Spinal Reflexes and the Somatosensory System

Question 1

what is a reflex?

Answer 1

• rapid, involuntary, stereotyped and coordinated response to a sensory stimulus
• can involve muscular contraction and glandular responses
• can be learned (Pavlovian) or unlearned (involving the somatic nervous system)

Question 2

what are spinal reflexes?

Answer 2

• somatic reflexes involving spinal cord circuitry
• require stimulation and sensory input
• quick: a few synapses are involved
• involuntary: we are aware as they happen, but they are hard to suppress
• little input from higher centres
• stereotyped: occur in the same way each time

Question 3

what is the patellar/stretch reflex?

Answer 3

• monosynaptic
• motor neuron stimulates extensor muscle contraction
• NOT IN RESPONSE TO PAIN
• tap on the knee stretches the thigh extensory muscle and associated tendon
• the reflex is a motion to correct the stretching
• important in maintaining body posture
• part of the proprioceptive system

Question 3

what is the patellar/stretch reflex?

Answer 3

• monosynaptic
• motor neuron stimulates extensor muscle contraction
• NOT IN RESPONSE TO PAIN
• tap on the knee stretches the thigh extensory muscle and associated tendon
• the reflex is a motion to correct the stretching
• important in maintaining body posture
• part of the proprioceptive system

Question 4

what is the process of the stretch/myotactic reflex?

Answer 4

1. Muscle spindle senses muscle stretch and send signals to spinal cord
2. monosynaptic connection to motor neuron in spinal cord fires AP which contracts the bicep
3. Simultaneously, a connection to an inhibitory interneuron inhibits firing of APs in motor neurons connected to the triceps
   - the antagonist muscle is relaxed
   - reciprocal inhibition

Question 5

what is reciprocal inhibition?

Answer 5

• the stretch of one muscle inhibits the activity of the opposing muscle
• Reciprocal inhibition prevents muscles from working against each other when external loads are encountered

Question 6

what are muscle spindles?

Answer 6

• proprioceptors
• detect muscle stretch
• found in most striated muscle
• abundant in muscles involved in fine motor ocntrol
• innervated by type Ia sensory fibres
• Ia sensory fibres input to alpha motor neurons which provide a response in the muscle

Question 7

do muscle spindles have muscles themselves?

Answer 7

yes

• muscle spindles are also innervated by gamma motor neurons
• gamma motor neurons stimulate intrafusal muscle fibres to adjust the tension in the muscle spindle while the extrafusal muscle fibres of the surrounding muscle contract
• ensures the spindle is never slackened

Question 8

what is kinesthesia?

Answer 8

• loss of a sense of your body moving in a space

Question 9

what is the Golgi Tendon Organ (GTO)?

Answer 9

• proprioceptor
• detects muscle tension during contraction
• GTO sensory Ib afferents being activated causes activation of inhibitory interneurons
• the interneurons inhibit alpha motor neurons that innervate the same muscle
• GTO reflex uses negative feedback that regulates muscle tension
• protects muscle from damage when large forces are generated
• prevents muscle contracting too much

Question 10

what is the difference between the muscle spindle and the GTO?

Answer 10

Muscle spindle detects stretch in muscle

GTO detects tension in muscle

Question 11

what is the flexor withdrawal reflex?

Answer 11

• quick contraction of flexor muscles to withdraw a limb from an injurious stimulus
• results from activation of nociceptors
• polysynaptic reflex
• activation of multiple excitatory neurons sustains the response: parallel after-discharge circuit

Question 12

what is the parallel after-discharge circuit?

Answer 12

• stimulus input takes different periods of time to reach output neuron depending on the number of interneurons
• ensures the initial signal is sustained over an extended period

Question 13

what 2 other responses are involved in the flexor withdrawal reflex?

Answer 13

1. reciprocal inhibition
   - inhibitory interneurons are activated to relax extensor muscles
2. crossed extensor reflex
   - due to rapid withdrawal of the limb causing imbalance, flexor reflexes involve contralateral element
   - crossed extensor reflex provides postural support during limb withdrawal

Question 14

what is the process of the flexor withdrawal reflex combined with crossed extensor reflex?

Answer 14

Flexor withdrawal reflex:

1. stepping on glass stimulates nociceptors in right foot
2. sensory neuron activates multiple excitatory and inhibitory interneurons
3. ipsilateral motor neurons to the flexor are excited
4. ipsilateral flexor contract
5. motor neurons to extensor are inhibited

Crossed extensor reflex:

6. contralateral motor neurons to extensor are excited
7. contralateral extensor (left leg) contracts to maintain balance
8. motor neurons to contralateral flexor are inhibited

Question 15

what are central pattern generators?

