Whole body counting

Additional recommended knowledge

Safe Weighing Range Ensures Accurate Results

What is the Correct Way to Check Repeatability in Balances?

Don't let static charges disrupt your weighing accuracy

Whole Body Counting

In Health Physics, this term refers to the measurement of radioactivity within the human body. The technique is only applicable to radioactive material that emit gamma rays, although in certain circumstances, beta emitters can be measured also.

Principle

A gamma ray is emitted from a radioactive element within the human body. If its energy is sufficient that it can escape the body before being absorbed or have any other interaction where it can lose enrgy, it can be detected. Usually either a scintillation detector or a semiconductor dector would be used for such purposes.

There are many ways a person can be positioned for this measurment: sitting, lying, standing. The detectors can be single or multiple and can either be stationary or moving.

The advantages of whole body counting are that it measures body contents directly and not does rely on indirect methods (such as urinalysis) and that it can measure insoluble radionuclides in the lungs.

On the other hand, disadvantages of whole body counting are that it can only be used for gamma emitters, except in special circumstances, and it can misinterpret external contamination as an internal contamination.

Calibration

Any radiation detector is a relative instrument, that is to say the measurement value can only be converted to an amount of material present by comparing the response signal (usually counts per minute, or per second) to the signal obtained from a standard whose quantity (activity) is well known.

A whole body counter is calibrated with a device known as a phantom containing a known distribution and known activity of radioactive material. The accepted industry standard is the Bottle Manikin Absorber phantom (BOMAB). The BOMAB phantom is comprised of 10 high density polyethylene containers and is used to calibrate in vivo counting systems that are designed to measure the radionuclides that emit high energy photons (200 keV < E < 3 MeV).

Because many different types of phantoms had been used to calibrate in vivo counting systems, the importance of establishing standard specifications for phantoms was emphasized at the 1990 international meeting of in vivo counting professionals held at the National Institute of Standards and Technology (NIST) (Kramer and Inn 1991). The consensus of the meeting attendees was that standard specifications were needed for the BOMAB phantom. The standard specifications for the BOMAB phantom provide the basis for a consistent phantom design for calibrating in vivo measurement systems. Such systems are designed to measure radionuclides that emit high-energy photons and that are assumed to be homogeneously distributed in the body.

Sensitivity

A well designed counting system can detect levels of most gamma emitters (>200 keV) at levels far below that which would cause adverse health affects in people. A typical detection limit for radioactive cesium (Cs-137) is about 40 Bq. The Annual Limit on Intake (i.e., the amount that would give a person a dose equal to the worker limit that is 20 mSv) is about 2,000,000 Bq. The amount of naturally occurring radioactive potassium, present in all humans and clearly not harmful as we've all got it, is also easily detectable.

The reason that these instruments are so sensitive if that they are often housed in low background counting chambers. Typically this is a small room with very thick walls made of steel (~20 cm)and perhaps lined with a thin layer of lead (~1 cm). The background reduction inside the chamber will be several orders of magnitude.

Count Times and Dection Limit

Depending on the counting geometry of the system, count times can be from 1 minute to about 30 minutes. The sensitivity of a counter does depend on counting time so the longer the count, for the same system, the better the detection limit. The detection limit, often referred to as the Minimum Detectable Activity (MDA), is given by the following formula

Where N is the number of counts of background in the region of interest, E = counting efficiency, and T = counting time.

This quantity is approximately twice the Decision Limit, another statistical quantity, that can be used to decide if there is any activity present. (i.e., a trigger point for more analysis).

External References

Kramer GH and Inn KGW. A Summary of the Proceedings of the Workshop on Standard Phantoms for In-Vivo Radioactivity Measurement Health Physics 61(6) 893-894, 1991