Search

Your search keyword '"Trusheim, P."' showing total 16 results
Start Over Author "Trusheim, P." Database eScholarship
16 results on '"Trusheim, P."'

1. Field programmable spin arrays for scalable quantum repeaters.

Author

Wang, Hanfeng, Trusheim, Matthew, Kim, Laura, Raniwala, Hamza, and Englund, Dirk

Abstract

The large scale control over thousands of quantum emitters desired by quantum network technology is limited by the power consumption and cross-talk inherent in current microwave techniques. Here we propose a quantum repeater architecture based on densely-packed diamond color centers (CCs) in a programmable electrode array, with quantum gates driven by electric or strain fields. This field programmable spin array (FPSA) enables high-speed spin control of individual CCs with low cross-talk and power dissipation. Integrated in a slow-light waveguide for efficient optical coupling, the FPSA serves as a quantum interface for optically-mediated entanglement. We evaluate the performance of the FPSA architecture in comparison to a routing-tree design and show an increased entanglement generation rate scaling into the thousand-qubit regime. Our results enable high fidelity control of dense quantum emitter arrays for scalable networking.

Published
2023

2. Association of Autologous Tumor Lysate-Loaded Dendritic Cell Vaccination With Extension of Survival Among Patients With Newly Diagnosed and Recurrent Glioblastoma

Author

Liau, Linda M, Ashkan, Keyoumars, Brem, Steven, Campian, Jian L, Trusheim, John E, Iwamoto, Fabio M, Tran, David D, Ansstas, George, Cobbs, Charles S, Heth, Jason A, Salacz, Michael E, D’Andre, Stacy, Aiken, Robert D, Moshel, Yaron A, Nam, Joo Y, Pillainayagam, Clement P, Wagner, Stephanie A, Walter, Kevin A, Chaudhary, Rekha, Goldlust, Samuel A, Lee, Ian Y, Bota, Daniela A, Elinzano, Heinrich, Grewal, Jai, Lillehei, Kevin, Mikkelsen, Tom, Walbert, Tobias, Abram, Steven, Brenner, Andrew J, Ewend, Matthew G, Khagi, Simon, Lovick, Darren S, Portnow, Jana, Kim, Lyndon, Loudon, William G, Martinez, Nina L, Thompson, Reid C, Avigan, David E, Fink, Karen L, Geoffroy, Francois J, Giglio, Pierre, Gligich, Oleg, Krex, Dietmar, Lindhorst, Scott M, Lutzky, Jose, Meisel, Hans-Jörg, Nadji-Ohl, Minou, Sanchin, Lhagva, Sloan, Andrew, Taylor, Lynne P, Wu, Julian K, Dunbar, Erin M, Etame, Arnold B, Kesari, Santosh, Mathieu, David, Piccioni, David E, Baskin, David S, Lacroix, Michel, May, Sven-Axel, New, Pamela Z, Pluard, Timothy J, Toms, Steven A, Tse, Victor, Peak, Scott, Villano, John L, Battiste, James D, Mulholland, Paul J, Pearlman, Michael L, Petrecca, Kevin, Schulder, Michael, Prins, Robert M, Boynton, Alton L, and Bosch, Marnix L

Subjects
Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Prevention, Brain Disorders, Clinical Trials and Supportive Activities, Rare Diseases, Neurosciences, Clinical Research, Cancer, Brain Cancer, 6.1 Pharmaceuticals, Humans, Glioblastoma, Temozolomide, Prospective Studies, Brain Neoplasms, Recurrence, Dendritic Cells, Vaccination, Public Health and Health Services, Oncology and carcinogenesis
Abstract

