1. Somatic Sensory System
Visceral Sensory System
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sensory physiology

2. Introduction Our awareness of bodily sensation Sensory experience
Depend on processing of
Sensory information from different sensory receptors
Touch, pain, temperature, auditory receptors
Sensory experience
Has several parameters
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3. Introduction Sensory parameters
Quality or modality (kind of sensation)
Warmth, cold, sweet,bitter
Intensity
Location
Timing
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4. Modality Different types of sensation that we are aware off include
Smell, touch, hearing, and taste
Pain, temperature,position sense, visceral sensation
Information transmission to CNS
By action potential
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5. Modality Action potential from How is it possible for nerves
Touch receptor not different from that of pain receptor
How is it possible for nerves
To transmit information about
Different sensation
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6. Determination of Modality
Specific pathways (Mullers doctrine)
Modality of sensation depends
What end organ or nerve fiber is stimulated
Each nerve tract
Terminate at specific point in CNS
Type of sensation felt
Determined by activation of specific area to which the fibers lead
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sensory physiology

7. Determination of Modality
There are specific pathways (labeled lines)
For different (modalities) kind of sensation
Stimulation of pain fibers by what ever mechanisms
Electrical, heat, crushing
Will elicit pain
Stimulation of retina by what ever mechanism
Visual sensation
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8. Intensity Discrimination
Weak stimulus activate
Receptors with low threshold only
Strong stimulus activate both
Low threshold & high threshold receptors
Hence the number of AP 
Frequency of AP 
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9. Intensity Discrimination
The stronger the stimulus
The greater the frequency of AP
The greater the number of sensory units activated
This is interpreted by the brain
As  in intensity
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10. Determination of Location
Determined (encoded) by
The location of sensory projection to cerebral cortex
No matter where particular sensory pathways is stimulated
Brain
Skin A B
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11. Determination of Location
Conscious sensation
Referred to the location of the receptor
Gives the sensation of
Phantom limbs in people with amputation
Brain
Skin A B
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12. Determination of Location
Each sensory neuron
Receive information
From particular sensory area
Called receptive field
Sensory nerve
Sensory receptors
Receptive field
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13. Determination of Location
However
Extensive overlap of the receptive fields
Application of stimulus at
Point “A” stimulates the blue nerve only
Point “C” stimulates the red nerve only
Point “B” stimulate both
Sensory nerves A C B
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14. Determination of Location
Transmit AP
Stimulus localization
Can be made more precise by
Lateral inhibition
Inhibited
Inhibited
Lateral inhibition
Lateral inhibition
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15. Nerve Fiber Classification
Type
Group
Diameter (m)
Speed (m/s)
Function A I
12 – 20
72 – 120
Muscle spindles, motor to skeletal muscles A II
6 – 12
36 – 72
Touch, pressure, muscle spindles A
III
1 – 6
6 – 36
Pain, temperature A 5
15 – 30
Motor to muscle spindles C IV
< 1m
0.5 – 2
Pain B
Pre-ganglionic Autonomic nerves
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16. Sensory Pathways Peripheral Tactile sensation
Touch, pressure, proprioception, vibration
Required for accurate localization on skin
Transmitted through
Rapid conducting fibers
Group II (type A)
30 – 72 m/sec
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17. Sensory Pathways Less critical type of sensation Crude touch
Transmitted in
Slow conducting fibers
Group IV (type C)
1 m/sec
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18. Sensory Pathways Muscle spindle & tendon organs
Transmit by group I (type A)
72 – 120 m/sec
Sensation from cold and warm receptors
Transmitted by group III (type A)
5 – 30 m/sec
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sensory physiology

19. Sensory Pathways Sensation from pain receptors
Transmitted through group III (type A) and
Group IV (type C)
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20. In the Spinal Cord Sensory afferents enter the spinal cord
Dorsal root fibers
Segregate according to function
Large fibers (A, A)
From special mechano-receptor
Skin, muscles, joints, viscera
Mediate fine touch, pressure, proprioception
Enter the dorsal column
Posterior/dorsal column
A, A
Lateral spinothalamic tract
A & gp IV
Anterior spinothalamic tract
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sensory physiology

