Medical Radiology and Radiation Safety. 2014. Vol. 59. No. 3. P. 52-58

RADIATION PHYSICS, TECHNOLOGY AND DOSIMETRY

V.Yu. Soloviev, T.M. Khamidulin

Voxel Phantom Technology in Accidental Dosimetry: Perspectives

Burnasyan Federal Medical Biophysical Center of FMBA, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Purpose: Evaluate the possibility of using voxel-phantom technology combined with a set of dosimeters for the purposes of gamma-neutron radiation field accidental dosimetry

Material and methods: The object of research is the vital organs volume distribution over dose within the voxel phantom irradiated in the field of neutron and gamma-ray source with the emission spectrum of the fissile material.

Results: For a typical energy distribution of the field of fissile material gamma-neutron radiation the family of neutron and gamma-ray dose distributions inside the voxel phantom has been obtained. The calculations were done for four different orientations of the phantom relative to the point-type radiation source (front, back, left and right side), not taking into account the walls, ceiling and the floor of the hall, and for each one the amount of dose absorbed by dosimeter (on the surface of the chest area) was evaluated. The phantom was placed at a distance of 2.5 meters away from the radiation source. Using this data the characteristics of the vital organs mass distribution over the dose were estimated. It was shown that red bone marrow is affected most when phantom is irradiated from behind, and the least damage is caused by radiation from the left and right sides with the same distance to the radiation source. With the dosimeter located on the chest the bone marrow mass over dose distribution median is 5 times smaller than the dosimeter reading in case of frontal irradiation, and significantly larger than the dosimeter reading in case of irradiation from behind. For practical calculations the dimensions of the hall and all the elements of physical shielding must be taken into account.

Conclusion: The result of the study is development of computational and experimental complex for the emergency dosimetry, which consists of a computational module and a set of gamma and neutron radiation dosimeters. The resulting information gives physicians full amount of data about vital organs radiation damage severity and dose distribution throughout the body, necessary for choosing optimal treatment strategy and tactics immediately after reading the dosimeter.

Key words: voxel phantom, gamma-neutron irradiation, dose, red bone marrow, accident dosimetry

Medical Radiology and Radiation Safety. 2014. Vol. 59. No. 3. P. 39-44

RADIATION THERAPY

A.O. Rasulov, D.V. Kuzmichev, S.I. Tkachev, V.F. Tsaryuk, S.S. Gordeyev, A.G. Perevoschikov, V.V. Glebovskaya, A.V. Polinovskiy

Factors of Chemoradiotherapy Efficacy of Localized Rectal Cancer

N.N. Blokhin Canser Research Center of RAMS, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Purpose: Factors of treatment response after chemoradiotherapy with fluorpyrimidines and radiosensitizers are discussed.

Methods: 137 patients, who received 5×5 Gy chemoradiotherapy were included in this study. A multifactor analysis was performed regarding the impact of sex, age, tumor histology, tumor size, treatment scheme, tumor stage (II or III) and time to surgery on tumor regression.

Results: No significant association was observed in investigated factors and grade III–IV treatment response. There was only low correlation between time to surgery and tumor regression.

Conclusions: We observed no impact of investigated factors on tumor regression. Complete and near-complete tumor regression in our study was associated with absence of local recurrences and distant metastases.

Key words: colorectal cancer, combined treatment, chemoradiotherapy, tumor regression

Medical Radiology and Radiation Safety. 2014. Vol. 59. No. 3. P. 45-51

NUCLEAR MEDICINE

A.V. Khmelev¹, P.S. Bakay²

Study of the ¹²⁴I Cyclotron Production Parameters Impact for its Activity and Radionuclide Purity

1. Russian Medical Academy for Postgraduate Education, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it. ; 2. N.N. Blokhin Russian Cancer Research Center of RAMS, Moscow, Russia

ABSTRACT

Purpose: Definition of terms wherein cyclotron-produced ¹²⁴I applicable for using in PET-diagnostics in oncology.

Material and methods: Numerical simulation of ¹²⁴I production process in nuclear reactions initiated in the target TeO₂ by 10–15 MeV proton beam as well as such reaction products decay was carried out.

Results: It is shown that ¹²⁴I activity gains the maximal value (86 mCi) at proton energy E = 12 MeV (for “beam current (I) × irradiation time” (t₀) parameter equaled 100 m A×hour) and it decreases on ~ 10 % at grow of ¹²³Te impurity concentration in the target from 0.5 up to 10 %. Existence of time span after the end of the target irradiation wherein produced ¹²⁴I satisfy to radionuclide purity and activity requirements for application in PET-diagnostics was found. Beginning of this time span depends on proton energy and concentration of impurity ¹²³Te (K_i). ¹²⁴I has become applicable in 2.1–8.3 days from the end of irradiation at energy changing in the range of 10–15 MeV. Beginning of time span grows from 4.7 days up to 5.1 days at K_i increasing from 0.5 up to 10 % at E = 12 MeV and It₀ = 100 μAhour. ¹²⁴I application time grows with increasing of It₀. This time also depends on proton energy and it gains the maximal value of 15.2 days at E = 11 MeV and It₀ = 100 μAhour.

Conclusion: Radionuclide purity and activity of ¹²⁴I are determined by parameters of its cyclotron production – beam current, target irradiation time and proton energy as well as ¹²³Te impurity concentration in the target and time from the end of the irradiation. Dependences of the beginning and duration of time span of cyclotron produced ¹²⁴I for its application in PET-diagnostics from these parameters are established and studied.

Key words: cyclotron, ¹²⁴I radionuclide, activity, radionuclide purity

Medical Radiology and Radiation Safety. 2014. Vol. 59. No. 3. P. 32-38

DIAGNOSTIC RADIOLODGY

A.A. Levitov, V.I. Krasnuk, V.I. Doga

Linear Digital Tomosynthesis: New Opportunities for Radiation Diagnostics

Burnasyan Federal Medical Biophysical Center of FMBA, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Modern medicine widely use radiological techniques in many fields and areas, such as screening, diagnosis, clarifying the nature of changes in the internal organs. One of the leaders in diagnostic imaging methods, which are based on Χ-rays: roentgenogrphy and CT scan. These methods, theoretical basis of which have found their technical realization in the medicine in a relatively short period of time, and they quickly entered into the daily practice of professionals. But there is a survey methodology, theoretical foundations of which were nominated some earlier to the point when their practical possibility appears. And now they are gradually coming into practice ray diagnosticians, complementing the long-known technique of examination and in many ways allowing to make the diagnostic process more accurate, faster and better. One of these methods is a digital linear tomosynthesis. Occupying an intermediate position in the diagnostic range between radiography and computed tomography, tomosynthesis can be considered as an interesting alternative to these methods. As a software and hardware option of the radiographic system, tomosynthesis is possible to carry out research in information close to the CT scan, and in the cases with the presence of metal and surpassing such, at a much lower radiation dose to the patient, the lower cost of research, and at less time costs evaluation and processing.

Key words: linear digital tomosynthesis, digital radiography, radiology, flat panel detector, cancer screening