Prognostic value of medulloblastoma extent of resection after accounting for molecular subgroup: a retrospective integrated clinical and molecular analysis.
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2016-04
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Abstract
Background
Patients with incomplete surgical resection of medulloblastoma are controversially regarded as having a marker of high-risk disease, which leads to patients undergoing aggressive surgical resections, so-called second-look surgeries, and intensified chemoradiotherapy. All previous studies assessing the clinical importance of extent of resection have not accounted for molecular subgroup. We analysed the prognostic value of extent of resection in a subgroup-specific manner.Methods
We retrospectively identified patients who had a histological diagnosis of medulloblastoma and complete data about extent of resection and survival from centres participating in the Medulloblastoma Advanced Genomics International Consortium. We collected from resections done between April, 1997, and February, 2013, at 35 international institutions. We established medulloblastoma subgroup affiliation by gene expression profiling on frozen or formalin-fixed paraffin-embedded tissues. We classified extent of resection on the basis of postoperative imaging as gross total resection (no residual tumour), near-total resection (<1·5 cm(2) tumour remaining), or sub-total resection (≥1·5 cm(2) tumour remaining). We did multivariable analyses of overall survival and progression-free survival using the variables molecular subgroup (WNT, SHH, group 4, and group 3), age (<3 vs ≥3 years old), metastatic status (metastases vs no metastases), geographical location of therapy (North America/Australia vs rest of the world), receipt of chemotherapy (yes vs no) and receipt of craniospinal irradiation (<30 Gy or >30 Gy vs no craniospinal irradiation). The primary analysis outcome was the effect of extent of resection by molecular subgroup and the effects of other clinical variables on overall and progression-free survival.Findings
We included 787 patients with medulloblastoma (86 with WNT tumours, 242 with SHH tumours, 163 with group 3 tumours, and 296 with group 4 tumours) in our multivariable Cox models of progression-free and overall survival. We found that the prognostic benefit of increased extent of resection for patients with medulloblastoma is attenuated after molecular subgroup affiliation is taken into account. We identified a progression-free survival benefit for gross total resection over sub-total resection (hazard ratio [HR] 1·45, 95% CI 1·07-1·96, p=0·16) but no overall survival benefit (HR 1·23, 0·87-1·72, p=0·24). We saw no progression-free survival or overall survival benefit for gross total resection compared with near-total resection (HR 1·05, 0·71-1·53, p=0·8158 for progression-free survival and HR 1·14, 0·75-1·72, p=0·55 for overall survival). No significant survival benefit existed for greater extent of resection for patients with WNT, SHH, or group 3 tumours (HR 1·03, 0·67-1·58, p=0·89 for sub-total resection vs gross total resection). For patients with group 4 tumours, gross total resection conferred a benefit to progression-free survival compared with sub-total resection (HR 1·97, 1·22-3·17, p=0·0056), especially for those with metastatic disease (HR 2·22, 1·00-4·93, p=0·050). However, gross total resection had no effect on overall survival compared with sub-total resection in patients with group 4 tumours (HR 1·67, 0·93-2·99, p=0·084).Interpretation
The prognostic benefit of increased extent of resection for patients with medulloblastoma is attenuated after molecular subgroup affiliation is taken into account. Although maximum safe surgical resection should remain the standard of care, surgical removal of small residual portions of medulloblastoma is not recommended when the likelihood of neurological morbidity is high because there is no definitive benefit to gross total resection compared with near-total resection.Funding
Canadian Cancer Society Research Institute, Terry Fox Research Institute, Canadian Institutes of Health Research, National Institutes of Health, Pediatric Brain Tumor Foundation, and the Garron Family Chair in Childhood Cancer Research.Type
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Thompson, Eric M, Thomas Hielscher, Eric Bouffet, Marc Remke, Betty Luu, Sridharan Gururangan, Roger E McLendon, Darell D Bigner, et al. (2016). Prognostic value of medulloblastoma extent of resection after accounting for molecular subgroup: a retrospective integrated clinical and molecular analysis. The Lancet. Oncology, 17(4). pp. 484–495. 10.1016/s1470-2045(15)00581-1 Retrieved from https://hdl.handle.net/10161/25903.
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Scholars@Duke
Roger Edwin McLendon
Brain tumors are diagnosed in more than 20,000 Americans annually. The most malignant neoplasm, glioblastoma, is also the most common. Similarly, brain tumors constitute the most common solid neoplasm in children and include astrocytomas of the cerebellum, brain stem and cerebrum as well as medulloblastomas of the cerebellum. My colleagues and I have endeavored to translate the bench discoveries of genetic mutations and aberrant protein expressions found in brain tumors to better understand the processes involved in the etiology, pathogenesis, and treatment of brain tumors. Using the resources of the Preston Robert Brain Tumor Biorepository at Duke, our team, consisting of Henry Friedman, Allan Friedman, and Hai Yan and lead by Darell Bigner, have helped to identify mutations in Isocitrate Dehydrogenase (IDH1 and IDH2) as a marker of good prognosis in gliomas of adults. This test is now offered at Duke as a clinical test. Working with the Molecular Pathology Laboratory at Duke, we have also brought testing for TERT promoter region mutations as another major test for classifying gliomas in adults. Our collaboration with the Toronto Sick Kids Hospital has resulted in prognostic testing for childhood medulloblastomas, primitive neuroectodermal tumors, and ependymomas at Duke.
Darell Doty Bigner
The Causes, Mechanisms of Transformation and Altered Growth Control and New Therapy for Primary and Metastatic Tumors of the Central Nervous System (CNS).