21. In the Spinal Cord Ascend to medulla Second order neuron
Synapse in gracilis & cuneatus nuclei
Second order neuron
Cross over to join the medial leminiscus
End up in ventral basal & ventral posterior nuclei of thalamus
Posterior/dorsal column
A, A
Lateral spinothalamic tract
A & gp IV
Anterior spinothalamic tract
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22. In the Spinal Cord Small fibers
A ( gp III) & C (gp IV)
Ascend or descend a few segments in the tract of Lissauer
Synapse with dorsal horn cells
Cross over to ascend
Lateral & ventral spinothalamic tract
Posterior/dorsal column
A, A
Lateral spinothalamic tract
A & gp IV
Anterior spinothalamic tract
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23. The Sensory Cortex The ventro-basal nucleus of the thalamus
Connected by both ascending and descending axons
From the two cortical areas
Sensory cortex I & II
The periphery of the body
Projected onto the cortex
Topographic organization
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sensory physiology

24. The Sensory Cortex Concerned with perception of Concerned with
Most stimuli that enter into consciousness
Concerned with
Recognition of form, texture, size, weight, consistency of objects
Stereo-gnosis
Discrimination of size & shape
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25. The Sensory Cortex Change in position of different parts of the body
Accurate localization and recognition of
Nature of stimuli applied to body
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26. The Sensory Cortex Discrimination between Ability to relate
2 simultaneously applied stimuli
2 point discrimination
Ability to relate
Sensory experience with
Other experiences
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27. Somatic Sensation Can be classified into
Mechano-receptive somatic sense
Mechanical stimulation of tissue
Thermo-receptive sense
Detect heat or cold
Pain sense
Activated by factors that damage tissue
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sensory physiology

28. Mechano-receptive Sensation
Sensation produced by
Mechanical stimulation of the skin
Divided into 3 sub modalities
Vibration
Touch
Pressure
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29. Mechano-receptive Sensation
Vibration sensation
Results from
Rapid repetitive sensory signals
Encoded by pacinian corpuscles
Rapid adapting receptors
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30. Mechano-receptive Sensation
Deformation of nerve terminals
 memb permeability to Na+, K+
Produce depolarizing receptor potential
Frequency of discharge by pacinian corpuscle
Equals the frequency of vibration
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31. Mechano-receptive Sensation
Pressure sensation
Result from deformation of deeper tissues
Encoded by Ruffini’s corpuscle
Capsule contain liquid filled collagen structure
gp II sensory nerve
Ruffini’s corpuscle
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32. Mechano-receptive Sensation
Any deformation or stretch of the collagen
Causes nerve terminals to depolarize
Generate action potential
Gp II sensory nerve
Ruffini’s corpuscle
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33. Mechano-receptive Sensation
Ruffini’s corpuscle are slow adapting
AP continue
As long as stimulus is present
The magnitude of stimulus
Is encoded by frequency of AP
Gp II sensory nerve
Ruffini’s corpuscle
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34. Mechano-receptive Sensation
Meisser’s corpuscle
Touch sensation
Result from stimulation of
Tactile receptors
In skin or tissues immediately beneath
Encoded by both
Meisser’s corpuscles
Merkel’s disks
Merkel’s disks
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sensory physiology

35. Mechano-receptive Sensation
Meisser’s corpuscle
Meissner’s corpuscles & merkle’s disks
Numerous on
Fingers, lips
Relative scarce on trunk
Merkel’s disks
Receptor cell
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sensory physiology

36. Mechano-receptive Sensation
Meisser’s corpuscle
Meissner’s corpuscles
Rapidly adapting
Receive group II sensory nerve
Frequency of firing
Proportional to rate of stimulation
Missner’s encode
The velocity of stimulus application
Merkel’s disks
Receptor cell
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sensory physiology

