Conformal radiation therapy for childhood CNS tumors

Radiation therapy plays a central role in the management of many childhood brain tumors. By combining advances in brain tumor imaging with technology to plan and deliver radiation therapy, pediatric brain tumors can be treated with conformal radiation therapy. Through conformal radiation therapy, the radiation dose is targeted to the tumor, which can minimize the dose to normal brain structures. Therefore, by limiting the radiation dose to normal brain tissues, conformal radiation therapy offers the possibility of limiting the long-term side effects of brain irradiation.In this review, we describe different approaches to conformal radiation therapy for pediatric central nervous system tumors including: A) three-dimensional conformal radiation therapy; B) stereotactic radiation therapy with arc photons; C) intensity-modulated radiation therapy; and D) proton beam radiation therapy. We discuss the merits and limitations of these techniques and describe clinical scenarios in which conformal radiation therapy offers advantages over conventional radiation therapy for treating pediatric brain tumors.     

New radiotherapy technologies

Conventional radiation therapy has had limited success in curing inoperable lung cancer due to poor local control. There is evidence to suggest that higher doses of radiation will improve local control. In order to safely deliver higher doses of thoracic radiation, advanced treatment techniques are required. Different biologic indices have been utilized to determine whether dose escalation can be safely accomplished, and the results have been reported from many institutions. Tumor motion control aids in treatment since it allows radiation oncologists to more accurately target tumors and therefore to spare more normal tissue from the radiation field. The imaging information from 18-FDG-PET scans also improves target delineation. Advanced treatment delivery techniques, such as three-dimensional conformal radiation therapy, intensity modulated radiation therapy, and stereotactic radiosurgery are also being used to safely escalate the radiation dose. This article explores the current literature on these issues and other advanced radiation therapy techniques.     

Intensity-modulated radiation therapy for the treatment of anal cancer

PURPOSE: The aim of this study was to assess whether intensity-modulated radiation therapy (RT; IMRT) can reduce dose to normal tissues (organs at risk) while maintaining equivalent target coverage. PATIENTS AND METHODS: A 9-field, non-coplanar, 1-cm beamlet IMRT plan was designed for 9 patients who were previously treated for anal cancer with conventional field arrangements. Clinical target volumes and organs at risk (OARs) were defined. Target coverage was assigned highest priority for optimization, followed sequentially by organ at risk. The genitalia and perineal skin were the highest priority OARs. Lexicographic ordering-based IMRT optimization was used to generate a conformal plan, which was compared with the conventional, previously delivered RT plan. RESULTS: The IMRT and conventional RT plan achieved homogeneous dose coverage of all target volumes. Intensity-modulated RT produced highly conformal dose distributions compared with conventional techniques, with avoidance of critical normal structures. Statistically significant reductions in mean doses to the perineal skin and to the genitalia were seen with IMRT, with only a modest increase in mean dose to the bony pelvis. CONCLUSION: Intensity-modulated RT, with lexicographic ordering, allows for substantial reduction of dose to OARs while maintaining adequate target coverage. These encouraging findings might translate into reductions of treatment-related toxicity, gains in local control, or improvements in quality of life.     

