January 23, 2015
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January 7, 2016
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January 19, 2021
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December 2015
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December 2023 (Final data collection date for primary outcome measure)
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Overall survival [ Time Frame: Through study completion with follow-up until 90 days after final DC vaccine administration or 24 months after apheresis, whichever occurs later ] Patients will be followed for survival, from apheresis (~ diagnosis), for which the accurate date and reason of death (cancer-related or non-related) will be recorded for every patient.
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Overall survival [ Time Frame: Through study completion (anticipated 2 years) with 2-year follow-up ] Patients will be followed for survival, from diagnosis and from start of treatment, for which the accurate date and reason of death (cancer-related or non-related) will be recorded for every patient.
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- Number of glioblastoma patients post surgical resection with feasible and safe DC vaccine production [ Time Frame: Vaccine production and quality testing (i.e. 4 weeks after leukapheresis) ]
Production of autologous DC vaccines from newly diagnosed glioblastoma patients that underwent maximal, safe surgical resection will be evaluated for:
- feasibility, assessed by success of leukapheresis and production of sufficient and qualified (phenotypic and functional requirements) vaccines.
- Safety, assessed by microbiological testing (bacteria, yeast, fungi, mycoplasma, endotoxin) of the DC vaccines.
- Feasibility of DC vaccine administration to glioblastoma patients combined with chemotherapy [ Time Frame: Upon maintenance chemotherapy treatment (i.e. +/- 12 weeks post leukapheresis) ]
Administration of 3 weekly DC vaccines following adjuvant chemoradiation (induction phase) and additional DC vaccination at day 21 of each maintenance chemotherapy cycle (booster phase) will be evaluated for feasibility, assessed by successful DC vaccine administration of the proposed treatment scheme.
- Number of participants with adverse events as a measure of safety and tolerability [ Time Frame: Through study completion with follow-up until 90 days after final DC vaccine administration or 24 months after apheresis, whichever occurs later ]
Monitoring the incidence of adverse events to evaluate the safety profile and tolerability of the treatment. The severity of adverse events will be assessed according to the NCI CTCAE scale (v4.03, published June 14, 2010).
- Immunological responses to the DC vaccine [ Time Frame: At first DC vaccination + day 1 of first and fourth temozolomide treatment cycles ]
Immunological responses to the vaccine will be evaluated ex vivo. Blood samples will be collected from patients on the day of the first DC vaccine, and on day 1 of the first and fourth maintenance temozolomide treatment cycles and will be examined for cell subset distribution and activation status and antigen-specific immunity.
- Objective clinical responses by tumor evaluation (clinical efficacy) [ Time Frame: Through study completion with follow up until 90 days after final DC vaccine administration or 24 months after apheresis, whichever occurs later ]
Disease evolution and progression-free survival will be assessed according to the Response Assessment in Neuro-Oncology (RANO) criteria, based on imaging findings (MRI, CT), clinical status and corticosteroid use.
Disease will be assessed following chemoradiation (≤ 2 weeks after completing chemoradiation), after every two cycles of temozolomide maintenance treatment and at least every 12 weeks during the booster phase, and every 9-12 weeks during follow-up after treatment discontinuation.
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- Number of glioblastoma patients post surgical resection with feasible and safe DC vaccine production [ Time Frame: Vaccine production and quality testing (i.e. 4 weeks after leukapheresis) ]
Production of autologous DC vaccines from newly diagnosed glioblastoma patients that underwent maximal, safe surgical resection will be evaluated for:
- feasibility, assessed by success of leukapheresis and production of sufficient and qualified (phenotypic and functional requirements) vaccines.
- Safety, assessed by microbiological testing (bacteria, yeast, fungi, mycoplasma, endotoxin) of the DC vaccines.
- Feasibility of DC vaccine administration to glioblastoma patients combined with chemotherapy [ Time Frame: Upon maintenance chemotherapy treatment (i.e. +/- 12 weeks post leukapheresis) ]
Administration of 3 weekly DC vaccines following adjuvant chemoradiation (induction phase) and additional DC vaccination at day 21 of each maintenance chemotherapy cycle (booster phase) will be evaluated for feasibility, assessed by successful DC vaccine administration of the proposed treatment scheme.