Answer 15

• extensors and flexors in limbs are alternately active or inhibited during walking
• activity of muscles in different limbs is coordinated so that legs alternate
• even if spinal cord connection to brain is severed, the alternation of limb movement is maintained
• local circuits are present to generate alternating pattern of flexion and extension

Question 16

what is the cellular basis of pattern generators?

Answer 16

• different neurons exhibit distinct patterns of rhythmic firing
• there is inhibition across the midline

Question 17

how is C. elegans a model organism for proprioception?

Answer 17

• TRP-4 stretch/mechanosensor allows DVA neuron to detect worm body bending
• the DVA neuron inhibits alternating motor neurons, allowing alternating muscle contraction

mutagenesis identified a mutant with loss of TRP-4 stretch receptor, causing the worm to have loopy swimming

Question 18

what are the two inputs into body sense?

Answer 18

1. mechanical stimuli

2. painful stimuli and temperature

Question 19

what are Meissner (tactile) corpuscles?

Answer 19

location:
- dermal papillae of skin e.g. palms, eyelids, lips, tongue

modality:

• light touch
• texture (movement)

sensitive to 30-50Hz
rapidly adapting

Question 20

what are Pacinian (lamellated) corpuscles?

Answer 20

location:
- dermis, joint capsules, viscera

modality:

• deep pressure
• stretch
• tickle
• vibration

sensitive to 250-350Hz
rapidly adapting

Question 21

what are Ruffini corpuscles?

Answer 21

location:
- dermis, subcutaneous tissue, joint capsules

modality:

• heavy touch
• pressure
• skin stretch
• joint movements

a proprioceptor
slowly adapting

Question 22

what are Merkel (tactile) discs?

Answer 22

location:
- superficial skin (epidermis)

modality:

• light touch
• texture
• edges
• shapes

slowly adapting

Question 23

what are free nerve endings?

Answer 23

location:
- widespread in epithelia and connective tissues

modality:

• pain
• heat
• cold

Question 24

what are hair follicles?

Answer 24

location:
- widespread in epithelia

modality:
- varied according to type

there are both rapid and slowly adapting subtypes

Question 25

what are the encapsulated nerve endings?

Answer 25

• Meissner corpuscles
• Pacinian corpuscles
• Ruffini corpuscles

Question 26

what are the unencapsulated nerve endings?

Answer 26

• Merkel discs

- free nerve endings

Question 27

what is a cellular receptor?

Answer 27

• device made of cells that detects changes in the body or the environment

Question 28

what is a molecular receptor?

Answer 28

• molecule located on surface of cell with transmembrane linkage to cytoplasm
• detects changes in molecular environment e.g. hormones, growth factors

Question 29

are all sensory receptors neurons?

Answer 29

no:
- some specialist cell types like photoreceptors, auditory/vestibular hair cells and taste receptors synapse with primary afferent neuron

some receptor cells can be neurons however e.g. olfactory receptor cells

Question 30

what are rapidly adapting/phasic receptors?

Answer 30

• give info about changes in the stimulus

- e.g. Pacinian corpuscle

Question 31

what are slowly adapting/tonic receptors?

Answer 31

• continue to respond as long as stimulus is present
• gives info about persistence of stimulus
• e.g. Ruffini corpuscle

Question 32

how are axons classified?

Answer 32

• according to the conduction velocity

- this relates to diameter: the faster the axon, the larger the diameter

Question 33

how are axons from the skin classified?

Answer 33

A, B and C:

• A is fastest and largest
• C is slowest and smallest

A is broken down by Greek letters, alpha, beta, delta

• alpha is fastest
• delta is slowest

Question 34

how are axons from the muscles classified?

Answer 34

Roman numerals: I, II, III, IV

• I = largest and fastest
• IV = smallest and slowest

Question 35

are pain fibres slower or faster than proprioceptors?

Answer 35

slower

Question 36

how is sensory information organised in the spinal cord dorsal horn?

Answer 36

Topological organisation:

• cell bodies of different sensory neurons are grouped in the DRG
• projections are organised into different layers of the dorsal horn
• e.g. info from different classes of hair follicle is represented in different layers

sensory info remains spatially organised as it is sent to the brain

Question 37

what are the two main routes of somatosensory projections to the brain?

Answer 37

1. Medial Lemniscal Tracts

2. Spinothalamic tract

Question 38

what is the medial lemniscal tract?

Answer 38

• carries mechanoreceptive and proprioceptive signals to thalamus
• projects into spinal cord before going to brain

Question 39

what is the spinothalamic tract?

Answer 39

• carries pain and temperature signals to the thalamus

- goes to the neuron immediately in the brain at the midline

Question 40

what are the 3 neurons that sensory info travels through to reach the higher centres?

Answer 40

1. First order neurons:
   - detect stimulus and transmit to spinal cord (DRG neurons
2. second order neurons:
   - neurons that relay signal to the thalamus
3. third order neurons:
   - carry the signal from the thalamus to the cortex

Question 41

what is special about second order neurons?

