The effect of pembrolizumab in combination with CD19-targeted chimeric antigen receptor (CAR) T cells in relapsed acute lymphoblastic leukemia (ALL).

2017 ◽  
Vol 35 (15_suppl) ◽  
pp. 103-103 ◽  
Author(s):  
Shannon L. Maude ◽  
George E Hucks ◽  
Alix Eden Seif ◽  
Mala Kiran Talekar ◽  
David T. Teachey ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Expansion ◽  
Lymphoblastic Leukemia ◽  
Prior History ◽  
Cell Detection ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion

103 Background: CD19-targeted CAR T cells show CR rates of 70-95% in B-ALL. Yet a subset of patients do not respond or relapse due to poor CAR T cell expansion and persistence. We hypothesized that PD-1 checkpoint pathway inhibition may improve CAR T cell expansion, function and persistence. Methods: Four children with relapsed B-ALL treated with murine (CTL019) or humanized (CTL119) anti-CD19 CAR T cells received 1-3 doses of the PD-1 inhibitor pembrolizumab (PEM) for partial/no response or prior history of poor CAR T cell persistence starting 14d-2mo post CAR T cell infusion. Results: PEM increased and/or prolonged detection of circulating CAR T cells in all 4 children, with objective responses in 2/4. It was well tolerated, with fever in 2 pts and no autoimmune toxicity. Pts 1-3 received CTL119 for CD19+ relapse after prior murine CD19 CAR T cells. Pt 1 had 1.2% CD19+ residual disease despite expansion with detectable CTL119 by D28 and received PEM at 2mo for progressive disease with decreasing circulating CTL119. CTL119 became detectable at 0.2% of CD3+ cells by flow cytometry, but disease progressed. Pt 2 had no response after initial CTL119 expansion with a rapid disappearance by D28. After CTL119 reinfusion with PEM added 14d later, circulating CAR T cells remained detectable at 4.4% by D28, but disease progressed with decreased CD19 expression. In Pt 3, prior treatment with both CTL019 and CTL119 produced CR with poor CAR T cell persistence followed by CD19+ relapse. CTL119 reinfusion combined with PEM at D14 resulted in CR with prolonged CTL119 persistence (detectable at D50 compared to loss by D36 after 1st CTL119 infusion). Pt 4 received PEM for widespread extramedullary (EM) involvement at D28 post CTL019 infusion despite marrow remission. Initial CTL019 expansion peaked at 63% at D10 and fell to 20% at D28. Resurgence of CTL019 expansion, with a 2nd peak of 70% 11d after PEM, was associated with dramatic reduction in PET-avid disease by 3mo post CTL019. Conclusions: PEM was safely combined with CAR T cells and increased or prolonged CAR T cell detection, with objective responses seen. Immune checkpoint pathways may impact response to CAR T cell treatments and warrant further investigation. Clinical trial information: NCT02374333, NCT02906371.

Characterization of HLH-Like Manifestations as a CRS Variant in Patients Receiving CD22 CAR T-Cells

Blood ◽  
2021 ◽  
Author(s):  
Daniel A Lichtenstein ◽  
Fiorella Schischlik ◽  
Lipei Shao ◽  
Seth M Steinberg ◽  
Bonnie Yates ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Expansion ◽  
Nk Cell ◽  
Severe Neutropenia ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion

CAR T-cell toxicities resembling hemophagocytic lymphohistiocytosis (HLH) occur in a subset of patients with cytokine release syndrome (CRS). As a variant of conventional CRS, a comprehensive characterization of CAR T-cell associated HLH (carHLH) and investigations into associated risk factors are lacking. In the context of 59 patients infused with CD22 CAR T-cells where a substantial proportion developed carHLH, we comprehensively describe the manifestations and timing of carHLH as a CRS variant and explore factors associated with this clinical profile. Amongst 52 subjects with CRS, 21 (40.4%) developed carHLH. Clinical features of carHLH included hyperferritinemia, hypertriglyceridemia, hypofibrinogenemia, coagulopathy, hepatic transaminitis, hyperbilirubinemia, severe neutropenia, elevated lactate dehydrogenase and occasionally hemophagocytosis. Development of carHLH was associated with pre-infusion NK-cell lymphopenia and higher bone marrow T/NK-cell ratio, which was further amplified with CAR T-cell expansion. Following CRS, more robust CAR T-cell and CD8 T-cell expansion in concert with pronounced NK-cell lymphopenia amplified pre-infusion differences in those with carHLH without evidence for defects in NK-cell mediated cytotoxicity. CarHLH was further characterized by persistent elevation of HLH-associated inflammatory cytokines, which contrasted with declining levels in those without carHLH. In the setting of CAR T-cell mediated expansion, clinical manifestations and immunophenotypic profiling in those with carHLH overlap with features of secondary HLH, prompting consideration of an alternative framework for identification and management of this toxicity profile to optimize outcomes following CAR T-cell infusion.

Effect of chimeric antigen receptor-modified T (CAR-T) cells on responses in children with non-CNS extramedullary relapse of CD19+ acute lymphoblastic leukemia (ALL).

