Development of a four-axis moving phantom for patient-specific QA of surrogate signal-based tracking IMRT

AAPM Task Group 119 has produced quantitative confidence limits as baseline expectation values for IMRT commissioning. A set of test cases was developed to assess the overall accuracy of planning and delivery of IMRT treatments. Each test uses contours of targets and avoidance structures drawn within rectangular phantoms. These tests were planned, delivered, measured, and analyzed by nine facilities using a variety of IMRT planning and delivery systems. Each facility had passed the Radiological Physics Center credentialing tests for IMRT. The agreement between the planned and measured doses was determined using ion chamber dosimetry in high and low dose regions, film dosimetry on coronal planes in the phantom with all fields delivered, and planar dosimetry for each field measured perpendicular to the central axis. The planar dose distributions were assessed using gamma criteria of 3%/3 mm. The mean values and standard deviations were used to develop confidence limits for the test results using the concept confidence limit = /mean/ + 1.96sigma. Other facilities can use the test protocol and results as a basis for comparison to this group. Locally derived confidence limits that substantially exceed these baseline values may indicate the need for improved IMRT commissioning.

Since its introduction more than a decade ago, intensity-modulated radiotherapy (IMRT) has spread to most radiotherapy departments worldwide for a wide range of indications. The technique has been rapidly implemented, despite an incomplete understanding of its advantages and weaknesses, the challenges of IMRT planning, delivery, and quality assurance, and the substantially increased cost compared with non-IMRT. Many publications discuss the theoretical advantages of IMRT dose distributions. However, the key question is whether the use of IMRT can be exploited to obtain a clinically relevant advantage over non-modulated external-beam radiation techniques. To investigate which level of evidence supports the routine use of IMRT for various disease sites, we did a review of clinical studies that reported on overall survival, disease-specific survival, quality of life, treatment-induced toxicity, or surrogate endpoints. This review shows evidence of reduced toxicity for various tumour sites by use of IMRT. The findings regarding local control and overall survival are generally inconclusive.

The success of highly target-conformal treatments such as intensity-modulated radiotherapy (IMRT) can be compromised by motion of the inner organs and random patient setup errors. This article gives an overview of different studies that looked at the effect of organ motion and setup errors on radiation therapy dose distributions, both from a qualitative and quantitative point of view. The qualitative findings are generally applicable (ie, case independent). It is found that motion always leads to a blurring of the dose distribution. In addition, there are so-called interplay effects if the treatment delivery involves moving parts, such as multileaf collimators. After a large number of fractions, the interplay effects lead to a normal distribution of the dose value around the average blurred value. Thirdly, organ motion can also cause a spatial deformation of the dose distribution. Quantitatively it has been found that both deformation and interplay effects appear to be small (in the order of 1%-2%) in many typical clinical cases. The dominant effect is the blurring of the dose distribution, which is, in essence, independent of the treatment technique, and is not more pronounced in IMRT than in more conventional treatment techniques. However, because in IMRT there is a tendency to reduce or compromise target margins, the blurring has potentially a bigger effect on the outcome of IMRT, unless precision dose delivery techniques (such as gated or motion-synchronized beams) are used. An alternative to the use of margins is to do the planning based on blurred dose distributions.