Sains Ma1aysiana 26(3&4): 119-120 (1997)                                                                               Sains Fizis dan Gunaan/

                                                                                                                                               Physical and Applied Sciences

 

Comparison of Measured and Calculated 40K

Activitiy per Gram of K

 

 

Supian Bin Samat

Department of Physics

Faculty of Physical and Applied Sciences

Universiti Kebangsaan Malaysia

43600 UKM Bangi Selangor D.E. MALAYSIA

 

Stuart Green & Alun H. Beddoe

Department of Medical Physics

University Hospital Birmingham NHS Trust

Queen Elizabeth Hospital

Birmingham 815 2TH, U.K.

 

 

Measurement of the natural 40K body gamma-ray radioactivity via the whole-body counter (WBC) technique may yield the total body potassium (TBK) status, from which for example, the body cell mass can be derived (Moore et al. 1963). The accuracy of the derived TBK is of course critically dependent on the assumed value of the ratio 40K:TBK. Potassium chloride (KCI) has been widely used as the 40K calibration standard. In reviewing the literature (Burkinshaw 1967; Ross & Morris 1968; Havlik 1970, Young et al 1975; Manocha & Mohindra 1976; Holtzman 1977; Graham 1983; HMSO 1985-1986, Lykken et al 1987; Lan & Weng 1989; Fenwick et al. 1991), it is apparent that inconsistencies occur in the use of 40K activity per gram of natural potassium. It varies between 27.33 to 31.31 Bq per gram of potassium. The objectives of this study were to independently measure and calculate the 40K activity per gram of natural potassium in an attempt to reduce the uncertainty in the accepted figure. Experimentally the activity of 40K from a known amount of K was determined by measuring the 40K photon emission of an analar grade KCI sample solution and the absolute efficiency of the detection system at energy 1460 KeV. Both the photopeak count-rate and the absolute efficiency were measured using the gamma-ray spectroscopy technique. The 40K activity is also calculated from its half-life (IAEA 1989) and the number of atoms present in the sample. The measured and calculated values obtained were 30.18 ± 0.72 Bq g-1 and 31.00 ± 0.33 Bq g-1 respectively. The difference is of the order of 2.6%. The measured value is consistent with the literature values being close to the mean of the values, namely 29.77. In conclusion, it is believed that the experimental values reported in this work is one of the few experimentally determined results and it is reassuring to note that the experimental and theoretical values are in reasonable agreement.

 

 

RUJUKAN/REFERENCES

 

Burkinshaw, L. 1967. Measurement of body potassium. Calibration and intercomparison of two whole-body radiation counters. Phys. Med. BioI. 12: 477-488.

Fenwick, J. D., McKenzie, A. L. & Boddy, K. 1991. Intercomparison of whole-body counters using a multinuclide calibration phantom. Phys. Med. BioI. 36: 191-­198.

Graham, S. G. 1983. Bremstrahlung production by potassium -40 muscle. Phys. Med. BioI. 28: 19-30.

Havlik, B. 1970. Radioactive pollution of rivers in Czechoslovakia. Health Phys. 19: 617-624.

HMSO. 1985-1986. Measurement of alpha and beta activity in water and samples. Department of Environment London: 71.

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IAEA 1989. Measurement of radionuclides in food and the environment. Technical Report Series No: 295 Vienna: 125.

Lan, C. Y. & Weng, P. S. 1989. Body K and 40K in Chinese subjects measured with a whole-body counter. Health Phys. 57: 743-746.

Lykken, G. I., Speaker, K. K. & MacKichian, A. K. 1987. Estimation of total body potassium in the presence of interfering radioisotopes (Chapter 17), Prof. in vivo body composition studies IPSM3 London, 115-117.

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Moore, F. D., Olesen, K. H. & McMurrey, J. D. 1963. The body cell mass and its supporting environment. Body composition in health and disease. Philadelphia: Saunders.

Ross, D. A. & Morris, A. C. 1968. A stable, low-back-ground whole-body counter designed for uniform detector geometry. Int. J. Appl. Radiat. Isot. 19: 731-739.

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