ImportanceGlioblastoma is the most lethal primary brain cancer. Clinical outcomes for glioblastoma remain poor, and new treatments are needed.ObjectiveTo investigate whether adding autologous tumor lysate-loaded dendritic cell vaccine (DCVax-L) to standard of care (SOC) extends survival among patients with glioblastoma.Design, setting, and participantsThis phase 3, prospective, externally controlled nonrandomized trial compared overall survival (OS) in patients with newly diagnosed glioblastoma (nGBM) and recurrent glioblastoma (rGBM) treated with DCVax-L plus SOC vs contemporaneous matched external control patients treated with SOC. This international, multicenter trial was conducted at 94 sites in 4 countries from August 2007 to November 2015. Data analysis was conducted from October 2020 to September 2021.InterventionsThe active treatment was DCVax-L plus SOC temozolomide. The nGBM external control patients received SOC temozolomide and placebo; the rGBM external controls received approved rGBM therapies.Main outcomes and measuresThe primary and secondary end points compared overall survival (OS) in nGBM and rGBM, respectively, with contemporaneous matched external control populations from the control groups of other formal randomized clinical trials.ResultsA total of 331 patients were enrolled in the trial, with 232 randomized to the DCVax-L group and 99 to the placebo group. Median OS (mOS) for the 232 patients with nGBM receiving DCVax-L was 19.3 (95% CI, 17.5-21.3) months from randomization (22.4 months from surgery) vs 16.5 (95% CI, 16.0-17.5) months from randomization in control patients (HR = 0.80; 98% CI, 0.00-0.94; P = .002). Survival at 48 months from randomization was 15.7% vs 9.9%, and at 60 months, it was 13.0% vs 5.7%. For 64 patients with rGBM receiving DCVax-L, mOS was 13.2 (95% CI, 9.7-16.8) months from relapse vs 7.8 (95% CI, 7.2-8.2) months among control patients (HR, 0.58; 98% CI, 0.00-0.76; P

Published
2023

3. A Useful and Sustainable Role for N‐of‐1 Trials in the Healthcare Ecosystem

Author

Selker, Harry P, Cohen, Theodora, D’Agostino, Ralph B, Dere, Willard H, Ghaemi, S Nassir, Honig, Peter K, Kaitin, Kenneth I, Kaplan, Heather C, Kravitz, Richard L, Larholt, Kay, McElwee, Newell E, Oye, Kenneth A, Palm, Marisha E, Perfetto, Eleanor, Ramanathan, Chandra, Schmid, Christopher H, Seyfert‐Margolis, Vicki, Trusheim, Mark, and Eichler, Hans‐Georg

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Clinical Trials and Supportive Activities, Clinical Research, Brain Disorders, 8.4 Research design and methodologies (health services), Health and social care services research, Generic health relevance, Good Health and Well Being, Delivery of Health Care, Ecosystem, Humans, Treatment Outcome, Pharmacology and Pharmaceutical Sciences, Pharmacology & Pharmacy, Pharmacology and pharmaceutical sciences
Abstract

Clinicians and patients often try a treatment for an initial period to inform longer-term therapeutic decisions. A more rigorous approach involves N-of-1 trials. In these single-patient crossover trials, typically conducted in patients with chronic conditions, individual patients are given candidate treatments in a double-blinded, random sequence of alternating periods to determine the most effective treatment for that patient. However, to date, these trials are rarely done outside of research settings and have not been integrated into general care where they could offer substantial benefit. Designating this classical, N-of-1 trial design as type 1, there also are new and evolving uses of N-of-1 trials that we designate as type 2. In these, rather than focusing on optimizing treatment for chronic diseases when multiple approved choices are available, as is typical of type 1, a type 2 N-of-1 trial tests treatments designed specifically for a patient with a rare disease, to facilitate personalized medicine. While the aims differ, both types face the challenge of collecting individual-patient evidence using standard, trusted, widely accepted methods. To fulfill their potential for producing both clinical and research benefits, and to be available for wide use, N-of-1 trials will have to fit into the current healthcare ecosystem. This will require generalizable and accepted processes, platforms, methods, and standards. This also will require sustainable value-based arrangements among key stakeholders. In this article, we review opportunities, stakeholders, issues, and possible approaches that could support general use of N-of-1 trials and deliver benefit to patients and the healthcare enterprise. To assess and expand the benefits of N-of-1 trials, we propose multistakeholder meetings, workshops, and the generation of methods, standards, and platforms that would support wider availability and the value of N-of-1 trials.

Published
2022

4. CTNI-08. DB102-01 ENGAGE STUDY: A BIOMARKER-GUIDED, RANDOMIZED, DOUBLE-BLIND, PLACEBO-CONTROLLED, MULTI-CENTER PHASE 3 CLINICAL TRIAL OF DB102 IN PATIENTS WITH NEWLY DIAGNOSED GLIOBLASTOMA (GBM)

Author

Bota, Daniela, Butowski, Nicholas, Piccioni, David, De la Fuente, Macarena, Mao, Ying, Li, Wen-Bin, Trusheim, John, Fink, Karen, Campian, Jian, Lobbous, Mina, Portnow, Jana, Zhu, Jay-Jiguang, Pearlman, Michael, Rudnick, Jeremy, Lesser, Glen, Drappatz, Jan, Vaillant, Brian, Sun, Show-Li, and Luo, Wen