2017 ◽  
Vol 35 (15_suppl) ◽  
pp. 10507-10507 ◽  
Author(s):  
Mala Kiran Talekar ◽  
Shannon L. Maude ◽  
George E Hucks ◽  
Laura S Motley ◽  
Colleen Callahan ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Lymphoblastic Leukemia ◽  
Phase 1 ◽  
Single Agent ◽  
Prior History ◽  
Hematopoietic Stem ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

10507 Background: Anti-CD19 CAR-T cell therapies have shown high efficacy in inducing durable marrow responses in patients with relapsed/refractory CD19+ ALL. We now report on outcome of 10 patients with extramedullary (EM) involvement of ALL treated with CAR-T, including 5 patients who had EM disease at time of infusion. Methods: We identified patients treated on pediatric phase 1/2a trials of murine (CTL019) or humanized (CTL119) anti-CD19 CAR-T cells for isolated EM or BM/EM relapse of ALL. EM relapse was defined as involvement of non-CNS site by imaging +/- pathology within 12 months (mos) of infusion. Post infusion, patients had diagnostic imaging done at 1, 3, 6, 9, and 12 mos. Results: Among 97 patients receiving CAR-T, ten (CTL019, n=6; CTL119, n=4) were identified who had EM involvement on average 2.3 mos (range 0-9 mos) prior to infusion; including 5/10 at time of infusion. Sites of EM relapses included testes, sinus, parotid, bone, uterus, kidney and skin, and 5 patients had multiple sites of EM involvement. Patients ranged from 2-4 relapses of their ALL pre-CAR-T. Two had isolated EM relapse (sites were parotid and multifocal bony lesions in one; testis and sinus in second). All 10 patients had undergone hematopoietic stem cell transplantation prior to EM relapse, 2 had received radiation directed to the EM site prior to CAR-T. Five patients evaluated by serial imaging had objective responses: 2 had resolution of EM disease by day 28; 2 had resolution by 3 mos; 1 had continued decrease in size of uterine mass at 3 and 6 mos and underwent hysterectomy at 8 mos with no evidence of disease on pathology. In the 4 patients with prior history of skin or testicular involvement, there was no evidence by exam at day 28. One patient had progressive EM disease within 2 weeks of CAR-T cell infusion and died at 6 weeks. Three relapsed with CD19+ disease [1 skin/medullary- died at 38 mos post CAR-T; 2 medullary (1 died at 17 mos, 1 alive at 28 mos)]. The remaining 6 are alive and well at median follow-up of 10 mos (range 3-16 mos) without recurrence of disease. Conclusions: Single agent CAR-T immunotherapy can induce potent and durable responses in patients with EM relapse of their ALL. Clinical trial information: NCT01626495, NCT02374333.

scholarly journals Addition of Fludarabine to Cyclophosphamide Lymphodepletion Improves In Vivo Expansion of CD19 Chimeric Antigen Receptor-Modified T Cells and Clinical Outcome in Adults with B Cell Acute Lymphoblastic Leukemia

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 3773-3773 ◽  
Author(s):  
Cameron J Turtle ◽  
Laila-Aicha Hanafi ◽  
Carolina Berger ◽  
Daniel Sommermeyer ◽  
Barbara Pender ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Expansion ◽  
Research Funding ◽  
Car T Cells ◽  
Cell Dose ◽  
Car T Cell ◽  
Car T ◽  
Ifn Γ ◽  
T Cell Expansion

