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EMG Final year bpT.pptx

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DrYeshaVashi

This document provides an overview of electromyography (EMG). It discusses that EMG records the electrical activity of muscles based on motor unit activity. It describes the components of a motor unit and how they produce electrical signals. The document outlines the EMG examination process, including the use of electrodes, signal processing, and analyzing insertional activity, spontaneous activity, motor unit potentials, and recruitment and interference patterns during voluntary contractions. It provides details on normal and abnormal EMG findings.

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Electromyography Dr. Khushbu C Naik (MPT-NEURO)
EMG is the recording of the electrical activity of muscle based on motor unit activity.  Motor units are composed of one anterior horn cell, one axon, its neuromuscular junctions, and all the muscle fibers innervated by that axon.
The single axon conducts an impulse to all its muscle fibers, causing them to depolarize at relatively the same time. This depolarization produces electrical activity that is manifested as a motor unit action potential (MUAP) and recorded and displayed graphically as the EMG signal.  The characteristics of the MUAP will change when there is damage to either the nerve or muscle.
Motor unit action potential  The sum of action potential produced in muscle.  Characterized by its duration, number of phase, amplitude & rate of rise of its first component.
Feature of MUP Duration • measured from the initial take-off to the point of return to the baseline. • 5-15 ms Phases • portion of the MUP between the departure & the return to the baseline • triphasic (positive, negative, positive) • Polyphasic-MUP with more than four phase (5- 15%) Amplitude • measured from maximum peak of negative phase to maximum peak of the positive phase • 0.5mV to 2mV Rise time • duration from the initial positive to subsequent negative peak • normal ↓ 500 µs
EMG Examination I. Input Phase:  The apparatus used in routine electrodiagnosis includes electrodes, amplifiers, display, loudspeaker and data storage devices. A) Electrodes: - Needle electrode - Surface electrode Most common types of electrodes are, - Bipolar - Monopolar
Needle electrode Surface electrode Monopolar needle electrode
 Monolpolar electrode : composed of a single fine needle, insulated except at the tip. A second surface electrode placed on the skin near the site of insertion serves as the reference electrode. These electrodes are less painful than concentric electrodes because they are smaller in diameter.  Bipolar electrode: is a hypodermic needle, through which a single wire of platinum or silver is threaded.
 The cannula shaft and wire are insulated from each other, and only their tips are exposed. The wire and the needle cannula act as recording and reference electrodes. II. Processing phase:  Electrodes convert the bioelectric signal from muscle or nerve depolarization into an electrical potential which is processed by an amplifier.
a) Amplifiers: 10-5000Hz  The electrodes will pick-up both desired bioelectric activity and interference signals. b) Filter: It restricts the frequency domain of a signal. To eliminate noise and bring out characteristics of waveforms.
Common Mode Rejection Ratio: (CMR): The amplifier amplifies differences that exist in the signals from its two inputs, but rejects signals that are common to both inputs, such as those caused by interference. It is a measure of how much the desired signal is amplified in relative to the unwanted signal.
Signal-to-noise ratio:  Noise also can be generated by the electric components of an amplifier, including resistors, transistors and ICs, which is manifested as a hissing sound on an oscilloscope.  The ability of the amplifier to limit this noise relative to the amplified signal is the signal-to noise ratio.
Gain and frequency response: Ratio of the output voltage to the input voltage is gain ( gain over the range of frequencies of the input signal) This is achieved by using a filter which selectively restricts the particular frequency domain of a signal. The frequency response is the range of frequencies between the low and high cut-off points.
III. Output phase: Display system: Analog or digital sytem.  A loudspeaker transforms the myoelectric signals into sound.