- Number of participants with adverse events as a measure of safety and tolerability [ Time Frame: Through study completion (anticipated 2 years) with 2-year follow-up ]
Monitoring the incidence of adverse events to evaluate the safety profile and tolerability of the treatment. The severity of adverse events will be assessed according to the NCI CTCAE scale (v4.03, published June 14, 2010).
- Immunological responses to the DC vaccine [ Time Frame: At first DC vaccination + day 1 of first and fourth temozolomide treatment cycles ]
Immunological responses to the vaccine will be evaluated ex vivo. Blood samples will be collected from patients on the day of the first DC vaccine, and on day 1 of the first and fourth maintenance temozolomide treatment cycles and will be examined for cell subset distribution and activation status and antigen-specific immunity.
- Objective clinical responses by tumor evaluation (clinical efficacy) [ Time Frame: Through study completion (anticipated 2 years) with 2-year follow-up ]
Disease evolution and progression-free survival will be assessed according to the Response Assessment in Neuro-Oncology (RANO) criteria, based on imaging findings (MRI, CT), clinical status and corticosteroid use.
Disease will be assessed following chemoradiation (≤ 2 weeks after completing chemoradiation), after every two cycles of temozolomide maintenance treatment and at least every 12 weeks during the booster phase, and every 9-12 weeks during follow-up after treatment discontinuation.
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General and disease-specific quality of life [ Time Frame: Through study completion with follow up until 90 days after final DC vaccine administration or 24 months after apheresis, whichever occurs later ] Patients will be asked to fill out general and disease-specific quality of life questionnaires to assess changes in general and disease-specific quality of life during the study at regular time points.
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Not Provided
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Adjuvant Dendritic Cell-immunotherapy Plus Temozolomide in Glioblastoma Patients
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Adjuvant Dendritic-Cell Immunotherapy Plus Temozolomide Following Surgery and Chemoradiation in Patients With Newly Diagnosed Glioblastoma
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In this phase I/II trial, the primary objective is to determine overall and progression-free survival of patients with newly diagnosed glioblastoma when autologous Wilms' tumor 1 (WT1) messenger (m)RNA-loaded dendritic cell (DC) vaccination is added to adjuvant temozolomide maintenance treatment following (sub)total resection and temozolomide-based chemoradiation.
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Glioblastoma multiforme (GBM), a microscopically infiltrative disease, is the most common malignant brain tumor worldwide. Despite optimized standard of care treatment median survival and prognosis remain poor with a median survival of only 15% and five year survival after diagnosis of 5%.
In this single arm single centre phase I/II trial the investigators will determine the overall and progression free survival of patients with newly diagnosed GBM when autologous WT1 mRNA loaded dendritic cell vaccination is added to standard of care treatment. During recruitment, the investigators will include 20 patients with newly diagnosed, histologically verified glioblastoma (WHO grade IV) who have received a total or subtotal resection of the tumor. Patients who underwent prior radiation or chemotherapy or with a history of other malignancy will be excluded. In addition to standard of care consisting of adjuvant chemoradiation with temozolomide and temozolomide maintenance patients will receive an intradermal vaccination with autologous WT1 mRNA-loaded dendritic cells commencing 1 week after radiotherapy. The dendritic cell therapy product will be generated and administered in the Antwerp University Hospital, more specifically the Center for Cell Therapy and Regenerative Medicine (CCRG) and the Division of Hematology, both headed by Prof. Zwi Berneman.
Recruitment began in December 2015 and is intended to continue until the end of 2020 or when 20 patients are enrolled. After a follow-up period (until 90 days after final DC vaccine administration or 24 months after apheresis , whichever occurs later), overall and progression free survival analysis will be performed and this will be compared with the published data of standard of care treatment without vaccination. In addition the investigators will look for feasibility, incidence of adverse events and immunogenicity.