There are over 16,000 deaths in the United States each year from primary brain tumors such as malignant gliomas and medulloblastomas, and metastatic tumors to the CNS and its covering from systemic tumors such as carcinoma of the lung, breast, colon, and melanoma. An estimated 80,000 cases of primary brain tumors were expected to be diagnosed last year. Of that number, approximately 4,600 diagnosed will be children less than 19 years of age. During the last 20 years, however, there has been a significant increase in survival rates for those with primary malignant brain tumors.
For the last 44 years my research has involved the investigation of the causes, mechanism of transformation and altered growth control, and development of new methods of therapy for primary brain tumors and those metastasizing to the CNS and its coverings. In collaboration with my colleagues in the Preston Robert Tisch Brain Tumor Center, new drugs and those not previously thought to be active against CNS tumors have been identified. Overcoming mechanisms of drug resistance in primary brain tumors are also being pursued.
As the founding Director of the Preston Robert Tisch Brain Tumor Center, I help coordinate the research activities of all 37 faculty members in the Brain Tumor Center. These faculty members have projects ranging from very basic research into molecular etiology, molecular epidemiology, signal transduction; translational research performing pre-clinical evaluation of new therapies, and many clinical investigative efforts. I can describe any of the Brain Tumor Center faculty member’s research to third year students and then direct them to specific faculty members with whom the students would like a discussion.
We have identified through genome-wide screening methodology several new target molecules selectively expressed on malignant brain tumors, but not on normal brain. These include EGFRwt, EGFRvIII, and two lacto series gangliosides, 3'-isoLM1 and 3',6'-isoLD1 and chondroitin proteoglycan sulfate. We raised conventional and fully human monoclonal antibodies against most of these targets as well as having developed single fragment chain molecules from naïve human libraries.
My personal research focuses on molecularly targeted therapies of primary and metastatic CNS tumors with monoclonal antibodies and their fragments. Our study we conducted was with a molecule we discovered many years ago, the extracellular matrix molecule, Tenascin. We have treated over 150 malignant brain tumor patients with excellent results with a radiolabeled antibody we developed against Tenascin. We are collaborating with Dr. Ira Pastan at NIH to develop tumor-targeted therapies by fusing single fragment chain molecules from monoclonal antibodies or from naïve human libraries to the truncated fragment of pseudomonas exotoxin A. One example of this is the pseudomonas exotoxin conjugated to a single fragment chain antibody that reacts with wild type EGFR and EGFRvIII, two overexpressed proteins on glioblastoma. The immunotoxin, called D2C7-IT, is currently being investigated in an FDA dose-escalation study, in which patients undergoing treatment of this investigational new drug are showing positive responses. My laboratory is also working with Matthias Gromeier, creator of the oncolytic poliovirus - a re-engineered poliovirus that is lethal to cancer cells, but not lethal to normal cells. The oncolytic poliovirus therapeutic approach has shown such promising results in patients with glioblastoma, that it was recently featured on a on a special two-segment program of 60 Minutes. The next clinical step will be to combine both the virus and the immunotoxin with anti-PD1, an immune checkpoint blockade inhibitor and with anti-CD40, a fully human monoclonal antibody which converts tumor stimulant macrophages into tumor suppressive macrophages. We believe that regional tumor-targeted cytotoxic therapies, such as oncolytic poliovirus and the D2C7 immunotoxin, not only specifically target and destroy tumor cells, but in the process, initiate immune events that promote an in situ vaccine effect. That immune response can be amplified by human checkpoint blockade to engender a long-term systemic immune response that effectively eliminates recurrent and disseminated GBM cells. Ultimately, all three agents may be used together, providing different antigenic targets and cytotoxicity mechanisms.
We have identified through genome-wide screening methodology several new target molecules selectively expressed on malignant brain tumors, but not on normal brain. These include glycoprotein non-metastatic B (GPNMB), a molecule shared with malignant melanoma; MRP3, a member of the multidrug resistant family; and two lacto series gangliosides, 3'-isoLM1 and 3',6'-isoLD1 and chondroitin proteoglycan sulfate. We are raising conventional monoclonal antibodies against all of these targets as well as developing single fragment chain molecules from naïve human libraries. When necessary, affinity maturation in vitro is carried out and the antibodies and fragments are armed either with radioactive iodine, radioactive lutetium, or radioactive Astatine-211. Other constructs are evaluated for unarmed activity and some are armed with Pseudomonas exotoxin. After development of the constructs, they are evaluated in human malignant glioma xenograft systems and then all studies necessary for Investigational New Drug Permits from the Food and Drug Administration are carried out prior to actual clinical trial.
I was senior author on a New England Journal of Medicine paper that was the first to show markedly increased survival in low to intermediate grade gliomas with an isocitrate dehydrogenase mutation.
The first fully funded Specialized Research Center on Primary and Metastatic Tumors to the CNS funded by the National Institutes of Health, of which I was Principal Investigator, was funded for 30 years at which time the type of grant was discontinued. My NCI MERIT Award, which ranked in the upper 1.2 percentile of all NIH grants at the time of its last review, is currently in its 40th year of continuous funding. It is one of the few MERIT awards awarded three consecutive times, and it is the longest continually funded grant of the NCI Division of Cancer Diagnosis and Treatment. My last NCI Award was an Outstanding Investigator Award from 2014 to 2022.
In addition to the representative publications listed, I have made national presentations and international presentations during the past year.
My laboratory has trained over 50 third year medical students, residents, Ph.D. students, and postdoctoral fellows and I have a great deal of experience in career development with some students having advanced all the way from fellowship status to endowed professorships. A major goal with third year medical students is to perform work that can be presented in abstract form at national or international meetings and to obtain publication in major peer-reviewed journals.
Gerald Arthur Grant
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