Abstract BACKGROUND: Chemotherapy followed by autologous T cells that are genetically modified to express a CD19-specific chimeric antigen receptor (CAR) has shown promise as a novel therapy for patients with relapsed or refractory B cell acute lymphoblastic leukemia (B-ALL); however, the risk of severe cytokine release syndrome (sCRS) and neurotoxicity has tempered enthusiasm for widespread application of this approach. The functional heterogeneity that is inherent in CAR-T cell products that are manufactured from undefined T cell subsets has hindered definition of dose-response relationships and identification of factors that may impact efficacy and toxicity. METHODS: We are conducting the first clinical trial that administers CD19 CAR-T cells manufactured from a defined composition of T cell subsets to adults with relapsed or refractory B-ALL. CD8+ and CD4+ T cells were enriched from each patient, transduced with a CD19 CAR lentivirus and separately expanded in vitro before formulation for infusion in a 1:1 ratio of CD8+:CD4+ CAR+ T cells at 2x105, 2x106 or 2x107 CAR-T cells/kg. Prior to CAR-T cell infusion, patients underwent lymphodepletion with a high-dose cyclophosphamide (Cy)-based regimen with or without fludarabine (Flu). RESULTS: Twenty-nine adults with B-ALL (median age 40, range 22 - 73 years; median 17% marrow blasts, range 0 - 97%), including 10 patients who had relapsed after allogeneic transplantation, received at least one CAR-T cell infusion. Twenty-four of 26 restaged patients (92%) achieved bone marrow (BM) complete remission (CR) by flow cytometry. CD4+ and CD8+ CAR-T cells expanded in vivo after infusion and their number in blood correlated with the infused CAR-T cell dose. Thirteen patients received lymphodepletion with Cy-based regimens without Flu. Ten of 12 restaged patients (83%) achieved BM CR by flow cytometry; however, 7 of these (70%) relapsed a median of 66 days after CAR-T cell infusion. Disease relapse correlated with a loss of CAR-T cell persistence in blood. We observed a CD8 cytotoxic T cell response to the murine scFv component of the CAR transgene that contributed to CAR-T cell rejection, and resulted in lack of CAR-T cell expansion after a second CAR-T cell infusion in 5 patients treated for persistent or relapsed disease. To minimize immune-mediated CAR-T cell rejection 14 patients were treated with Cy followed by Flu lymphodepletion (Cy/Flu, Cy 60 mg/kg x 1 and Flu 25 mg/m2 x 3-5) before CAR-T cell infusion. All patients (100%) who received Cy/Flu lymphodepletion achieved BM CR after CAR-T cell infusion. CAR-T cell expansion and persistence in blood was higher in Cy/Flu-lymphodepleted patients compared to their counterparts who received Cy alone (Day 28 after 2x106 CAR-T cells/kg: CD8+ CAR-T cells, mean 55.8/μL vs 0.10/μL, p<0.01; CD4+ CAR-T cells, 2.1/μL vs 0.02/μL, p<0.01), enabling reduction in CAR-T cell dose for Cy/Flu-treated patients. Patients who received Cy/Flu lymphodepletion appear to have longer disease-free survival (DFS) than those who received Cy alone (Cy/Flu, median, not reached; Cy alone, 150 days, p=0.09). CAR-T cell infusion was associated with sCRS, characterized by fever and hypotension requiring intensive care in 7 of 27 patients (26%) and neurotoxicity (≥ grade 3 CTCAE v4.03) in 13 of 27 patients (48%). Two patients died following complications of sCRS. Patients with sCRS or neurotoxicity had higher peak serum levels of IL-6, IFN-γ, ferritin and C-reactive protein compared to those without serious toxicity. Importantly IL-6, IFN-γ and TNF-α levels in serum collected on day 1 after CAR-T cell infusion from those who subsequently developed neurotoxicity were higher than those collected from their counterparts who did not develop neurotoxicity (IL-6, p<0.01; IFN-γ, p=0.05; TNF-α, p=0.04), providing potential biomarkers to test early intervention strategies to prevent neurotoxicity. The risks of sCRS and neurotoxicity correlated with higher leukemic marrow infiltration and increasing CAR-T cell dose. We have now adopted a risk-stratified approach to CAR-T cell dosing in which the CAR-T cell dose inversely correlates to the patient's bone marrow tumor burden. CONCLUSION: Risk-stratified dosing of CD19 CAR-T cells of defined subset composition is feasible and safe in a majority of patients with refractory B-ALL, and results in a CR rate of 92%. Addition of Flu to Cy-based lymphodepletion improves CAR-T cell expansion, persistence and DFS. Disclosures Turtle: Juno Therapeutics: Patents & Royalties, Research Funding. Berger:Juno Therapeutics: Patents & Royalties. Jensen:Juno Therapeutics: Equity Ownership, Patents & Royalties, Research Funding. Riddell:Adaptive Biotechnologies: Consultancy; Juno Therapeutics: Equity Ownership, Patents & Royalties, Research Funding; Cell Medica: Membership on an entity's Board of Directors or advisory committees. Maloney:Seattle Genetics: Honoraria; Janssen Scientific Affairs: Honoraria; Roche/Genentech: Honoraria; Juno Therapeutics: Research Funding.

scholarly journals Antigen-specific stimulation and expansion of CAR-T cells using membrane vesicles as target cell surrogates

2021 ◽  
Author(s):  
Valeria M. Ukrainskaya ◽  
Yuri P. Rubtsov ◽  
Dmitry S. Pershin ◽  
Nadezhda A. Podoplelova ◽  
Stanislav S. Terekhov ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Lines ◽  
Cell Expansion ◽  
Membrane Vesicles ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion ◽  
Specific Stimulation

Development of CAR-T therapy led to immediate success in the treatment of B cell leukemia and lymphoma. It also raised an opportunity to design new protocols to target solid tumors. Manufacturing of therapy-competent functional CAR-T cells needs robust protocols for ex vivo/in vitro expansion of modified T-cells. This step is challenging, especially if non-viral low efficiency delivery protocols are used to generate CAR-T cells. Modern protocols for CAR-T cell expansion are based on incubation with high doses of recombinant cytokines to support proliferation, non-specific stimulation with surface-bound antibodies to induce TCR cross-linking, or co-cultivation with antigen-expressing feeder cell lines. These approaches are imperfect since non-specific stimulation results in rapid outgrowth of CAR-negative T cells, and removal of feeder cells from mixed cultures necessitates additional purification steps. In an effort to develop a specific and improved protocol for CAR-T cell expansion, we took advantage of cell-derived membrane vesicles, and the simple structural demands of the CAR-antigen interaction. Our approach was to make antigenic microcytospheres from common cell lines stably expressing surface-bound CAR antigens (antigenic vesicles, AVs), and then use them for stimulation and expansion of CAR-T cells. We developed a rapid, simple, efficient, and inexpensive protocol to generate, stabilize and purify AVs. As proof-of-concept we tested the efficacy of our AV constructs on several CAR-antigen pairs. The data presented in this article clearly demonstrate that our protocol produced AVs with the capacity to induce stronger stimulation, proliferation and functional activity of CAR-T cells than is possible with existing protocols. We predict that this new methodology will significantly improve the ability to obtain improved populations of functional CAR-T cells for therapy.

