Pain & Thermoregulation PDF

Summary

This document provides an overview of pain physiology, including somatosensory transmission, pain perception, and modulation. It covers different types of pain, pain assessment, and management strategies. The document also touches upon the role of nociceptors and pain pathways in the nervous system.

Full Transcript

pain &
Thermoregulation
Tobi Ajayi
Lesson Objectives:
1. Review of somatosensory transmission.

2. Physiology of pain: transmission, perception & modulation

3. Types of Pain

4. Pain Assessment

5. Management of Pain

6. Nursing considerations
 SOMATOSENSORY FUNCTION
The somatosensory system is designed to provide
the central nervous system (CNS) with
information on:
Touch, temperature, body position, and pain.

1st order neurons: transmit sensory information
from the periphery to the CNS.

2nd order neurons: communicate with various
reflex networks and sensory pathways in the spinal
cord and transmit information to the thalamus.

3rd order neurons: relay information from the
thalamus to the cerebral cortex
 levels of somatosensory system
1. Sensory Units: are made up of sensory receptors (like those in the skin) and the neurons that carry signals from those
receptors.

Nerve fibers are like different types of wires that carry signals in the nervous system.
Type A nerve fiber – fast
Myelinated: protective covering (myelin) that helps them send messages quickly.
Carry information about sharp pain, touch, and pressure. They help us react quickly to things like touching
something hot. (Can trigger ‘reflexes’).
Type B nerve fiber – myelinated but regular speed
Transmit signals related to things like sensations from internal organs and autonomic functions (like heart
rate).
Type C nerve fiber -unmyelinated (slow)
Carry dull, aching, burning pain and sensations like warmth. Responsible for the longer-lasting, more diffuse
pain after the initial sharp pain.

Dorsal root ganglion (DRG) = cluster of nerve cell bodies located near the dorsal (back) of spinal cord, containing the
cell bodies of sensory neurons.
When you feel something (e.g. touch or pain), the sensory nerve endings in the skin send that signal to the DRG,
where the axon continues into the spinal cord to connect with second-order neurons.
 levels of somatosensory system
2. The Ascending pathways: are the neural pathways that carry sensory information from the spinal cord up to the
brain

Discriminative pathway (medial lemniscus): helps to detect exactly where and what kind of sensation is felt.
responsible for transmitting detail sensation such as fine touch, 2-point discrimination, pressure, vibration, and
proprioception (awareness of body position).
Signals travel from the sensory receptors in the skin through first-order neurons to the spinal cord, then up to the
brain without crossing over until they reach the brainstem.

Anterolateral pathway: mainly carries information about pain, temperature, and crude (less precise) touch.
Signals from the sensory receptors travel through first-order neurons to the spinal cord, where they
immediately cross over to the opposite side and then ascend to the brain.

Both pathways work together to provide a complete picture of sensory experiences. For example, if you touch
something hot, the discriminative pathway helps you identify the exact spot and texture, while the anterolateral
pathway alerts you to the pain and temperature.
Neuron crossover (decussation) helps in coordinating complex movements, allowing for smoother and more
integrated actions between both sides of the body. It also affects how information is processed.
For example, in the discriminative pathway, signals cross over in the brainstem, allowing the brain to
pinpoint exact locations of stimuli. Whereas, in the anterolateral pathway, signals cross over at the
spinal cord, enabling a quicker response to potential harm.
levels of somatosensory system
 levels of somatosensory system

3. Central processing unit: are the specific areas in the brain that process and interpret sensory
information coming from the ascending pathway
Thalamus and the somatosensory cortex.
Help recognize what is being felt (e.g. hot, cold, sharp, or dull) and where it’s coming from on
the body.

The afferent pathway relays sensory information from PNS to CNS
The sensory impulse must be strong enough to reach threshold and general action potential
(no message sent if stimuli is not strong enough).
 Sensory Receptprs
Mechanoreceptors: detect changes in the environment caused
by mechanical forces, such as pressure on the skin, stretching
muscles, or feeling vibrations.

Tactile Receptors: Found in the skin, help us feel light touch,
pressure, and texture.
Free nerve endings, Meissner corpuscles, Merkel disks,
Pacinian corpuscles, Hair follicle end organs, and Ruffini
end organs.

Proprioceptors: Located in muscles and joints. They help sense
body position and movement, letting us know where the limbs
are without looking.

Baroreceptors: Found in blood vessels, they detect changes in
blood pressure.
 Sensory Receptprs
Thermoreceptors: detect changes in
temperature (heat and cold).
These receptors respond rapidly to sudden
changes in temperature and then adapt
over the next few minutes although they do
not adapt completely
E.g. Walking out to the cold.
 pain

PHYSIOLOGY AND PHARMACOLOGY OF PAIN
 pain
Pain is an “unpleasant sensory and emotional experience associated with, or resembling that
associated with, actual or potential tissue damage.
Pain receptors (Nociceptors) are free nerve endings that are activated in response to actual or
impending tissue injury. They respond to mechanical, thermal and chemical stimuli.