 Analogue display or audio microproces Amplifier
Factors that effect MUAP  Technical factors: - Type of needle electrode - Characteristics of recording surface - Electrical characteristics of cable - Preamplifire & Amplifire - Method of recording  Physiological factors: - Age of patient - Muscle examined - Temperature
Phases of EMG Process a) Insertional activity b) Spontaneous activity: 1. Fibrillation potential 2. Positive sharp wave 3. Fasciculation 4. Complex Repetitive Discharge 5. Myotonic Discharge a) Minimal voluntary activity/Motor unit action potential b) Maximal voluntary activity/ Recruitment and interference pattern
a) Insertional Activity: - Needle electrode is placed in the muscle and electrical activity associated with its insertion is evaluated  This normally lasts less than 300 milliseconds (msec).  Insertional activity can be described as normal, reduced, absent, increased, or prolonged.  Burst of high frequency positive and negative spikes occurring during the movement of needle electrode.  It occurs due to stimulation of muscle fibre due to mechanical irritation/ injury by the penetrating needle
The level of response depends on magnitude and speed of needle movement. - Though its normal response exaggeration/attenuation of this response may suggest pathology. Like: Muscle necrosis , neuropathy and myopathies
Insertioanl Activity Increased Insertional activity Descreased Insertional activity
 A normal relaxed muscle will exhibit electrical silence, which is the absence of electrical potentials.  Observation of silence in the relaxed state is an important part of the EMG examination. Potentials arising spontaneously during this period are significant abnormal findings. After observing the muscle at rest, the patient is asked to contract the muscle minimally.
This weak voluntary effort should cause individual motor units to fire. These motor unit potentials are examined with respect to amplitude, duration, shape, sound, and frequency.  Finally, the patient is asked to increase levels of contraction progressively to a strong effort, allowing determination of recruitment patterns.
Gradually increasing the force of contraction will allow the electromyographer to observe the pattern of recruitment in the muscle. With greater effort, increasing numbers of motor units fire at higher frequencies, until the individual potentials are summated and can no longer be recognized, and an interference pattern is seen. This is the normal finding with a strong contraction.
A. During single motor unit potential during minimal contraction. B. During maximal contraction C. Interference pattern
Spontaneous Activity Normal spontaneous activities originated from the NMJ or terminal axons. (1) End plate Noise (2) End plate potential - Once insertional activity decays after a second or so, in normal individual, there is no spontaneous electrical activity. - In the end plate zone, miniature endplate potentials are spontaneously recorded.
END PLATE POTENTIAL: - On needle recording, end plate potential appears as monophasic negative waves < 100microvolt & 1-3 ms duration. - Usually seen with an irregular baseline and called END PLATE NOISE (Sea shell sound) - In end plate region, Action potential which are brief, spiky and irregular with an initial negative deflection are known as End plate Spike.
 End plate spike are due to mechanical activation of nerve terminal by needle.  To avoid normally occuring spontaneous end plate activities, the needle should be introduced slightly away from the muscle end plate which is usually situated near the center of muscle belly.
Abnormal Spontaneous Activities (1) Originated from Muscle fiber - Fibrillation potential & positive sharp wave - Myotonic discharge - Complex Repetitive Discharge (CRD) (2) Originated from Motor neuron or axon - Fasciculation - Doublets, triplets, multiplets - Myokymia - Cramps
Fibrillation potentials are believed to arise from spontaneous depolarization of a single muscle fiber. - Their sound is a high-pitched click, which has been likened to rain falling on a roof or wrinkling tissue paper. - Fibrillations fires regularly at a rate of 0.5 to 15 hz, with an amplitude of 20-200 microvolt and duration of 1-5 ms when recorded by concentric needle. - Rarely be regular. - These are biphasic or triphasic waves with initial positive, which is imp differential features from end plate spike.

Positive sharp waves are longer duration biphasic potentials with initial sharp positive waves followed by a long duration negative phase resulting in a saw tooth appearance.  Appears regularly with an amplitude of 20-200 microvolt and duration of 10-30 ms.  Sound like dull pop.  Positive sharp waves are the action potential resulting from injured muscle fiber.
 Both fibrillation potential and positive sharp waves are recognized by their characteristic sound on the loudspeaker.(clicking sound of clock)  Fibrillations and sharp waves aare found in various lower motor neuron disease such as AHC disorders, radiculopathy, plexopathy, axonal type of neuropathies, muscle disorders such as myositis, muscular dystrophy, muscle trauma and relative NMJ, Myasthenia gravis.
 Fibrillation potential and sharp waves are graged as following, 0- None +1- Persistent single trains of potential in at least two areas. +2- Moderate number of potential in three or more area. +3- Many fibrillations and sharp waves in all area +4- Full interfernce pattern of fibrillations and sharp waves.
The waves are typically biphasic, with a sharp initial positive deflection (below baseline) followed by a slow negative phase.
