Surface levels of CD20 determine anti-CD20 antibodies mediated cell death in vitro.

BACKGROUND: The sensitivity of human Burkitt's lymphoma cells to rituximab (Rtx) and tositumomab (Tst) was assessed on cells expressing different levels of CD20 on surface. Cells that harbor low CD20 levels may resists against therapeutics response to CD20-specific antibodies. We postulated that, radiation-induced modulation of CD20 surface levels may play a crucial and central role in determining the relative efficacy of rituximab and tositumomab in treating Burkitt's lymphoma disease. Here, we examined the γ-radiation-induced CD20 expression in the Burkitt lymphoma cell line 'Daudi' and the relation of differential levels of CD20 with anti-CD20 mAbs mediated cell death. METHODOLOGY: In this study we examined kinetics of CD20 expression following sub lethal doses ofγ-radiation to Daudi cells and thereafter anti-CD20 mAbs (rituximab and tositumomab) were added in cell suspensions. The correlation of kinetics of CD20 expression and cells treated with anti-CD20 mAbs/or corresponding isotype Abs with special reference to changes in mitochondrial membrane potential and reactive oxygen species generation was also examined. Further, we also investigated the efficacy of anti-CD20 mAbs and possible induction of cell death in relation to levels of CD20 cell surface expression. CONCLUSION: This report provides evidence that CD20 expression can be induced by exposure of cells to γ-radiation. In addition, these findings demonstrated that the efficacy of anti-CD20 mAbs is dependent on the surface levels of CD20. Based on these findings, we hypothesized (i) irradiation just prior to immunotherapy may provide new treatment options even in aggressive B cell tumors, which are resistant to current therapies in vivo (ii) The efficacy of induction of apoptosis varies with type of monoclonal antibodies in vitro.

Overview of accountable care organizations for oncology specialists.

Accountable care organizations (ACOs) are poised to become major components of health care delivery in the United States. The practice of oncology, often laden with high charges, is likely to undergo major shifts as ACOs become widespread. In this article, we review the economic factors leading to the growth of ACOs and discuss some elements of the current ACO model proposed in the Affordable Care Act. Oncology specialists-in medicine, surgery, and radiation oncology-will have important roles in determining the place of specialty care in an ACO framework and will have to take the lead in educating patients, primary care physicians, and administrators on the value propositions related to their activities. We also describe how oncology specialists may participate in the model to ensure success for physicians and patients.

ACR-ASTRO practice guideline for the performance of therapy with unsealed radiopharmaceutical sources.

This guideline is intended to guide appropriately trained and licensed physicians performing therapy with unsealed radiopharmaceutical sources. Adherence to this guideline should help to maximize the efficacious use of these procedures, maintain safe conditions, and ensure compliance with applicable regulations. The topics dealt with in this guideline include indications for the use of iodine-131, both for the treatment of hyperthyroidism and thyroid carcinoma. In addition, indications for other less common procedures include those for the use of phosphorous-32 in its liquid and colloidal forms, strontium-89, samarium-153, and the use of Y-90 antibodies.

Convergence technology in cancer medicine.

The field of convergence technology may be defined as an area of technologic innovation in which multiple devices or functionalities are combined within a single platform in a way that adds functional, operational or economic synergies. Within the field of medical devices, this concept embodies many different types of novel combinations representing syntheses of therapeutic, diagnostic and digital information technologies. In the current era of healthcare reform, such combinatorial technologies will be pressed to demonstrate improvements in comparative effectiveness compared with the use of separate independent components. Moreover, the new more stringent regulatory environment will require much greater levels of pre- and post-market safety reviews conducted under the auspices and authority of the US FDA Office of Combination Products. This branch of the FDA scrutinizes submissions and divides them into drugs, devices and biological products and includes many submissions previously regulated by disparate centers, such as the Center for Devices and Radiologic Health and the Center for Drug Evaluation and Research. The field of convergence technologies already amounts to a worldwide market extending to tens of billions of dollars and this article will attempt to summarize some of the key elements of this continued push for added value and more personalized medicine.

The Role of Functional Imaging in Radiotherapy Planning and Management for Gynecologic Malignancies.

In addition to allowing much greater technical precision, the modern era allows investigation of target physiology and it is the potential incorporation of physiologic information into the treatment-planning rubric that gives modern PET-CT its allure and promise. Although oncologic PET scanning has been clinically available for more than 10 years, it is only recently that sufficient investigative and retrospective data have become available to confidently assert that future radiotherapy treatment planning will include functional imaging as an obligatory dimension of clinical characterization for most gynecologic tumors. This article explores the role of functional imaging in radiotherapy planning and management of gynecologic malignancies.

Update on the rational use of tositumomab and iodine-131 tositumomab radioimmunotherapy for the treatment of non-Hodgkin's lymphoma.