Proton radiotherapy in management of pediatric base of skull tumors

PURPOSE: Primary skull base tumors of the developing child are rare and present a formidable challenge to both surgeons and radiation oncologists. Gross total resection with negative margins is rarely achieved, and the risks of functional, structural, and cosmetic deficits limit the radiation dose using conventional radiation techniques. Twenty-nine children and adolescents treated with conformal proton radiotherapy (proton RT) were analyzed to assess treatment efficacy and safety. MATERIALS AND METHODS: Between July 1992 and April 1999, 29 patients with mesenchymal tumors underwent fractionated proton (13 patients) or fractionated combined proton and photon (16 patients) irradiation. The age at treatment ranged from 1 to 19 years (median 12); 14 patients were male and 15 female. Tumors were grouped as malignant or benign. Twenty patients had malignant histologic findings, including chordoma (n = 10), chondrosarcoma (n = 3), rhabdomyosarcoma (n = 4), and other sarcomas (n = 3). Target doses ranged between 50.4 and 78.6 Gy/cobalt Gray equivalent (CGE), delivered at doses of 1.8-2.0 Gy/CGE per fraction. The benign histologic findings included giant cell tumors (n = 6), angiofibromas (n = 2), and chondroblastoma (n = 1). RT doses for this group ranged from 45.0 to 71.8 Gy/CGE. Despite maximal surgical resection, 28 (97%) of 29 patients had gross disease at the time of proton RT. Follow-up after proton RT ranged from 13 to 92 months (mean 40). RESULTS: Of the 20 patients with malignant tumors, 5 (25%) had local failure; 1 patient had failure in the surgical access route and 3 patients developed distant metastases. Seven patients had died of progressive disease at the time of analysis. Local tumor control was maintained in 6 (60%) of 10 patients with chordoma, 3 (100%) of 3 with chondrosarcoma, 4 (100%) of 4 with rhabdomyosarcoma, and 2 (66%) of 3 with other sarcomas. The actuarial 5-year local control and overall survival rate was 72% and 56%, respectively, and the overall survival of the males was significantly superior to that of the female patients (p = 0.002). Of the patients with benign tumors, 1 patient (giant cell tumor) had local failure at 10 months. The other 8 patients continued to have local tumor control; all 9 patients were alive at last follow-up (actuarial 5-year local control and overall survival rate of 89% and 100%, respectively). Severe late effects (motor weakness and sensory deficits) were observed in 2 (7%) of 29 patients. CONCLUSION: Proton RT for children with aggressively recurring tumors after major skull base surgery can offer a considerable prospect of tumor control and survival. Longer follow-up is necessary to assess the real value of protons, in particular with regard to bone growth and cosmetic outcome.     

Treatment planning comparison of conventional, 3D conformal, and intensity-modulated photon (IMRT) and proton therapy for paranasal sinus carcinoma

PURPOSE: To determine the potential improvements in patients with paranasal sinus carcinoma by comparing proton and intensity-modulated radiotherapy (IMRT) with conventional and conformal photon treatment planning techniques. METHODS AND MATERIALS: In 5 patients, comparative treatment planning was performed by comparing proton plans and related conventional, conformal, and IMRT photon plans. The evaluations analyzed dose-volume histogram findings of the target volumes and organs at risk (OARs, i.e., pituitary gland, optical pathway structures, brain, nontarget tissue). RESULTS: The mean and maximal doses, dose inhomogeneities, and conformity indexes for the planning target volumes were comparable for all techniques. Photon plans resulted in greater volumes of irradiated nontarget tissues at the 10-70% dose level compared with the corresponding proton plans. The volumes thereby increased by a factor of 1.3-3.1 for conventional, 1.1-3.8 for conformal, and 1.1-3.7 for IMRT. Compared with conventional techniques, conformal and IMRT photon treatment planning options similarly reduced the mean dose to the OARs. The use of protons further reduced the mean dose to the OARs by up to 65% and 62% compared with the conformal and IMRT technique, respectively. CONCLUSION: Compared with conventional treatment techniques, conformal RT and IMRT similarly enabled dose reductions to the OARs. Additional improvements were obtained using proton-based treatment planning modalities.     

Treatment planning and delivery of external beam radiotherapy for pediatric sarcoma: the St. Jude Children's Research Hospital experience

PURPOSE: To describe and review the radiotherapy (RT) treatment planning and delivery techniques used for pediatric sarcoma patients at St. Jude Children's Research Hospital. The treatment characteristics serve as a baseline for future comparison with developing treatment modalities. PATIENTS AND METHODS: Since January 2003, we have prospectively treated pediatric and young-adult patients with soft-tissue and bone sarcomas on an institutional Phase II protocol evaluating local control and RT-related treatment effects from external-beam RT (conformal or intensity-modulated RT; 83.4%), low-dose-rate brachytherapy (8.3%), or both (8.3%). Here we describe the treatment dosimetry and delivery parameters of the initial 72 patients (median, 11.6 years; range, 1.4-21.6 years). RESULTS: Cumulative doses from all RT modalities ranged from 41.4 to 70.2 Gy (median, 50.4 Gy). Median D(95) and V(95) of the planning target volume of external-beam RT plans were, respectively, 93.4% of the prescribed dose and 94.6% of the target volume for the primary phase and 97.8% and 99.2% for the cone-down/boost phase. The dose-volume histogram statistics for 27 critical organs varied greatly. The spinal cord in 13 of 36 patients received dose >45 Gy (up to 52 Gy in 1 cc) because of tumor proximity. CONCLUSIONS: Planning and delivery of complex multifield external beam RT is feasible in pediatric patients with sarcomas. Improvements on conformity and dose gradients are still desired in many cases with sensitive adjacent critical structures. Long-term follow-up will determine the risk of local failure and the benefit of normal tissue avoidance for this population.     