scholarly journals Tisagenlecleucel and Axicabtagene Ciloleucel Expansion Kinetics and CAR T Cell Attributes in the Infusion Products Are Early Predictors of Clinical Efficacy

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 3877-3877
Author(s):  
Cristiana Carniti ◽  
Chiara Monfrini ◽  
Vanessa Aragona ◽  
Martina Magni ◽  
Cristina Vella ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Cell Expansion ◽  
B Cell Lymphoma ◽  
Advisory Board ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion

Abstract Background: CD19-directed CAR-T cell therapy has shown promising efficacy in relapsed/refractory (R/R) B-cell malignancies in clinical trials resulting in the approval and commercialization of two products (tisagenlecleucel/Tisa-cel and axicabtagene ciloleucel/Axi-cel) for R/R diffuse large B cell lymphoma (DLBCL) and primary mediastinal large B cell lymphoma (PMBCL). However, relapses occur in 60-65% of patients (pts) and thus a better understanding of the early determinants of response is critical to improve long-term survival in the real-world scenario. Aims of the study: To assess whether CAR-T cell expansion after infusion represents a crucial determinant to sustain effective anti-tumor responses to both Tisa-cel and Axi-celTo evaluate differences in CAR-T cell kinetics due to the use of CD28 or 4-1BB costimulatory moleculesTo identify immune phenotypic features of infusion products accounting for CAR-T cell expansion and survival probability Methods: We analyzed samples from 43 pts [29 DLBCL, 8 high grade B-cell lymphoma (HGBCL) and 6 PMBCL] treated with Axi-cel (n=22) and Tisa-cel (n=21) at the Fondazione IRCCS Istituto Nazionale Tumori prospectively collected between November 2019 and April 2021. CAR-T cells were monitored in the peripheral blood (PB) on days 0, 4, 7, 10, 14, 21, 28 and monthly post infusion by flow cytometry (FCM). Cells were stained with CD19 CAR Detection Reagent (Miltenyi), CD3, CD4, CD8, CD45, CD14, CD45RO, CD62L, CD197, CD279, CD223 and CD366. Residual cells obtained from washings of 32 infused commercial CAR-T bags (10 Tisa-cel and 22 Axi-cel) were also analyzed by FCM. Data were acquired on a BD FACSCanto II (BD Biosciences) and a MACSQuant® Analyzer MQ10 (Miltenyi) and analyzed using FlowJo software, version 10. Results: The median time to maximal expansion of CAR-T cells was at day 10 post infusion with no differences between Axi-cel and Tisa-cel [median concentration at day 10 (C 10) 25 for Axi-cel vs 26 CAR-T cells/µl for Tisa-cel; p, ns], nor among the different histologies (median C 10 33 for DLBCL vs 19 for HGBCL vs 18 CAR-T cells/µl for PMBCL; p, ns). On the contrary, CAR-T peak concentration (C max) was higher in responders at 3 months post infusion (RE, n=28) (defined as pts achieving complete or partial response by PET/CT) than in non responders (NR, n=13) (median C max 87 in RE vs 26 in NR CAR-T cells/µl; p&lt;0.01; Fig 1A). Consistently, the magnitude of CAR-T cell expansion in the first 30 days was higher in RE than in NR [median area under the curve (AUC 0-30) 189 vs 50; p&lt;0.005; Fig 1B]. Circulating CAR-T cells were enriched in subpopulations representing naïve T cells (CD8+ T N; CD45RO−/CD62L+) in RE (median 0.4% in RE vs 0.04% in NR, p&lt;0.05) while NR had significantly higher levels of effector memory T cells (CD8+ T EM; CD45RO+/CD62L+) (median 26.5% in RE vs 66.2% in NR, p&lt;0.05). Additionally, the extent of CAR-T cell expansion predicted the progression free survival (PFS), but not the overall survival (OS), irrespective of the product used (Fig 2, p&lt;0.05) and the overall survival was improved by salvage treatment with bispecifc antibodies. Finally, we evaluated whether CAR-T cell expansion was influenced by the immune phenotypic attributes of the infused products. A significant enrichment of central memory populations (CD8+ T CM; CD45RO−/CCR7+/CD62L+) among CAR-T cells within the infusion products of pts with longer PFS was documented, as compared with those with shorter PFS (CD8+ T CM; median 15.2% vs 3.1%; p&lt;0.005). Conclusion: To the best of our knowledge, this is the first study assessing the clinical utility of early CAR-T cell monitoring in lymphoma pts receiving both commercial anti-CD19 CAR-T cell therapies. We provide evidence that in pts treated with Axi-cel and Tisa-cel: i) the in vivo kinetics of the CAR-T cell products are similar, consistent with the fact that no differences in the outcome of Axi-cel and Tisa-cel treated pts were detected; ii) CAR-T cell expansion is critical for efficacy and predicts the PFS; iii) circulating CAR-T cells in responders have a naïve phenotype; iv) a memory signature in the CAR-T cell product before infusion is associated with in vivo expansion and survival. Figure 1 Figure 1. Disclosures Chiappella: Celgene Bristol Myers Squibb: Other: lecture fee, advisory board; Incyte: Other: lecture fee; Novartis: Other: lecture fee; Astrazeneca: Other: lecture fee; Servier: Other: lecture fee; Takeda: Other: advisory board; Gilead Sciences: Other: lecture fee, advisory board; Clinigen: Other: lecture fee, advisory board; Roche: Other: lecture fee, advisory board; Janssen: Other: lecture fee, advisory board. Corradini: AbbVie, ADC Theraputics, Amgen, Celgene, Daiichi Sankyo, Gilead/Kite, GSK, Incyte, Janssen, KyowaKirin, Nerviano Medical Science, Novartis, Roche, Sanofi, Takeda: Consultancy; AbbVie, ADC Theraputics, Amgen, Celgene, Daiichi Sankyo, Gilead/Kite, GSK, Incyte, Janssen, KyowaKirin, Nerviano Medical Science, Novartis, Roche, Sanofi, Takeda: Honoraria; KiowaKirin; Incyte; Daiichi Sankyo; Janssen; F. Hoffman-La Roche; Kite; Servier: Consultancy; Novartis; Gilead; Celgene: Consultancy, Other: Travel and accommodations; BMS: Other: Travel and accommodation; Sanofi: Consultancy, Honoraria; Amgen; Takeda; AbbVie: Consultancy, Honoraria, Other: Travel and accommodations; Incyte: Consultancy; Novartis, Janssen, Celgene, BMS, Takeda, Gilead/Kite, Amgen, AbbVie: Other: travel and accomodations.

