Stella C. Lymberis

A Phase 2 Trial of Stereotactic Radiosurgery Boost After Surgical Resection for Brain Metastases

PURPOSE To evaluate local control after surgical resection and postoperative stereotactic radiosurgery (SRS) for brain metastases. METHODS AND MATERIALS A total of 49 patients (50 lesions) were enrolled and available for analysis. Eligibility criteria included histologically confirmed malignancy with 1 or 2 intraparenchymal brain metastases, age≥18 years, and Karnofsky performance status (KPS)≥70. A Cox proportional hazard regression model was used to test for significant associations between clinical factors and overall survival (OS). Competing risks regression models, as well as cumulative incidence functions, were fit using the method of Fine and Gray to assess the association between clinical factors and both local failure (LF; recurrence within surgical cavity or SRS target), and regional failure (RF; intracranial metastasis outside of treated volume). RESULTS The median follow-up was 12.0 months (range, 1.0-94.1 months). After surgical resection, 39 patients with 40 lesions were treated a median of 31 days (range, 7-56 days) later with SRS to the surgical bed to a median dose of 1800 cGy (range, 1500-2200 cGy). Of the 50 lesions, 15 (30%) demonstrated LF after surgery. The cumulative LF and RF rates were 22% and 44% at 12 months. Patients who went on to receive SRS had a significantly lower incidence of LF (P=.008). Other factors associated with improved local control include non-small cell lung cancer histology (P=.048), tumor diameter<3 cm (P=.010), and deep parenchymal tumors (P=.036). Large tumors (≥3 cm) with superficial dural/pial involvement showed the highest risk for LF (53.3% at 12 months). Large superficial lesions treated with SRS had a 54.5% LF. Infratentorial lesions were associated with a higher risk of developing RF compared to supratentorial lesions (P<.001). CONCLUSIONS Postoperative SRS is associated with high rates of local control, especially for deep brain metastases<3 cm. Tumors≥3 cm with superficial dural/pial involvement demonstrate the highest risk of LF.

Hypofractionated Stereotactic Radiotherapy Using Intensity-Modulated Radiotherapy in Patients with One or Two Brain Metastases

Purpose: A small fraction of patients with 1–2 brain metastases will not be suitable candidates to either surgical resection or stereotactic radiosurgery (SRS) due to either their location or their size. The objective of this study was to determine the local control, survival, patterns of relapse and the incidence of brain injury following a course of hypofractionated stereotactic radiotherapy while avoiding upfront whole brain radiation therapy (WBRT) in this subgroup of patients. Methods: A Gill-Thomas removable head frame system was used for immobilization. Brain LAB software with dynamic multileaf collimator hardware was used to design and deliver an intensity-modulated radiation therapy treatment plan. A dose of 600 cGy was prescribed to the 100% isodose line that would encompass the lesion with a 3-mm margin. A total dose of 3,000 cGy was delivered in 5 fractions using 2 fractions per week. The patients were followed with neurological examination and serial MRI images done every 3 months following the procedure. Results: Twenty patients have been treated using this fractionation schedule since April 2004. The 1-year local control at the site of original disease is 70%. The complete response, partial response and stable disease at the last follow-up were 15, 30 and 45%, respectively. Two patients had local recurrence at the site of original disease, while 5 had evidence of leptomeningeal disease. Two additional patients developed new brain metastases, resulting in a 1-year brain relapse-free survival of 36% following this approach. The median overall survival was 8.5 months. Three patients (15%) developed steroid dependency lasting 3 months or longer following the procedure. Four patients (20%) needed WBRT as salvage following this approach. Conclusions: The preliminary results of hypofractionated SRS are comparable to both surgery and SRS data for solitary brain metastases in terms of local control and overall survival with acceptable morbidity in this cohort of unfavorable patients.

