstrated. The quadriceps is
informative about integrity of briefly stretched by sharply tapping the patellar
tendon
CNS

Sequence of events in the knee jerk
Testing and grading stretch reflex responses
Testing stretch reflexes, often called tendon jerks, forms
part of routine neurological testing.

Testing provides information about the integrity of the
pathways involved in these reflex responses

Grade 4: very brisk, often with clonus* (record number of beats)
Grade 3: brisk but normal
Grade 2: normal
Grade 1: minimal
Grade 0: absent

*Clonus is involuntary and rhythmic muscle contractions caused by a permanent lesion in descending motor neurons
Diminished stretch reflex response (hyporeflexia)

Hyporeflexia results if any part of the reflex pathway from the spindle
back to the muscle is damaged
Examples of conditions associated with hyporeflexia:

Poliomyelitis (virus damages lower motor neurons)

Muscular dystrophy (degenerative disease of skeletal muscle)

Lower motor neuron lesions (e.g. those serving foot)
 Absent stretch reflex (Areflexia)

Areflexia: Apparent loss of tendon reflexes

Can be due to lack of clinical experience!

Causes: any lesion of the reflex arc (e.g. root lesion or
peripheral neuropathy)
 Exaggerated stretch reflex responses (hyperreflexia)

Hyperreflexia: results following damage to motor pathways
from the brain to the spinal cord.
Greatly exaggerated muscle jerk response

Causes: Upper motor neuron lesion, UMNL
after stroke or brain tumour
Damage to motor areas of cerebral cortex
Results in loss of inhibitory inputs from higher areas to some motor neurons

- Certain stretch reflexes become exaggerated (e.g. elbow)
 Reciprocal innervation
Somatic reflexes result in limb movement (e.g. in
the knee jerk response, the knee extends and the
leg kicks forward).

When a specific muscle (the protagonist),
contracts the opposing muscles (the
antagonist) must relax to allow the
movement.*

Furthermore, stretch reflexes in the antagonist
muscle must be inhibited

This is achieved by reciprocal innervation.
Neuronal connections involved in
*this includes the knee-jerk reflex; the antagonist is the stretch reflex (e.g. knee jerk) showing
semitendinosus muscle reciprocal innervation
Polysynaptic reflexes
From 2 to 100s of synapses between afferent and efferent nerves

These produce more complex responses than monosynaptic
reflexes

May be several interneurons acting between the sensory afferent
fibres and the -motoneurons

Furthermore, these interneurons may control several muscle
groups
Polysynaptic reflexes
The withdrawal reflexes are
examples of polysynaptic
reflexes.

They move a part
of the body away
from painful
stimulation i.e.
are protective

e.g. withdrawal of the hand
from a hot plate
 Flexor withdrawal reflex
1. Hand on hot plate
2. Nociceptors (pain receptors) in hand are stimulated.
3. Action potentials conducted along fast, pain
communicating A (sensory) fibres
4. Sensory pathways synapse first on interneurons
5. Motor neurons contacted secondarily
6. Integrative centres of the cord cause those muscles
to contract that can most effectively remove the
pained part of the body from the object
The biceps muscle (flexor) contracts and the
hand is pulled up and away
Contraction of the extensor (antagonist) triceps
muscle is inhibited

Value of immediate response to noxious stimulation (i.e. withdrawal reflex)
Involuntary reflex control over skeletal muscles provides an immediate response.
Immediate response is of great importance to prevent injury/damage.
Strength of the reflex is related to the intensity of the stimulus
Crossed extensor reflex
Not all spinal reflex action is limited to motor
responses on side of the body to which the stimulus is
applied.

If you stand on a sharp object, you lift your foot away
from it, but you don’t fall over! This is because of the
(flexor) reflex is accompanied by another reflex
known as the crossed extensor reflex

0.2 to 0.5 s after stimulus elicits flexor reflex in one
limb the opposite limb begins to extend
Signals from sensory nerves cross to opposite
side of cord to excite extensor muscles
Opposite leg simultaneously prepares to
suddenly bear all the weight to avoid losing
balance/fall
Controlling your reflexes
Spinal reflexes can be voluntarily “over-rided” (at least temporarily) by higher
brain centres

Pin prick or needle insertion during a blood draw:

e.g. bran sends IPSPs via descending pathways to biceps motorneurons and
EPSPs to triceps to keep arm from pulling away

e.g. over-riding bladder contraction (autonomic reflex)
Acquired/conditioned reflexes
Some reflexes are a result of practice and learning

e.g. certain responses in music (pianist) and sports (e.g.
somersault, catching a ball)

May involve “over-riding” basic reflexes

Person learns to consciously inhibit postural reflexes

Repeated skill performance generates new synaptic patterns
in CNS which substitute for natural reflex

Becomes automatic

See https://www.youtube.com/watch?v=2fdp8SVOSF4 for some examples of skill
performance
 Further reading

Medical Sciences by Niash

Further reading in Human Physiology by Sherwood
Clinical Neurology by Greenberg, Aminoff & Simon (or similar)