Creation of the First Non-Human Primate Model That Faithfully Recapitulates Chimeric Antigen Receptor (CAR) T Cell-Mediated Cytokine Release Syndrome (CRS) and Neurologic Toxicity Following B Cell-Directed CAR-T Cell Therapy

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 651-651 ◽  
Author(s):  
Agne Taraseviciute ◽  
Leslie Kean ◽  
Michael C Jensen
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
B Cell ◽  
Cell Expansion ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion

Abstract The advent ofadoptive T-cell therapy using CD19 Chimeric Antigen Receptor (CAR) T cells has revolutionized the treatment of relapsed and refractory acute lymphoblastic leukemia (ALL). CAR T cells have shown encouraging results in clinical trials, with complete remissions in 90% of patients with refractory B-cell ALL. However, CD19 CAR T cell therapy is associated with significant side effects, including cytokine release syndrome (CRS), encompassing fevers, myalgias, hypotension, respiratory distress, coagulopathy as well as neurologic toxicity, ranging from headaches to hallucinations, aphasia, seizures and fatal cerebral edema. Our understanding of CRS and neurologic toxicity has been significantly limited by the lack of animal models that faithfully recapitulate these symptoms. We chose the non-human primate (NHP), Macaca mulatta, given that it closely recapitulates the human immune system, to create an animal model of B-cell-directed CAR T cell therapy targeting CD20. Rhesus macaques (n=3) were treated with 30-40mg/kg cyclophosphamide followed 3-6 days later by an infusion of CAR T cells at a dose of 1x107 transduced cells/kg. Recipient animals were monitored for clinical signs and symptoms of CRS and neurotoxicity, and data were collected longitudinally to determine CAR T cell expansion and persistence, B cell aplasia, as well as clinical labs of CRS and cytokine levels. Prior to testing the CD20 CAR T cells, we performed a control experiment, in which 1x107/kg control T cells, transduced to express GFP only (without a CAR construct), were infused following cyclophosphamide conditioning. This infusion resulted in short-lived persistence of the adoptive cellular therapy, with disappearance of the cells from the peripheral blood by Day +14 (Figure 1, green traces) and no clinical signs of CRS (Figure 2) or neurologic toxicities. In contrast, recipients of 1x107 cells/kg CD20 CAR-expressing T cells (n = 3) demonstrated significant expansion of the CAR T cells, and persistence for as long as 43days post-infusion, which corresponded to concurrent B cell aplasia (Figure 1). These recipients also developed clinical signs and symptoms of CRS as well as neurologic toxicity which was manifested by behavioral abnormalities and extremity tremors, beginning between days 5 to 7 following CAR T cell infusion, with the onset of clinical symptoms coinciding with maximum CAR T cell expansion and activation. The neurologic symptoms were responsive to treatment with the anti-epileptic medicationlevetiracetam. The clinical syndrome was accompanied by elevations in CRP, Ferritin, LDH and serum cytokines, including IL-6, IL-8 and ITAC (Figure 2 A and B), recapitulating data from clinical trials using CD19 CAR T cells. An expansion of CD20 CAR T cells on day 7 following infusion was also observed in the CSF in the animals, and coincided with the onset of neurotoxicity. Strikingly, we also detected CD20 CAR T cells in multiple regions of the brain via flow cytometry, including the frontal, parietal, and occipital lobes, as well as the cerebellum, and demonstrated an increased number of infiltrating T cells by immunofluorescence in the brains of animals treated with CD20 CAR T cells when compared to healthy controls. These data demonstrate the successful establishment of a large animal model of B-cell directed CAR T cell therapy that recapitulates the most significant toxicities of CAR T cell therapy, including CRS and neurotoxicity. This model will permit a detailed interrogation of the mechanisms driving these toxicities as well as the pre-clinical evaluation of therapies designed to prevent or abort them after CAR T cell infusion. Figure 1. Absolute numbers of GFP T cell (n=1) and CD20 CAR T cell (n=3) expansion and persistence in rhesus macaques (top graph). Maximum CD20 CAR T cell expansion occurred between day 7 and day 8 following CAR T cell infusion. Absolute numbers of B cells in rhesus macaques following GFP T cell (n=1) and CD20 CAR T cell (n=3) infusion (bottom graph). Figure 1. Absolute numbers of GFP T cell (n=1) and CD20 CAR T cell (n=3) expansion and persistence in rhesus macaques (top graph). Maximum CD20 CAR T cell expansion occurred between day 7 and day 8 following CAR T cell infusion. Absolute numbers of B cells in rhesus macaques following GFP T cell (n=1) and CD20 CAR T cell (n=3) infusion (bottom graph). Figure 2. A. CRP, Ferritin and LDH levels were elevated following CD20 CAR T cell infusion, their peaks closely correlated with maximum CAR T cell expansion. No elevation of CRP, Ferritin or LDH was observed in Animal 1 which received GFP T cells. B. Elevations in IL-6, IL-8 and ITAC levels following CD20 CAR T cell infusion were highest surrounding the time of maximum CAR T cell expansion. Figure 2. A. CRP, Ferritin and LDH levels were elevated following CD20 CAR T cell infusion, their peaks closely correlated with maximum CAR T cell expansion. No elevation of CRP, Ferritin or LDH was observed in Animal 1 which received GFP T cells. B. Elevations in IL-6, IL-8 and ITAC levels following CD20 CAR T cell infusion were highest surrounding the time of maximum CAR T cell expansion. Disclosures Kean: Juno Therapeutics, Inc: Research Funding. Jensen:Juno Therapeutics, Inc: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Research Funding.

