Hypofractionated irradiation for gliomas with 45.5Gy in 13 fractions: a retrospective study.

AIM: The aim of the present retrospective study was to evaluate the efficacy and toxicity of a hypofractionated radiotherapy (HFRT) schedule for grade IV glioblastoma multiforme (GBM). METHODS: Fourteen elderly patients with KPS less than 70, received 13 fractions of 350cGy with 3D-conformal technique (3DCRT) and non-coplanar fields. Acute and late skin and CNS toxicity was graded according to EORTC/RTOG criteria. RESULTS: The median follow-up was 9 months. All patients completed the irradiation without interruptions due to toxicity and received temozolomide (TMZ) after the completion of 3DCRT. The KPS during RT and at follow-up was not significantly changed (P=0.108). The median overall survival was 7 months. No severe skin acute or late toxicity was noted. In terms of CNS toxicity, only one patient presented grade III toxicity requiring hospitalization for two days. The irradiation schedule of 45.5Gy in 13 fractions seems effective and without moderate or severe toxicity. CONCLUSION: The suggested HFRT schedule might be an alternative one, for elderly patients with dismal prognosis, unfit for six weeks of daily irradiation. Prospective studies are needed for further validation of our results, especially with the use of TMZ.

Investigating the clinical aspects of using CT vs. CT-MRI images during organ delineation and treatment planning in prostate cancer radiotherapy.

In order to apply highly conformal dose distributions, which are characterized by steep dose fall-offs, it is necessary to know the exact target location and extension. This study aims at evaluating the impact of using combined CT-MRI images in organ delineation compared to using CT images alone, on the clinical results. For 10 prostate cancer patients, the respective CT and MRI images at treatment position were acquired. The CTV was delineated using the CT and MRI images, separately, whereas bladder and rectum were delineated using the CT images alone. Based on the CT and MRI images, two CTVs were produced for each patient. The mutual information algorithm was used in the fusion of the two image sets. In this way, the structures drawn on the MRI images were transferred to the CT images in order to produce the treatment plans. For each set of structures of each patient, IMRT and 3D-CRT treatment plans were produced. The individual treatment plans were compared using the biologically effective uniform dose () and the complication-free tumor control probability (P(+)) concepts together with the DVHs of the targets and organs at risk and common dosimetric criteria. For the IMRT treatment, at the optimum dose level of the average CT and CT-MRI delineated CTV dose distributions, the P(+) values are 74.7% in both cases for a of 91.5 Gy and 92.1 Gy, respectively. The respective average total control probabilities, PB are 90.0% and 90.2%, whereas the corresponding average total complication probabilities, P(I) are 15.3% and 15.4%. Similarly, for the 3D-CRT treatment, the average P(+) values are 42.5% and 46.7%, respectively for a of 86.4 Gy and 86.7 Gy, respectively. The respective average P(B) values are 80.0% and 80.6%, whereas the corresponding average P(I) values are 37.4% and 33.8%, respectively. For both radiation modalities, the improvement mainly stems from the better sparing of rectum. According to these results, the expected clinical effectiveness of IMRT can be increased by a maximum ΔP(+) of around 0.9%, whereas of 3D-CRT by about 4.2% when combined CT-MRI delineation is performed instead of using CT images alone. It is apparent that in both IMRT and 3D-CRT radiation modalities, the better knowledge of the CTV extension improved the produced dose distribution. It is shown that the CTV is irradiated more effectively, while the complication probabilities of bladder and rectum, which is the principal organs at risk, are lower in the CT-MRI based treatment plans.