Jarrod B. Adkison

Dose Escalated, Hypofractionated Radiotherapy Using Helical Tomotherapy for Inoperable Non-Small Cell Lung Cancer : Preliminary Results of a Risk-Stratified Phase I Dose Escalation Study

To improve local control for inoperable non-small cell lung cancer (NSCLC), a phase I dose escalation study for locally advanced and medically inoperable patients was devised to escalate tumor dose while limiting the dose to organs at risk including the esophagus, spinal cord, and residual lung. Helical tomotherapy provided image-guided IMRT, delivered in a 5-week hypofractionated schedule to minimize the effect of accelerated repopulation. Forty-six patients judged not to be surgical candidates with Stage I-IV NSCLC were treated. Concurrent chemotherapy was not allowed. Radiotherapy was delivered via helical tomotherapy and limited to the primary site and clinically proven or suspicious nodal regions without elective nodal irradiation. Patients were placed in 1 of 5 dose bins, all treated for 25 fractions, with dose per fraction ranging from 2.28 to 3.22 Gy. The bin doses of 57 to 80.5 Gy result in 2 Gy/fraction normalized tissue dose (NTD) equivalents of 60 to 100 Gy. In each bin, the starting dose was determined by the relative normalized tissue mean dose modeled to cause < 20% Grade 2 pneumonitis. Dose constraints included spinal cord maximum NTD of 50 Gy, esophageal maximum NTD < 64 Gy to ≤ 0.5 cc volume, and esophageal effective volume of 30%. No grade 3 RTOG acute pneumonitis (NCI-CTC v.3) or esophageal toxicities (CTCAE v.3.0 and RTOG) were observed at median follow-up of 8.1 months. Pneumonitis rates were 70% grade 1 and 13% grade 2. Multivariate analysis identified lung NTDmean (p=0.012) and administration of adjuvant chemotherapy following radiotherapy (p=0.015) to be independent risk factors for grade 2 pneumonitis. Only seven patients (15%) required narcotic analgesics (RTOG grade 2 toxicity) for esophagitis, with only 2.3% average weight loss during treatment. Best in-field gross response rates were 17% complete response, 43% partial response, 26% stable disease, and 6.5% in-field thoracic progression. The out-of-field thoracic failure rate was 13%, and distal failure rate was 28%. The median survival was 18 months with 2-year overall survival of 46.8% ± 9.7% for this cohort, 50% of whom were stage IIIB and 30% stage IIIA. Dose escalation can be safely achieved in NSCLC with lower than expected rates of pneumonitis and esophagitis using hypofractionated image-guided IMRT. The maximum tolerated dose has yet to be reached.

OUTCOMES AFTER ACCELERATED PARTIAL BREAST IRRADIATION IN PATIENTS WITH ASTRO CONSENSUS STATEMENT CAUTIONARY FEATURES

PURPOSE To evaluate outcomes among women with American Society for Radiation Oncology (ASTRO) consensus statement cautionary features treated with brachytherapy-based accelerated partial breast irradiation (APBI). METHODS AND MATERIALS Between March 2001 and June 2006, 322 consecutive patients were treated with high-dose-rate (HDR) APBI at the University of Wisconsin. A total of 136 patients were identified who met the ASTRO cautionary criteria. Thirty-eight (27.9%) patients possessed multiple cautionary factors. All patients received 32 to 34 Gy in 8 to 10 twice-daily fractions using multicatheter (93.4%) or Mammosite balloon (6.6%) brachytherapy. RESULTS With a median follow-up of 60 months, there were 5 ipsilateral breast tumor recurrences (IBTR), three local, and two loco-regional. The 5-year actuarial rate of IBTR was 4.8%±4.1%. The 5-year disease-free survival was 89.6%, with a cause-specific survival and overall survival of 97.6% and 95.3%, respectively. There were no IBTRs among 32 patients with ductal carcinoma in situ (DCIS) vs. 6.1% for patients with invasive carcinoma (p=0.24). Among 104 patients with Stage I or II invasive carcinoma, the IBTR rate for patients considered cautionary because of age alone was 0% vs. 12.7% in those deemed cautionary due to histopathologic factors (p=0.018). CONCLUSIONS Overall, we observed few local recurrences among patients with cautionary features. Women with DCIS and patients 50 to 59 years of age with Stage I/II disease who otherwise meet the criteria for suitability appear to be at a low risk of IBTR. Patients with tumor-related cautionary features will benefit from careful patient selection.