Correlation of patient characteristics and biomarkers with clinical outcomes of JCAR017 in R/R aggressive B-NHL (TRANSCEND NHL 001 study).

2018 ◽  
Vol 36 (5_suppl) ◽  
pp. 122-122 ◽  
Author(s):  
Tanya Siddiqi ◽  
Jeremy S. Abramson ◽  
Maria Lia Palomba ◽  
Leo I. Gordon ◽  
Matthew Alexander Lunning ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Expansion ◽  
Patient Characteristics ◽  
Durable Response ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion ◽  
Seamless Design

122 Background: JCAR017 is a defined composition, CD19-directed 4-1BB CAR T cell product administered at a precise dose of CD8 and CD4 CAR T cells in a seamless design Ph1 pivotal trial of R/R B-cell NHL (TRANSCEND NHL 001; NCT02631044). Methods: Blood samples were collected for biomarker analyses at protocol-defined time points. PK (CAR T cell expansion and persistence) was measured using flow cytometry. Cytokines were measured on a Luminex platform. Additional analytes will be presented. All reported p-values are 2-sided without multiplicity adjustment. Results: Safety (n = 59) and efficacy (n = 54) outcomes were analyzed for correlations with patient (pt) characteristics and biomarkers. Dose level did not correlate with cytokine release syndrome (CRS) or neurotoxicity (NT) despite higher median Cmax and median AUC0-28 at DL2. In pts with NT or ≥Gr 2 CRS, CD4 and CD8 CAR T cell levels were 5-10 fold and 3-5 fold higher, respectively, than median DL2 levels. Pt factors that correlated with any grade CRS and NT were ECOG 2 (p = 0.03) and high disease burden (p < 0.05). Higher levels of IL-8, IL-10, and CXCL10 before CART cell infusion were associated with Gr 3-4 NT (each p< 0.05), suggesting that inherent pt factors may result in higher CAR T expansion and associated CRS and NT. Lower pre-CAR T cell ferritin, LDH, CXCL10, G-CSF, and IL-10 were associated with CR/PR, and lower pre-CAR T cell ferritin, CRP, LDH, CXCL10, IL-8, IL-10, IL-15, MCP-1, MIP-1β, TNF-α were associated with 3-month durable response (each p< 0.05). Median Cmax and AUC0-28 of CD8 CAR T cells were higher in responding patients and with durable response at Month 3 (CD8 Cmax median = 20.8 vs 5.5; CD8 AUC median = 235 vs 55 in CR/PR vs PD at Month 3). Of pts evaluable for persistence at 3 months (n = 29), 90% and 93% had detectable CD8+ and CD4+ CAR+ T cells; of those with available PK results at time of relapse (n = 11), 82% had persistence at time of relapse. Conclusions: JCAR017 demonstrated increased CAR T cell expansion and persistence and higher durability of response at higher dose levels, with manageable toxicities. CAR T cells were also detected at time of relapse, suggesting potential opportunities for future combination clinical trials. Clinical trial information: NCT02631044.

