Low Frequency Currents SRS

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AN INTRODUCTION
Low Frequency Currents

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What is electrotherapy?
Medical therapy using electric currents. Also
called electrotherapeutics1.
Electrotherapy, also electro physical agents (EPA) are any
forms of treatment or assessment conducted using an electro
physical agent which can be applied externally to the human
body2.
http://www.thefreedictionary.com/electrotherapy
Robertson V, Ward A, Low J, Reed A. Electrotherapy Explained. 4th edition. Elsevier; 2006. p. 2

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History
Electric fish for the treatment of gout in Greek and Roman times.
By 1780, Luigi Galvani, an obstetrician and anatomist, University
of Bologna, first observed the quick twitching of the muscle,
produced by electricity in a nerve muscle preparation of the frog’s
leg.
As this type of electricity seemed quite distinct from electrostatic
currents derived from frictional machines it was called Galvanic
current.
In honour of Luigi Galvani, the use of direct current in medicine is
called Galvanism.

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Johann G Kruger, professor of Medicine at Halle, Germany,
published first book on medical electricity in 1743 entitled
‘Thoughts about the Electricity’.
Christian G Kratzenstein published in 1745, was the first to use
‘Medical Electricity’ in its title.
Richard Lovett of England, in 1756 treated numerous conditions
with static shocks and published treatise recommending
electrotherapy.
John Wesley, inspired by Richard Lovett published his own
experiences on the subject in 1759, in the book entitled ‘The
Desideratum’.

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History
In the early 1800s, Michael Faraday laid the groundwork for the
creation of alternating current (AC).
The medical use of such current is called Faradism.
The current was initially used for tightening and toning the
muscles.
In1965 Ronald Melzack and Patrick David Wall published their
paper “Pain Mechanism: A New Theory” which revealed the
benefits of electricity used as pain therapy to the people of
today.

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Types of Currents
Mainly three types of currents used therapeutically:
Direct current
Alternating current
Pulsed current.

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Direct Current
“Galvanic” can be used to
describe DC
Uninterrupted unidirectional
flow of electrons
Electrons travel from the
cathode to the anode
Example: Flashlight

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Alternating current
Bidirectional flow of electrons –
direction & magnitude of flow
reverses
magnitude may not be equal on both
sides of the baseline.
AC possesses no true positive or
negative pole.
Electrons shuffle back & forth between
the two electrodes as they take turn
being + ve & - ve.
Household electricity uses AC.

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Alternating Current
Amplitude: (peak value) – the maximal
distance to which the wave rises above
or below the baseline (only one side of
the baseline)
Peak-to-Peak Value: measured from
the peak on the (+) side of the line to
the peak on the (-) side of the line.
Cycle Duration: measured from the
originating point on the baseline to its
terminating point; the amount of time
required to complete one full cycle
Hertz: number of cycles per second (1
MHz = 1 million cycles/second)
Pattern – Sine Wave

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Pulsed Current
• Unidirectional or bi-directional
flow
• Usually 3 or more pulses grouped
together
• Pulses are interrupted
• 3 Types of Waveforms
• Monophasic
• Biphasic
• Polyphasic

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Pulse Attributes
A
B
C D
F
E
B
E
A : Amplitude
B : Phase Duration
C : Pulse Duration
D : Interpulse Interval
E : Pulse Period
F : Intrapulse Interval

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Wave forms
Rise and decay time
Rise time is the time taken by
pulse to reach maximum
amplitude in each phase.
Decay time is the time taken by
pulse to return to neutral
They are generally from ns to ms
The more rapid the rise in
amplitude the greater the nerve
tissue excitability.

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Current Modulation

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Types of LF Currents
Pure faradic current
Direct current:
Constant direct current
Interrupted direct current
Faradic Type of current
TENS

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Faradic Current
From Smart Bristow faradic coil
Sinusoidal current
First long duration low amplitude
High intensity short duration
waves
Not used now
Original
Modern

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Faradic type Current
Short duration interrupted direct current
Pulse duration 0.1 – 1 ms
Frequencies 50 – 100 Hz
Shorter duration used for stimulating innervated muscle

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Modified Faradic Current
Faradic currents are surged for
treatment purposes.
To produce a near normal tetanic
type of contraction and relaxation
The surges can be of various
Duration
Frequencies
Wave forms

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Modified Faradic Current
The intensity of the successive
impulses increases gradually.
Surges can be adjusted from 2 to
5-second surge, continuously or
by regularly selecting frequencies
from 6 to 30 surges / minute.
Rest period (pause duration)
should be at least 2 to 3 times that
of the pulse to give the muscle
enough time to recover its normal
state.

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Interrupted Direct Current
Interruption of unidirectional
currents
Frequency of up to 5 Hz.
The equipment commonly
provide duration of 0.01, 0.03,
0.1, 0.3, 1, 3, 10, 30, 100, 300
ms.
Longer duration used for
stimulating denervated muscle

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Physiological Effects
Effects on body tissues
Stimulation of sensory nerves
Stimulation of motor nerves
Increasing metabolism
Removal of waste products
Stimulation of denervated muscle
Chemical effects

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Effects on body tissues:
Tissues contain fluid, thus ions so are good conductors. ex. muscles
Epidermis has high resistance, thus is a bad conductor.
So some media like water or conductive gel used to lower resistance
Washing the area with soap and water lower resistance to some
extend.