Reirradiation of large-volume recurrent glioma with pulsed reduced-dose-rate radiotherapy.

PURPOSE Pulsed reduced-dose-rate radiotherapy (PRDR) is a reirradiation technique that reduces the effective dose rate and increases the treatment time, allowing sublethal damage repair during irradiation. PATIENTS AND METHODS A total of 103 patients with recurrent glioma underwent reirradiation using PRDR (86 considered to have Grade 4 at PRDR). PRDR was delivered using a series of 0.2-Gy pulses at 3-min intervals, creating an apparent dose rate of 0.0667 Gy/min to a median dose of 50 Gy (range, 20-60) delivered in 1.8-2.0-Gy fractions. The mean treatment volume was 403.5±189.4 cm3 according to T2-weighted magnetic resonance imaging and a 2-cm margin. RESULTS For the initial or upgraded Grade 4 cohort (n=86), the median interval from the first irradiation to PRDR was 14 months. Patients undergoing PRDR within 14 months of the first irradiation (n=43) had a median survival of 21 weeks. Those treated ≥14 months after radiotherapy had a median survival of 28 weeks (n=43; p=0.004 and HR=1.82 with a 95% CI ranging from 1.25 to 3.10). These data compared favorably to historical data sets, because only 16% of the patients were treated at first relapse (with 46% treated at the second relapse, 32% at the third or fourth relapse, and 4% at the fourth or fifth relapse). The median survival since diagnosis and retreatment was 6.3 years and 11.4 months for low-grade, 4.1 years and 5.6 months for Grade 3, and 1.6 years and 5.1 months for Grade 4 tumors, respectively, according to the initial histologic findings. Multivariate analysis revealed age at the initial diagnosis, initial low-grade disease, and Karnofsky performance score of ≥80 to be significant predictors of survival after initiation of PRDR. CONCLUSION PRDR allowed for safe retreatment of larger volumes to high doses with palliative benefit.

Phase I Trial of Pelvic Nodal Dose Escalation with Hypofractionated IMRT for High Risk Prostate Cancer

PURPOSE Toxicity concerns have limited pelvic nodal prescriptions to doses that may be suboptimal for controlling microscopic disease. In a prospective trial, we tested whether image-guided intensity-modulated radiation therapy (IMRT) can safely deliver escalated nodal doses while treating the prostate with hypofractionated radiotherapy in 5½ weeks. METHODS AND MATERIALS Pelvic nodal and prostatic image-guided IMRT was delivered to 53 National Comprehensive Cancer Network (NCCN) high-risk patients to a nodal dose of 56 Gy in 2-Gy fractions with concomitant treatment of the prostate to 70 Gy in 28 fractions of 2.5 Gy, and 50 of 53 patients received androgen deprivation for a median duration of 12 months. RESULTS The median follow-up time was 25.4 months (range, 4.2-57.2). No early Grade 3 Radiation Therapy Oncology Group or Common Terminology Criteria for Adverse Events v.3.0 genitourinary (GU) or gastrointestinal (GI) toxicities were seen. The cumulative actuarial incidence of Grade 2 early GU toxicity (primarily alpha blocker initiation) was 38%. The rate was 32% for Grade 2 early GI toxicity. None of the dose-volume descriptors correlated with GU toxicity, and only the volume of bowel receiving ≥30 Gy correlated with early GI toxicity (p = 0.029). Maximum late Grades 1, 2, and 3 GU toxicities were seen in 30%, 25%, and 2% of patients, respectively. Maximum late Grades 1 and 2 GI toxicities were seen in 30% and 8% (rectal bleeding requiring cautery) of patients, respectively. The estimated 3-year biochemical control (nadir + 2) was 81.2 ± 6.6%. No patient manifested pelvic nodal failure, whereas 2 experienced paraaortic nodal failure outside the field. The six other clinical failures were distant only. CONCLUSIONS Pelvic IMRT nodal dose escalation to 56 Gy was delivered concurrently with 70 Gy of hypofractionated prostate radiotherapy in a convenient, resource-efficient, and well-tolerated 28-fraction schedule. Pelvic nodal dose escalation may be an option in any future exploration of potential benefits of pelvic radiation therapy in high-risk prostate cancer patients.

