Rapamycin pretreatment rescues the bone marrow AML cell elimination capacity of CAR-T cells

2021 ◽  
pp. clincanres.0452.2021
Author(s):  
Zhigang Nian ◽  
Xiaohu Zheng ◽  
Yingchao Dou ◽  
Xianghui Du ◽  
Li Zhou ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
Elimination Capacity ◽  
Car T Cells ◽  
Car T

scholarly journals CHIMERIC ANTIGEN RECEPTOR FOR CHRONIC LYMPHOCYTIC LEUKEMIA - A REVIEW

2019 ◽  
Vol 12 (1) ◽  
pp. 62
Author(s):  
Kiruthiga Raghunathan ◽  
Brindha Devi P
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
Radiation Therapy ◽  
Chronic Lymphocytic Leukemia ◽  
Tumor Cells ◽  
Chimeric Antigen Receptor ◽  
Lymphocytic Leukemia ◽  
Normal Cells ◽  
Car T Cells ◽  
Car T

Chronic lymphocytic leukemia cancer is a deadly one which affects the bone marrow from making it to produce more amounts of white blood cells in the humans. This disease can be treated either by radiation therapy, bone marrow transplantation, chemotherapy, or immunotherapy. In radiation therapy, the ionizing radiation is used toward the tumor cells, but the main drawback is the radiation may affect the normal cells as well. To overcome this drawback, immunotherapy chimeric antigen receptor (CAR) is used. These CAR cells will target only the antigen of the tumor cells and not damage the normal cells in the body. In this therapy, the T-cells are taken either from the patients or a healthy donor and are engineered to express the CARs which are called as CAR-T-cells. When these CAR-T-cells come in contact with the antigen present on the surface of the tumor cells, they will get activated and become toxic to the tumor cells. This new class of therapy is having a great prospect in cancer immunotherapy.

Hematologic Malignancies: Plasma Cell Disorders

2017 ◽  
pp. 561-568 ◽  
Author(s):  
Madhav V. Dhodapkar ◽  
Ivan Borrello ◽  
Adam D. Cohen ◽  
Edward A. Stadtmauer
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
Monoclonal Antibodies ◽  
T Cell ◽  
Cell Surface ◽  
Plasma Cell ◽  
Antigen Specificity ◽  
Immune Effector ◽  
Car T Cells ◽  
Car T

Multiple myeloma (MM) is a plasma cell malignancy characterized by the growth of tumor cells in the bone marrow. Properties of the tumor microenvironment provide both potential tumor-promoting and tumor-restricting properties. Targeting underlying immune triggers for evolution of tumors as well as direct attack of malignant plasma cells is an emerging focus of therapy for MM. The monoclonal antibodies daratumumab and elotuzumab, which target the plasma cell surface proteins CD38 and SLAMF7/CS1, respectively, particularly when used in combination with immunomodulatory agents and proteasome inhibitors, have resulted in high response rates and improved survival for patients with relapsed and refractory MM. A number of other monoclonal antibodies are in various stages of clinical development, including those targeting MM cell surface antigens, the bone marrow microenvironment, and immune effector T cells such as antiprogrammed cell death protein 1 antibodies. Bispecific preparations seek to simultaneously target MM cells and activate endogenous T cells to enhance efficacy. Cellular immunotherapy seeks to overcome the limitations of the endogenous antimyeloma immune response through adoptive transfer of immune effector cells with MM specificity. Allogeneic donor lymphocyte infusion can be effective but can cause graft-versus-host disease. The most promising approach appears to be genetically modified cellular therapy, in which T cells are given novel antigen specificity through expression of transgenic T-cell receptors (TCRs) or chimeric antigen receptors (CARs). CAR T cells against several different targets are under investigation in MM. Infusion of CD19-targeted CAR T cells following salvage autologous stem cell transplantation (SCT) was safe and extended remission duration in a subset of patients with relapsed/refractory MM. CAR T cells targeting B-cell maturation antigen (BCMA) appear most promising, with dramatic remissions seen in patients with highly refractory disease in three ongoing trials. Responses are associated with degree of CAR T-cell expansion/persistence and often toxicity, including cytokine release syndrome (CRS) and neurotoxicity. Ongoing and future studies are exploring correlates of response, ways to mitigate toxicity, and “universal” CAR T cells.

