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Chapter 8: Acoustic Output 127

Acoustic Output

In Situ

= Water [e

-(0.23alf)

]

where:

In Situ

intensity value

Water = Water intensity value

e = 2.7183

a = attenuation factor (dB/cm MHz)

Attenuation factor (a) for various tissue types are given below:

brain = 0.53

heart = 0.66

kidney = 0.79

liver = 0.43

muscle = 0.55

l = skinline to measurement depth in cm

f = center frequency of the transducer/system/mode combination in MHz

Since the ultrasonic path during the exam is likely to pass through varying lengths and types of

tissue, it is difficult to estimate the true

In Situ

intensity. An attenuation factor of 0.3 is used for

general reporting purposes; therefore, the

In Situ

value commonly reported uses the formula:

In Situ

(derated) = Water [e

-(0.069lf)

]

Since this value is not the true

In Situ

intensity, the term “derated” is used to qualify it.

The maximum derated and the maximum water values do not always occur at the same operating

conditions; therefore, the reported maximum water and derated values may not be related by the

In Situ

(derated) formula. For example: a multi-zone array transducer that has maximum water

value intensities in its deepest zone, but also has the smallest derating factor in that zone. The same

transducer may have its largest derated intensity in one of its shallowest focal zones.

Tissue models and equipment survey

Tissue models are necessary to estimate attenuation and acoustic exposure levels

In Situ

from

measurements of acoustic output made in water. Currently, available models may be limited in their

accuracy because of varying tissue paths during diagnostic ultrasound exposures and uncertainties

in the acoustic properties of soft tissues. No single tissue model is adequate for predicting exposures

in all situations from measurements made in water, and continued improvement and verification of

these models is necessary for making exposure assessments for specific exam types.

A homogeneous tissue model with attenuation coefficient of 0.3 dB/cm MHz throughout the beam

path is commonly used when estimating exposure levels. The model is conservative in that it

overestimates the

In Situ

acoustic exposure when the path between the transducer and site of