Breast conserving surgery and accelerated partial breast irradiation after prior breast radiation therapy.

Objective:Although mastectomy has been traditional treatment for breast cancer after prior radiotherapy, patients are increasingly requesting additional breast conservation. This report details our experience of accelerated partial breast irradiation (APBI) as a component of salvage breast conserving treatment. Methods:Eleven patients with prior external beam radiotherapy to the breast were treated with lumpectomy and APBI using high dose rate iridium-192 to a dose of 34 gray with 10 twice-daily fractions over 5 days. Six patients were previously treated for Hodgkin disease, 4 for invasive or in situ breast cancer, and 1 for soft tissue sarcoma. All had tumor ≤2 cm, negative nodes, and negative margins. Results:At median follow-up of 53.7 months, 10 patients were alive without evidence of disease recurrence following treatment which occurred at median interval of 19.1 years after prior radiotherapy. One was lost to follow-up. One developed mastitis under treatment requiring oral and IV antibiotics. Another received oral antibiotics for 6 weeks following formation of a draining sinus tract with contracture and painless fibrosis. Three others reported slight to moderate firmness. Four noted mild hyperpigmentation, but none developed telangiectasia. One patient with prior whole breast radiation had necrosis requiring mastectomy 9.4 months following retreatment, with pathology revealing a chronic breast abscess. Of the 9 women with successful breast conservation, all but one reported satisfaction pursuing breast conservation rather than mastectomy. Conclusions:Repeat lumpectomy and APBI for in-breast tumor recurrence after prior external beam radiotherapy has been delivered with acceptable outcomes, justifying a phase II multicenter trial for validation.

Systemic iodine 125 activity after GliaSite brachytherapy: safety considerations.

PURPOSE After contaminated radioactive linens were detected on the completion of intracranial brachytherapy for a patient episodically incontinent of urine, the systemic absorption of iodine 125 from the GliaSite Radiation Therapy System was studied. Diffusion and leakage of (125)I through the walls of the GliaSite balloon catheter have previously been reported to be negligible in both animal and human studies examining the radioactivity of urine during and after treatment. Our study estimated total systemic absorption based on activity defect measurements rather than using urinary excretion as a surrogate. METHODS AND MATERIALS Six patients treated with complete data were reviewed. The activity at the time of injection was compared to the activity recovered on completion of treatment after adjustment for decay. RESULTS By comparing the activity of (125)I infused with the activity recovered, 0.5-5.5% of infused (125)I remained unaccounted after adjusting for decay over the 4-day treatment period. The patient with contaminated hospital linens due to urinary incontinence had unaccounted activity of 2.3%. Comparisons of the volume of liquid (125)I and saline removed on completion to treatment to the volume originally instilled revealed no difference using hand-held syringes. CONCLUSIONS The systemic absorption of (125)I is much greater than previously appreciated with potential clinical sequelae and safety concerns. GliaSite should be used with caution in patients incontinent of urine, and a Foley catheter should be placed to collect contaminated urine for incontinent patients.

Radiographic pneumonitis patterns and low pulmonary toxicity after helical tomotherapy.

AJR 2010; 194:W459 0361–803X/10/1945–W459