Subjects
Clinical Research, Rare Diseases, Brain Disorders, Brain Cancer, Neurosciences, Clinical Trials and Supportive Activities, Genetics, Cancer, Patient Safety, Orphan Drug, Human Genome, Evaluation of treatments and therapeutic interventions, 6.1 Pharmaceuticals, Detection, screening and diagnosis, 4.2 Evaluation of markers and technologies, Good Health and Well Being, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

Abstract: Precision medicine is vital for treating many cancers. Lack of valid biomarkers might contribute to the failure of drug therapy for GBM. The Denovo Genomic Marker 1 (DGM1), a novel pharmacogenomic biomarker, has been discovered by a genome-wide screen of patients treated with DB102 (enzastaurin) in a trial for lymphoma. Similarly, retrospective analyses showed that DB102 significantly improved outcomes in the biomarker positive GBM patients treated with DB102, regardless of MGMT promoter methylation status. The ENGAGE Study (DB102-01, NCT03776071) is a global Phase 3 clinical trial to confirm clinical benefits in patients with newly diagnosed GBM who are DGM1 biomarker positive. This is a prospective, randomized, double-blind, placebo-controlled, multi-center study. A total of 318 patients with newly diagnosed GBM will be enrolled. After screening, patients will be randomized to receive radiation therapy (RT) and temozolomide (TMZ) plus either DB102 or a matched placebo for 6 weeks in the Concurrent Phase, followed by DB102 or placebo for approximately 5 weeks in the Single-Agent Phase and then TMZ plus DB102 or placebo in the Adjuvant Phase (up to 12 cycles). Thereafter DB102 or placebo may be continued as a single agent for up to 2 years. The primary endpoint is overall survival (OS). The secondary endpoints include progression free survival (PFS), objective response rate (ORR) and drug safety. By April 2021, the safety-run-in part was completed. The study is now open for enrollment in the US and soon in Canada and China.

Published
2021

5. First results on survival from a large Phase 3 clinical trial of an autologous dendritic cell vaccine in newly diagnosed glioblastoma

Author

Liau, Linda M, Ashkan, Keyoumars, Tran, David D, Campian, Jian L, Trusheim, John E, Cobbs, Charles S, Heth, Jason A, Salacz, Michael, Taylor, Sarah, D’Andre, Stacy D, Iwamoto, Fabio M, Dropcho, Edward J, Moshel, Yaron A, Walter, Kevin A, Pillainayagam, Clement P, Aiken, Robert, Chaudhary, Rekha, Goldlust, Samuel A, Bota, Daniela A, Duic, Paul, Grewal, Jai, Elinzano, Heinrich, Toms, Steven A, Lillehei, Kevin O, Mikkelsen, Tom, Walbert, Tobias, Abram, Steven R, Brenner, Andrew J, Brem, Steven, Ewend, Matthew G, Khagi, Simon, Portnow, Jana, Kim, Lyndon J, Loudon, William G, Thompson, Reid C, Avigan, David E, Fink, Karen L, Geoffroy, Francois J, Lindhorst, Scott, Lutzky, Jose, Sloan, Andrew E, Schackert, Gabriele, Krex, Dietmar, Meisel, Hans-Jorg, Wu, Julian, Davis, Raphael P, Duma, Christopher, Etame, Arnold B, Mathieu, David, Kesari, Santosh, Piccioni, David, Westphal, Manfred, Baskin, David S, New, Pamela Z, Lacroix, Michel, May, Sven-Axel, Pluard, Timothy J, Tse, Victor, Green, Richard M, Villano, John L, Pearlman, Michael, Petrecca, Kevin, Schulder, Michael, Taylor, Lynne P, Maida, Anthony E, Prins, Robert M, Cloughesy, Timothy F, Mulholland, Paul, and Bosch, Marnix L

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Immunology, Prevention, Orphan Drug, Clinical Research, Vaccine Related, Rare Diseases, Immunization, Neurosciences, Brain Disorders, Cancer, Clinical Trials and Supportive Activities, Brain Cancer, Patient Safety, 6.1 Pharmaceuticals, Adult, Aged, Brain Neoplasms, Cancer Vaccines, Dendritic Cells, Endpoint Determination, Female, Glioblastoma, Humans, Male, Middle Aged, Prognosis, Survival Analysis, Treatment Outcome, Young Adult, Immunotherapy, Dendritic cell, Vaccine, Medical and Health Sciences, Biomedical and clinical sciences, Health sciences
Abstract

