The use of film dosimetry of the penumbra region to improve the accuracy of intensity modulated radiotherapy.

Accurate measurements of the penumbra region are important for the proper modeling of the radiation beam for linear accelerator-based intensity modulated radiation therapy. The usual data collection technique with a standard ionization chamber artificially broadens the measured beam penumbrae due to volume effects. The larger the chamber, the greater is the spurious increase in penumbra width. This leads to inaccuracies in dose calculations of small fields, including small fields or beam segments used in IMRT. This source of error can be rectified by the use of film dosimetry for penumbra measurements because of its high spatial resolution. The accuracy of IMRT calculations with a pencil beam convolution model in a commercial treatment planning system was examined using commissioning data with and without the benefit of film dosimetry of the beam penumbrae. A set of dose-spread kernels of the pencil beam model was calculated based on commissioning data that included beam profiles gathered with a 0.6-cm-i.d. ionization chamber. A second set of dose-spread kernels was calculated using the same commissioning data with the exception of the penumbrae, which were measured with radiographic film. The average decrease in the measured width of the 80%-20% penumbrae of various square fields of size 3-40 cm, at 5 cm depth in water-equivalent plastic was 0.27 cm. Calculations using the pencil beam model after it was re-commissioned using film dosimetry of the penumbrae gave better agreement with measurements of IMRT fields, including superior reproduction of high dose gradient regions and dose extrema. These results show that accurately measuring the beam penumbrae improves the accuracy of the dose distributions predicted by the treatment planning system and thus is important when commissioning beam models used for IMRT.

Clinical application of intensity-modulated radiotherapy for locally advanced cervical cancer.

Intensity-modulated radiotherapy (IMRT) offers technical advantages over conventional external beam radiotherapy (CXRT) that might prove clinically advantageous in the management of gynecologic malignancies. Especially in the case of locally advanced cervical cancer, IMRT provides an opportunity to improve the therapeutic ratio by allowing a selective combination of normal tissue dose reduction and/or concomitant integrated boost dose to the tumor. The clinical and biologic rationale for IMRT in this setting is presented here, and pertinent technical considerations such as the delineation of relevant clinical and planning target volumes are discussed. The capacity for IMRT-mediated normal tissue sparing is illustrated by example and review of the literature. Furthermore, for a small cohort of patients with locally advanced or recurrent cervical cancer treated with concomitant integrated boost IMRT and concurrent chemotherapy, preliminary clinical observations of toxicity and tumor response are presented. Concomitant integrated boost IMRT appears clinically tolerable and efficacious in this setting, and formal clinical investigation is warranted as a means of exploiting the fraction-size dependence of radiosensitizers in common clinical use.

Technical considerations in the application of intensity-modulated radiotherapy as a concomitant integrated boost for locally-advanced cervix cancer.

The technical aspects of IMRT applied to cervix cancer are discussed in this paper, as well as issues related to tumor delineation, target volume definitions, inverse planning, and IMRT delivery. A theoretical example illustrating how IMRT can accurately mimic dose distributions obtained using conventional planning plus HDR brachytherapy is also shown. The notion of clinical optimization parameters is introduced to account for the radiation delivery variables, which affect the overall treatment time. This is especially relevant to the possible introduction of intrafractional movement and resulting inaccuracy, as well as facility efficiency.

The effect of high-dose-rate brachytherapy dwell sequence on cell survival.

PURPOSE: During a high-dose-rate (HDR) brachytherapy treatment, as the source steps through different dwell positions, the dose rate at any fixed point within the implant varies, because the distance between the point and the source continually changes. The instantaneous dose rate may vary by a factor of 100 or more, in a complex dwell position sequence. Two different points which receive the same total dose may have received that dose with a very different sequence of dose rates. Any effects due to the complex changes in dose rate, including the sequence of dose delivery, are ignored. We investigated the possible effects of the sequence in which dose is delivered at two different dose rates, representative of dose rates that occur during an HDR treatment. METHODS AND MATERIALS: The target consisted of a tube containing a 1.0 cm(3) suspension of V-79 Chinese hamster cells. Two fixed source dwell positions near and far from the target, representing high and intermediate dose rates, were considered. The experiments compared the survival of V-79 cells exposed to an irradiation sequence consisting of either an HDR component followed by an intermediate-dose-rate component (H-I arm), or the reverse (I-H arm). In either case, the total dose and the dose ratio were the same, only the order in which the high- or intermediate-dose-rate components of the dose were delivered was changed. RESULTS: When the intermediate-dose-rate component was given before the HDR component, there was increased survival. All data pairs from three experiments showed greater survival for the I-H arm than the H-I arm by amounts ranging from 4% to 24%. Simple linear-quadratic models such as the Lea-Catchside model, which is invariant to time reversal of irradiation sequence, do not predict these results. CONCLUSIONS: These results suggest that targets receiving the same total dose of radiation during an HDR implant may not experience the same biological effect. This may be related to induced radioresistance or sublethal damage repair.