Initial outcomes analysis for large multicenter integrated cancer network implementation of intensity modulated radiation therapy for breast cancer.

To analyze the initial clinical outcomes for breast cancer patients treated with intensity-modulated radiation therapy (IMRT) in a large integrated cancer center network. A total of 495 patients with breast cancer received IMRT following breast conserving surgery among nine cancer centers. Seven community cancer centers span a 100-mile radial distance from the two central academic sites. All nine cancer centers followed the same clinical pathway guidelines for the radiotherapeutic management of breast cancer. IMRT planning for all centers was performed at one central location, D3 Advanced Radiation Planning Service. The median IMRT prescription dose was 50 Gy followed by a boost with median dose of 10 Gy. The median breast volume was 918 cm(3). The median Dose Homogeneity Index (DHI) was 93%. The median % of ipsilateral lung volume receiving >20 Gy was 4.6%. For left breast IMRT, the median % heart volume receiving more than 5% of prescription dose was 13.1. There was no statistical difference in the mean DHI, heart and lung dose between the academic and community sites. For all patients, NCI CTC Grades 0,1,2,3 for acute skin erythema was 16%, 55%, 28%, and 1%, respectively. The rates of Grade 0,1,2,3 acute skin desquamation were 75%, 20%, 4%, and 1%, respectively. There was no statistically significant difference in acute skin toxicities (>grade 2) among the academic and community cancer centers. With centralized processes, IMRT can be safely and effectively delivered in a large health system with an admixture of academic and community centers but long-term follow-up is necessary.

Four-dimensional computed tomography-based interfractional reproducibility study of lung tumor intrafractional motion.

PURPOSE: To evaluate the interfractional reproducibility of respiration-induced lung tumors motion, defined by their centroids and the intrafractional target motion range. METHODS AND MATERIALS: Twentythree pairs of four-dimensional/computed tomography scans were acquired for 22 patients. Gross tumor volumes were contoured, Clinical target volumes (CTVs) were generated. Geometric data for CTVs and lung volumes were extracted. The motion tracks of CTV centroids, and CTV edges along the cranio-caudal, anterior-posterior, and lateral directions were evaluated. The Pearson correlation coefficient for motion tracks along the cranio-caudal direction was determined for the entire respiratory cycle and for five phases about the end of expiration. RESULTS: The largest motion extent was along the cranio-caudal direction. The intrafractional motion extent for five CTVs was <0.5 cm, the largest motion range was 3.59 cm. Three CTVs with respiration-induced displacement >0.5 cm did not exhibit the similarity of motion, and for 16 CTVs with motion >0.5 cm the correlation coefficient was >0.8. The lung volumes in corresponding phases for cases that demonstrated CTVs motion similarity were reproducible. No correlation between tumor size and mobility was found. CONCLUSION: Target motion reproducibility seems to be present in 87% of cases in our dataset. Three cases with dissimilar motion indicate that it is advisable to verify target motion during treatment. The adaptive adjustment to compensate the possible interfractional shifts in a target position should be incorporated as a routine policy for lung cancer radiotherapy.

The intrafraction motion induced dosimetric impacts in breast 3D radiation treatment: a 4DCT based study.

The question remains regarding the dosimetric impact of intrafraction motion in 3D breast treatment. This study was conducted to investigate this issue utilizing the 4DCT scan. The 4D and helical CT scan sets were acquired for 12 breast cancer patients. For each of these patients, based on the helical CT scan, a conventional 3D conformal plan was generated. The breast treatment was then simulated based on the 4DCT scan. In each phase of the 4DCT scan, dose distribution was generated with the same beam parameters as the conventional plan. A software package was developed to compute the cumulative dose distribution from all the phases. Since the intrafraction organ motion is reflected by the 4DCT images, the cumulative dose computed based on the 4DCT images should be closer to what the patient received during treatment. Various dosimetric parameters were obtained from the plan and 4D cumulative dose distribution for the target volume and heart, and were compared to deduce the motion-induced impacts. The studies were performed for both whole breast and partial breast treatment. In the whole breast treatment, the average intrafraction motion induced changes in D95, D90, V100, V95, and V90 of the target volume were -5.4%, -3.1%, -13.4%, -5.1%, and -3.2%, respectively, with the largest values at -26.2%, -14.1%, -91.0%, -15.1%, and -9.0%, respectively. Motion had little impact on the Dmax of the target volume, but its impact on the Dmin of the target volume was significant. For left breast treatment, the motion-induced Dmax change to the heart could be negative or positive, with the largest increase at about 6 Gy. In partial breast treatment, the only non-insignificant impact was in the Dmin of the CTV (ranging from -15.2% to 11.7%). The results showed that the intrafraction motion may compromise target dose coverage in breast treatments and the degree of that compromise was correlated with motion magnitude. However, the dosimetric impact of the motion on the heart dose may be limited.