Stimulation of nociceptors
Mechanical: can arise from intense pressure applied to skin form from extreme stretch or contraction
of muscles.
Thermal: Extreme heat or cold stimuli nociceptors.
Chemical: arise from tissue trauma, ischemia, and inflammation that cause the release of chemical
mediators from injured or inflamed tissue
Bradykinin, Histamine, Serotonin & Potassium activate and also sensitize nociceptors.
Prostaglandins sensitizes nociceptors by lowering mechanical and thermal activation thresholds in
nociceptive nerve endings, thus reducing the stimulus intensity required to elicit action potential
firing.
 Nociceptors
Nociceptive action potential are transmitted to the spinal cord through:
A-delta fibers:
Myelinated - transmit sharp, localized, fast pain” at a rate of 6-20 m/s.
Typically elicited by mechanical or thermal stimuli.
Often triggers ‘reflexes’.

C-fibers:
Unmyelinated - transmit “slow-wave pain” impulses at a rate of 0.5-2 m/s.
Incited by chemical stimuli or persistent mechanical or thermal stimuli.
Responsible for aching, burning, dull, diffuse pain.
 PNS to CNS
When nociceptors are stimulated, A or C fibers (1st order) of the PNS contacts
second-order pain-transmission neurons (interneurons) in the spinal cord.
The second-order neurons ascend the spinal cord to the thalamus (relay center).
From there thalamus, 2nd order neurons synapse with 3rd order neuron, leading
to the somatosensory cortex in the brain where perception and localization of
pain takes place = awareness.
The cortex has a body part map called the sensory homunculus.
 pain mediators
Transmission of impulses between the nociceptive neurons(1st order) and dorsal horn
neurons (2nd order) in the spinal cord is mediated by chemical neurotransmitters released
from nociceptive neurons.
Glutamate: main excitatory neurotransmitter for pain. (Binds NMDA receptor)
Substance P: elicit slow, excitatory action potentials. Also prolongs and enhances the action
of glutamate. (Mostly on C-fibers)
Endorphins: inhibitory neurotransmitters aka ‘neuromodulators’.
 Pain pathways
From the spinal cord, signal ascend through different
pathways:
Neospinothalamic tract: fast-conducting fibers (sharp, fast
pain) transmit information to the thalamus, which relays to
the somatosensory area to provide precise location of the
pain.

Paleospinothalamic tract: slow-conducting fibers
terminate in several thalamic regions, including parts that
project to the limbic system. (Limbic system regulates
emotions and behaviors).
This pathway is associated with the emotional-
motivational aspects of pain).
This pathway also projects into the reticular nuclei of the
brain stem, contributing to alertness which indirectly
influences the hypothalamus to increase blood pressure,
heart rate, and other responses.
 Flexor Reflex: Withdrawal reflex

Stimulus – sharp pain => reflex withdrawal without cerebral control
Activation of a sensory neuron (afferent)– interneuron (at level of stimulus in CNS) –
automatic activation of a motor neuron (efferent) - Response by the effector
 pain gate theory

Gate control theory: postulates the presence of neural gating mechanisms at the segmental spinal cord
level to account for interactions between pain and other sensory modalities.
Nociceptors inhibit inhibitory neurons, but when other receptors are activated they block this
The simultaneous firing of the large-diameter touch fibers (A-beta) can block the transmission of
impulses from the small-diameter myelinated and unmyelinated pain fibers.
Pain intensity can be reduced during active tactile stimulation
Rubbing a wound, ice, transcutaneous nerve stimulation.
Brain also send descending signals to spinal cord to reduce pain, through Endorphins
 summary of pain transmission
1. Pain begins a s a message received by nerve endings (e.g.
burnt finger).

2. The release of substance P, bradykinin, and prostaglandins
sensitize nerve endings, helping to transmit the pain from site of
injury towards the brain.

3. The pain signal travels as an electrochemical impulse along
the nerve to the dorsal horn of the spinal cord.

4. The spinal cord sends the message to the thalamus, and then
the cortex.

5. Pain relief starts with signals from the brain that descend to
the spinal cord, where:

6. Chemicals such as endorphin S are released in the dorsal horn
to diminish pain message
Endogenous Analgesic Mechanism - Efferent
‘Endogenous opioid peptides’ – inhibitory
neurotransmitters aka ‘neuromodulators’: endorphins,
enkephalins, dynorphins.
Act on mu, delta, and kappa receptors.
Released from hypothalamus, limbic system, reticular
formation.
DESCENDING (efferent) pathway.
inhibit substance P.
induced secretion of:
Serotonin: enhances mood and reduce pain
perception.
Norepinephrine: dampens pain signals at the spinal
level, and enhances alertness/stress responses.
 Types of Pain
Acute pain:
Elicited by nociceptive stimuli at the site of local tissue damage.
Serves as a warning system.
Short duration (Seconds to