The negative phase is of much lower amplitude than the positive phase, and of much longer duration, sometimes up to 100 msec. The sound has been described as a dull thud. Both Fibrillations and positive sharp waves are recognized by their characteristic sound on the loudspeaker - clicking sound of clock
 Myotonic Discharge: The action potentials of muscle fibers firing for a prolonged period after external excitation are the characteristics of myotonic discharge.  Increase and decrease in amplitude & frequency in a waxing and waning fashion are found because of muscle membrane abnormality.  Myotonic discharge are rhythmic with frequency ranging between 20 Hz to 150 Hz.  Variation in frequency and amplitude gives sound like a dive bomber.
 Depending on the location of needle electrode to the muscle fiber, there are two types of these potentials: (1) Positive waves (2) Brief spikes.  Positive waves are similar to the runs of positive sharp waves and are attribute to the muscle fibers.  Brief spikes are biphasic or triphasic 20-300 microvolt and resemble the fibrillation potential.
EMG Final year bpT.pptx
 Causes of Myotonic Discharge: - Myotoniadystrophica - Myotonia congenita - Paramyotomia - Hyperkalemicperiodic paralysis - Polymyositis - Acid maltase deficiency
 Complex Repetitive Discharge (CRD) : It refers to repetitive and synchronous firing of a group of muscle fibers spontaneously or following needle movement.  Amplitude of potential range from 50 microvolt to 1 macrovolt. Duration 50 ms to 100 ms.  The entire sequence repeats at slow or fast rate ranging between 5 Hz and 100 Hz.  The unique repetitive pattern bears a superficial resemblance to myotonic discharge and these are also called pseudomyotonic discharge.
EMG Final year bpT.pptx
 CRD do not have waxing and waning pattern, instead of these appear and disappear abruptly and this feature helps in differentiate it from myotonic discharge.  CRD are identical in morphology from one discharge to another giving a machine –like sound on EMG.  Causes : - Myogenic: Polymyositis, Muscular dystrophies, Schwartz jample syndrome - Neurogenic: Polymyositis, ALS, Spinal muscular atrophy, Chronic radiculopathy and neuropathy
Abnormal spontaneous activity originating from Motor neuron or Axon  Fasciculation: Is a spontaneous contraction of a number of muscle fibers belonging to whole or a part of motor unit.  It occurs randomly and irregularly at variable rates ranging between 0.1 Hz and 10 Hz.  The size and shape of fasciculations depends upon the motor unit from which they arise and to the distance of recording electrode to the motor unit.
 Fasciculations may have the appearance of normal and abnormal MUAP. Fasciculation can occur in normal individual also as well as in a wide variety of disease such as ALS, Root compression, Axonal neuropathy and metabolic disorders.  The differentiation between bening and pathological fasciculation is difficult.
 Bening: are not companied by muscle weakness, muscle wasting and reflex changes. These are of normal MUAP , fire at faster rate and same site repetitively.  During voluntary contraction, muscle twitching may b seen in patient with chronic neurogenic lesion (contraction fasciculation)
 Causes : Neurogenic Disorders: - ALS - Spinal muscular atrophy - Radiculopathy - Syringomyelia - Peripheral neuropathies Metabolic Disorders: - Tetany - Thyrotoxixosis - Uremia Normal - Benign Fasciculation - Muscle cramps
 Doublets, Triplets & Multiplets: MUAP that fire in groupof two, three or multiple potentials are reffered as doublets, triplets and multiplets.  It is because spontaneous depolarization of motor unit or its axons similar to fasciculations.  These are seen in hyperventilation, tetany, MNDand other metabolic disease.  Ischemia can also induce these abnormality.
EMG Final year bpT.pptx
 Myokymic Discharge: Are spontaneous bursting, repetitive discharge of the same MUAP, which is associated with fine, worm like quivering of muscles.  On EMG,these discharges reveal normal MUAPs, which fire in fixed pattern and rhythm, occuring in bursts of 2 to 10 potential firing at 40-60 Hz.  The burts reoccur regular intervals of 0.1-10 s creating a marching round.  Mainly seen in demylinating neuropathy.