Preliminary results from a Phase II trail of conformal radiation therapy for pediatric patients with localised low-grade astrocytoma and ependymoma.

PURPOSE: To estimate the local control and patterns of failure for pediatric patients with low-grade astroglial tumors (LGA) and ependymoma (EP) treated with three-dimensional conformal radiation therapy (CRT) using an anatomically defined clinical target volume (CTV). METHODS AND MATERIALS: From an ongoing, prospective Phase II trial initiated in July 1997, 102 pediatric patients with LGA (n = 38) and EP (n = 64) have been treated with CRT using an anatomically defined CTV extending 1.0 cm beyond the gross tumor volume and a 0.5-cm margin (planning target volume) extending outside of the CTV. The prescribed dose was 54 Gy (LGA) and 59.4 Gy (EP). RESULTS: Patients with EP have been followed for a median of 17 months (range 3--43 months), and six failures have occurred. Patients with LGA have been followed for a median of 17 months (3--44 months), and four failures have occurred. Three-dimensional magnetic resonance (MR) studies performed to document treatment failure were registered with the MR and computed tomography (CT) data used in the treatment planning process. Failure occurred within the CTV for 5 patients with EP, including 3 with concurrent subarachnoid dissemination. One patient with EP developed metastatic disease with no evidence of local failure. Three patients with LGA failed within the CTV and one failed immediately outside of the CTV. CONCLUSIONS: Treatment of an anatomically defined CTV, encompassing 1.0 cm of non-involved brain beyond the margin of resection or neuroimaging-defined tumor, appears to be safe for pediatric patients with LGA and EP based on these preliminary data. Normal tissue sparing through the use of advanced radiation therapy treatment planning and delivery techniques should be beneficial to pediatric patients if the rate and patterns of failure are similar to conventional techniques and toxicity reduction can be objectively documented.

Verification of multileaf collimator leaf positions using an electronic portal imaging device.

An automated method is presented for determining individual leaf positions of the Siemens dual focus multileaf collimator (MLC) using the Siemens BEAMVIEW(PLUS) electronic portal imaging device (EPID). Leaf positions are computed with an error of 0.6 mm at one standard deviation (sigma) using separate computations of pixel dimensions, image distortion, and radiation center. The pixel dimensions are calculated by superimposing the film image of a graticule with the corresponding EPID image. A spatial correction is used to compensate for the optical distortions of the EPID, reducing the mean distortion from 3.5 pixels (uncorrected) per localized x-ray marker to 2 pixels (1 mm) for a rigid rotation and 1 pixel for a third degree polynomial warp. A correction for a nonuniform dosimetric response across the field of view of the EPID images is not necessary due to the sharp intensity gradients across leaf edges. The radiation center, calculated from the average of the geometric centers of a square field at 0 degrees and 180 degrees collimator angles, is independent of graticule placement error. Its measured location on the EPID image was stable to within 1 pixel based on 3 weeks of repeated extensions/retractions of the EPID. The MLC leaf positions determined from the EPID images agreed to within a pixel of the corresponding values measured using film and ionization chamber. Several edge detection algorithms were tested: contour, Sobel, Roberts, Prewitt, Laplace, morphological, and Canny. These agreed with each other to within < or = 1.2 pixels for the in-air EPID images. Using a test pattern, individual MLC leaves were found to be typically within 1 mm of the corresponding record-and-verify values, with a maximum difference of 1.8 mm, and standard deviations of <0.3 mm in the daily reproducibility. This method presents a fast, automatic, and accurate alternative to using film or a light field for the verification and calibration of the MLC.