Targeted radioimmunotherapy in non-Hodgkin's B-cell lymphoma (NHL) offers an efficacious therapy and minimal toxicity compared to conventional chemotherapy. Iodine 131 tositumomab ((131)I-TST) is a murine monoclonal antibody against the CD20 cell surface protein and is directly covalently conjugated to (131)I, a radioactive beta and gamma emitter. While initially approved for use in relapsed, refractory, or transformed low grade B-cell NHL, investigational uses with promising results include autologous stem cell transplant, intermediate grade NHL, and the frontline management of indolent NHL. This review summarizes the (131)I-TST literature on mechanism of action, treatment indications, treatment delivery, efficacy, investigational uses, and future prospects.

Low dose irradiation for diffuse choroidal hemangioma.

Sturge-Weber Syndrome is a nonheritable congenital syndrome characterized by a "port-wine stain" on the face and angioma of the meninges. Ocular findings include diffuse choroidal hemangioma, retinal detachment, and various types of glaucoma. Management of diffuse choroidal hemangioma is aimed at preserving the affected eye and preventing glaucoma. In the past this has been challenging. Herein, we describe a case of Sturge-Weber Syndrome with diffuse choroidal hemangioma which was successfully treated with low dose lens-sparing external beam radiotherapy.

Regulation of CD20 expression by radiation-induced changes in intracellular redox status.

Increasing the levels of CD20 expression in cells that harbor low CD20 levels may enhance their responsiveness to CD20-specific antibody therapies. Here, we examined the regulation of CD20 expression after treatment with 0.5-2.0 Gy X-irradiation and hydrogen peroxide (H(2)O(2)), in the presence or absence of known antioxidants, in the Burkitt lymphoma cell lines Daudi and Raji. Irradiation of cells enhanced cell-surface CD20 expression; the kinetics and extent of this change were cell-type specific and time-dependent. The kinetics of reactive oxygen species generation and changes in mitochondrial membrane potential after irradiation were also correlated with changes in CD20 expression. Raji and Daudi cells treated with H(2)O(2) showed a 2-to 2.5-fold increase in CD20 expression at 12 and 20 h, respectively. Buthionine sulfoximine, which depletes glutathione, also increased surface CD20, whereas antioxidants, such as PEG-catalase, PEG-SOD, vitamin C, and amifostine, decreased CD20 expression induced by radiation or H(2)O(2). The antioxidant-mediated decrease in CD20 expression induced by radiation or H(2)O(2) suggests a mechanism involving redox regulation. These results demonstrate the critical role of radiation-induced oxidative stress in CD20 expression and may have implications for defining and improving the efficacy of CD20-targeted antibody therapy and radioimmunotherapy.

Radioimmunotherapy as a therapeutic option for Non-Hodgkin's lymphoma.

Radioimmunotherapy (RIT) represents a relatively new antibody-based radiopharmaceutical treatment for patients with various kinds of tumors. Although the field has a long history of preclinical and clinical investigations using many different agents, to date, only 2 of these immunologically targeted radiopharmaceuticals have been cleared for commercial sale. Both of these agents ((90)Y-ibritumomab tiuxetan or "Zevalin" [Biogen-Idec, Boston, MA] and (131)I-tositumomab or "Bexxar" [GlaxoSmithKline Research, Triangle Park, NC]) are directed against the CD20 surface antigen found on normal mature B cells and greater than 95% of B-cell non-Hodgkin lymphoma (NHL). Both compounds produce similar impressive clinical outcomes (approximately 20%-40% complete response rates and 60%-80% overall response rates for patients with indolent B-cell NHL). Current protocol-based investigations of anti-CD20 RIT relate to new clinical uses and new CD20(+) targets.

Review of image-guided radiation therapy.

Image-guided radiation therapy represents a new paradigm in the field of high-precision radiation medicine. A synthesis of recent technological advances in medical imaging and conformal radiation therapy, image-guided radiation therapy represents a further expansion in the recent push for maximizing targeting capabilities with high-intensity radiation dose deposition limited to the true target structures, while minimizing radiation dose deposited in collateral normal tissues. By improving this targeting discrimination, the therapeutic ratio may be enhanced significantly. The principle behind image-guided radiation therapy relies heavily on the acquisition of serial image datasets using a variety of medical imaging platforms, including computed tomography, ultrasound and magnetic resonance imaging. These anatomic and volumetric image datasets are now being augmented through the addition of functional imaging. The current interest in positron-emitted tomography represents a good example of this sort of functional information now being correlated with anatomic localization. As the sophistication of imaging datasets grows, the precise 3D and 4D positions of the target and normal structures become of great relevance, leading to a recent exploration of real- or near-real-time positional replanning of the radiation treatment localization coordinates. This 'adaptive' radiotherapy explicitly recognizes that both tumors and normal tissues change position in time and space during a multiweek course of treatment, and even within a single treatment fraction. As targets and normal tissues change, the attenuation of radiation beams passing through these structures will also change, thus adding an additional level of imprecision in targeting unless these changes are taken into account. All in all, image-guided radiation therapy can be seen as further progress in the development of minimally invasive highly targeted cytotoxic therapies with the goal of substituting remote technologies for direct contact on the part of an operator or surgeon. Although data demonstrating clear-cut superiority of this new high-tech paradigm compared with more conventional radiation treatment approaches are scant, the emergence of preliminary data from several early studies shows that interest in this field is broad based and robust. As outcomes data accumulate, it is very likely that this field will continue to expand greatly. Although at present most of the work is being performed at major academic centers, the enthusiastic adoption of many of the devices and approaches being developed for this field suggest a rapid penetration into the community and the use of the technology by teams of specialists in the fields of radiation medicine, radiation physics and various branches of surgery. A recent survey of practitioners predicted very widespread adoption within the next 10 years.