BackgroundStandard therapy for glioblastoma includes surgery, radiotherapy, and temozolomide. This Phase 3 trial evaluates the addition of an autologous tumor lysate-pulsed dendritic cell vaccine (DCVax®-L) to standard therapy for newly diagnosed glioblastoma.MethodsAfter surgery and chemoradiotherapy, patients were randomized (2:1) to receive temozolomide plus DCVax-L (n = 232) or temozolomide and placebo (n = 99). Following recurrence, all patients were allowed to receive DCVax-L, without unblinding. The primary endpoint was progression free survival (PFS); the secondary endpoint was overall survival (OS).ResultsFor the intent-to-treat (ITT) population (n = 331), median OS (mOS) was 23.1 months from surgery. Because of the cross-over trial design, nearly 90% of the ITT population received DCVax-L. For patients with methylated MGMT (n = 131), mOS was 34.7 months from surgery, with a 3-year survival of 46.4%. As of this analysis, 223 patients are ≥ 30 months past their surgery date; 67 of these (30.0%) have lived ≥ 30 months and have a Kaplan-Meier (KM)-derived mOS of 46.5 months. 182 patients are ≥ 36 months past surgery; 44 of these (24.2%) have lived ≥ 36 months and have a KM-derived mOS of 88.2 months. A population of extended survivors (n = 100) with mOS of 40.5 months, not explained by known prognostic factors, will be analyzed further. Only 2.1% of ITT patients (n = 7) had a grade 3 or 4 adverse event that was deemed at least possibly related to the vaccine. Overall adverse events with DCVax were comparable to standard therapy alone.ConclusionsAddition of DCVax-L to standard therapy is feasible and safe in glioblastoma patients, and may extend survival. Trial registration Funded by Northwest Biotherapeutics; Clinicaltrials.gov number: NCT00045968; https://clinicaltrials.gov/ct2/show/NCT00045968?term=NCT00045968&rank=1 ; initially registered 19 September 2002.

Published
2018

6. Correction to: First results on survival from a large Phase 3 clinical trial of an autologous dendritic cell vaccine in newly diagnosed glioblastoma

Author

Liau, Linda M, Ashkan, Keyoumars, Tran, David D, Campian, Jian L, Trusheim, John E, Cobbs, Charles S, Heth, Jason A, Salacz, Michael, Taylor, Sarah, D’Andre, Stacy D, Iwamoto, Fabio M, Dropcho, Edward J, Moshel, Yaron A, Walter, Kevin A, Pillainayagam, Clement P, Aiken, Robert, Chaudhary, Rekha, Goldlust, Samuel A, Bota, Daniela A, Duic, Paul, Grewal, Jai, Elinzano, Heinrich, Toms, Steven A, Lillehei, Kevin O, Mikkelsen, Tom, Walbert, Tobias, Abram, Steven R, Brenner, Andrew J, Brem, Steven, Ewend, Matthew G, Khagi, Simon, Portnow, Jana, Kim, Lyndon J, Loudon, William G, Thompson, Reid C, Avigan, David E, Fink, Karen L, Geoffroy, Francois J, Lindhorst, Scott, Lutzky, Jose, Sloan, Andrew E, Schackert, Gabriele, Krex, Dietmar, Meisel, Hans-Jorg, Wu, Julian, Davis, Raphael P, Duma, Christopher, Etame, Arnold B, Mathieu, David, Kesari, Santosh, Piccioni, David, Westphal, Manfred, Baskin, David S, New, Pamela Z, Lacroix, Michel, May, Sven-Axel, Pluard, Timothy J, Tse, Victor, Green, Richard M, Villano, John L, Pearlman, Michael, Petrecca, Kevin, Schulder, Michael, Taylor, Lynne P, Maida, Anthony E, Prins, Robert M, Cloughesy, Timothy F, Mulholland, Paul, and Bosch, Marnix L

Subjects
Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Rare Diseases, Brain Disorders, Neurosciences, Medical and Health Sciences, Immunology, Biomedical and clinical sciences, Health sciences
Abstract

Following publication of the original article [1], the authors reported an error in the spelling of one of the author names. In this Correction the incorrect and correct author names are indicated and the author name has been updated in the original publication. The authors also reported an error in the Methods section of the original article. In this Correction the incorrect and correct versions of the affected sentence are indicated. The original article has not been updated with regards to the error in the Methods section.