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Interventional
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Phase 1 Phase 2
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Allocation: N/A Intervention Model: Single Group Assignment Masking: None (Open Label) Primary Purpose: Treatment
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Glioblastoma Multiforme of Brain
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Biological: Dendritic cell vaccine plus temozolomide chemotherapy
When eligible after total or subtotal resection (as assessed by neurosurgeon and post-operative brain MRI):
- Leukocyte apheresis (before chemoradiation): for DC vaccine production
- Chemoradiation (standard treatment: initiated as soon as the patient's hematological blood values are adequate after apheresis): 2 Gy once daily 5 days/week for 6 weeks with 75 mg/m² temozolomide daily from the first until the last day of radiotherapy (no longer than 49 days in total)
- Induction immunotherapy: intradermal vaccination with autologous WT1 mRNA-loaded DCs weekly (+/-1 day) for 3 weeks, starting ≥ 1 week after radiotherapy
- Chemo-immunotherapy: 150-200 mg/m²/d temozolomide days 1-5 every 28 days +/- 2 days (max. 12 months) starting ≥3 days after the third vaccine of the induction immunotherapy + DC vaccination on day 21±3 days of every 28-day cycle
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Experimental: Single Arm
Dendritic cell vaccine plus temozolomide chemotherapy
Intervention: Biological: Dendritic cell vaccine plus temozolomide chemotherapy
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- Van Tendeloo VF, Van de Velde A, Van Driessche A, Cools N, Anguille S, Ladell K, Gostick E, Vermeulen K, Pieters K, Nijs G, Stein B, Smits EL, Schroyens WA, Gadisseur AP, Vrelust I, Jorens PG, Goossens H, de Vries IJ, Price DA, Oji Y, Oka Y, Sugiyama H, Berneman ZN. Induction of complete and molecular remissions in acute myeloid leukemia by Wilms' tumor 1 antigen-targeted dendritic cell vaccination. Proc Natl Acad Sci U S A. 2010 Aug 3;107(31):13824-9. doi: 10.1073/pnas.1008051107. Epub 2010 Jul 14.
- Van Driessche A, Van de Velde AL, Nijs G, Braeckman T, Stein B, De Vries JM, Berneman ZN, Van Tendeloo VF. Clinical-grade manufacturing of autologous mature mRNA-electroporated dendritic cells and safety testing in acute myeloid leukemia patients in a phase I dose-escalation clinical trial. Cytotherapy. 2009;11(5):653-68. doi: 10.1080/14653240902960411.
- Van Driessche A, Berneman ZN, Van Tendeloo VF. Active specific immunotherapy targeting the Wilms' tumor protein 1 (WT1) for patients with hematological malignancies and solid tumors: lessons from early clinical trials. Oncologist. 2012;17(2):250-9. doi: 10.1634/theoncologist.2011-0240. Epub 2012 Jan 30. Review.
- Smits EL, Anguille S, Cools N, Berneman ZN, Van Tendeloo VF. Dendritic cell-based cancer gene therapy. Hum Gene Ther. 2009 Oct;20(10):1106-18. doi: 10.1089/hum.2009.145. Review.
- Anguille S, Smits EL, Lion E, van Tendeloo VF, Berneman ZN. Clinical use of dendritic cells for cancer therapy. Lancet Oncol. 2014 Jun;15(7):e257-67. doi: 10.1016/S1470-2045(13)70585-0. Review.
- Anguille S, Smits EL, Bryant C, Van Acker HH, Goossens H, Lion E, Fromm PD, Hart DN, Van Tendeloo VF, Berneman ZN. Dendritic Cells as Pharmacological Tools for Cancer Immunotherapy. Pharmacol Rev. 2015 Oct;67(4):731-53. doi: 10.1124/pr.114.009456. Review.
- Willemen Y, Huizing MT, Smits E, Anguille S, Nijs G, Stein B, Van Tendeloo V, Peeters M, Berneman Z. J Clin Oncol 30(suppl): abstr e13051, 2012.