PROSPECTIVE STUDY OF CONE-BEAM COMPUTED TOMOGRAPHY IMAGE-GUIDED RADIOTHERAPY FOR PRONE ACCELERATED PARTIAL BREAST IRRADIATION

PURPOSE To report setup variations during prone accelerated partial breast irradiation (APBI). METHODS New York University (NYU) 07-582 is an institutional review board-approved protocol of cone-beam computed tomography (CBCT) to deliver image-guided ABPI in the prone position. Eligible are postmenopausal women with pT1 breast cancer excised with negative margins and no nodal involvement. A total dose of 30 Gy in five daily fractions of 6 Gy are delivered to the planning target volume (the tumor cavity with 1.5-cm margin) by image-guided radiotherapy. Patients are set up prone, on a dedicated mattress, used for both simulation and treatment. After positioning with skin marks and lasers, CBCTs are performed and the images are registered to the planning CT. The resulting shifts (setup corrections) are recorded in the three principal directions and applied. Portal images are taken for verification. If they differ from the planning digital reconstructed radiographs, the patient is reset, and a new CBCT is taken. RESULTS 70 consecutive patients have undergone a total of 343 CBCTs: 7 patients had four of five planned CBCTs performed. Seven CBCTs (2%) required to be repeated because of misalignment in the comparison between portal and digital reconstructed radiograph image after the first CBCT. The mean shifts and standard deviations in the anterior-posterior (AP), superior-inferior (SI), and medial-lateral (ML) directions were -0.19 (0.54), -0.02 (0.33), and -0.02 (0.43) cm, respectively. The average root mean squares of the daily shifts were 0.50 (0.28), 0.29 (0.17), and 0.38 (0.20). A conservative margin formula resulted in a recommended margin of 1.26, 0.73, 0.96 cm in the AP, SI, and ML directions. CONCLUSION CBCTs confirmed that the NYU prone APBI setup and treatment technique are reproducible, with interfraction variation comparable to those reported for supine setup. The currently applied margin (1.5 cm) adequately compensates for the setup variation detected.

Ionizing radiation modulates the exposure of the HUIV26 cryptic epitope within collagen type IV during angiogenesis

PURPOSE The majority of the research on the biologic effects of ionizing radiation has focused on the impact of radiation on cells in terms of gene expression, DNA damage, and cytotoxicity. In comparison, little information is available concerning the direct effects of radiation on the extracellular microenvironment, specifically the extracellular matrix and its main component, collagen. We have developed a series of monoclonal antibodies that bind to cryptic epitopes of collagen Type IV that are differentially exposed during matrix remodeling and are key mediators of angiogenesis. We have hypothesized that ionizing radiation might affect the process of angiogenesis through a direct effect on the extracellular matrix and specifically on collagen Type IV. METHODS AND MATERIALS Angiogenesis was induced in a chick chorioallantoic membrane (CAM) model; 24 h later, a single-dose treatment with ionizing radiation (0.5, 5, and 20 cGy) was administered. Angiogenesis was assessed, and the exposure of two cryptic regulatory epitopes within collagen Type IV (HUI77 and HUIV26) was studied in vitro by solid-phase ELISA and in vivo by immunofluorescence staining. RESULTS A dose-dependent reduction of angiogenesis with maximum inhibition (85%-90%) occurring at 20 cGy was demonstrated in the CAM model. Exposure of the cryptic HUIV26 site, an angiogenesis control element, was inhibited both in vitro and in vivo by the same radiation dose, whereas little if any change was observed for the HUI77 cryptic epitope. CONCLUSIONS A dose-dependent alteration of the functional exposure of the HUIV26 cryptic epitope is induced by radiation in vitro and in the CAM model in vivo. This radiation-induced change in protein structure and function may contribute to the inhibitory effects of ionizing radiation on new blood vessel growth and warrants further studies in other models.