The Gray Lecture 2001: coming technical advances in radiation oncology

PURPOSE: To review the current limits on the efficacy of radiotherapy (RT) due to technical factors and to assess the potential for major improvements in technology. METHODS AND MATERIALS: The method of this review was to assess the efficacy of current RT in general terms; strategies for improving RT; historical record of technological advances; rationale for further reductions of treatment volume; and importance of defining and excluding nontarget tissues from the target volume. The basis for the interest in proton beam RT is developed, and the relative dose distributions of intensity-modulated radiotherapy (IMRT) and intensity-modulated proton RT (IMPT) are discussed. The discovery of the proton and the first proposal that protons be used in RT is described. This is followed by a brief mention of the clinical outcome studies of proton RT. Likely technical advances to be integrated into advanced proton RT are considered, specifically, four-dimensional treatment planning and delivery. Finally, the increment in cost of some of these developments is presented. RESULTS: For definitive RT, dose limits are set by the tolerance of normal tissues/structures adjacent or near to the target. Using imaging fusion of CT, MRI, positron emission tomography, magnetic resonance spectroscopic imaging, and other studies will result in improved definition of the target margins. Proton beams are likely to replace photon beams because of their physical characteristics. Namely, for each beam path, the dose deep to the target is zero, across the target it is uniform, and proximal to the target it is less. Proton therapy can use as many beams, beam angles, noncoplanar, and dynamic, as well as static, intensity modulation, as can photon plans. The ability for much greater accuracy in defining the target position in space and then maintaining the target in a constant position in the radiation beam despite target movement between and during dose fractions will be possible. The cost of proton RT will be modestly higher than comparable high technology photon therapy. CONCLUSION: The technology of RT is clearly experiencing intense and rapid technical developments as pertains to treatment planning and dose delivery. It is predicted that radical dose RT will move to proton beam technology and that the treatment will be four dimensional (the fourth dimension is time). The impact will be higher tumor control probability and reduced frequency and severity of treatment-related morbidity.     

Radiation therapy for lung cancer

Radiation therapy is one of the most important modalities for the treatment of lung cancer. Current progress of radiation therapy in cooperation with the development of physics and biology is remarkable. The techniques of three-dimensional treatment planning and three-dimensional conformal radiotherapy (3D-CRT) have facilitated the use of higher radiation doses. Patients with early-stage non-small cell lung cancer (NSCLC) are candidates for curative surgical resection. However, the number of elderly patients has been increasing, and these patients often have medical contraindications that prevent curative surgery. Recently, several clinical trials on stereotactic body radiotherapy (SBRT) using the 3D-CRT technique for solitary lung tumors have been reported. The local control rate for stage I disease is more than 90%, and survival rates are promising. Now a prospective multi-institutional trial is ongoing to determine whether this modality can become a standard treatment for inoperable patients or an alternative to lobetectomy. For locally advanced NSCLC, unfortunately, recent studies have demonstrated that conventional therapies may have reached a therapeutic plateau. Now several radiation dose escalation studies utilizing conventional fractionation and 3D-CRT techniques are ongoing. The strategies of almost all of these trials are to eliminate elective nodal irradiation and deliver a higher dose of radiation to gross tumor volume while sparing normal tissues. Preliminary experience has resulted in promising survival, but should be developed to integrate into the combined treatment to completely control both local disease and other microscopically involved lesions. The combination of novel chemotherapeutic agents and molecular targeting therapies with radiation therapy is being investigated. Development of molecular imaging techniques is expected to facilitate more selective dose escalation in tumors.     