scholarly journals Engineered Cytokine Signaling to Improve CAR T Cell Effector Function

2021 ◽  
Vol 12 ◽  
Author(s):  
Matthew Bell ◽  
Stephen Gottschalk
Keyword(s):  
T Cells ◽  
T Cell ◽  
T Cell Activation ◽  
Cell Expansion ◽  
Cytokine Signaling ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
T Cell Expansion

Adoptive immunotherapy with T cells genetically modified to express chimeric antigen receptors (CARs) is a promising approach to improve outcomes for cancer patients. While CAR T cell therapy is effective for hematological malignancies, there is a need to improve the efficacy of this therapeutic approach for patients with solid tumors and brain tumors. At present, several approaches are being pursued to improve the antitumor activity of CAR T cells including i) targeting multiple antigens, ii) improving T cell expansion/persistence, iii) enhancing homing to tumor sites, and iv) rendering CAR T cells resistant to the immunosuppressive tumor microenvironment (TME). Augmenting signal 3 of T cell activation by transgenic expression of cytokines or engineered cytokine receptors has emerged as a promising strategy since it not only improves CAR T cell expansion/persistence but also their ability to function in the immunosuppressive TME. In this review, we will provide an overview of cytokine biology and highlight genetic approaches that are actively being pursued to augment cytokine signaling in CAR T cells.

scholarly journals Myeloid Cells in Peripheral Blood Mononuclear Cell (PMBC) Concentrates Inhibit the Expansion of Chimeric Antigen Receptor (CAR) T Cells

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 383-383
Author(s):  
David F. Stroncek ◽  
Daniel W. Lee ◽  
Jiaqiang Ren ◽  
Marianna Sabatino ◽  
Hanh Khuu ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Expansion ◽  
Myeloid Cells ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T Cell Therapy ◽  
Car T ◽  
T Cell Expansion

Abstract Introduction: While autologous anti-CD19 and anti-GD2 CAR T cell therapy has shown promise results in children with B cell acute lymphocytic leukemia (ALL) and sarcoma respectively, T cells from some patients fail to expand in culture. The anti-CD19 and anti-GD2 CAR T cell products manufactured by our center and the factors affecting CAR T cell expansion were reviewed. Methods: The manufacturing methods for both types of CAR T cells were similar; autologous PBMC concentrates collected by apheresis were used as starting material, anti-CD3/CD28 beads were used for T cell enrichment, and IL-2 plus CD3/CD28 beads were used for T cell activation and expansion. Retroviral vector transduction of CD19 anti-GD2 CAR T cells was performed on days 2 and 3. Anti-CD19 CAR T cells from 28 patients were expanded over 7 to 11 days and anti-GD2 CAR T cells from 9 patients expanded over 10 to 11 days. The target dose of transduced cells was 1 or 3x106/Kg for both clinical protocols. Results: Following transduction and expansion, the 28 anti-CD19 CAR T cell products contained a mean of 1,130±916 x106 transduced T cells. Four of the 28 had poor expansion defined as not yielding enough transduced cells for one dose (1x106 CAR cells/kg). When the characteristics of the PBMC concentrates collected from the 4 patients whose T cells expanded poorly was compared with that of the other 24, those collected from the poor expanders contained greater quantities of monocytes (39.8±12.9% vs 15.3±10.8%, p=0.0014) and less lymphocytes (42.3±8.4% vs 75.3±14.1%; p<0.001). The poorly expanding apheresis products also contained less CD3+ cells (27.4±10.6% vs 59.7±19.5%; p=0.0045) and more CD56+ cells (26.9±14.5% vs 6.1±5.5%; p<0.001), but there was no difference in the quantity of CD19+ cells. The sum of the proportion of granulocytes and monocytes in each PBMC concentrate was inversely associated with T cell expansion (r= -0.59). A comparison of the quantity of anti-GD2 CAR T cells produced from the 9 sarcoma patients with the quantity of anti-CD19 CAR T cells produced from the 22 ALL patients whose cells were also expanded over 10 to 11 days revealed that the anti-GD2 CAR T cell products contained less transduced cells (197±205x106 vs 1,313±917x106; p=0.0083). The PMBC concentrates collected from sarcoma patients contained more monocytes (31.4±12.4% vs 18.5±13.7%; p=0.019) than those collected from the ALL patients. Of the 9 anti-GD2 CAR T cell products, one failed to meet dose (prescribed doses ranged from 1 x 105/kg-3 x 106/kg); the apheresis product from this patient contained large quantities of myeloid cells: 37% monocytes and 55% granulocytes. However, for sarcoma patients there was no relationship between the sum of granulocytes and monocytes in the PBMC concentrate and the yield of transduced anti-GD2 CAR T cells (r=-0.11). Among the 5 products that expanded poorly, manufacturing was repeated for 2 ALL and 1 sarcoma patient using a cryopreserved aliquot of their PBMC concentrate but incorporating an upfront step to deplete myeloid cells by plastic adherence, with or without density gradient separation. All three products expanded well following myeloid cell depletion. For the ALL patients 0 and 2.4x106 transduced anti-CD19 CAR T cells were produced initially compared to 147x106 and 160x106 transduced cells using the second manufacturing procedure. For the sarcoma patient 4.8x106 transduced anti-GD2 CAR T cells were produced by the first procedure and 5,200x106 by the second procedure. Conclusions: These results show that the expansion of autologous T cells for CAR T cell therapy is highly variable and the variability is due at least in part to the contamination of the starting apheresis concentrate with myeloid cells. More rigorous removal of myeloid cells prior to initiating cell culture was associated with improved T cell expansion. Suppression of expansion by myeloid cells appears to more problematic in sarcoma patients than in leukemia patients. Disclosures Sabatino: Kite Pharma: Employment. Mackall:Juno: Patents & Royalties: CD22-CAR.

