Thermal Modalities
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Transcript Thermal Modalities
Thermal Modalities
General Principles
© 2004
Physical Laws
Cosine Law
Inverse Square Law
Arndth-Schultz Principle
Law of Grotthus-Draper
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Cosine Law
Angle of incidence: The angle
at which radiant energy strikes
the body.
As the angle of incidence
changes from 90º, the less
effective the transmission.
Based on the cosine of the
angle of incidence:
Effective energy = Energy *
Cosine (angle)
Radiant energy should be
±90º
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90º
45º
100%
50% Transmission
Transmission
(cosine of 45º
90º = .50)
1.0)
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0”
100 W
4”
25 W
8”
6.25 W
Intensity
Intensity of radiant
energy depends on the
distance between the
source and the target.
Changing the distance
changes the intensity
Change is proportional to
the square of the distance.
Distance
Inverse Square Law
Inverse Square Law
Formula:
E = Es/D2
E – energy received by the tissue
Es – energy produced by the source
D2 – Square of the distance between the target and
the source
Doubling the distance between the tissues and
the target decreases the intensity by a factor of
four.
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Arndth-Schultz Principle
Energy must be absorbed by the tissues
Must be sufficient to stimulate a physiological
response
Too little stimulus: no effect
Too much stimulus: injury
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Grotthus-Draper
Inverse relationship between absorption and
penetration of energy.
Energy absorbed by one tissue layer is not
passed along to deeper layers.
The more energy absorbed in superficial layers,
the less available for deeper layers.
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General Physiology
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Metabolic Changes
Heat increases metabolism
Cold decreases metabolism
A 1.8ºF (1ºC) change in tissue temperature =
13% change in metabolism
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Tissue Properties
Deeper tissues have higher temperatures
Different tissues have different conductivity
properties:
Tissue
Skinc
Adipose Tissuei
Musclec
c – conductor
i - insulator
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Thermal Conductivity
0.96
0.19
0.64
Thermoreceptors
Cold-responsive receptors
Heat-responsive receptors
More cold receptors than heat receptors
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Physics
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Transfer of Thermal
Energy
Conduction
Convection
Radiation
Evaporation
Conversion
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General Principles
Exchange of kinetic energy
(heat)
Transfer of energy is based on
a gradient between two points
Energy always moves from a
high concentration to a low
concentration
Moist heat pack to the skin
Skin to an ice pack
The greater the gradient, the
more energy that is transferred
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100ºF
110ºF
120ºF
100ºF
80ºF
90ºF
Conduction
Objects are touching each other
One object loses heat; the other gains heat
Conductors
Skin
Muscle
Insulators
Adipose tissue
Terrycloth towels
32.1°F
32.2°F
32.3°F
32.4°F
32.5°F
32.6°F
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87°F
83°F
80°F
77°F
74°F
70°F
67°F
64°F
61°F
58°F
Convection
Involves the circulation of air or water
One object is cooled
Another object is heated
Example:
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Whirlpool
Radiation
No medium is required
Examples:
LASER
Infrared light
Ultraviolet light
Thermal modalities provide radiant energy
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But is not the primary form of heat exchange
Evaporation
Change from liquid to gaseous state
Draws heat from the body
Cools superficial tissues
Examples:
Sweating
Vapocoolant sprays
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Conversion
Change of one form of energy to another
Electromagnetic energy to heat
Acoustical energy to heat
Examples:
Short wave diathermy
Ultrasound
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