The role of radiation therapy in thoracic tumors

Radiation plays an important role in the treatment of thoracic tumors. During the last 10 years there have been several major advances in thoracic RT including the incorporation of concurrent chemotherapy and the application of con-formal radiation-delivery techniques (eg, stereotactic RT, three-dimensional conformal RT, and intensity-modulated RT) that allow radiation dose escalation. Radiation as a local measure remains the definitive treatment of medically inoperable or surgically unresectable disease in NSCLC and part of a multimodality regimen for locally advanced NSCLC, limited stage SCLC, esophageal cancer, thymoma, and mesothelioma.     

The impact of three-dimensional radiation on the treatment of non-small cell lung cancer.

PURPOSE: Non-small cell lung cancer (NSCLC) patients with locally advanced unresectable disease have a grim prognosis. Radiotherapeutic strategies are necessary to improve the permanent eradication of thoracic disease. The poor results achieved with conventional external beam radiation therapy reflect in part, the inadequacy of such therapy in achieving its primary objective of achieving local control. The impact of three-dimensional conformal radiation therapy (3-DCRT) on local disease eradication and its potential role in improving survival is assessed. DESIGN: This review addresses aspects of the software and hardware technology of 3-DCRT, the clinical and technical aspects of target volume definition, the use of 3-DCRT to predict radiation pneumonitis, strategies for dose escalation in NSCLC, and analyses the clinical results to date. RESULTS: Initially investigators compared the best treatment techniques devised with conventional planning techniques to those devised with 3-DCRT. These analyses showed that 3-DCRT had the potential to deliver high dose radiation (>70 Gy) with minimal underdosing and with a concomitant relative sparing of normal tissues. This technical demonstration of enhanced therapeutic ratio is the basis for the evolving clinical utilization of 3-DCRT for NSCLC. Software and hardware developments continue to develop and have the potential to solve evolving clinical issues. Dose-volume-histograms have been used to accurately quantify lung dose and derived parameters have the potential to predict the risk of pneumonitis for individual patients before treatment. Initial clinical results have been promising and strategies for further dose escalation are emerging. CONCLUSION: Preliminary experience has resulted in promising survival following three-dimensional conformal radiation therapy alone for locally advanced NSCLC. More follow-up and experience will determine late toxicity, maximum dose, and efficacy of dose escalation with three-dimensional conformal radiation therapy. Strategies should be developed to integrate this modality into the combined treatment of locally advanced non-small cell lung cancer.     

Three-dimensional conformal radiotherapy for paranasal sinus carcinoma: clinical results for 25 patients

PURPOSE: To assess local control, survival, and clinical and dosimetric prognostic factors in 25 patients with locally advanced maxillary or ethmoid sinus carcinoma treated by three-dimensional conformal radiotherapy (RT). MATERIALS AND METHODS: Surgery was performed in 22 patients and was macroscopically complete in 16. Seven patients received chemotherapy (concomitant with RT in four). The following quality indexes were defined for the 95% and 90% isodoses: tumor conformity index, normal tissue conformity index, and global conformity index. RESULTS: The median radiation dose to the planned treatment volume was 63 Gy, with a minimal dose of 60 Gy, except in 2 patients whose cancer progressed during RT. The maximal doses tolerated by the structures involved in vision were respected, except for tumors that involved the optic nerve. After a median follow-up of 25 months, 14 local tumor recurrences developed. The major prognostic factors were central nervous system involvement by disease and the presence of nonresectable tumors. The radiation dose and tumor conformity index value were not significant prognostic indicators. Two patients died of acute infectious toxicity, and two developed late ipsilateral ocular toxicity. CONCLUSIONS: Improving local control remains the main challenge in RT for paranasal tumors.     

Conformal chemoradiation for primary and metastatic liver malignancies

Historically, radiation therapy has played a minor role in the management of patients with unresectable primary hepatobiliary malignancies and liver metastases from colorectal cancer. This can be attributed chiefly to the low tolerance of the whole liver to radiation. Three-dimensional radiation planning techniques have allowed much higher doses of radiation to be delivered to focal liver tumors, while sparing the majority of the normal liver. When combined with fluorodeoxyuridine (FUdR), high-dose focal liver radiation is associated with excellent response rates, local control, and survival in patients with large unresectable tumors. There appears to be a radiation dose response for intrahepatic malignancies. Advancements in tumor imaging, radiation techniques that can safely deliver higher doses of radiation, novel tumor radiation sensitizers, and normal-tissue radioprotectors should substantially improve the outcome of patients with unresectable intrahepatic malignancies treated with chemoradiation.     