Feasibility of Accelerated Whole-Breast Radiation in the Treatment of Patients with Ductal Carcinoma In Situ of the Breast

BACKGROUND We report the results of a prospective trial investigating the use of accelerated, hypofractionated whole-breast radiation therapy after breast-conservation surgery for ductal carcinoma in situ (DCIS). PATIENTS AND METHODS A total of 59 patients with a median age of 54 years (range, 36-78 years) completed a phase I/II study of hypofractionated radiation therapy for treatment of DCIS. Eligibility criteria included patients with mammographically detected DCIS, status after segmental mastectomy with negative margins, and no residual calcifications. All patients were treated with external-beam radiation therapy without a boost, over 3 weeks, to a total dose of 42 Gy to the entire breast (2.8 Gy per fraction in 15 fractions). To optimally spare heart and lung, 34 of the 59 patients (57%) were treated in the prone position. Twenty-nine of 59 patients (49%) received adjuvant hormonal therapy. RESULTS Overall, radiation therapy was well tolerated, with modest acute toxicity limited to grade 1 radiation dermatitis (76%), breast edema (17%), and fatigue (12%). With a median follow-up of 36 months, late toxicities included grade 1 hyperpigmentation changes (85%), induration (66%), asymmetry (64%), and breast fibrosis (17%), with 3 cases of grade 2 fibrosis and 1 case of grade 2 hyperpigmentation. Among the patients with >or= 3 years of follow-up, cosmesis was scored as good to excellent in 21 patients (91%) and fair in 2 patients (9%). At the time of this report, no ipsilateral or contralateral breast recurrences have occurred. CONCLUSION These data demonstrate the feasibility of treating the whole breast for DCIS with a hypofractionated regimen, with modest acute and late toxicity.

Radiation Sensitivity of GL261 Murine Glioma Model and Enhanced Radiation Response by Flavopiridol

Response of a solid tumor to radiation treatment depends, in part, on the intrinsic radiosensitivity of tumor cells, the proliferation rate of tumor cells between radiation treatments and the hypoxic state of the tumor cells. A successful radiosensitizing agent would target S-phase cells and hypoxia. Recently, we demonstrated the anti-tumor effects of flavopiridol in the GL261 murine glioma model might involve 1) recruitment of tumor cells to S-phase (Newcomb et al., Cell Cycle 2004; 3:230-234) and 2) an anti-angiogenic effect on the tumor vasculature by downregulation of hypoxia-inducible factor -1? (HIF-1?) (Newcomb et al., Neuro-Oncology 2005; 7:225-235). Given that flavopiridol has demonstrated radiosensitizing activity in several murine tumor models, we tested whether it would enhance the response of GL261 tumors to radiation. In the present study, we evaluated the intrinsic radiation sensitivity of the GL261 glioma model using the tumor control/cure dose of radiation assay (TCD50). We found that a single dose of 65 Gy (CI 57.1-73.1) was required to cure 50% of the tumors locally. Using the tumor growth delay assay, fractionated radiation (5 fractions of 5 Gy over 10 days) combined with flavopiridol (5 mg/kg) given three times weekly for 3 cycles produced a significant growth delay. Our results indicate that the GL261 murine glioma model mimics the radioresistance encountered in human gliomas, and thus should prove useful in identifying promising new investigational radiosensitizers for use in the treatment of glioma patients.

Comparison of Acute and Late Toxicity of Two Regimens of 3- and 5-Week Concomitant Boost Prone IMRT to Standard 6-Week Breast Radiotherapy