Radioimmunotherapy for non-Hodgkin's lymphoma: a review for radiation oncologists.

PURPOSE: The aim of this study was to review advances in radioimmunotherapy (RIT) for non-Hodgkin's lymphoma (NHL) and to discuss the role of the radiation oncologist in administering this important new form of biologically targeted radiotherapy. METHODS AND MATERIALS: A review of articles and abstracts on the clinical efficacy, safety, and radiation safety of yttrium Y 90 (90Y) ibritumomab tiuxetan (Zevalin) and iodine I 131 tositumomab (Bexxar) was performed. RESULTS: The clinical efficacy of RIT in NHL has been shown in numerous clinical trials of 90Y ibritumomab tiuxetan and 131I tositumomab. Both agents have produced significant responses in patients with low-grade, follicular, or transformed NHL, including patients with disease that had not responded or had responded poorly to previous chemotherapy or immunotherapy. Reversible toxicities such as neutropenia, thrombocytopenia, and anemia are the most common adverse events with both agents. CONCLUSIONS: Radioimmunotherapy is safe and effective in many patients with B-cell NHL. 90Y ibritumomab tiuxetan and 131I tositumomab can produce clinically meaningful and durable responses even in patients in whom chemotherapy has failed. Treatment with RIT requires a multispecialty approach and close communication between the radiation oncologist and other members of the treatment team. The radiation oncologist plays an important role in treating patients with RIT and monitoring them for responses and adverse events after treatment.

Iodine-131 tositumomab (Bexxar) in a radiation oncology environment.

Iodine-131 (I-131) tositumomab (Bexxar; GlaxoSmithKline, Research Triangle Park, NC) is one of two recently approved radiolabeled antibodies directed against the CD20 surface antigen found on normal B cells and in more than 95% of B cell non-Hodgkin's lymphoma. The compound itself is formulated as an IgG2a immunoglobulin radiolabeled with the mixed beta/gamma emitter I-131. Multicenter clinical trials have repeatedly shown impressive clinical responses (20-40% complete response rates and 60-80% overall response rates) in the patient groups for whom this treatment is indicated. Treatment-related toxicity is generally extremely mild and typically involves only reversible hematopoietic suppression and (in some cases) a risk of treatment-induced hypothyroidism. Owing to the radiation safety concerns necessitated by the clinical use of this targeted radiopharmaceutical, it is important for radiation oncology departments wishing to participate in the care of these patients to establish methodologies and standard operating procedures for safe and efficient departmental use. This summary reviews the pertinent background information related to the current clinical experience with I-131 tositumomab and highlights some of the major opportunities for the participation of radiation oncology in the patient evaluation and treatment process. I-131 tositumomab provides an excellent example of the way in which the increasingly important new field of "targeted therapy" intersects with the practice of clinical radiotherapy. The author contends that it will be worth the time and effort involved in establishing a firm basis for the development of a comprehensive program for systemic targeted radiopharmaceutical therapies (STaRT) within the radiation medicine domain.

Radioimmunotherapy in a radiation oncology environment: building a multi-specialty team.

Radioimmunotherapy (RIT) is a new branch of radiation medicine in which antibodies specific for tumor-associated antigens are linked to radioactive atoms to provide biologically targeted short-range molecular radiotherapy. Two such biologically targeted radiopharmaceuticals have been approved for commercial use in the last few years. Y-90 ibritumomab tiuxetan (Zevalin) and I-131 tositumomab (Bexxar) both recognize the CD-20 surface antigen found on normal and malignant B cells. Both of these compounds produce impressive clinical results when used in the management of indolent, refractory, and transformed CD-20+ B-cell non-Hodgkin's lymphoma, but the unsealed sources involved in this class of compounds also require new types of patient care coordination and patient/environmental safety procedures. Because these multifunctional compounds are ideally administered through a multi-departmental team approach, the planning process to initiate and direct such a team is quite important. This article reviews some of the key processes that may be necessary to establish a successful clinical RIT team. The manuscript highlights the important roles that the radiation oncology team members may play in this multi-department enterprise.

