Neurophysiology

Question 1

It affects the central and peripheral nervous system that is an autosomal disorder manifesting in early childhood. Sensorimotor neuropathy, corticospinal tract involvement with upper motor neuron signs, and optic atrophy leading to vision loss. The characteristic gait includes walking on the inner edges of the feet. The integument is also involved, and patients often have tightly curled hair. What is the diagnosis and gene involved?

Answer 1

Giant Axonal Neuropathy (GAN)

gigaxonin gene

Question 2

What is accumulated in Refsum Disease?

Answer 2

Phytanic Acid

Question 3

F-wave is obtained via

Answer 3

Supramaximal stimulation of a motor nerve

Question 4

What are the 3 main measures of Sensory NCS?

Answer 4

Sensory Nerve Amplitude (SNAP) in microvolts
Sensory Latency (Onset and Peak)
Conduction Velocity

Question 5

Definition of SNAP amplitude

Answer 5

SNAP amplitude (in microvolts) represents a measure of the number of axons conducting between the stimulation site and the recording site.

Question 6

Definition of Sensory Latency.

Answer 6

Sensory latency (in milliseconds) is the time that it takes for the action potential to travel between the stimulation site and the recording site of the nerve.

Question 7

What is the definition of conduction velocity?

Answer 7

The conduction velocity is measured in meters per second and is obtained by dividing the distance between the stimulation site and the recording site by the latency: Conduction velocity = Distance/Latency.

Question 8

How is sensory NCS obtained?

Answer 8

It is obtained by stimulating a sensory nerve while recording the transmitted potential at a different site along the same nerve.

Question 9

Compound Muscle Action is one of the resulting responses of motor CS. What does this interpret?

Answer 9

It depends on the motor axons transmitting the action potential, status of the neuromuscular junction, and muscle fibers.

Question 10

Decrease in amplitude correlates best with…

Answer 10

Axonal loss lesions

Question 11

What are the NCS findings in demyelination?

Answer 11

Prolonged latencies

Slowed conduction velocities

Question 12

What is F-wave and what does it measure?

Answer 12

Supramaximal stimulation of a motor nerve while recording from a muscle.
The electrical impulse travels antidromically (conduction along the axon opposite to the normal direction of impulses) along the motor axons toward the motor neuron, backfiring and then traveling orthodromically (conduction along the motor axon in the normal direction) down the nerve to be recorded at the muscle

Question 13

What is the equivalent of H-reflex?

Answer 13

Ankle Reflex (S1 reflex arc)
It is obtained by stimulating the tibial nerve at the popliteal fossa while recording at the soleus. The electrical impulse travels orthodromically through a sensory afferent, enters the spinal cord, and synapses with the anterior horn cell, traveling down the motor nerve to be recorded at the muscle.

Question 14

How is insertional activity recorded? What does it imply?

Answer 14

Insertional activity is recorded as the needle is inserted into a relaxed muscle.

increased in denervated muscles and myotonic disorders
decreased when the muscle is replaced by fat or connective tissue and during episodes of periodic paralysis.

Question 15

How is spontaneous activity recorded? What does it imply?

Answer 15

Spontaneous activity is assessed with the muscle at rest, and examples include fibrillation potentials, fasciculation potentials, and myokymia and myotonic potentials. All spontaneous activity is abnormal.

Question 16

How are motor unit potentials recorded? What does it imply?

Answer 16

MUPs are obtained while the needle is inserted into the muscle during voluntary contraction.

Characterized by recruitment pattern and MUP morphologic features (Duration, amplitude adn configuration)

Question 17

What is the definition of recruitment?

Answer 17

measure of MUPs firing during increased force of voluntary muscle contraction

Reduced recruitment- Axonal loss

Early or rapid recruitment- myopathic processes with loss of muscle fiber

Question 18

What are the electromyographic findings in neuropathic disorders with denervation and reinnervation?

Answer 18

MUPs disclose increased duration and amplitude, and may be polyphasic.

