Whole-body counting
In health physics, whole-body counting is the measurement of radioactivity within the bodies of humans and other animals. The technique is primarily applicable to radioactive material that emits gamma rays. Alpha particle decays can also be detected indirectly by their coincident gamma radiation. In certain circumstances, beta emitters can also be measured, but with degraded sensitivity. The instrument used for whole-body counting is referred to as a whole-body counter. In contrast, a whole-body monitor is a device used in radiation protection to check for a person's body external contamination when leaving a radiation controlled area.
Principles
If a gamma ray is emitted from a radioactive element within the human body due to radioactive decay, and its energy is sufficient to escape, then it can be detected by means of either a scintillation detector or a semiconductor detector placed close to the body. Radioactive decay may give rise to gamma radiation, which cannot escape the body due to being absorbed or other interactions through which it can lose energy. Any measurement analysis must take this into account. Whole-body counting is suitable to detect radioactive elements that emit neutron radiation or high-energy beta radiation, but only in experimental applications.Whole-body counting can take place while a person is sitting, standing, or lying down, depending on the particular equipment setup used for the measurement. 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 does not rely on indirect bio-assay methods as it can measure insoluble radionuclides in the lungs.
However, there are some disadvantages to whole-body counting. Aside from special circumstances, it can only be used to detect gamma emitters due to self-shielding of the human body. It can also misinterpret external contamination as an internal contamination; to prevent this, a person must be rigorously decontaminated before the measurement. Whole body counting may be unable to distinguish between radioisotopes that have similar gamma energies. Alpha and beta radiation is largely shielded by the body and will not be detected externally, but the coincident gamma from alpha decay may be detected, as well as radiation from the parent or daughter nuclides.
[Image:Scanning Bed WBC.JPG|thumb|A scanning-bed whole-body counter]
Calibration
Any radiation detector is a relative instrument, meaning that the measurement value can only be converted to an amount of material present by comparing the response signal to the signal obtained from a standard whose radioactivity 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. The BOMAB phantom consists 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. 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. 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
[Image:Stand-up_WBC.JPG|thumb|A walk-in whole-body monitor with phantom (mannequin) for calibration]A well-designed counting system can detect levels of most gamma emitters at levels far below that which would cause adverse health effects in people. A typical detection limit for radioactive caesium is about 40 Bq. The annual limit on intake–the amount that would give a person a dose equal to the worker limit, which is 20 mSv–is about 2,000,000 Bq. A counting system can also easily detect the amount of naturally occurring radioactive potassium present in all humans; risk of death by potassium deficiency approaches 100% as whole-body count approaches zero.
The reason that these instruments are so sensitive is that they are often housed in low background counting chambers. Typically, this is a small room with very thick walls made of low-background steel and sometimes lined with a thin layer of lead. This shielding can significantly reduce background radiation inside the chamber, which increases the sensitivity of the instruments.
Count times and detection limit
Depending on the counting geometry of the system, counting can take between 1 and 30 minutes. The sensitivity of a counter does depend on counting time; for a single counting system, longer counting times have better detection limits. The detection limit, often referred to as the minimum detectable activity, is given by the formula:...where N is the number of counts of background in the region of interest; E is the counting efficiency; and T is the 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. This can be used as a trigger point for more analysis.