Answer 41

• they cross the midline so are commissural (ipsilateral to contralateral)

Question 42

how are axons of the Medial Lemniscal system topologically organised?

Answer 42

Upper body: 1st order axons follow lateral pathway and synapse to 2nd order neurons in cuneate nucleus

Lower body: `1st order axons follow medial pathway and synapse to neurons in gracile nucleus

2nd order axons cross midline and ascend in medial lemniscus
- topology is reversed so that lower body axons are lateral when reaching thalamus

3rd order axons reverse topology so lower body axons synapse to medial cortical neurons, while upper body axons go to lateral cortex

Question 43

how are axons of the Medial Lemniscal system topologically organised?

Answer 43

Upper body: 1st order axons follow lateral pathway and synapse to 2nd order neurons in cuneate nucleus

Lower body: `1st order axons follow medial pathway and synapse to neurons in gracile nucleus

2nd order axons cross midline and ascend in medial lemniscus
- topology is reversed so that lower body axons are lateral when reaching thalamus

3rd order axons reverse topology so lower body axons synapse to medial cortical neurons, while upper body axons go to lateral cortex

Question 44

what are the dorsal column nuclei?

Answer 44

1. cuneate nucleus
   - for upper body axons in lateral pathway synapsing to 2nd order neurons
2. gracile nucleus
   - for lower body axons in medial pathway synapsing to 2nd order neurons

Question 45

what is topological organisation?

Answer 45

spatial arrangement of objects relative to one another

Question 46

where is the somatosensory cortex is the brain?

Answer 46

• sits posteriorly to the central sulcus

- postcentral gyrus

Question 47

what is the role of the somatosensory cortex?

Answer 47

• produces a topological map of the body in the cortex
• the map is fine
• reflects the fact that each DRG innervates a dermatome (a specific domain of the body)

Question 48

what is a dermatome?

Answer 48

• each sensory ganglion innervating a specific region of the skin
• regions arise due to the dermis of each region being formed from a somite

Question 49

what is a somite and how does it relate to the specific innervation of sensory ganglions?

Answer 49

• somites form musculature and skeleton
• in the embryo each DRG (sensory ganglion) is associated with a specific somite, so innervates the tissues that arise from that somite

topological organisation is preserved in the spinal cord and the somatosensory projections

Question 50

what do topological and topographical mean?

Answer 50

topological = the way in which constituent parts are interrelated/arranged

topographical = representation of distribution of parts/features on the surface of/within the organ or organism

Question 51

where else are there topological maps in the nervous system

Answer 51

• in the thalamus, which acts as a way station between 2nd and 3rd order neurons
• in the dorsal column nuclei

Question 52

is the topographic map representative of the physical size of the body parts it is relating to?

Answer 52

no

• the area occupied by different regions in the cortex is not proportional to their physical size
• e.g. area for hands is much larger than area for legs

Question 53

what does the receptive field of a neuron depend on?

Answer 53

• where the neuron is in the body, as some regions have denser innervation than others

Question 54

how can the size of a receptive field be measured?

Answer 54

Two point discrimination:

• assess the ability of the subject to discriminate two sharp points set apart at different distances
• if the subject feels two pin points, then the distance between the points is larger than the receptive field

allows determination of sizes of receptive fields in different parts of the body

Question 55

how does receptive field size vary?

Answer 55

• where receptive fields are large, discrimination is low e.g. in arms and legs
• where receptive fields are small, discrimination is high e.g. fingers

Question 56

how is the cortex involved in receptive fields?

Answer 56

• there is more cortex dedicated to regions where receptive fields are small
• in small regions, number of nerve endings from different neurons is higher, so there is more sensory input
• this results in larger number of axons per unit area being represented in the cortex

Question 57

what does the number of sensory neurons innervating a particular area depend on?

Answer 57

the behavioural significance of that area

Question 58

what does behavioural significance determine in the brain?

Answer 58

• cortical representation of certain body parts
• e.g. the representation of the hand is large in the human cortex, whereas in rodents, whiskers have a larger representation in the cortex

Question 59

where is the somatotopic map preserved?

Answer 59

• in the coronal plane of the postcentral gyrus

Question 60

where are sensory modalities located in the postcentral gyrus?

Answer 60

• along the sagittal axis

Question 61

what are Brodmann areas?

Answer 61

• different regions that receive inputs from different types of sensory receptors

Question 62

how is the cortical map plastic?

Answer 62

• neurons which are used more are strengthened

- neurons which are used less are eliminated

Question 63

what experiment proves cortical map plasticity?

Answer 63

• digits of monkey are mapped onto different areas of the cortex
• digit 3 was removed
• over months, the areas dedicated to digit 2 and 4 spread to where the neurons for digit 3 were
• if the stimulus increased to the digits, the area in the cortex that represents those digits increases