Published
2018

7. Correction to: First results on survival from a large Phase 3 clinical trial of an autologous dendritic cell vaccine in newly diagnosed glioblastoma.

Author

Liau, Linda M, Ashkan, Keyoumars, Tran, David D, Campian, Jian L, Trusheim, John E, Cobbs, Charles S, Heth, Jason A, Salacz, Michael, Taylor, Sarah, D'Andre, Stacy D, Iwamoto, Fabio M, Dropcho, Edward J, Moshel, Yaron A, Walter, Kevin A, Pillainayagam, Clement P, Aiken, Robert, Chaudhary, Rekha, Goldlust, Samuel A, Bota, Daniela A, Duic, Paul, Grewal, Jai, Elinzano, Heinrich, Toms, Steven A, Lillehei, Kevin O, Mikkelsen, Tom, Walbert, Tobias, Abram, Steven R, Brenner, Andrew J, Brem, Steven, Ewend, Matthew G, Khagi, Simon, Portnow, Jana, Kim, Lyndon J, Loudon, William G, Thompson, Reid C, Avigan, David E, Fink, Karen L, Geoffroy, Francois J, Lindhorst, Scott, Lutzky, Jose, Sloan, Andrew E, Schackert, Gabriele, Krex, Dietmar, Meisel, Hans-Jorg, Wu, Julian, Davis, Raphael P, Duma, Christopher, Etame, Arnold B, Mathieu, David, Kesari, Santosh, Piccioni, David, Westphal, Manfred, Baskin, David S, New, Pamela Z, Lacroix, Michel, May, Sven-Axel, Pluard, Timothy J, Tse, Victor, Green, Richard M, Villano, John L, Pearlman, Michael, Petrecca, Kevin, Schulder, Michael, Taylor, Lynne P, Maida, Anthony E, Prins, Robert M, Cloughesy, Timothy F, Mulholland, Paul, and Bosch, Marnix L

Subjects
Immunology, Medical and Health Sciences
Abstract

Following publication of the original article [1], the authors reported an error in the spelling of one of the author names. In this Correction the incorrect and correct author names are indicated and the author name has been updated in the original publication. The authors also reported an error in the Methods section of the original article. In this Correction the incorrect and correct versions of the affected sentence are indicated. The original article has not been updated with regards to the error in the Methods section.

Published
2018

8. First results on survival from a large Phase 3 clinical trial of an autologous dendritic cell vaccine in newly diagnosed glioblastoma.

Author

Liau, Linda M, Ashkan, Keyoumars, Tran, David D, Campian, Jian L, Trusheim, John E, Cobbs, Charles S, Heth, Jason A, Salacz, Michael, Taylor, Sarah, D'Andre, Stacy D, Iwamoto, Fabio M, Dropcho, Edward J, Moshel, Yaron A, Walter, Kevin A, Pillainayagam, Clement P, Aiken, Robert, Chaudhary, Rekha, Goldlust, Samuel A, Bota, Daniela A, Duic, Paul, Grewal, Jai, Elinzano, Heinrich, Toms, Steven A, Lillehei, Kevin O, Mikkelsen, Tom, Walbert, Tobias, Abram, Steven R, Brenner, Andrew J, Brem, Steven, Ewend, Matthew G, Khagi, Simon, Portnow, Jana, Kim, Lyndon J, Loudon, William G, Thompson, Reid C, Avigan, David E, Fink, Karen L, Geoffroy, Francois J, Lindhorst, Scott, Lutzky, Jose, Sloan, Andrew E, Schackert, Gabriele, Krex, Dietmar, Meisel, Hans-Jorg, Wu, Julian, Davis, Raphael P, Duma, Christopher, Etame, Arnold B, Mathieu, David, Kesari, Santosh, Piccioni, David, Westphal, Manfred, Baskin, David S, New, Pamela Z, Lacroix, Michel, May, Sven-Axel, Pluard, Timothy J, Tse, Victor, Green, Richard M, Villano, John L, Pearlman, Michael, Petrecca, Kevin, Schulder, Michael, Taylor, Lynne P, Maida, Anthony E, Prins, Robert M, Cloughesy, Timothy F, Mulholland, Paul, and Bosch, Marnix L