Question 19

What are the electromyographic findings in myopathic disorders?

Answer 19

MUPs are of reduced duration and amplitude, and may also be polyphasic

Question 20

When do you observe fibrillation potentials?

Answer 20

fibrillation potentials seen 3 weeks after the onset of motor axon loss

Question 21

What are the repetitive stimulation findings in Myasthenia Gravis?

Answer 21

slow repetitive RNS (2-3Hz)

-decrement of CMAP amplitudes with a decrement of greater than 10%

Question 22

What is the pathophysiology behind decremental response in Myasthenia Gravis?

Answer 22

decremental responses occur due to:

• normal reduction in the release of acetylcholine after subsequent stimulation
• reduced availability of receptors from the disease, leading to a loss of end- plate potentials and reduction of the motor action potentials

Question 23

What are the repetitive stimulation findings in Lambert Eaton Myasthenic Syndrome?

Answer 23

decremental response with slow repetitive stimulation, given that there is a decline in acetylcholine release with each stimulus, leading to loss of end-plate potentials and reduction of the motor action potential.

Rapid stimulation with frequencies of 20 to 50 Hz produces an incremental response by overcoming the efflux of calcium
The incremental response has to be more than 50% to be considered diagnostic.

Question 24

What is jitter in Single Fiber-EMG?

Answer 24

Recording with a single-fiber needle electrode positioned to detect potentials from two muscle fibers of the same motor unit.

The variability of the interpotential interval between these two potentials is the jitter, and it is abnormal in MG due to delayed neuromuscular transmission.

Question 25

Single Fiber EMG, Sensitive or Specific to MG?

Answer 25

Sensitive

Question 26

Slow-Oxidative. Type 1 or 2?

Answer 26

Type 1

Question 27

Slow ATPase activity. Type 1 or 2?

Answer 27

Type 1

Question 28

large oxidative capacity with large numbers of mitochondria. Type 1 or Type 2?

Answer 28

Type 1

Question 29

Fast Oxidative glycolytic fibers and fast ATPase. Type 1 or 2?

Answer 29

Type 2a

Question 30

Red in color and large in diameter. Type I or Type @?

Answer 30

Type 2

Question 31

At what number of days does Wallerian Degeneration is completed?

Answer 31

7-10days from injury

Question 32

____weeks after injury, NCS cannot localize focal axonal loss

Answer 32

3 weeks after injury

Question 33

What are the manifestations of diabetic autonomic neuropathy?

Answer 33

Multiple organ systems
Cardiovascular:
- resting tachycardia, bradycardia, loss of respiratory variability of heart rate, loss of normal tachycardic response, orthostativ hypotension and increased risk of silent MI
Gastrointenstinal
-delayed gastric emptying time, constipation from colonic atony, bacterial overgrowth and diarrhea
Neurogenic bladder and Sexual Dysfunction
-impotence, erectile dysfunction, retrograde ejaculation
Abnormalities in Sudomotor Function
Hypohidrosis an hyperhidrosis

Question 34

What is the definition of Amyotrophic Lateral Sclerosis according to El Escorial Diagnostic Criteria?

Answer 34

clinical and/or electrophysiologic evidence of both upper and lower motor neuron involvement in at least three of the four following regions: bulbar, cervical, thoracic, and lumbosacral.

Question 35

What is the gene defect in Kennedy’s Disease?

Answer 35

expansion of a CAG repeats in the androgen receptor protein gene on the X chromosome.

Question 36

What is the preganglionic neurotransmitter of Parasympathetic ANS?

A. Acetylcholine
B. Norepinephrine
C. Serotonin
D. GABA

Answer 36

A. Acetylcholine

Question 37

What is the preganglionic neurotransmitter of Sympathetic ANS?

A. Acetylcholine
B. Norepinephrine
C. Serotonin
D. GABA

Answer 37

A. Acetylcholine

Question 38

What is the postganglionic neurotransmitter of Sympathetic ANS?

