Electroneurography Flashcards
1
Q
What is electroneurography?
A
- nerve conduction measurement
2
Q
Motor nerve conduction
A
- using same EMG and nerve stimulation equipment
- can quantify motor nerve conduction
3
Q
Use of electrodes
A
- most nerve conduction studies use surface electrodes
- occasionally monopolar needle electrodes are used
- stimulating cathode placed peripherally (closest to muscle being monitored)
4
Q
Basic measurements
A
- nerve typically stimulated at 2 sites down its length
- site nearest to muscle is called the distal site
- further is proximal site
- measurements made of muscle potential amplitude, duration of negative (upward) phase, distal and proximal latencies
5
Q
Decay
A
Decay = 100 x (Adist-Aprox)/Adist
- measure of decrease in size of the muscle potential when stimulated at the proximal compared with the distal site
- because of spread in nerve conduction velocities, muscle potentials arising from proximal stimulation may be more dispersed causing slight reduction in amplitude
6
Q
Dispersion
A
Dispersion = 100 X (DURprox - DURdist)/DURprox
- measures spread of potential when stimulated at the proximal compared with the distal site
7
Q
Conduction block
A
- > 20% amplitude or area decay less than 15% dispersion
- > 50% amplitude or area decay
- both criteria are equally sensitive, but latter is more specific
- decay will be increased
- spread of conduction velocities increasing dispersion will also affect amplitude causing increase in decay when there is no conduction block
8
Q
Simple conduction velocity measurement
A
- conduction velocity is temperature dependent, becoming faster as the muscle warms up
- for accurate measurements, temperature controller may be used
9
Q
Sensory nerve conduction
A
- no large muscle action potential to measure
- can’t stick needles into nerves
- surface electrodes can measure very small compound nerve action potentials, but these may be lost in the noise
10
Q
Averager
A
- adds together responses from repetitive stimulation
- responses sum linearly, whereas noise sums in proportion to the square root of the number of stimuli
- stimuli should not be synchronised with the mains frequency
11
Q
Ring electrodes for sensory stimulation
A
- for motor nerve stimulation
- electrodes designed for minimal current density in the skin = minimising discomfort
- sensory stimulation electrodes are designed to stimulate nerve endings
- spring electrodes can be slipped over fingers and tightened
12
Q
Averager response
A
- with single stimulus, response can be seen
- can be easily mistaken for a noise peak
- some averagers designed to deliver stimuli at different points of the mains cycle to eliminate this type of interference
13
Q
Sensory nerve conduction velocity measurement
A
- sensory stimulating electrodes placed away from motor end plate zone of any muscles innervated by the nerve
- avoids stimulating motor nerves
14
Q
Hopf collision technique
A
- method of obtaining complete distribution of motor nerve velocities, rather than just measuring the fastest
- proximal and distal stimuli applied (distal first) with variable interval in between (DPSI)
- because of refractory period = when antidromic pulse from distal site collides with orthodromic potential from proximal site, propagation ceases in both directions
- if DPSI is long enough, distal pulse will pass proximal site allowing time for refractory period to end before proximal stimulus is given
- proximal potential can then propagate to muscle and induce a muscle action potential
15
Q
Increasing distal-proximal stimulus interval
A
- gradual increase in size of second proximally stimulated muscle action potential as DPSI is increased
- initially, no second pulse, then muscle fibres innervated by faster nerves create a potential and finally the slower ones
- each DPSI value corresponds to specific nerve conduction velocity
- amplitude or area of second muscle potential corresponds with cumulative distribution of the motor nerve conduction velocities
- SEE SLIDE