scholarly journals P04.01 Immunomonitoring of CD19. CAR T-cells in Large B-Cell Lymphoma- a two-center experience

2021 ◽  
Vol 9 (Suppl 1) ◽  
pp. A16-A16
Author(s):  
V Blumenberg ◽  
S Völkl ◽  
G Busch ◽  
S Baumann ◽  
M Winkelmann ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Expansion ◽  
B Cell Lymphoma ◽  
Car T Cells ◽  
Car T Cell ◽  
Large B Cell Lymphoma ◽  
Car T ◽  
T Cell Expansion

BackgroundCD19. CAR T-cells for the treatment of relapsed and refractory (r/r) Diffuse Large B-Cell Lymphoma (DLBCL) demonstrated complete responses in 40%-58% of the patients. Recently, others could associate high tumor volume and low CAR T-cell expansion in vivo with poor outcome. We hypothesize, that the expansion and immunphenotype of (CAR) T cells in vivo determine treatment response and depend on patient- and disease associated factors.Materials and MethodsPatients with r/r DLBCL (n=34) were treated with either Axi-cel or Tisa-cel at the University Hospitals of Erlangen and Munich (LMU). The CAR T-cell product and peripheral blood were collected on day 0, 4, 7, 14, 30, 60 and 90 post transfusion. CAR T-cells were detected through flow cytometry utilizing a two step-staining with a biotinylated CD19 protein. Effector:Target (E:T) Ratios were estimated as absolute peak expansion of CAR T-cells (/ul) per tumorvolume (cm3). Responder (R, complete or partial remission) were compared to Non-Responder (NR, stable or progressive disease) according to response assessment with PET-CT three months after transfusion.ResultsCAR T-cell expansion peaked between day 7 and day 14 after transfusion with a greater expansion of CD8+compared to CD8- CAR T-cells on day 14 (59.27% vs 37.42%, p=0.021). The ratio of CD8+ and CD8- CAR T-cells did not differ between R and NR, however R exhibited higher E:T ratios of CD3+ CAR T-cells compared to NR (20.94 vs 12.81, p=0.015) and an increased E:T ratio of CD8+ CAR T-cells correlated with better progression-free survival (p=0.033). Interestingly, high CRP and ferritin levels at baseline were inversely associated with the E:T ratio (p=0.048 and p=0.017). CD3+ CAR T-cells of R showed earlier peak expression of PD-1 than NR (day 7 vs day 21). Further, peak expansion of CD3+ CAR T-cells correlated with higher PD-1 expression in R but not in NR (p=0.003 vs p=0.12). In addition, R revealed an increased relative frequency of effector memory differentiated CD3+ CAR T-cells (CCR7-CD45RA-, p=0.02), whereas CAR T-cells in NR showed an increased relative frequency of a naïve phenotype (CCR7+CD45RA+, p=0.001) on day 7 post infusion.ConclusionsFlow-based immunomonitoring with longitudinal characterization of CAR T-cells demonstrated a correlation of the E:T ratio with treatment response and survival. Increased inflammatory conditions at baseline correlated with diminished E:T ratios. Notably, in R CAR peak expansion was positively associated with higher PD-1 expression suggestive for superior CAR T-cell activation. In addition, greater memory differentiation was associated with efficacy during the time of peak expansion. Multiparameter analysis with other clinical covariates will show, whether CAR T-cell expansion and immunphenotypes can predict patient outcome.Disclosure InformationV. Blumenberg: B. Research Grant (principal investigator, collaborator or consultant and pending grants as well as grants already received); Significant; Novartis, Gilead Sciences, Janssen, BMS/Celgene. S. Völkl: None. G. Busch: None. S. Baumann: None. M. Winkelmann: None. B. Tast: None. D. Nixdorf: None. G. Hänel: None. L. Frölich: None. C. Schmidt: None. R. Jitschin: None. F. Vettermann: None. W. Kunz: None. D. Mougiakakos: None. M. von Bergwelt: None. V. Bücklein: None. A. Mackensen: None. M. Subklewe: None.

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