Treatment of nasal cavity and paranasal sinus cancer with modern radiotherapy techniques in the postoperative setting--the MSKCC experience

PURPOSE: To perform a retrospective analysis of patients with paranasal sinus (PNS) cancer treated with postoperative radiotherapy (RT) at Memorial Sloan-Kettering Cancer Center. METHODS AND MATERIALS: Between January 1987 and July 2005, 85 patients with PNS and nasal cavity cancer underwent postoperative RT. Most patients had squamous cell carcinoma (49%; n = 42), T4 tumors (52%; n = 36), and the maxillary sinus (53%; n = 45) as the primary disease site. The median radiation dose was 63 Gy. Of the 85 patients, 76 underwent CT simulation and 53 were treated with either three-dimensional conformal RT (27%; n = 23) or intensity-modulated RT (35%; n = 30). Acute and late toxicities were scored according to the Radiation Therapy Oncology Group radiation morbidity scoring criteria. RESULTS: With a median follow-up for surviving patients of 60 months, the 5-year estimates of local progression-free, regional progression-free, distant metastasis-free, disease-free, and overall survival rates were 62%, 87%, 82%, 55%, and 67%, respectively. On multivariate analysis, squamous cell histology and cribriform plate involvement predicted for an increased likelihood of local recurrence, and squamous cell histologic features predicted for worse overall survival. None of the patients who underwent CT simulation and were treated with modern techniques developed a Grade 3-4 late complication of the eye. CONCLUSION: Complete surgical resection followed by adjuvant RT is an effective and safe approach in the treatment of PNS cancer. Emerging tools, such as three-dimensional conformal treatment and, in particular, intensity-modulated RT for PNS tumors, may minimize the occurrence of late complications associated with conventional RT techniques. Local recurrence remains a significant problem.     

软组织肉瘤的放射治疗

软组织肉瘤(soft tissue sarcomas,STS) 是起源于结缔组织的软组织恶性肿瘤,具有多种不同类型。手术是 STS 主要治疗方法,放疗也是其重要的治疗方式并且是综合治疗早期选择之一。对 STS 进行放疗已经超过 50 年历史,术前和术后放疗对于局部控制都有疗效,只是不良反应不同。软组织肉瘤放疗技术包括远距离放疗(适形放疗、调强放疗、立体定向放疗等) 、近距离放疗(组织间插植放疗、腔内后装放疗、术中放疗等) 等。放疗技术的进步,提高了放疗的精准性和确定性,降低了对病灶周围正常组织的损伤。本文主要针对 STS 放疗技术以及适用原则进行综述。      

Early findings on toxicity of proton beam therapy with concurrent chemotherapy for nonsmall cell lung cancer

BACKGROUND:

Concurrent chemoradiation therapy, the standard of care for locally advanced nonsmall cell lung cancer (NSCLC), can cause life‐threatening pneumonitis and esophagitis. X‐ray (photon)‐based radiation therapy (RT) often cannot be given at tumoricidal doses without toxicity to proximal normal tissues. We hypothesized that proton beam therapy for most patients with NSCLC could permit higher tumor doses with less normal‐tissue toxicity than photon RT delivered as 3‐dimensional conformal RT (3D‐CRT) or intensity‐modulated RT (IMRT).

METHODS:

We compared the toxicity of proton therapy+concurrent chemotherapy in 62 patients with NSCLC (treatment period 2006‐2008) with toxicity for patients with similar disease given 3D‐CRT+chemotherapy (n = 74; treatment period 2001‐2003) or IMRT+chemotherapy (n = 66; treatment period 2003‐2005). Proton therapy to the gross tumor volume was given with weekly intravenous paclitaxel (50 mg/m²) and carboplatin (area under the curve 2 mg/mL/min). The primary endpoint was toxicity (Common Terminology Criteria for Adverse Events version 3.0).

