Patterns of relapse after successful completion of initial therapy in primary central nervous system lymphoma: a case series.
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2020-04
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Abstract
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Primary central nervous system lymphoma (PCNSL) is a subtype of non-Hodgkin's lymphoma that involves the brain, spinal cord, or leptomeninges, without evidence of systemic disease. This rare disease accounts for ~ 3% of all primary central nervous system (CNS) tumors. Methotrexate-based regimens are the standard of care for this disease with overall survival rates ranging from 14 to 55 months. Relapse after apparent complete remission can occur. We sought to understand the outcomes of patients who relapsed.Methods
This is an IRB-approved investigation of patients treated at our institution between 12/31/2004 and 10/12/2016. We retrospectively identified all cases of PCNSL as part of a database registry and evaluated these cases for demographic information, absence or presence of relapse, location of relapse, treatment regimens, and median relapse-free survival.Results
This analysis identified 44 patients with a pathologically confirmed diagnosis of PCNSL. Mean age at diagnosis was 63.1 years (range 20-86, SD = 13.2 years). Of the 44 patients, 28 patients successfully completed an initial treatment regimen without recurrence or toxicity that required a change in therapy. Relapse occurred in 11 patients with the location of relapse being in the CNS only (n = 5), vitreous fluid only (n = 1), outside CNS only (n = 3), or a combination of CNS and outside of the CNS (n = 2). Sites of relapse outside of the CNS included testes (n = 1), lung (n = 1), adrenal gland (n = 1), kidney/adrenal gland (n = 1), and retroperitoneum (n = 1). Median relapse-free survival after successful completion of therapy was 6.7 years (95% CI 1.1, 12.6).Conclusion
After successful initial treatment, PCNSL has a propensity to relapse, and this relapse can occur both inside and outside of the CNS. Vigilant monitoring of off-treatment patients with a history of PCNSL is necessary to guide early diagnosis of relapse and to initiate aggressive treatment.Type
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Patel, Mallika P, John P Kirkpatrick, Margaret O Johnson, Patrick Healy, James E Herndon, Eric S Lipp, Elizabeth S Miller, Annick Desjardins, et al. (2020). Patterns of relapse after successful completion of initial therapy in primary central nervous system lymphoma: a case series. Journal of neuro-oncology, 147(2). pp. 477–483. 10.1007/s11060-020-03446-3 Retrieved from https://hdl.handle.net/10161/34381.
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Scholars@Duke
John P. Kirkpatrick
Malignant and benign tumors of the brain, spine and base of skull. Mathematical modelling of tumor metabolism, mass transfer and the response to ionizing radiation. Enhancing clinical outcome in stereotactic radiosurgery, fractionated stereotactic radiotherapy and stereotactic body radiotherapy.
Margaret Johnson
I am a neuro-oncologist, neurologist, and palliative care physician at the Preston Robert Tisch Brain Tumor Center. I also provide neuro-oncology expertise for the National Tele-Oncology Program and National Precision Oncology Program at the Veteran's Health Administration. My clinical and research interests encompass supportive care and palliative care with a special interest in older adults with brain tumors. The incidence of malignant brain tumors like glioblastoma and non-malignant tumors like meningioma affect aging populations and it is crucial to be able to provide better care for these patients.
James Emmett Herndon
Current research interests have application to the design and analysis of cancer clinical trials. Specifically, interests include the use of time-dependent covariables within survival models, the design of phase II cancer clinical trials which minimize some of the logistical problems associated with their conduct, and the analysis of longitudinal studies with informative censoring (in particular, quality of life studies of patients with advanced cancer).
Annick Desjardins
Henry Seth Friedman
Overview: Our laboratory is pursuing a comprehensive analysis of the biology and therapy of adult and childhood central nervous system malignancies, particularly high-grade medulloblastoma, glioma, and ependymoma.
Laboratory Studies: Active programs, using human adult and pediatric CNS tumor continuous cell lines, transplantable xenografts growing subcutaneously and intracranially in athymic nude mice and rats, and as well as in the subarachnoid space of the athymic nude rats, and patients tumor specimens, are defining:
1) the chemotherapeutic profile of medulloblastoma, adult and childhood glioma and ependymoma
2) mechanisms of resistance to classical bifunctional alkylators, nitrosoureas and methylators operational in malignant glioma and medulloblastoma, particularly DNA adduct and crosslink repair, O6-alkylguanine-DNA alkyltransferase elevation and DNA mismatch repair deficiency.