37. Mechano-receptive Sensation
Meisser’s corpuscle
Merkle’s disks
Transducer is not on on nerve terminal
On epithelial cell that make up the disk
Disk make synaptic contact
Group II sensory nerve
Merkel’s disks
Receptor cell
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38. Mechano-receptive Sensation
Meisser’s corpuscle
Disk is 0.25 mm
Can only be stimulated
If stimulus is applied directly on disk
Ideal for recognition
Exact point of body being stimulated
Merkel’s disks
Receptor cell
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39. Proprioception In the conscious state This ability is known as
We are constantly aware of
Position
Movements of different parts of body
This ability is known as
Proprioception or deep sensibility
Stimuli to receptors
Derived from the body itself
Not from the surrounding
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40. Proprioception Receptors lie in The sense of position
Muscles, tendon, joints
The sense of position
Ability to know the position of ones limb
The orientation of their part
With respect to one another
Static position
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41. Sense of Position Inform us of From this information
Angles at each joint
From this information
Overall orientation of the limb is derived
Sense of position exhibit
Little adaptation
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42. Sense of Movement When we change the angle of joints
We are aware of both the
Direction and
Velocity of movement
This quality of proprioception
Called sense of movement
Kinaesthesia
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43. Thermal Sensation Cutaneous temperature sensibility
Sensation of cold
Sensation of warmth (heat)
Temperature slightly
Above body temp perceived as warmth
Temp below body temp
Perceived as cold
Thermoneutral range
Cold  Below
Above warm
37OC ± 0.5OC
Body temp
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44. Thermal Sensation There are discrete Cold spots are numerous on
Cold sensitive spots
Warm sensitive spots
Are 4 – 10 times as many as
Are warm spots
Cold spots are numerous on
Lips, finger tips, earlobes
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45. Thermal Sensation Warm receptors Begin to respond at 30OC
Reach maximum at 45oC
Cease to operate at 47OC
Warm fibers
Discharge rate
Cold fibers 40 10 20 30 50
Increase in Temperature OC
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46. Thermal Sensation Cold receptors Begin to respond at 15OC
Reach maximum at 25oC
Cease to operate at 42OC
Warm fibers
Discharge rate
Cold fibers 40 10 20 30 50
Increase in Temperature OC
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47. Thermal Sensation If the temp > 45OC This is threshold
Cold receptor begin to fire again
This is threshold
For activating pain receptors
Thus if the skin is heated >45OC
Sensation of pain accompanied by feeling of coolness
Paradoxical cold
Warm fibers
Discharge rate
Cold fibers 40 10 20 30 50
Increase in Temperature OC
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sensory physiology

48. Pain Sensation Purpose is not to inform the brain But to indicate that
About the quality of stimulus
But to indicate that
The stimulus is damaging
Unpleasant
Leads to removal of the damaging stimulus
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49. Pain Sensation Peripheral mechanism Receptors Nociceptors
Respond to noxious stimuli
Free nerve endings of small
Myelinated A fibers
Unmyelinated C fibers
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50. Pain Sensation Nociceptors Respond to damaging or potentially damaging
Specific for painful stimuli
Respond to damaging or potentially damaging
Mechanical, chemical, electrical, thermal stimuli
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51. Pain Sensation Adequate stimulus for nociceptors Assumed that
Not known
Assumed that
Damaged cells by painful stimulus
Release chemicals such as
Histamine, H+, K+, bradykinin, 5HT
These chemicals then
Activate the nociceptors
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52. Types of Pain Two types of pain sensation Fast (initial) pain
Result from strong noxious stimuli
Fast (initial) pain
Discrete, well localized
Pinprick sensation
Results from activation of A fibers
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53. Types of Pain Slow or delayed pain Poorly localized
Dull ache, burning sensation
Results from activation of C fibers
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54. Types of Pain Two types of pain sensation use Fast pain
Different pathway to reach centers for consciousness
Fast pain
Conducted by A (gp III)
Velocity of conduction is 12 – 30 m/sec
AP travel faster
Reach the brain before slow pain fibers
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55. Types of Pain The A sensory fibers Slow pain
Use spinothalamic tract to sensory cortex
Topographically represented on cortex
Slow pain
Conducted by group IV type C fibers
Velocity of conduction is m/sec
Give collaterals to
Reticular formation
Activate fibre tracts that produce the
Emotional perception accompanying pain
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56. Types of Pain The two types of pain elicit different reflexes
Fast pain
Evoke withdrawal reflex
Sympathetic response
 BP
 mobilization of body energy supplies
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57. Types of Pain Slow pain evoke Nausea Profuse sweating  BP
Generalized reduction in skeletal muscle tone
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sensory physiology