RESULTS:

Median follow‐up times were 15.2 months (proton), 17.9 months (3D‐CRT), and 17.4 months (IMRT). Median total radiation dose was 74 Gy(RBE) for the proton group versus 63 Gy for the other groups. Rates of severe (grade ≥3) pneumonitis and esophagitis in the proton group (2% and 5%) were lower despite the higher radiation dose (3D‐CRT, 30% and 18%; IMRT, 9% and 44%; P<.001 for all).

CONCLUSIONS:

We found that higher doses of proton radiation could be delivered to lung tumors with a lower risk of esophagitis and pneumonitis. A randomized comparison of IMRT versus proton therapy is underway. Cancer 2011. © 2011 American Cancer Society.     

How to reduce radiation-related toxicity in patients with cancer of the head and neck

Radiation for head and neck cancers is often curative, but high doses are used. Normal tissues, including mucosa, salivary glands, and muscles, are exposed to these high doses, resulting in severe mucositis, xerostomia, and dysphagia. Efforts to minimize toxicity have involved advances in radiation physics and development of pharmacologic agents. Radiation techniques include conformal and intensity-modulated therapy, which minimizes dose to normal tissues while delivering high doses to tumor targets. Drugs used to prevent mucositis have targeted infection, but recently interest has been shown in the use of growth factors. Cholinergic agonists and cytoprotective agents, specifically amifostine, can address xerostomia. Involvement of speech pathologists in evaluation and treatment of patients with dysphagia can minimize swallowing difficulties and identify the tissues most responsible for swallowing. Minimizing radiation dose to these tissues may lower the incidence of radiation-induced dysphagia.     

Optimisation of radiotherapy for carcinoma of the parotid gland: a comparison of conventional, three-dimensional conformal, and intensity-modulated techniques.

BACKGROUND AND PURPOSE: To compare external beam radiotherapy techniques for parotid gland tumours using conventional radiotherapy (RT), three-dimensional conformal radiotherapy (3DCRT), and intensity-modulated radiotherapy (IMRT). To optimise the IMRT techniques, and to produce an IMRT class solution. MATERIALS AND METHODS: The planning target volume (PTV), contra-lateral parotid gland, oral cavity, brain-stem, brain and cochlea were outlined on CT planning scans of six patients with parotid gland tumours. Optimised conventional RT and 3DCRT plans were created and compared with inverse-planned IMRT dose distributions using dose-volume histograms. The aim was to reduce the radiation dose to organs at risk and improve the PTV dose distribution. A beam-direction optimisation algorithm was used to improve the dose distribution of the IMRT plans, and a class solution for parotid gland IMRT was investigated. RESULTS: 3DCRT plans produced an equivalent PTV irradiation and reduced the dose to the cochlea, oral cavity, brain, and other normal tissues compared with conventional RT. IMRT further reduced the radiation dose to the cochlea and oral cavity compared with 3DCRT. For nine- and seven-field IMRT techniques, there was an increase in low-dose radiation to non-target tissue and the contra-lateral parotid gland. IMRT plans produced using three to five optimised intensity-modulated beam directions maintained the advantages of the more complex IMRT plans, and reduced the contra-lateral parotid gland dose to acceptable levels. Three- and four-field non-coplanar beam arrangements increased the volume of brain irradiated, and increased PTV dose inhomogeneity. A four-field class solution consisting of paired ipsilateral coplanar anterior and posterior oblique beams (15, 45, 145 and 170 degrees from the anterior plane) was developed which maintained the benefits without the complexity of individual patient optimisation. CONCLUSIONS: For patients with parotid gland tumours, reduction in the radiation dose to critical normal tissues was demonstrated with 3DCRT compared with conventional RT. IMRT produced a further reduction in the dose to the cochlea and oral cavity. With nine and seven fields, the dose to the contra-lateral parotid gland was increased, but this was avoided by optimisation of the beam directions. The benefits of IMRT were maintained with three or four fields when the beam angles were optimised, but were also achieved using a four-field class solution. Clinical trials are required to confirm the clinical benefits of these improved dose distributions.     