3) modulations designed to over come or circumvent specific mechanisms of resistance
4) the activity of signal pathway inhibitors of EGFR, m-tor and other targets
5) the therapeutic advantages of intrathecal and intratumoral drug delivery in the treatment of neoplastic meningitis and intracranial malignancies, respectively.
The results of the therapeutic studies to date have demonstrated the marked activity of alkylating agents, particularly melphalan and cyclophosphamide and the role of glutathione, AGT glutathione-S-transferase, abnormal drug transport and alterations in formation and repair of DNA-DNA crosslinks in modulating cytotoxicity of these agents. Modulations shown to be effective in enhancing alkylator activity/reversing alkylator resistance include BSO-mediated glutathione depletion, inhibition of DNA-DNA crosslink repair and inhibition of 06-alkylguanine-DNA alkyltransferase by 06-benzylguanine. Recent studies have demonstrated profound activity of temozolomide, CPT-11 topotecan, irofulven, and karenitecin as well as the combination of CPT-11 or topotecan plus BCNU or temozolomide. Successful treatment of neoplastic meningitis in nude rats with intrathecal 4-hydroperoxycyclophosphamide, melphalan, temozolomide and busulfan, and intracranial glioma in nude rats with intratumoral temozolomide has also been demonstrated. More recent studies have revealed cyclophosphamide resistance secondary to DNA interstrand crosslink repair. Additional studies have shown that cyclophosphamide crosslinks are formed at the 1,3 N7 position, serving as the basis for construction of a defined crosslink in a plasmid vector to assay for crosslink repair and allowing demonstration of the lack of a role of nucleotide excision repair. Mismatch repair deficiency has been shown as a mechanism mediating acquired methylator (procarbazine and temozolomide) resistance in an adult glioblastoma xenograft.
Clinical Studies: Clinical investigations are designed to translate laboratory programs into successful treatment for adults and children with malignant brain tumors, particularly medulloblastoma. Clinical trials for adults include phase II trials of temozolomide, ZD1839 (Iressa), karenitecin, and temozolomide plus O6-BG as well as phase I trials of topotecan plus BCNU, CPT-11 plus temozolomide, and PTK787 ± temozolomide or CCNU. Studies are in progress in children evaluating the activity CPT-11 plus temozolomide, intrathecal busulfan and cyclophosphamide/melphalan or cyclophosphamide/busulfan plus autologous bone marrow support . Extension of these studies to a larger cohort of patients is being performed nationally under the auspices of the Pediatric Brain Tumor Consortium (Henry S. Friedman -- Head of New Agents Committee).
Future studies will address the role of agents designed to decrease repair of interstrand crosslinks when given in combination with alkylating agents, as well as newer signal pathway inhibitors such as RAD001, PKI166, and DB-67.
Katherine Barnett Peters
Katy Peters, MD, PhD, FAAN is a professor of neurology and neurosurgery at the Preston Robert Tisch Brain Tumor Center (PRTBTC) at Duke. Her academic medical career started at Stanford University School of Medicine, receiving an MD and Ph.D. in Cancer Biology. After completing a neurology residency at Johns Hopkins University and a fellowship in cognitive neurosciences, Katy joined the PRTBTC as a neuro-oncology fellow. In 2009, she became a faculty member at PRTBTC. With a fantastic team of nursing and advanced practice providers, she actively sees and cares for patients with primary brain tumors. Her research interests include supportive care for brain cancer patients, cognitive dysfunction in cancer patients, and physical function and activity of brain cancer patients. While she runs clinical trials to treat primary brain tumors, her key interest is on clinical trials that focus on improving brain tumor patients' quality of life and cognition. In 2019, the PRTBTC designated her as the Director of Supportive Care, thus furthering the PRTBTC and her committee to better the quality of life for brain tumor patients. She is active in teaching medical school students, residents, fellows, and advanced practice providers and is the Program Director of the PRTBRC neuro-oncology fellowship. She is board certified by the American Board of Psychiatry and Neurology and the United Council of Neurologic Subspecialties for neuro-oncology.
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