Subjects
Dendritic Cells, Humans, Glioblastoma, Brain Neoplasms, Cancer Vaccines, Prognosis, Treatment Outcome, Endpoint Determination, Survival Analysis, Adult, Aged, Middle Aged, Female, Male, Young Adult, Dendritic cell, Immunotherapy, Vaccine, Biotechnology, Clinical Research, Brain Disorders, Prevention, Immunization, Brain Cancer, Rare Diseases, Cancer, Patient Safety, Clinical Trials and Supportive Activities, Vaccine Related, 6.1 Pharmaceuticals, Immunology, Medical and Health Sciences
Abstract

BackgroundStandard therapy for glioblastoma includes surgery, radiotherapy, and temozolomide. This Phase 3 trial evaluates the addition of an autologous tumor lysate-pulsed dendritic cell vaccine (DCVax®-L) to standard therapy for newly diagnosed glioblastoma.MethodsAfter surgery and chemoradiotherapy, patients were randomized (2:1) to receive temozolomide plus DCVax-L (n = 232) or temozolomide and placebo (n = 99). Following recurrence, all patients were allowed to receive DCVax-L, without unblinding. The primary endpoint was progression free survival (PFS); the secondary endpoint was overall survival (OS).ResultsFor the intent-to-treat (ITT) population (n = 331), median OS (mOS) was 23.1 months from surgery. Because of the cross-over trial design, nearly 90% of the ITT population received DCVax-L. For patients with methylated MGMT (n = 131), mOS was 34.7 months from surgery, with a 3-year survival of 46.4%. As of this analysis, 223 patients are ≥ 30 months past their surgery date; 67 of these (30.0%) have lived ≥ 30 months and have a Kaplan-Meier (KM)-derived mOS of 46.5 months. 182 patients are ≥ 36 months past surgery; 44 of these (24.2%) have lived ≥ 36 months and have a KM-derived mOS of 88.2 months. A population of extended survivors (n = 100) with mOS of 40.5 months, not explained by known prognostic factors, will be analyzed further. Only 2.1% of ITT patients (n = 7) had a grade 3 or 4 adverse event that was deemed at least possibly related to the vaccine. Overall adverse events with DCVax were comparable to standard therapy alone.ConclusionsAddition of DCVax-L to standard therapy is feasible and safe in glioblastoma patients, and may extend survival. Trial registration Funded by Northwest Biotherapeutics; Clinicaltrials.gov number: NCT00045968; https://clinicaltrials.gov/ct2/show/NCT00045968?term=NCT00045968&rank=1 ; initially registered 19 September 2002.

Published
2018

9. Rindopepimut with temozolomide for patients with newly diagnosed, EGFRvIII-expressing glioblastoma (ACT IV): a randomised, double-blind, international phase 3 trial

Author

Weller, Michael, Butowski, Nicholas, Tran, David D, Recht, Lawrence D, Lim, Michael, Hirte, Hal, Ashby, Lynn, Mechtler, Laszlo, Goldlust, Samuel A, Iwamoto, Fabio, Drappatz, Jan, O'Rourke, Donald M, Wong, Mark, Hamilton, Mark G, Finocchiaro, Gaetano, Perry, James, Wick, Wolfgang, Green, Jennifer, He, Yi, Turner, Christopher D, Yellin, Michael J, Keler, Tibor, Davis, Thomas A, Stupp, Roger, Sampson, John H, investigators, ACT IV trial, Campian, Jian, Recht, Lawrence, Goldlust, Samuel, Becker, Kevin, Barnett, Gene, Nicholas, Garth, Desjardins, Annick, Benkers, Tara, Wagle, Naveed, Groves, Morris, Kesari, Santosh, Horvath, Zsolt, Merrell, Ryan, Curry, Richard, O'Rourke, James, Schuster, David, Mrugala, Maciej, Jensen, Randy, Trusheim, John, Lesser, Glenn, Belanger, Karl, Sloan, Andrew, Purow, Benjamin, Fink, Karen, Raizer, Jeffrey, Schulder, Michael, Nair, Suresh, Peak, Scott, Brandes, Alba, Mohile, Nimish, Landolfi, Joseph, Olson, Jon, Jennens, Ross, DeSouza, Paul, Robinson, Bridget, Crittenden, Marka, Shih, Kent, Flowers, Alexandra, Ong, Shirley, Connelly, Jennifer, Hadjipanayis, Costas, Giglio, Pierre, Mott, Frank, Mathieu, David, Lessard, Nathalie, Sepulveda, Sanchez Juan, Lövey, József, Wheeler, Helen, Inglis, Po-Ling, Hardie, Claire, Bota, Daniela, Lesniak, Maciej, Portnow, Jana, Frankel, Bruce, Junck, Larry, Thompson, Reid, Berk, Lawrence, McGhie, John, Macdonald, David, Saran, Frank, Soffietti, Riccardo, Blumenthal, Deborah, and de, Sá Barreto Costa Marcos André