EMG Final year bpT.pptx
C) Minimal voluntary Activity: Motor unit potential: The motor unit consists of a group of muscle fibers innervated by a single anterior horn cell Represents the sum of muscle action potentials supplied by an AHC Higher amplitude and longer duration than action potential produced by a single muscle fiber They are characterized by duration, phases, amplitude, turns and rate of rise.
EMG Final year bpT.pptx
A. Normal Motor unit action potential B. Long duration polyphasic potential (appears twice) C. Shirt duration (Low amplitude, polyphasic potential)
 Abnormal MUAP: 1) Short Duration/Low amplitude/Recruitment increased at minimal effort - Myopathies, inflammatory disorders of muscles and NMJ disorders, Early stage of reinnervation after severe PNI 2) Long Duration/ High amplitude/ Recruitment Poor: - MND, Axonal Neuropathies, radiculopathies, chronic myositis (Polymyositis)
c) Polyphasic: >= 4 phase: - Myopathies, regeneration of axons D) Mixed pattern / mixed variety of MUAPs: - Myopathies and neuropathies E) Double/triplets/ amplitude vary / fired two or more times at one interval of 10 to 30 sec: - Tetany, MND and Metabolic disease
d) Maximal Voluntary Contraction:  The change in electrical activity is assessed as the level of muscle contraction gradually increases and reaches a maximum  Recruitment and interference pattern are evaluated Recruitment Pattern: - The firing rate of MUAPS for a muscle is constant - During a voluntary contraction, the motor units are recruited in an orderly fashion; the smallest appearing first, larger later and the largest later
A reduced or increased pattern indicates a fewer or greater no. of discharging units than expected In the early stage of neuropraxia, reduced recruitment pattern is evident In myopathies, more motor units are recruited at relatively low force which is known as rapid recruitment, where the firing rate remains same
Interference pattern: With stronger contraction, many motor units begin to fire very rapidly. The discharge of many action potentials results in pattern which unable to differentiate of the individual muscle fibre potentials, hence the name interference pattern The spike density and the average amplitude of the summated response are determined.
EMG Final year bpT.pptx
Abnormal Interference pattern: - In disorders of the motor neuron, root or peripheral nerve with reduced no. of excitable motor units, recruitment and interference pattern are limited. - LMN disorders present with a rapid rate of discharge. - LMN and UMN both shows reduced interference pattern.

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EMG Final year bpT.pptx

  • 2. EMG is the recording of the electrical activity of muscle based on motor unit activity.  Motor units are composed of one anterior horn cell, one axon, its neuromuscular junctions, and all the muscle fibers innervated by that axon.
  • 3. The single axon conducts an impulse to all its muscle fibers, causing them to depolarize at relatively the same time. This depolarization produces electrical activity that is manifested as a motor unit action potential (MUAP) and recorded and displayed graphically as the EMG signal.  The characteristics of the MUAP will change when there is damage to either the nerve or muscle.
  • 4. Motor unit action potential  The sum of action potential produced in muscle.  Characterized by its duration, number of phase, amplitude & rate of rise of its first component.
  • 5. Feature of MUP Duration • measured from the initial take-off to the point of return to the baseline. • 5-15 ms Phases • portion of the MUP between the departure & the return to the baseline • triphasic (positive, negative, positive) • Polyphasic-MUP with more than four phase (5- 15%) Amplitude • measured from maximum peak of negative phase to maximum peak of the positive phase • 0.5mV to 2mV Rise time • duration from the initial positive to subsequent negative peak • normal ↓ 500 µs
  • 6. EMG Examination I. Input Phase:  The apparatus used in routine electrodiagnosis includes electrodes, amplifiers, display, loudspeaker and data storage devices. A) Electrodes: - Needle electrode - Surface electrode Most common types of electrodes are, - Bipolar - Monopolar
  • 7. Needle electrode Surface electrode Monopolar needle electrode
  • 8.  Monolpolar electrode : composed of a single fine needle, insulated except at the tip. A second surface electrode placed on the skin near the site of insertion serves as the reference electrode. These electrodes are less painful than concentric electrodes because they are smaller in diameter.  Bipolar electrode: is a hypodermic needle, through which a single wire of platinum or silver is threaded.
  • 9.  The cannula shaft and wire are insulated from each other, and only their tips are exposed. The wire and the needle cannula act as recording and reference electrodes. II. Processing phase:  Electrodes convert the bioelectric signal from muscle or nerve depolarization into an electrical potential which is processed by an amplifier.