Small-molecule inhibitor of p53 binding to mitochondria protects mice from gamma radiation.

p53-dependent apoptosis contributes to the side effects of cancer treatment, and genetic or pharmacological inhibition of p53 function can increase normal tissue resistance to genotoxic stress. It has recently been shown that p53 can induce apoptosis through a mechanism that does not depend on transactivation but instead involves translocation of p53 to mitochondria. To determine the impact of this p53 activity on normal tissue radiosensitivity, we isolated a small molecule named pifithrin-mu (PFTmu, 1) that inhibits p53 binding to mitochondria by reducing its affinity to antiapoptotic proteins Bcl-xL and Bcl-2 but has no effect on p53-dependent transactivation. PFTmu has a high specificity for p53 and does not protect cells from apoptosis induced by overexpression of proapoptotic protein Bax or by treatment with dexamethasone (2). PFTmu rescues primary mouse thymocytes from p53-mediated apoptosis caused by radiation and protects mice from doses of radiation that cause lethal hematopoietic syndrome. These results indicate that selective inhibition of the mitochondrial branch of the p53 pathway is sufficient for radioprotection in vivo.

Treatment of anaplastic histology Wilms' tumor: results from the fifth National Wilms' Tumor Study.

PURPOSE: An objective of the fifth National Wilms' Tumor Study (NWTS-5) was to evaluate the efficacy of treatment regimens for anaplastic histology Wilms' tumor (AH). PATIENTS AND METHODS: Prospective single-arm studies were conducted. Patients with stage I AH were treated with vincristine and dactinomycin for 18 weeks. Patients with stages II to IV diffuse AH were treated with vincristine, doxorubicin, cyclophosphamide, and etoposide for 24 weeks plus flank/abdominal radiation. RESULTS: A total of 2,596 patients with Wilms' tumor were enrolled onto NWTS-5, of whom 281 (10.8%) had AH. Four-year event-free survival (EFS) and overall survival (OS) estimates for assessable patients with stage I AH (n = 29) were 69.5% (95% CI, 46.9 to 84.0) and 82.6% (95% CI, 63.1 to 92.4). In comparison, 4-year EFS and OS estimates for patients with stage I favorable histology (FH; n = 473) were 92.4% (95% CI, 89.5 to 94.5) and 98.3% (95% CI, 96.4 to 99.2). Four-year EFS estimates for patients who underwent immediate nephrectomy with stages II (n = 23), III (n = 43), and IV (n = 15) diffuse AH were 82.6% (95% CI, 60.1 to 93.1), 64.7% (95% CI, 48.3 to 77.7), and 33.3% (95% CI, 12.2 to 56.4), respectively. OS was similar to EFS for these groups. There were no local recurrences among patients with stage II AH. Four-year EFS and OS estimates for patients with bilateral AH (n = 29) were 43.8% (95% CI, 24.2 to 61.8) and 55.2% (95% CI, 34.8 to 71.7), respectively. CONCLUSION: The prognosis for patients with stage I AH is worse than that for patients with stage I FH. Novel treatment strategies are needed to improve outcomes for patients with AH, especially those with stage III to V disease.

Review of clinical radioimmunotherapy.

Radioimmunotherapy involves a form of biologically targeted radiopharmaceutical treatment in which a radioactive isotope (typically a short-range, high-energy beta-emitter) is chemically bound to a target-specific monoclonal antibody or fragment. Thus, these radioimmunoconjugates combine the exquisite targeting specificity of the humoral immune system with the known cancer-killing power of high-energy radiotherapy. To date, two radioimmunotherapy agents have been fully approved for commercial use: 90Yttrium ibritumomab tiuxetan and (131)Iodine tositumomab. Both compounds target the CD20 surface molecule found on normal and malignant B cells, and both are medically indicated for the treatment of indolent B-cell lymphoma and related conditions. Clinical results are excellent (20-40% complete response rates and 60-80% overall response rates) and toxicity is typically quite mild. Current research is now attempting to both explore the biology of these compounds and to expand the spectrum of CD20+ diseases that could be treated using either or both of these active agents. Concurrently, work is in progress to achieve the same excellent clinical results using antibodies specific for other, more common epithelial tumors. This work is at an earlier stage than the lymphoma work, partly due to the high innate radiosensitivity of the lymphoid system. Thus, various enhancement methodologies are being explored to increase clinical response rates for these solid tumors, and a number of solid tumor RIT agents are now in early-stage clinical trials. The most likely pattern of use for this field in the next 5 years will probably involve combination or sequential regimens incorporating both radioimmunotherapy and more conventional chemotherapy or external radiotherapy.