7b. Spinal Cord and Muscles Flashcards
Organisation of the Ventral Horn of the Spinal Cord
Distal limb motor neurones are lateral
Proximal limb motor neurones are medial
Motor Neurone Pool
All 200-500 α motor neurones that innervate a given muscle
Located close together in the ventral horn
Motor Unit
Single α motor neurone and all the muscle fibres it branches to innervate
Basic unit of force production
Each muscle contains 200-500 motor units as they are innervated by 200-500 α motor neurones
3 Mechanisms of Controlling Contraction Force
- Type of motor unit stimulated
- Rate coding
- Motor unit recruitment
3 Types of Motor Unit
- Slow
- Fast, fatigue resistant
- Fast fatigable
Types of Motor Unit
- Slow Motor Unit Anatomical Characteristics
- Small fibres
- Few fibres per unit
- Highly vascular
Types of Motor Unit
- Slow Motor Unit Biochemical Characteristics
- Oxidative metabolism
- Abundant myoglobin (red)
Types of Motor Unit
- Slow Motor Unit Physiological Characteristics
- Slow twitch
- Low tension generation
- Fatigue resistant
- Slow, small diameter axons
Types of Motor Unit
- Slow Motor Unit Use
Continuous generation of small forces
Types of Motor Unit
- Fast Fatiguable Motor Unit Anatomical Characteristics
- Large fibres
- Many fibres per unit
- Few capillaries
Types of Motor Unit
- Fast Fatiguable Motor Unit Biochemistry Characteristics
- Glycolytic metabolism
- Little myoglobin (white)
Types of Motor Unit
- Fast Fatiguable Motor Unit Physiology Characteristics
- Fast twitch
- High tension generation
- Fatigable
- Fast, large diameter axons
Types of Motor Unit
- Fast Fatiguable Motor Unit Use
High forces over a short period of time
Rate Coding
Rate coding can be used to control generation of low-medium forces
An increase in action potential firing frequency generates more twitches.
However, muscle go into tetanus at quite low frequencies, so motor unit recruitment is used to generate higher forces
Motor Unit Recruitment
Motor unit recruitment can be used to control force generation
Motor Unit Recruitment
- Size Principle
Low force motor units are recruited first then higher force motor units
Therefore force always increments by the finest available motor unit so is as smooth as possible
Motor Unit Recruitment
- Developmental Plasticity
Motor neurones with low firing threshold innervate few muscle fibres and induce them to become slow twitch, low force fatigue resistant fibres.
Motor neurones with high firing threshold innervate many fibres and induce them to become fast twitch, high force and fatiguable
Avoids the need for the brain to control motor neurones independently as inputs to motor neurones innervating a given muscle will automatically recruit motor neurones that generate the lowest force first, as they are low threshold
Motor Neurone Damage
- Result
Flaccid Paralysis
Motor Neurone Damage
- Degeneration
Motor neurone disease (ALS)
Motor Neurone Damage
- Autoimmune disease
Guillain Barre syndrome, where motor neurones demyelinate
Motor Neurone Innervation
- 3 Sources
- Muscle spindle afferents
- Descending fibres
- Spinal interneurones
Proprioception
- Definition
- Receptors
Sense of position or movement of the body
- Proprioceptors
- Ruffini endings (exteroceptors)
Proprioceptors
- Description
Sensory fibres in muscles and joints
Peripheral Sensory Fibres
- 3 Types
- Proprioceptors (muscles, tendons and joints)
- Exteroceptors (skin)
- Teloceptors (special sense organs)
Number of Sensory and Motor Neurones in Muscle Nerves
Sensory neurones massively outnumber motor neurones in muscle nerves
Proprioceptors
- 3 Types
- Muscle spindle affernets
- Golgi tendon organ afferents
- Join receptors
Proprioceptors
- 3 Functions
- Spinal reflexes
- Proprioception
- Provide information for supra spinal motor systems
Muscle Spindle Afferents
- Receptor Type
Proprioceptors that detect:
- Muscle length
- Change in muscle length
Signal:
- Muscle length
- Changes in muscle length
2 Types of Muscle Fibre
- Extrafusal muscle fibre
- Intrafusal muscle fibre
Extrafusal Muscle Fibre
- Large
- Not present in muscle spindles
- Contract to generate tension
Intrafusal Muscle Fibre
- Characteristics
- Small
- Present in muscle spindles
- Contract to alter sensitivity of sensory neurone endings in the spindle
- Only the ends are striated and contractile
Muscle Spindles
- Number
20-100 in each muscle
Muscle Spindles
- Number of Intrafusal Fibres
10-12
Intrafusal Muscle Fibre
- 2 Types
- Bag fibre
- Chain fibre
Intrafusal Muscle Fibre
- Bag Fibre Structure
- Swollen centre containing many nuclei
- Striated contractile ends
Intrafusal Muscle Fibre
- Chain Fibre Structure
- Uniform diameter
- Many nuclei in a line
- Uniform striations
Intrafusal Muscle Fibre
- 2 Types of Afferent
- Primary Ia spindle afferent
- Secondary IIa spindle afferent
Intrafusal Muscle Fibre
- Primary Ia Spindle Afferents
- Large
- Fast conducting
- Spiral around centre of bag and chain fibre
- Terminal fibres are called annulospiral endings
- Equivalent to Aα motor neurones
- Rapidly adapting
- Very sensitive
- Carry mainly dynamic responses to change in muscle length
Intrafusal Muscle Fibre
- Secondary IIa Spindle Afferents
- Small
- Slow conducting
- Terminate adjacent to the central region of the intrafusal muscle fibre
- Equivalent to Aβ motor neurones
- Carry mainly static response to muscle length
Intrafusal Muscle Fibre
- Bag Fibre Stretch Response
Both a dynamic and static response to stretch
Dynamic:
Dynamic response to change in muscle length, as non-contractile centre stretch first.