Purpose: Limited information is available comparing toxicity of accelerated radiotherapy (RT) to that of standard fractionation RT for early stage breast cancer. We report early and late toxicities of two prone regimens of accelerated intensity-modulated radiation therapy (IMRT) with a concomitant boost (CB) to the tumor bed delivered over 3 or 5 weeks as compared to standard 6 week RT with a sequential electron boost. Methods: From 2/2003 to 12/2007, 169 consecutive patients with Stage I–II breast cancer were offered the choice to undergo prone RT with either: a 6-week standard RT regimen of 46 Gy/23 fractions (fx) to the whole breast (WB), followed by a14 Gy sequential boost (SB) to the tumor bed (6wSB), a 5-week regimen of 50 Gy to WB with an IMRT CB of 6.25 Gy in 25 fx (5wCB); or a 3-week protocol of 40.5 Gy to WB with an IMRT CB of 7.5 Gy in 15 fx (3wCB). These regimens were estimated as biologically equivalent, based on alpha/beta = 4 for tumor control. Toxicities were reported using RTOG and LENT/SOMA scoring. Results: 51/169 patients chose standard 6wSB, 28 selected 5wCB, and 90 enrolled in 3wCB protocol. Maximum acute toxicity was Grade 3 dermatitis in 4% of the patients in the 6wSB compared 1% in 3wCB. In general, acute complications (breast pain, fatigue, and dermatitis) were significantly less in the 3wCB than in the other schedules (P < 0.05). With a median follow-up of 61 months, the only Grade 3 late toxicity was telangiectasia in two patients: one in 3wCB and one in 5wCB group. Notably, fibrosis was comparable among the three groups (P = NS). Conclusion: These preliminary data suggest that accelerated regimens of breast RT over 3 or 5 weeks in the prone position, with an IMRT tumor bed CB, result in comparable late toxicity to standard fractionation with a sequential tumor boost delivered over 6 weeks. As predicted by radiobiological modeling the shorter regimen was associated with less acute effects.

Prone Accelerated Partial Breast Irradiation After Breast-Conserving Surgery: Compliance to the Dosimetry Requirements of RTOG-0413

PURPOSE The dosimetric results from our institutions trials of prone accelerated partial breast irradiation are compared with the dosimetric requirements of RTOG-0413. METHODS AND MATERIALS Trial 1 and Trial 2 are 2 consecutive trials of prone-accelerated partial breast irradiation. Eligible for both trials were stage I breast cancer patients with negative margins after breast-conserving surgery. The planning target tumor volume (PTV) was created by extending the surgical cavity 2.0 cm for Trial 1 and 1.5 cm for Trial 2, respectively. Contralateral breast, heart, lungs, and thyroid were contoured. Thirty Gray was delivered in five daily fractions of 6 Gy by a three-dimensional conformal radiation therapy technique in Trial 1 and were by image-guided radiation therapy/intensity-modulated radiation therapy in Trial 2. Dosimetric results from the trials are reported and compared with RTOG 0413 requirements. RESULTS One hundred forty-six consecutive plans were analyzed: 67 left and 79 right breast cancers. The plans from the trials complied with the required>90% of prescribed dose covering 90% of PTV_EVAL (=generated from the PTV by cropping 0.5 cm from the skin edge and excluding the chest wall): V90% was 98.1±3.0% (with V100% and V95%, 89.4±12.8%, 96.4±5.1%, respectively). No significant difference between laterality was found (Students t test). The dose constraints criteria of the RTOG-0413 protocol for ipsilateral and contralateral lung (V30<15% and Dmax<3%), heart (V5<40%), and thyroid (Dmax<3%) were satisfied because the plans showed an average V5% of 0.6% (range, 0-13.4) for heart, an average V30% of 0.6% (range, 0-9.1%) for ipsilateral lung, and <2% maximum dose to the thyroid. However, our partial breast irradiation plans demonstrated a higher dose to contralateral breast than that defined by RTOG constraints, with a median value of maximum doses of 4.1% (1.2 Gy), possibly as a result of contouring differences. CONCLUSIONS Our technique for prone accelerated partial breast irradiation generally satisfied RTOG-0413 requirements.

Preplanning prediction of the left anterior descending artery maximum dose based on patient, dosimetric, and treatment planning parameters