Proton radiotherapy for childhood ependymoma: initial clinical outcomes and dose comparisons

PURPOSE: To report preliminary clinical outcomes for pediatric patients treated with proton beam radiation for intracranial ependymoma and compare the dose distributions of intensity-modulated radiation therapy with photons (IMRT), three-dimensional conformal proton radiation, and intensity-modulated proton radiation therapy (IMPT) for representative patients. METHODS AND MATERIALS: All children with intracranial ependymoma confined to the supratentorial or infratentorial brain treated at the Francis H. Burr Proton Facility and Harvard Cyclotron between November 2000 and March 2006 were included in this study. Seventeen patients were treated with protons. Proton, IMRT, and IMPT plans were generated with similar clinical constraints for representative infratentorial and supratentorial ependymoma cases. Tumor and normal tissue dose-volume histograms were calculated and compared. RESULTS: At a median follow-up of 26 months from the start date of radiation therapy, local control, progression-free survival, and overall survival rates were 86%, 80%, and 89%, respectively. Subtotal resection was significantly associated with decreased local control (p = 0.016). Similar tumor volume coverage was achieved with IMPT, proton therapy, and IMRT. Substantial normal tissue sparing was seen with proton therapy compared with IMRT. Use of IMPT will allow for additional sparing of some critical structures. CONCLUSIONS: Preliminary disease control with proton therapy compares favorably with the literature. Dosimetric comparisons show the advantage of proton radiation compared with IMRT in the treatment of ependymoma. Further sparing of normal structures appears possible with IMPT. Superior dose distributions were accomplished with fewer beam angles with the use of protons and IMPT.     

An evaluation of two techniques for beam intensity modulation in patients irradiated for stage III non-small cell lung cancer

In locally advanced lung cancer, the use of high dose radiotherapy (RT) and/or concurrent chemo-RT is associated with significant pulmonary and esophageal toxicity. Despite a 3D conformal RT technique and the omission of elective mediastinal fields, three (of ten) patients with inoperable stage 3 NSCLC who were treated with induction chemotherapy (carboplatin-paclitaxel) followed by RT to 70 Gy, developed symptomatic radiation pneumonitis. In this planning study, the actual treatment plans of all ten patients were compared to plans derived using two beam intensity-modulated (BIM) techniques, for which similar geometrical beam setup parameters were used. In the first technique (BF-BIM), cranial and caudal boost fields were applied in order to allow field length reduction. The second technique (C-BIM) utilised 3-D missing-tissue compensators for all radiation beams. Both BIM techniques resulted in a significant sparing of critical normal tissues and the C-BIM technique was superior in all cases. When compared to the actual RT technique used for treatment, a reduction of 8.1+/-4.7% (1 S.D.) was observed in the mean lung dose for the BF-BIM plan, vs. 20.3+/-5.8% (1 S.D.) for the C-BIM plan. Similar reductions were observed in the percentage of the total lung volume exceeding 20 Gy (V(20)) for these techniques. BIM techniques appear to be a promising tool for enabling radiation dose-escalation and/or intensive concurrent chemo-RT in inoperable lung cancer.     

Advances in treatment techniques: arc-based and other intensity modulated therapies

Treatment planning and radiation delivery techniques have advanced significantly during the past 2 decades. The development of the multileaf collimator has changed the scope of radiotherapy. The dynamic conformal arc technique emerged from traditional cone-based conformal arc therapies, which aim to improve target dose uniformity and reduce normal tissue doses. With dynamic conformal arc, the multileaf collimator aperture is shaped dynamically to conform to the target. With the advent of intensity-modulated radiotherapy (IMRT), the concept of arc therapy in combination with IMRT has enabled better-quality dose distributions and more efficient delivery. Helical tomotherapy has been developed to treat targets sequentially by modulating the beam intensity in each "slice" of the patient. Helical tomotherapy offers improved dose distributions for complicated treatments, such as whole-body radiation. Intensity-modulated arc therapy has been studied to modulate fluences in a cone beam rather than fan beam geometry to improve delivery efficiency. This article reviews arc-based IMRT, intensity-modulated arc therapy, and helical tomotherapy techniques. We compare the dosimetric results reported in the literature for each technique in various treatment sites. We also review the application of these techniques in specialized clinical procedures including total marrow irradiation, simultaneous treatment of multiple brain metastases, dose painting, simultaneous integrated boost, and stereotactic radiosurgery.