- Anguille S, Van de Velde AL, Smits EL, Van Tendeloo VF, Juliusson G, Cools N, Nijs G, Stein B, Lion E, Van Driessche A, Vandenbosch I, Verlinden A, Gadisseur AP, Schroyens WA, Muylle L, Vermeulen K, Maes MB, Deiteren K, Malfait R, Gostick E, Lammens M, Couttenye MM, Jorens P, Goossens H, Price DA, Ladell K, Oka Y, Fujiki F, Oji Y, Sugiyama H, Berneman ZN. Dendritic cell vaccination as postremission treatment to prevent or delay relapse in acute myeloid leukemia. Blood. 2017 Oct 12;130(15):1713-1721. doi: 10.1182/blood-2017-04-780155. Epub 2017 Aug 22.
- Z. Berneman, A. Van de Velde, S. Anguille, Y. Willemen, M. Huizing, P. Germonpré, K. Saevels, G. Nijs, N. Cools, A. Van Driessche, B. Stein, H. De Reu, W. Schroyens, A. Gadisseur, A. Verlinden, K. Vermeulen, M. Maes, M. Lammens, H. Goossens, M. Peeters, V. Van Tendeloo, E. Smits. Vaccination with Wilms' Tumor Antigen (WT1) mRNA-Electroporated Dendritic Cells as an Adjuvant Treatment in 60 Cancer Patients: Report of Clinical Effects and Increased Survival in Acute Myeloid Leukemia, Metastatic Breast Cancer, Glioblastoma and Mesothelioma. Cytotherapy 2016, 18(6), p. S13-14
- Z. Berneman, S. Anguille, Y. Willemen, A. Van de Velde, P. Germonpré, M. Huizing, V. Van Tendeloo, K. Saevels, L. Rutsaert, K. Vermeulen, A. Snoeckx, B. Op de Beeck, N. Cools, G. Nijs, B. Stein, E. Lion, A. van Driessche, M. Peeters, E. Smits. Vaccination of cancer patients with dendritic cells electroporated with mRNA encoding the Wilms' Tumor protein (WT1): correlation of clinical effect and overall survival with T-cell response. Cytotherapy 2019, 21(5), p. S10.
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Recruiting
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20
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Same as current
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December 2024
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December 2023 (Final data collection date for primary outcome measure)
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Inclusion Criteria:
Exclusion Criteria:
- History of another malignancy, except for adequately controlled basal cell skin carcinoma, squamous skin carcinoma, or carcinoma in situ of the uterine cervix or unless the investigator rationalizes otherwise
- Prior radiation or chemotherapy
- Any pre-existing contraindication for temozolomide treatment
- Any pre-existing contraindication for contrast-enhanced brain MRI
- Pregnant or breast-feeding
- Documented immune deficiency or systemic immune-suppressive treatment
- Known positive viral serology for HIV, HBV, HCV, or syphilis
- Any other condition, either physical or psychological, or reasonable suspicion thereof on clinical or special investigation, which contraindicates the use of the vaccine, or may negatively affect patient compliance, or may place the patient at higher risk of potential treatment complications
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Sexes Eligible for Study: |
All |
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18 Years and older (Adult, Older Adult)
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No
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Belgium
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NCT02649582
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CCRG14-001
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No
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Not Provided
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Not Provided
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Zwi Berneman, University Hospital, Antwerp
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Same as current
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University Hospital, Antwerp
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Same as current
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Not Provided
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Study Director: |
Zwi N Berneman, MD, PhD |
Antwerp University Hospital, Division of Hematology and Center for Cell Therapy and Regenerative Medicine |
Principal Investigator: |
Pol Specenier, MD, PhD |
Antwerp University Hospital (UZA), Division of Oncology |
Principal Investigator: |
Yannick Willemen, MD |
University of Antwerp, Laboratory of Experimental Hematology |
Principal Investigator: |
Evelien LJ Smits, MSc, PhD |
University of Antwerp, Laboratory of Experimental Hematology |
Investigator: |
Barbara Stein, MSc |
Antwerp University Hospital, Division of Hematology |
Investigator: |
Eva Lion, MSc, PhD |
University of Antwerp, Laboratory of Experimental Hematology |
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University Hospital, Antwerp
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January 2021
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