Subjects
Brain Disorders, Rare Diseases, Clinical Research, Cancer, Clinical Trials and Supportive Activities, Neurosciences, Brain Cancer, 6.1 Pharmaceuticals, Evaluation of treatments and therapeutic interventions, Adult, Aged, Antineoplastic Combined Chemotherapy Protocols, Brain Neoplasms, Cancer Vaccines, Dacarbazine, Disease-Free Survival, Dose-Response Relationship, Drug, Double-Blind Method, Drug Administration Schedule, ErbB Receptors, Female, Follow-Up Studies, Gene Expression Regulation, Neoplastic, Glioblastoma, Humans, Internationality, Kaplan-Meier Estimate, Male, Middle Aged, Patient Selection, Proportional Hazards Models, Survival Analysis, Temozolomide, Time Factors, Treatment Outcome, Vaccines, Subunit, Young Adult, ACT IV trial investigators, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

BackgroundRindopepimut (also known as CDX-110), a vaccine targeting the EGFR deletion mutation EGFRvIII, consists of an EGFRvIII-specific peptide conjugated to keyhole limpet haemocyanin. In the ACT IV study, we aimed to assess whether or not the addition of rindopepimut to standard chemotherapy is able to improve survival in patients with EGFRvIII-positive glioblastoma.MethodsIn this randomised, double-blind, phase 3 trial, we recruited patients aged 18 years and older with glioblastoma from 165 hospitals in 22 countries. Eligible patients had newly diagnosed glioblastoma confirmed to express EGFRvIII by central analysis, and had undergone maximal surgical resection and completion of standard chemoradiation without progression. Patients were stratified by European Organisation for Research and Treatment of Cancer recursive partitioning analysis class, MGMT promoter methylation, and geographical region, and randomly assigned (1:1) with a prespecified randomisation sequence (block size of four) to receive rindopepimut (500 μg admixed with 150 μg GM-CSF) or control (100 μg keyhole limpet haemocyanin) via monthly intradermal injection until progression or intolerance, concurrent with standard oral temozolomide (150-200 mg/m2 for 5 of 28 days) for 6-12 cycles or longer. Patients, investigators, and the trial funder were masked to treatment allocation. The primary endpoint was overall survival in patients with minimal residual disease (MRD; enhancing tumour

Published
2017

10. A state-of-the-art review and guidelines for tumor treating fields treatment planning and patient follow-up in glioblastoma

Author

Trusheim, John, Dunbar, Erin, Battiste, James, Iwamoto, Fabio, Mohile, Nimish, Damek, Denise, Bota, Daniela A, and Connelly, Jennifer

Subjects
Brain Disorders, Rare Diseases, Cancer, Neurosciences, Brain Cancer, Patient Safety, Good Health and Well Being, Algorithms, Antineoplastic Agents, Alkylating, Brain Neoplasms, Combined Modality Therapy, Dacarbazine, Female, Follow-Up Studies, Glioblastoma, Humans, Magnetic Field Therapy, Magnetic Resonance Imaging, Male, Practice Guidelines as Topic, Temozolomide, NovoTAL, TTFields, alternating electric fields, glioblastoma, guidelines, response assessment, treatment planning, tumor treating fields
Abstract

Tumor treating fields (TTFields) are an integral treatment modality in the management of glioblastoma and extend overall survival when combined with maintenance temozolomide in newly diagnosed patients. Complexities exist regarding correct selection of imaging sequences with which to perform TTFields treatment planning. Guidelines are warranted first, to facilitate treatment planning standardization across medical disciplines and institutions, to ensure optimal TTFields delivery to the tumor and peritumoral brain zone while maximizing patient safety, and also to mitigate the risk of premature cessation of a potentially beneficial treatment. This summary guideline outlines methods for starting patients on TTFields, for monitoring patient response to therapy and provides a framework for evaluating when therapy should be re-planned, based on the extent of sequential imaging changes.

Published
2017

11. A state-of-the-art review and guidelines for tumor treating fields treatment planning and patient follow-up in glioblastoma.

