Primary bone lymphoma.

Primary bone lymphoma is a rare condition which represents a low percentage of both the malignant primary bone tumours and the non-Hodgkin extranodal lymphoma. This explains the lack of publications, lines of investigations, and specific diagnostic and treatment protocols. In the following article we will carry out a revision of the existing literature on this rare subject, using as argument a clinical case of left femoral location stage IE treated with CHOP chemotherapy and radiotherapy.

A Monte Carlo approach for small electron beam dosimetry.

Background And Purpose: In treatments where it is necessary to conform the field shape yielding a very small effective beam area, dosimetry and conventional treatment planning may be inaccurate. The Monte Carlo (MC) method can be an alternative to verify dose calculations. A conjunctival mucosa-associated lymphoid tissues lymphoma is presented, to show the importance of an independent assessment in critical situations.

Lateral scatter correction algorithm for percentage depth dose in a large-field photon beam.

Differences between the scatter conditions of dosimetry and treatment situation are more important in the case of large-field photon beams than in standard ones. In the former, the scattering volume is defined by the phantom cross section; in the latter, the radiation field size. Two factors should be considered: the thickness and the cross section of the phantom.

Computer-based anthropometrical system for total body irradiation.

For total body irradiation (TBI) dose calculation requirements, anatomical information about the whole body is needed. Despite the fact that video image grabbing techniques are used by some treatment planning systems for standard radiotherapy, there are no such systems designed to generate anatomical parameters for TBI planning. The paper describes an anthropometrical computerised system based on video image grabbing which was purpose-built to provide anatomical data for a PC-based TBI planning system.

Verification of an on line in vivo semiconductor dosimetry system for TBI with two TLD procedures.

This work presents the verification of an on line in vivo dosimetry system based on semiconductors. Software and hardware has been designed to convert the diode signal into absorbed dose. Final verification was made in the form of an intercomparison with two independent thermoluminiscent (TLD) dosimetry systems, under TBI conditions.