Purpose Maximum dose to the left anterior descending artery (LADmax) is an important physical constraint to reduce the risk of cardiovascular toxicity. We generated a simple algorithm to guide the positioning of the tangent fields to reliably maintain LADmax <10 Gy. Methods and materials Dosimetric plans from 146 consecutive women treated prone to the left breast enrolled in prospective protocols of accelerated whole breast radiation therapy, with a concomitant daily boost to the tumor bed (40.5 Gy/15 fraction to the whole breast and 48 Gy to the tumor bed), provided the training set for algorithm development. Scatter plots and correlation coefficients were used to describe the bivariate relationships between LADmax and several parameters: distance from the tumor cavity to the tangent field edge, cavity size, breast separation, field size, and distance from the tangent field. A logistic sigmoid curve was used to model the relationship of LADmax and the distance from the tangent field. Furthermore, we tested this prediction model on a validation data set of 53 consecutive similar patients. Results A lack of linear relationships between LADmax and distance from cavity to LAD (−0.47), cavity size (−0.18), breast separation (−0.02), or field size (−0.28) was observed. In contrast, distance from the tangent field was highly negatively correlated to LADmax (-0.84) and was used in the models to predict LADmax. From a logistic sigmoid model we selected a cut-point of 2.46 mm (95% confidence interval, 2.19-2.74 mm) greater than which LADmax is <10 Gy (95% confidence interval, 9.30-10.72 Gy) and LADmean is <3.3 Gy. Conclusions Placing the edge of the tangents at least 2.5 mm from the closest point of the contoured LAD is likely to assure LADmax is <10 Gy and LADmean is <3.3 Gy in patients treated with prone accelerated breast radiation therapy.

Abstract 5639: Preoperative concurrent paclitaxel and radiation in locally advanced breast cancer (LABC): Five-year outcomes on 105 patients

Purpose: A prospective trial of preoperative concurrent paclitaxel and radiation for patients with LABC was conducted at three academic institutions. Five-year local and systemic control rates are reported. Patients and Methods: 105 patients with LABC were treated with concurrent neoadjuvant paclitaxel and radiation. Paclitaxel was administered at 30 mg/m2 intravenously twice a week for 10-12 weeks. Daily radiotherapy was delivered to the breast, axillary and supraclavicular lymph nodes during weeks 2-7, at 1.8 Gy per fraction to a total dose of 45 Gy followed by a boost of 14 Gy at 2 Gy per fraction to the originally palpable tumor. Weekly trastuzumab (2mg/kg) was added for 8 more recent patients whose tumor over-expressed Her-2/neu. At one of the three institutions preoperative paclitaxel (3 cycles of 175 mg/m2 q 3 weeks) was also administered prior to chemo-radiation to 36 patients. Pathologic response was defined as complete response (pCR) in the absence of invasive cancer in breast or lymph nodes; partial response (pPR) as the persistence of Results: Pathological response (pCR and pPR) after neoadjuvant chemo-radiation was achieved in 36/105 patients (34.3%, 95% confidence interval: 25.3% - 44.2%). 30/105 patients underwent breast-conserving surgery after neoadjuvant chemo-radiation (28.6%), while 74 underwent mastectomy. One patient progressed during therapy and did not undergo surgery. With a median follow up of 60 months and a maximum of 137 months, the median survival has not been reached. The estimated 5-year overall cumulative survival (OS) is 71.6% (95% confidence interval: 60.5% - 80.1%). Local recurrence occurred in 4/105 patients (3.8%): in 3/4 synchronously with or following systemic recurrence. Five patients (4.8%) developed contra-lateral breast cancer. Patients without a pathologic response had a higher risk of recurrence or death than patients who had a pathologic response (hazard ratio = 2.86, logrank p-value=0.009); similarly, survival was shorter (hazard ratio = 4.28, logrank p-value=0.003). The 5-year estimated OS for non-responders was 61.6% compared with 87.9% for responders. A separate analysis of patients who received additional preoperative paclitaxel before chemo-radiation showed a pathologic response rate of 41.7% (15/36 patients, 95% confidence interval: 25.5% to 59.2%); with an estimated 5-year OS of 63.9% (95% confidence interval: 46.1% - 77.2%). Conclusion: This series of 105 patients with LABC treated with concurrent paclitaxel and radiation demonstrated a 71.6% 5-year OS and 96% local control rate. Pathological response to concurrent paclitaxel and radiation was associated with a significantly better 5-year survival. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 5639.