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Calculation of residence times and radiation doses using the standard PC software Excel (1997)

Herzog, H. ; Zilken, H. ; Niederbremer, A. ; [et al.]

Springer

European journal of nuclear medicine 24 (1997), S. 1514-1521

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ISSN: 1619-7089

Keywords: Key words: Residence times ; Radiation dosimetry ; Excel ; MIRDOSE3Introduction

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract. We developed a program which aims to facilitate the calculation of radiation doses to single organs and the whole body. IMEDOSE uses Excel to include calculations, graphical displays, and interactions with the user in a single general-purpose PC software tool. To start the procedure the input data are copied into a spreadsheet. They must represent percentage uptake values of several organs derived from measurements in animals or humans. To extrapolate these data up to seven half-lives of the radionuclide, fitting to one or two exponentional functions is included and can be checked by the user. By means of the approximate time-activity information the cumulated activity or residence times are calculated. Finally these data are combined with the absorbed fraction doses (S-values) given by MIRD pamphlet No. 11 to yield radiation doses, the effective dose equivalent and the effective dose. These results are presented in a final table. Interactions are realized with push-buttons and drop-down menus. Calculations use the Visual Basic tool of Excel. In order to test our program, biodistribution data of fluorine-18 fluorodeoxyglucose were taken from the literature (Meija et al., J Nucl Med 1991; 32:699–706). For a 70-kg adult the resulting radiation doses of all target organs listed in MIRD 11 were different from the ICRP 53 values by 1%±18% on the average. When the residence times were introduced into MIRDOSE3 (Stabin, J Nucl Med 1996; 37:538–546) the mean difference between our results and those of MIRDOSE3 was –3%±6%. Both outcomes indicate the validity of the present approach.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002590050182

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Iodine-123 α-methyl tyrosine single-photon emission tomography of cerebral gliomas: standardised evaluation of tumour uptake and extent (1998)

Weckesser, Matthias ; Grießmeier, Martin ; Schmidt, Daniela ; [et al.]

Springer

European journal of nuclear medicine 25 (1998), S. 150-156

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ISSN: 1619-7089

Keywords: Key words: Single-photon emission tomography ; Glioma ; l-3-[123I]iodo-α-methyltyrosine

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract. Single-photon emission tomography (SPET) with the amino acid analogue l-3-[123I]iodo-α-methyl tyrosine (IMT) is helpful in the diagnosis and monitoring of cerebral gliomas. Radiolabelled amino acids seem to reflect tumour infiltration more specifically than conventional methods like magnetic resonance imaging and computed tomography. Automatic tumour delineation based on maximal tumour uptake may cause an overestimation of mean tumour uptake and an underestimation of tumour extension in tumours with circumscribed peaks. The aim of this study was to develop a program for tumour delineation and calculation of mean tumour uptake which takes into account the mean background activity and is thus optimised to the problem of tumour definition in IMT SPET. Using the frequency distribution of pixel intensities of the tomograms a program was developed which automatically detects a reference brain region and draws an isocontour region around the tumour taking into account mean brain radioactivity. Tumour area and tumour/brain ratios were calculated. A three-compartment phantom was simulated to test the program. The program was applied to IMT SPET studies of 20 patients with cerebral gliomas and was compared to the results of manual analysis by three different investigators. Activity ratios and chamber extension of the phantom were correctly calculated by the automatic analysis. A method based on image maxima alone failed to determine chamber extension correctly. Manual region of interest analysis in patient studies resulted in a mean inter-observer standard deviation of 8.7%±6.1% (range 2.7%–25.0%). The mean value of the results of the manual analysis showed a significant correlation to the results of the automatic analysis (r = 0.91, P〈0.0001 for the uptake ratio; r = 0.87, P〈0.0001 for the tumour area). We conclude that the algorithm proposed simplifies the calculation of uptake ratios and may be used for observer-independent evaluation of IMT SPET studies. Three-dimensional tumour recognition and transfer to co-registered morphological images based on this program may be useful for the planning of surgical and radiation treatment.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002590050208

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