5
Somatosensitivity, viscerosensititvity,
proprioception and pain I
Somatosensitivity, viscerosensititvity, proprioception and pain I2
The role of nervous system
Somatosensitivity, viscerosensititvity, proprioception and pain I3
Input
Integration
Output
REGULATION
Potential input Potential output
ANTICIPATION
Sensor Effector
Cortex Cortex
Receptors/sensors
Somatosensitivity, viscerosensititvity, proprioception and pain I4
• Energy convertor
– Signal reception
– Signal transformation
• Receptor potential
– Generator potential
• Action potential
• Adequate stimulus
• Non adequate stimulus
http://www.slideshare.net/CsillaEgri/presentations
Receptor/generator and action potential
Somatosensitivity, viscerosensititvity, proprioception and pain I5
http://www.slideshare.net/drpsdeb/presentations
Receptors/sensors
Somatosensitivity, viscerosensititvity, proprioception and pain I6
• Energy convertor
– Signal reception
– Signal transformation
• Receptor potential
– Generator potential
• Action potential
• Adequate stimulus
• Non adequate stimulus
http://www.slideshare.net/CsillaEgri/presentations
Receptors/sensors
Somatosensitivity, viscerosensititvity, proprioception and pain I7
• Energy convertor
– Signal reception
– Signal transformation
• Receptor potential
– Generator potential
• Action potential
• Adequate stimulus
• Non adequate stimulus
http://www.slideshare.net/CsillaEgri/presentations
Receptors/sensors
Somatosensitivity, viscerosensititvity, proprioception and pain I8
• Energy convertor
– Signal reception
– Signal transformation
• Receptor potential
– Generator potential
• Action potential
• Adequate stimulus
• Non adequate stimulus
http://www.slideshare.net/CsillaEgri/presentations
Receptors/sensors
Somatosensitivity, viscerosensititvity, proprioception and pain I9
• Energy convertor
– Signal reception
– Signal transformation
• Receptor potential
– Generator potential
• Action potential
• Adequate stimulus
• Non adequate stimulus
http://www.slideshare.net/CsillaEgri/presentations
Receptors/sensors
Somatosensitivity, viscerosensititvity, proprioception and pain I10
• Energy convertor
– Signal reception
– Signal transformation
• Receptor potential
– Generator potential
• Action potential
• Adequate stimulus
• Non adequate stimulus
http://www.slideshare.net/CsillaEgri/presentations
Intensity coding
Somatosensitivity, viscerosensititvity, proprioception and pain I11
http://www.slideshare.net/CsillaEgri/presentations
• Amplitude of receptor
potential is transtucted
into the frequency of AP
Intensity coding
Somatosensitivity, viscerosensititvity, proprioception and pain I12
• In the other words: an
increased intensity is
associated with
increase in frequency
of AP
• A high-intensity
stimulus may also
activate more
receptors
http://neuronresearch.net/neuron/files/neuralcode.htm
Intensity coding
Somatosensitivity, viscerosensititvity, proprioception and pain I13
http://slideplayer.cz/slide/3217923/
Amplitudeofreceptorpotential
Actionpotentialfrequency
Stimulus intensity Stimulus intensity
• Relation between receptor and
action potential is logarithmic
Qualitative information
Somatosensitivity, viscerosensititvity, proprioception and pain I14 http://www.slideshare.net/drpsdeb/presentations
• The law of specific nerve
energies:
The nature of perception is
defined by the pathway over
which the sensory
information is carried
• Labeled line coding define
the information about
quality
Qualitative information
Somatosensitivity, viscerosensititvity, proprioception and pain I15
• Labeled line coding
• Receptive field
• Nerve stimulation
mimics receptor
stimulation
http://www.slideshare.net/drpsdeb/presentations
Receptive fields
Somatosensitivity, viscerosensititvity, proprioception and pain I16
• Various size and overaly
• Small receptive field –
high resolution
• Spatial resolving power
increased by lateral
inhibition
http://www.slideshare.net/drpsdeb/presentations
Lateral inhibition
Somatosensitivity, viscerosensititvity, proprioception and pain I17
http://www.slideshare.net/drpsdeb/presentations
Receptor adaptation
Somatosensitivity, viscerosensititvity, proprioception and pain I18
• The decline of receptor
responses in spite of
stimulus presence
• Tonic receptors – slow
adaptation – presence of
stimulus, position
• Phasic receptors – rapid
adaptation – change of stimulus
http://www.slideshare.net/CsillaEgri/presentations
Receptors
Somatosensitivity, viscerosensititvity, proprioception and pain I19
• Simple
• Complex
• General
– Superficial – somatosensors
– Deep – viscerosensors
– Muscles, tendons, joints –
proprioceptors
• Special
– Part of sensory organs
Receptors
Somatosensitivity, viscerosensititvity, proprioception and pain I20
• Simple
• Complex
• General
– Superficial – somatosensors
– Deep – viscerosensors
– Muscles, tendons, joints –
proprioceptors
• Special
– Part of sensory organs
Receptors
Somatosensitivity, viscerosensititvity, proprioception and pain I21
http://www.slideshare.net/CsillaEgri/presentations
• Simple
• Complex
• General