Because primary Ia afferents are in the central region, stretch gives strong rapid increase in action potential frequency
Static:
Static response to muscle length as stretch is relieved as contractile ends elongate, decreasing action potential frequency
Intrafusal Muscle Fibre
- Chain Fibre Stretch Response
Very small dynamic response to stretch.
Static response to stretch as the whole fibre is contractile
Intrafusal Muscle Fibre
- Efferent Innervation Function
Controls the sensitivity of the terminals by triggering contraction.
Contraction elongates the ends of the spindle, elongating the central region and sensitising the response of afferent fibres innervating it.
Allows muscle spindles to gave a similar sensitivity to length changes from different starting points, which is a type of adaptation
Intrafusal Muscle Fibre
- Efferent Innervation Neurones
Gamma motor neurones:
- Small diameter
- Slow conducting
Gamma Motor Neurone
- 2 Types
- Static gamma motor neurones
- Dynamic gamma motor neurones
Intrafusal Muscle Fibre
- Afferent Firing Frequency
Could be increased by:
- Muscle stretch
- Increased efferent innervation
Therefore muscle length is ambiguous
Intrafusal Muscle Fibre
- Efferent Copy
Efferent copy is a record of recent gamma motor neurone activity, which allows the brain to determine muscle length
Golgi Tendon Organs
- Receptor Type
Proprioceptors that detect tendon tension
Golgi Tendon Organs
- Activation
Active tension in the tendon brought about by muscle contraction.
Passive stretch of the muscle doesn’t activate Golgi tendon organs as muscle elasticity prevents tension on the tendon
Joint Receptors
- Receptor Type
Proprioceptors that signal joint position and movement, especially at extremes
Stretch Reflex
- Function
Muscles contract in response to being stretched
Stretch Reflex
- Exceptions
- Eye muscles, which contract against a fixed load
- Intrinsic tongue muscles
Stretch Reflex
- Sensory Arm
Muscle stretch stimulates muscle spindle afferents
Stretch Reflex
- Synapse
Muscle spindle afferent synapses with motor neurones to several different muscles in the spinal cord
Stretch Reflex
- Motor Arm
α motor neurones to trigger contraction of the:
- Stretched muscle
- Synergist muscles
Stretch Reflex
- Spinal Interneurones
None = monosynaptic reflex
Stretch Reflex
- Use
Postural control
Disadvantages of Stretch Reflex Negative Feedback
- Gain <1
- Delays
Gain
Stretch should elicit contraction to precisely counteract, giving a gain of 1.
When measured, gain<1
completely cancel it out
Damage to Descending Motor Systems
- Characteristics
Causes spastic paralysis, where:
- Stretch is exaggerated so strong responses are evoked
- Oscillating muscle contractions following fast muscle stretch = myoclonus
Damage to Descending Motor Systems
- 2 Causes
- Cerebral palsy
- Stroke
Stretch Reflex
- Role
Brain may be able to control gain of the stretch reflex so that it suits the movement required, through adjusting spindle afferent sensitivity using efferent innervation.
- Slow, precise movements have low gain stretch reflexes to allow negative feedback
- Rapid movement shave high gain stretch reflexes to allow feedforward predictive mechanisms
Renshaw Cells
- Pathway
Motor neurones give off intraspinal branches (recurrent collaterals), that innervate Renshaw cells.
Renshaaw cells project to the spinal cord and inhibit the motor neurone that excited it
Renshaw Cells
- Function
Mediate recurrent inhibition
Regulate pattern of motor neurone discharge to prevent jerkiness and tremor
Nociceptor Withdraw Reflex
- Function
Nociceptor activation trigger movement of the Boyd part away from the stimulus
Nociceptor Withdraw Reflex
- Sensory Arm
C-fibres and A-delta fibres
Terminate in superficial forsal horn, in the substantia gelatinosa
Nociceptor Withdraw Reflex
- Interneurones
- Excitatory interneurones in the superficial dorsal horn, in the substantial gelatinosa
- Inhibitory internueones in the intermediate zone of the spinal cord that are activated by excitatory interneurones
Nociceptor Withdraw Reflex
- Motor Arm
Secondary interneurones synapse with motor neurones that generate reflex flexor contraction and extensor inhibition
Nociceptor Withdraw Reflex
- Properties
- Spatial summation
- Temporal summation
- Local sign, where contracted muscle differ depending on the stimulus location
Tendon Organ Reflex
- Sensory Arm
Tendon organ afferents
Tendon Organ Reflex
- Interneurones
- Excitatory interneurone
- Inhibitory interneurone, excited by the excitatory interneurone
The presence of 2 interneurones allows context dependence:
- Static postures = tendon organ reflex evokes inhibition of parent muscle
- Locomotion = tendon organ reflex evokes excitation of parent muscle, supporting contraction against load
Tendon Organ Reflex
- Motor Arm
Motor neurones
Spinal Reflexes
- Importance
- Show developmental changes so give an indication of neural development
- Changes upon brain damage
Spinal Reflexes
- Developmental Changes
Infantile grasp reflex:
- Grasping object placed in hand
- Disappears at 6-9 months
Reflex stepping:
- Appears at 4 months
- Different sequence appears at 1 year
Babinski’s sign:
- Curling of toes in response to scratching the sole
- Infants = upward curl
- Adults = downward curl
Spinal Reflexes
- Brain Damage
Loss of supra spinal control allows the brainstem and spinal cord to control movement entirely.
- Exaggerated stretch reflexes (spasticity) and myoclonus
- Babinki’s sign reverts to infant form
- Clasp knife reflex, where limbs snap into either extension or flexion