  • 10. a) Amplifiers: 10-5000Hz  The electrodes will pick-up both desired bioelectric activity and interference signals. b) Filter: It restricts the frequency domain of a signal. To eliminate noise and bring out characteristics of waveforms.
  • 11. Common Mode Rejection Ratio: (CMR): The amplifier amplifies differences that exist in the signals from its two inputs, but rejects signals that are common to both inputs, such as those caused by interference. It is a measure of how much the desired signal is amplified in relative to the unwanted signal.
  • 12. Signal-to-noise ratio:  Noise also can be generated by the electric components of an amplifier, including resistors, transistors and ICs, which is manifested as a hissing sound on an oscilloscope.  The ability of the amplifier to limit this noise relative to the amplified signal is the signal-to noise ratio.
  • 13. Gain and frequency response: Ratio of the output voltage to the input voltage is gain ( gain over the range of frequencies of the input signal) This is achieved by using a filter which selectively restricts the particular frequency domain of a signal. The frequency response is the range of frequencies between the low and high cut-off points.
  • 14. III. Output phase: Display system: Analog or digital sytem.  A loudspeaker transforms the myoelectric signals into sound.
  • 16. Factors that effect MUAP  Technical factors: - Type of needle electrode - Characteristics of recording surface - Electrical characteristics of cable - Preamplifire & Amplifire - Method of recording  Physiological factors: - Age of patient - Muscle examined - Temperature
  • 17. Phases of EMG Process a) Insertional activity b) Spontaneous activity: 1. Fibrillation potential 2. Positive sharp wave 3. Fasciculation 4. Complex Repetitive Discharge 5. Myotonic Discharge a) Minimal voluntary activity/Motor unit action potential b) Maximal voluntary activity/ Recruitment and interference pattern
  • 18. a) Insertional Activity: - Needle electrode is placed in the muscle and electrical activity associated with its insertion is evaluated  This normally lasts less than 300 milliseconds (msec).  Insertional activity can be described as normal, reduced, absent, increased, or prolonged.  Burst of high frequency positive and negative spikes occurring during the movement of needle electrode.  It occurs due to stimulation of muscle fibre due to mechanical irritation/ injury by the penetrating needle
  • 19. The level of response depends on magnitude and speed of needle movement. - Though its normal response exaggeration/attenuation of this response may suggest pathology. Like: Muscle necrosis , neuropathy and myopathies
  • 20. Insertioanl Activity Increased Insertional activity Descreased Insertional activity
  • 21.  A normal relaxed muscle will exhibit electrical silence, which is the absence of electrical potentials.  Observation of silence in the relaxed state is an important part of the EMG examination. Potentials arising spontaneously during this period are significant abnormal findings. After observing the muscle at rest, the patient is asked to contract the muscle minimally.
  • 22. This weak voluntary effort should cause individual motor units to fire. These motor unit potentials are examined with respect to amplitude, duration, shape, sound, and frequency.  Finally, the patient is asked to increase levels of contraction progressively to a strong effort, allowing determination of recruitment patterns.
  • 23. Gradually increasing the force of contraction will allow the electromyographer to observe the pattern of recruitment in the muscle. With greater effort, increasing numbers of motor units fire at higher frequencies, until the individual potentials are summated and can no longer be recognized, and an interference pattern is seen. This is the normal finding with a strong contraction.
  • 24. A. During single motor unit potential during minimal contraction. B. During maximal contraction C. Interference pattern
  • 25. Spontaneous Activity Normal spontaneous activities originated from the NMJ or terminal axons. (1) End plate Noise (2) End plate potential - Once insertional activity decays after a second or so, in normal individual, there is no spontaneous electrical activity. - In the end plate zone, miniature endplate potentials are spontaneously recorded.
  • 26. END PLATE POTENTIAL: - On needle recording, end plate potential appears as monophasic negative waves < 100microvolt & 1-3 ms duration. - Usually seen with an irregular baseline and called END PLATE NOISE (Sea shell sound) - In end plate region, Action potential which are brief, spiky and irregular with an initial negative deflection are known as End plate Spike.
  • 27.  End plate spike are due to mechanical activation of nerve terminal by needle.  To avoid normally occuring spontaneous end plate activities, the needle should be introduced slightly away from the muscle end plate which is usually situated near the center of muscle belly.