Author

Trusheim, John, Dunbar, Erin, Battiste, James, Iwamoto, Fabio, Mohile, Nimish, Damek, Denise, Bota, Daniela A, and Connelly, Jennifer

Subjects
Humans, Glioblastoma, Brain Neoplasms, Dacarbazine, Antineoplastic Agents, Alkylating, Magnetic Resonance Imaging, Combined Modality Therapy, Follow-Up Studies, Algorithms, Female, Male, Practice Guidelines as Topic, Magnetic Field Therapy, NovoTAL, TTFields, alternating electric fields, glioblastoma, guidelines, response assessment, treatment planning, tumor treating fields, Temozolomide
Abstract

Tumor treating fields (TTFields) are an integral treatment modality in the management of glioblastoma and extend overall survival when combined with maintenance temozolomide in newly diagnosed patients. Complexities exist regarding correct selection of imaging sequences with which to perform TTFields treatment planning. Guidelines are warranted first, to facilitate treatment planning standardization across medical disciplines and institutions, to ensure optimal TTFields delivery to the tumor and peritumoral brain zone while maximizing patient safety, and also to mitigate the risk of premature cessation of a potentially beneficial treatment. This summary guideline outlines methods for starting patients on TTFields, for monitoring patient response to therapy and provides a framework for evaluating when therapy should be re-planned, based on the extent of sequential imaging changes.

Published
2017

12. PIPELINEs: Creating Comparable Clinical Knowledge Efficiently by Linking Trial Platforms

Author

Trusheim, Shrier, AA, Antonijevic, Z, Beckman, RA, Campbell, RK, Chen, C, Flaherty, KT, Loewy, J, Lacombe, D, Madhavan, S, Selker, HP, and Esserman, LJ

Subjects
Clinical Trials and Supportive Activities, Clinical Research, Generic health relevance, Clinical Trials as Topic, Cooperative Behavior, Endpoint Determination, Humans, Patient Selection, Reimbursement Mechanisms, Research Design, Time Factors, Translational Research, Biomedical, Pharmacology and Pharmaceutical Sciences, Pharmacology & Pharmacy
Abstract

Adaptive, seamless, multisponsor, multitherapy clinical trial designs executed as large scale platforms, could create superior evidence more efficiently than single-sponsor, single-drug trials. These trial PIPELINEs also could diminish barriers to trial participation, increase the representation of real-world populations, and create systematic evidence development for learning throughout a therapeutic life cycle, to continually refine its use. Comparable evidence could arise from multiarm design, shared comparator arms, and standardized endpoints-aiding sponsors in demonstrating the distinct value of their innovative medicines; facilitating providers and patients in selecting the most appropriate treatments; assisting regulators in efficacy and safety determinations; helping payers make coverage and reimbursement decisions; and spurring scientists with translational insights. Reduced trial times and costs could enable more indications, reduced development cycle times, and improved system financial sustainability. Challenges to overcome range from statistical to operational to collaborative governance and data exchange.

Published
2016

13. PIPELINEs: Creating Comparable Clinical Knowledge Efficiently by Linking Trial Platforms.

Author

Trusheim, MR, Shrier, AA, Antonijevic, Z, Beckman, RA, Campbell, RK, Chen, C, Flaherty, KT, Loewy, J, Lacombe, D, Madhavan, S, Selker, HP, and Esserman, LJ

Subjects
Humans, Endpoint Determination, Cooperative Behavior, Research Design, Patient Selection, Time Factors, Reimbursement Mechanisms, Clinical Trials as Topic, Translational Medical Research, Pharmacology & Pharmacy, Pharmacology and Pharmaceutical Sciences
Abstract

Adaptive, seamless, multisponsor, multitherapy clinical trial designs executed as large scale platforms, could create superior evidence more efficiently than single-sponsor, single-drug trials. These trial PIPELINEs also could diminish barriers to trial participation, increase the representation of real-world populations, and create systematic evidence development for learning throughout a therapeutic life cycle, to continually refine its use. Comparable evidence could arise from multiarm design, shared comparator arms, and standardized endpoints-aiding sponsors in demonstrating the distinct value of their innovative medicines; facilitating providers and patients in selecting the most appropriate treatments; assisting regulators in efficacy and safety determinations; helping payers make coverage and reimbursement decisions; and spurring scientists with translational insights. Reduced trial times and costs could enable more indications, reduced development cycle times, and improved system financial sustainability. Challenges to overcome range from statistical to operational to collaborative governance and data exchange.

Published
2016

Catalog

Books, media, physical & digital resources
See catalog results