– Superficial – somatosensors
– Deep – viscerosensors
– Muscles, tendons, joints –
proprioceptors
• Special
– Part of sensory organs
Somato/viscero/ proprio
Somatosensitivity, viscerosensititvity, proprioception and pain I22
• Somatosensitivity
– Pain
– Temperature
– Touch
• Viscerosensitivity
– Pain
• Proprioception
– Position
– Movement
http://www.slideshare.net/CsillaEgri/presentations
Somato/viscero/ proprio
Somatosensitivity, viscerosensititvity, proprioception and pain I23
• Somatosensitivity
– Pain
– Temperature
– Touch
• Viscerosensitivity
– Pain
• Proprioception
– Position
– Movement
http://www.slideshare.net/CsillaEgri/presentations
Evolutionary point of view
Somatosensitivity, viscerosensititvity, proprioception and pain I24
http://www.slideshare.net/CsillaEgri/presentations
• The signals indicating potential
damage are the most important and
the corresponding systems evolved
early
– Pain
– Temperature
• The touch signals have adaptive value
and evolved later
• The structure of the receptor, nerve
fibers and pathways reflects the
evolution
Evolutionary point of view
Somatosensitivity, viscerosensititvity, proprioception and pain I25
http://www.slideshare.net/CsillaEgri/presentations
• The signals indicating potential
damage are the most important and
the corresponding systems evolved
early
– Pain
– Temperature
• The touch signals have adaptive value
and evolved later
• The structure of the receptor, nerve
fibers and pathways reflects the
evolution
Evolutionary point of view
Somatosensitivity, viscerosensititvity, proprioception and pain I26
http://www.slideshare.net/CsillaEgri/presentations
• The signals indicating potential
damage are the most important and
the corresponding systems evolved
early
– Pain
– Temperature
• The touch signals have adaptive value
and evolved later
• The structure of the receptor, nerve
fibers and pathways reflects the
evolution
Evolutionary point of view
Somatosensitivity, viscerosensititvity, proprioception and pain I27
http://www.slideshare.net/CsillaEgri/presentations
• The signals indicating potential
damage are the most important and
the corresponding systems evolved
early
– Pain
– Temperature
• The touch signals have adaptive value
and evolved later
• The structure of the receptor, nerve
fibers and pathways reflects the
evolution
Free nerve endindgs
Somatosensitivity, viscerosensititvity, proprioception and pain I28
http://www.slideshare.net/CsillaEgri/presentations
• Non-specialized nerve
endings
• Polymodal
– Nociception
– Termoreception
– Mechanoreception
• A delta fibres
• C fibres
Nerve fibres
Somatosensitivity, viscerosensititvity, proprioception and pain I29 http://www.slideshare.net/CsillaEgri/presentations
Nociceptors
• Free nerve endings responding to high-intensiti stimuli
• Stimulus
– Mechanical
✓High pressure
✓Sharp object
– Thermal
✓Above aprox. 45°C
✓Low treshold – variable
– Chemical
✓pH
✓Mediators of inflammation and so on
Somatosensitivity, viscerosensititvity, proprioception and pain I30
Thermoreceptors
Somatosensitivity, viscerosensititvity, proprioception and pain I31
http://www.slideshare.net/CsillaEgri/presentations
• Free nerve endings receptive to thermal stimuli
• TRP (transient receptor potential) channels
• Polymodal receptor (chemoreception, thermoreception)
• Present also in many cells (including neurons, keratinocytes, mechanoreceptros)
Thermoreceptors
Somatosensitivity, viscerosensititvity, proprioception and pain I32
• Perceived temperature is determined by relative activity of
cold and warm receptors
http://www.slideshare.net/CsillaEgri/presentations
Thermoreceptors
Somatosensitivity, viscerosensititvity, proprioception and pain I33
• Mostly phasic response
http://www.slideshare.net/CsillaEgri/presentations
The receptors of the skin
Somatosensitivity, viscerosensititvity, proprioception and pain I34
• Simple versus complex
(rapid vibration)
(slow vibration, texture)
(rapid vibration)
(deep
pressure)
(movement of
hairs)
(sustained touch,
pressure)
http://www.slideshare.net/CsillaEgri/presentations
The receptors of the skin
Somatosensitivity, viscerosensititvity, proprioception and pain I35
http://www.slideshare.net/CsillaEgri/presentations
The receptors of the skin
Somatosensitivity, viscerosensititvity, proprioception and pain I36
http://neuroscience.uth.tmc.edu/s2/chapter02.html
72. Receptors, receptor potential vs. action potential,
receptive field
Somatosensitivity, viscerosensititvity, proprioception and pain I37
✓ Receptor definition (energy converter)
✓ Receptor potential vs. Action potential
• RP – analogue (amplitude), AP – digital
(frequency)
• RP – various ionic mechansims, AP - Na-K based
✓ Basic attributes of stimulus
• Modality, localization, intensity, duration
• The law of specific nerve energies (labeled line
coding)
✓ Receptive field
• Definition
• Examples of large and small receptive fields,
association with resolution
• Lateral inhibition
• Receptor adaptation (tonic and phasic response)
✓ Various classifications of receptors
• Brief overview of the skin receptors