  • 28. Abnormal Spontaneous Activities (1) Originated from Muscle fiber - Fibrillation potential & positive sharp wave - Myotonic discharge - Complex Repetitive Discharge (CRD) (2) Originated from Motor neuron or axon - Fasciculation - Doublets, triplets, multiplets - Myokymia - Cramps
  • 29. Fibrillation potentials are believed to arise from spontaneous depolarization of a single muscle fiber. - Their sound is a high-pitched click, which has been likened to rain falling on a roof or wrinkling tissue paper. - Fibrillations fires regularly at a rate of 0.5 to 15 hz, with an amplitude of 20-200 microvolt and duration of 1-5 ms when recorded by concentric needle. - Rarely be regular. - These are biphasic or triphasic waves with initial positive, which is imp differential features from end plate spike.
  • 30.
  • 31. Positive sharp waves are longer duration biphasic potentials with initial sharp positive waves followed by a long duration negative phase resulting in a saw tooth appearance.  Appears regularly with an amplitude of 20-200 microvolt and duration of 10-30 ms.  Sound like dull pop.  Positive sharp waves are the action potential resulting from injured muscle fiber.
  • 32.  Both fibrillation potential and positive sharp waves are recognized by their characteristic sound on the loudspeaker.(clicking sound of clock)  Fibrillations and sharp waves aare found in various lower motor neuron disease such as AHC disorders, radiculopathy, plexopathy, axonal type of neuropathies, muscle disorders such as myositis, muscular dystrophy, muscle trauma and relative NMJ, Myasthenia gravis.
  • 33.  Fibrillation potential and sharp waves are graged as following, 0- None +1- Persistent single trains of potential in at least two areas. +2- Moderate number of potential in three or more area. +3- Many fibrillations and sharp waves in all area +4- Full interfernce pattern of fibrillations and sharp waves.
  • 34. The waves are typically biphasic, with a sharp initial positive deflection (below baseline) followed by a slow negative phase.
  • 35. The negative phase is of much lower amplitude than the positive phase, and of much longer duration, sometimes up to 100 msec. The sound has been described as a dull thud. Both Fibrillations and positive sharp waves are recognized by their characteristic sound on the loudspeaker - clicking sound of clock
  • 36.  Myotonic Discharge: The action potentials of muscle fibers firing for a prolonged period after external excitation are the characteristics of myotonic discharge.  Increase and decrease in amplitude & frequency in a waxing and waning fashion are found because of muscle membrane abnormality.  Myotonic discharge are rhythmic with frequency ranging between 20 Hz to 150 Hz.  Variation in frequency and amplitude gives sound like a dive bomber.
  • 37.  Depending on the location of needle electrode to the muscle fiber, there are two types of these potentials: (1) Positive waves (2) Brief spikes.  Positive waves are similar to the runs of positive sharp waves and are attribute to the muscle fibers.  Brief spikes are biphasic or triphasic 20-300 microvolt and resemble the fibrillation potential.
  • 39.  Causes of Myotonic Discharge: - Myotoniadystrophica - Myotonia congenita - Paramyotomia - Hyperkalemicperiodic paralysis - Polymyositis - Acid maltase deficiency
  • 40.  Complex Repetitive Discharge (CRD) : It refers to repetitive and synchronous firing of a group of muscle fibers spontaneously or following needle movement.  Amplitude of potential range from 50 microvolt to 1 macrovolt. Duration 50 ms to 100 ms.  The entire sequence repeats at slow or fast rate ranging between 5 Hz and 100 Hz.  The unique repetitive pattern bears a superficial resemblance to myotonic discharge and these are also called pseudomyotonic discharge.
  • 42.  CRD do not have waxing and waning pattern, instead of these appear and disappear abruptly and this feature helps in differentiate it from myotonic discharge.  CRD are identical in morphology from one discharge to another giving a machine –like sound on EMG.  Causes : - Myogenic: Polymyositis, Muscular dystrophies, Schwartz jample syndrome - Neurogenic: Polymyositis, ALS, Spinal muscular atrophy, Chronic radiculopathy and neuropathy
  • 43. Abnormal spontaneous activity originating from Motor neuron or Axon  Fasciculation: Is a spontaneous contraction of a number of muscle fibers belonging to whole or a part of motor unit.  It occurs randomly and irregularly at variable rates ranging between 0.1 Hz and 10 Hz.  The size and shape of fasciculations depends upon the motor unit from which they arise and to the distance of recording electrode to the motor unit.