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Stimulation of sensory nerves
Faradic current produces mild prickling sensation.
IDC results in a stabbing or burning sensation
ES produces slight erythema due to reflex vasodilatation.

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Stimulation of motor nerves
Faradic current produces a tetanic contraction because of higher
frequency rate.
So they are surged to avoid muscle fatigue.
Galvanic current produces a muscle twitch followed by
relaxation.

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Increasing metabolism and Removal of waste products
The contraction and relaxation of muscle causes pumping
action on blood vessels.
This results in increased supply of oxygen and nutrients
Also aids in lymphatic and venous drainage.
So removal of waste products

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Stimulation of denervated muscle
Impulses of more than 1 ms required for this.
Faradic current of more than 1 ms is not tolerable for the
patient.
IDC of sufficient intensity and duration is used for this.

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Chemical effects
Chemical effects are produced at the electrode site resulting in
chemical burns
This risk is more in DC
Using AC, depolarized DC and pulsing avoid this danger.

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Accommodation
When a constant current flows nerve adapts itself to the current.
Consequently the nerve no longer respond to the stimulus
This is accommodation.
A current rises or fall suddenly is more effective

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Effects of nerve stimulation
When a sensory nerve is stimulated
Downward impulse has no effect
Upward impulses appreciated when it reaches CNS.
Long duration impulses produce uncomfortable stabbing sensation
Short duration gives milder sensations
When motor nerve stimulated
Upward impulses do not pass
Downward impulses cause muscle contraction
Motor point causes maximum muscle stimulation

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Effects of frequency of stimulation
Increasing the frequency of stimuli shortens the period of
relaxation
Frequencies exceeding 20 Hz causes partial tetani,
Frequencies exceeding 60 Hz causes tetanic contraction

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Strength of contraction
Depends on :
The number of motor units activated
Intensity of current
Rate of change of current; slow rising currents causes
accommodation

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Indications
Facilitation of muscle contraction inhibited by pain
Muscle re-education
Training a new muscle action
Improvement of venous and lymphatic drainage
Prevention and loosening of adhesions
Nerve injury

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Indications
Facilitation of muscle contraction inhibited by pain
Pain has an inhibitory effect on anterior horn cells.
ES
1. reduces this inhibition
2. Facilitate transmission of voluntary impulses to the muscle and
3. Induce relaxation of its antagonists
The procedure should be pain free,
Otherwise this would inhibit the discharge from the AHC.

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Indications
Muscle re-education
Inability to contract a muscle can be due to:
Prolonged disuse
Incorrect use
Faradic stimulation may be used to restore the sense of
movement.

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Indications
Training a new muscle action
This could be in:
Tendon transplant
Reconstructive surgeries
Faradic type current is used for this
The patient is expected to assist with voluntary contraction

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Indications
Improvement of venous and lymphatic drainage
The contraction and relaxation of muscle causes pumping
action on blood vessels.
A faradism under pressure is used to treat edema

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Indications
Prevention and loosening of adhesions
Adhesions can be formed due to :
Long standing effusions.
improper muscle actions
Faradic stimulation and adequate exercise loosens, stretches
and prevent the adhesions.

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Indications
Nerve injury
Seddon’s Classification:
Neuropraxia: faradic current used to maintain the properties of
muscle
Axonotmesis: Short or Long duration current according to
diagnostic responce
Neurotmesis: start with faradic, but IDC after degeneration
Wallerian degeneration

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Contraindication
Someone with a pacemaker
Someone with a heart condition
On head or neck of someone with epilepsy
Someone with venous or arterial thrombosis or thrombophlebitis
Cardiac pacemakers.
Superficial metals.
Near operating diathermy device

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Contraindication
On the eyes
Using electrodes on infected skin
Electrodes across the chest of a patient with cardiac disease
Electrodes should not be placed near carotid artery in the anterolateral
region of the neck. There is a potential risk that stimulation at this site
might cause heart block by exciting the vagus nerve.

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Precautions
Areas of skin irritation, damage or lesions
Areas with impaired sensation
Over abdominal, lumbosacral or pelvic regions during pregnancy other
than for labor/delivery
Tissues vulnerable to hemorrhage or hematoma
Extreme caution is needed with patients taking narcotic medication or
who are known to have hyposensitive areas.
Incompetent patients may not be able to manage the device and it must
be kept out of reach of children.

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Recommended Textbooks
1. Electrotherapy explained, 4th edition, Low & Reed
2. Clayton’s Electotherapy, Theory and Practice. Angela Forster. 9th Ed.
3. Clayton’s electrotherapy, 10th edition, Sheila Kitchen
4. Textbook of Electrotherapy, Jagmohan Singh.
5. Physical Agents in Rehabilitation, From Research to Practice, Michelle H.
Cameron

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Recommended Reference Books
1. Biophysical Basis of Electrotherapy, Alex J Ward
2. Handbook of practical electrotherapy, Pushpal Kumar Mitra,
3. Electrotherapy : Evidence Based Practice, Tim Watson
4. Principles and Practice of Electrotherapy. Joseph Kahn.
5. Thermal Agents in Rehabilitation. Susan L. Michlovitz.
6. Therapeutic modalities for physical therapists by William E Prentice
7. Clinical Electrotherapy by Roger Nelson, Dean Currier
8. Modalities for Therapeutic Intervention: Contemporary Perspectives in
Rehabilitation by Susan Michlovitz, Thomas Nolan

Low Frequency Currents SRS

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