A. Acetylcholine
B. Norepinephrine
C. Serotonin
D. GABA

Answer 38

B. Norepinephrine

EXCEPT SWEAT GLANDS —> Acetylcholine

Question 39

What is the preganglionic neurotransmitter of Parasympathetic ANS?

A. Acetylcholine
B. Norepinephrine
C. Serotonin
D. GABA

Answer 39

A. Acetylcholine

Question 40

What is the preganglionic receptor of Sympathetic and Parasympathetic ANS?

A. Alpha-Adrenergic Receptor
B. Nicotinic Receptor
C. Muscarinic Receptor
D. Beta-Adrenergic Receptor

Answer 40

B. Nicotinic Receptor

Question 41

What is the postganglionic receptor of Parasympathetic ANS?

A. Alpha-Adrenergic Receptor
B. Nicotinic Receptor
C. Muscarinic Receptor
D. Beta-Adrenergic Receptor

Answer 41

C. Muscarinic Receptor

Question 42

What is the postganglionic receptor of Somatic System?

A. Alpha-Adrenergic Receptor
B. Nicotinic Receptor
C. Muscarinjc Receptor
D. Beta-Adrenergic Receptor

Answer 42

B. Nicotinic Receptor

Question 43

Which is not true of sympathetic nervous system?

A. Origin of Preganglionic never is at the nuclei of Spinal Cord Segments T1-T12; L1-L3 (Thoracolumbar)
B. It has a long pre-ganglionic nerve axon
C. It has a long post-ganglionic nerve axon
D. Main neurotransmitter in the receptor organs are norephinephrine

Answer 43

B. It has a long pre-ganglionic nerve axon

IT HAS A SHORT PRE-GANGLIONIC NERVE AXON

Sympathetic
Thoracolumbar
Short pre
Long Post
EN
(except sweat glands, Ach)

Question 44

Which is not true of parasympathetic nervous system?

A. Origin of Preganglionic nerve is nuclei of cranial nerves III, VII, IX and X; spinal cord segments S2-S4
B. It has a short pre-ganglionic nerve axon
C. It has a short post-ganglionic nerve axon
D. Main neurotransmitter in the receptor organs are norephinephrine

Answer 44

B. It has a short pre-ganglionic nerve axon

PARASYMPATHETIC- Long Preganglionic

Para
CranioSpinal
Long Pre
Short Post
Ach

Question 45

Generator for positive sharp waves.

A. Muscle Fiber
B. Terminal Axon
C. Multiple Muscle Fibers
D. Neuromuscular junction
E. Motor Neuron/Axon

Answer 45

A. Muscle Fiber

Question 46

Generator for End-Plate Noise.

A. Muscle Fiber
B. Terminal Axon
C. Multiple Muscle Fibers
D. Neuromuscular junction
E. Motor Neuron/Axon

Answer 46

D. Neuromuscular junction

Question 47

Generator for Fibrillation.

A. Muscle Fiber
B. Terminal Axon
C. Multiple Muscle Fibers
D. Neuromuscular junction
E. Motor Neuron/Axon

Answer 47

A. Muscle Fiber

Question 48

Generator for Complex Repetitive Discharges.

A. Muscle Fiber
B. Terminal Axon
C. Multiple Muscle Fibers
D. Neuromuscular junction
E. Motor Neuron/Axon

Answer 48

C. Multiple Muscle Fibers

Question 49

Generator for Myokymia

A. Muscle Fiber
B. Terminal Axon
C. Multiple Muscle Fibers
D. Neuromuscular junction
E. Motor Neuron/Axon

Answer 49

E. Motor Neuron/Axon

Question 50

Generator for Tetany

A. Muscle Fiber
B. Terminal Axon
C. Multiple Muscle Fibers
D. Neuromuscular junction
E. Motor Neuron/Axon

Answer 50

E. Motor Neuron/Axon