  • 44.  Fasciculations may have the appearance of normal and abnormal MUAP. Fasciculation can occur in normal individual also as well as in a wide variety of disease such as ALS, Root compression, Axonal neuropathy and metabolic disorders.  The differentiation between bening and pathological fasciculation is difficult.
  • 45.  Bening: are not companied by muscle weakness, muscle wasting and reflex changes. These are of normal MUAP , fire at faster rate and same site repetitively.  During voluntary contraction, muscle twitching may b seen in patient with chronic neurogenic lesion (contraction fasciculation)
  • 46.  Causes : Neurogenic Disorders: - ALS - Spinal muscular atrophy - Radiculopathy - Syringomyelia - Peripheral neuropathies Metabolic Disorders: - Tetany - Thyrotoxixosis - Uremia Normal - Benign Fasciculation - Muscle cramps
  • 47.  Doublets, Triplets & Multiplets: MUAP that fire in groupof two, three or multiple potentials are reffered as doublets, triplets and multiplets.  It is because spontaneous depolarization of motor unit or its axons similar to fasciculations.  These are seen in hyperventilation, tetany, MNDand other metabolic disease.  Ischemia can also induce these abnormality.
  • 49.  Myokymic Discharge: Are spontaneous bursting, repetitive discharge of the same MUAP, which is associated with fine, worm like quivering of muscles.  On EMG,these discharges reveal normal MUAPs, which fire in fixed pattern and rhythm, occuring in bursts of 2 to 10 potential firing at 40-60 Hz.  The burts reoccur regular intervals of 0.1-10 s creating a marching round.  Mainly seen in demylinating neuropathy.
  • 51. C) Minimal voluntary Activity: Motor unit potential: The motor unit consists of a group of muscle fibers innervated by a single anterior horn cell Represents the sum of muscle action potentials supplied by an AHC Higher amplitude and longer duration than action potential produced by a single muscle fiber They are characterized by duration, phases, amplitude, turns and rate of rise.
  • 53. A. Normal Motor unit action potential B. Long duration polyphasic potential (appears twice) C. Shirt duration (Low amplitude, polyphasic potential)
  • 54.  Abnormal MUAP: 1) Short Duration/Low amplitude/Recruitment increased at minimal effort - Myopathies, inflammatory disorders of muscles and NMJ disorders, Early stage of reinnervation after severe PNI 2) Long Duration/ High amplitude/ Recruitment Poor: - MND, Axonal Neuropathies, radiculopathies, chronic myositis (Polymyositis)
  • 55. c) Polyphasic: >= 4 phase: - Myopathies, regeneration of axons D) Mixed pattern / mixed variety of MUAPs: - Myopathies and neuropathies E) Double/triplets/ amplitude vary / fired two or more times at one interval of 10 to 30 sec: - Tetany, MND and Metabolic disease
  • 56. d) Maximal Voluntary Contraction:  The change in electrical activity is assessed as the level of muscle contraction gradually increases and reaches a maximum  Recruitment and interference pattern are evaluated Recruitment Pattern: - The firing rate of MUAPS for a muscle is constant - During a voluntary contraction, the motor units are recruited in an orderly fashion; the smallest appearing first, larger later and the largest later
  • 57. A reduced or increased pattern indicates a fewer or greater no. of discharging units than expected In the early stage of neuropraxia, reduced recruitment pattern is evident In myopathies, more motor units are recruited at relatively low force which is known as rapid recruitment, where the firing rate remains same
  • 58. Interference pattern: With stronger contraction, many motor units begin to fire very rapidly. The discharge of many action potentials results in pattern which unable to differentiate of the individual muscle fibre potentials, hence the name interference pattern The spike density and the average amplitude of the summated response are determined.
  • 60. Abnormal Interference pattern: - In disorders of the motor neuron, root or peripheral nerve with reduced no. of excitable motor units, recruitment and interference pattern are limited. - LMN disorders present with a rapid rate of discharge. - LMN and UMN both shows reduced interference pattern.