scholarly journals Immunotherapeutic Targeting of TSLPR with Chimeric Antigen Receptor T Cells in AML

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 2789-2789
Author(s):  
Lindsey F Call ◽  
Sommer Castro ◽  
Thao T. Tang ◽  
Cynthia Nourigat-Mckay ◽  
LaKeisha Perkins ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
Cell Surface ◽  
Peripheral Blood ◽  
Surface Expression ◽  
Cell Surface Expression ◽  
Car T Cells ◽  
Car T

Abstract Adoptive transfer of T cells engineered to express chimeric antigen receptors (CARs) has achieved impressive outcomes in the treatment of refractory/relapsed B-ALL, providing potentially curative treatment options for these patients. The use of CAR T in AML, however, is still in its infancy with limitations due to the innate heterogeneity associated with AML and the lack of AML-specific targets for therapeutic development. The CRLF2 gene encodes for thymic stromal lymphopoietin receptor (TSLPR) and has previously been shown to be highly upregulated in a subset of children and adults with B-ALL. Targeting TSLPR with CAR T cells demonstrates potent anti-leukemia activity against TSLPR-positive B-ALL (PMID 26041741). Through Target Pediatric AML (TpAML), we profiled the transcriptome of nearly 3000 children and young adults with AML and identified CRLF2 (TSLPR) to be highly expressed in a subset of AML, including the majority of AML harboring KM2TA (aka MLL) fusions. TSLPR cell surface expression was validated in primary patient samples using flow cytometry, which showed uniform expression of TSLPR on AML blasts. Given that TSLPR is expressed in AML with confirmed cell surface expression, we developed TSLPR-directed CAR T for preclinical evaluation in AML. We generated a TSLPR-directed CAR using the single-chain variable fragment (scFv) derived from an anti-TSLPR binder (clone 3G1, MD Anderson), IgG4 spacer and 41-BB/CD3zeta signaling domains. The in vitro cytotoxicity of TSLPR CAR T cells was evaluated against the REH-1 cell line and primary AML specimens. TSLPR CAR T cells demonstrated anti-leukemia activity against REH-1 as well as against primary AML specimens. To evaluate the in vivo efficacy of TSLPR CAR T cells, we developed a patient-derived xenograft (PDX) model using bone marrow cells from a TSLPR-positive patient. These cells provided a robust model system to evaluate the in vivo activity of TSLPR CAR T cells, as they produced an aggressive leukemia in humanized NSG-SGM3 mice. The PDX generated from these cells died within 2 months of transplant with significant leukemia infiltration into the bone marrow, liver, and spleen. In the in vivo study, the leukemia burden was assessed by flow cytometric analysis of AML cells in the peripheral blood and bone marrow aspirates following treatment with unmodified control or TSLPR CAR T cells given at 10x10 6 T cells per mouse. After CAR T treatment, we detected a significant decrease in leukemia infiltration into the peripheral blood and bone marrow in the CAR T-treated mice compared to mice that received unmodified T cells. In this study, we report that similar to B-ALL, CRLF2 (TSLPR) is overexpressed in a subset of AML, providing a strategy to eliminate AML cells with CAR T cell therapy. We validated the cell surface expression of TSLPR and showed that the expression is uniform across AML specimens. We further demonstrate that CAR T cells targeting TSLPR were effective in eliminating AML cells in vitro and in vivo. Given that TSLPR is highly expressed in the KMT2A-rearranged AML, a subtype that is associated with poor outcomes, TSLPR-directed CAR T cells represent a promising immunotherapy for this high-risk AML subset. Disclosures Pardo: Hematologics, Inc.: Current Employment.

scholarly journals CD19 CAR-T Cell Therapy in Children with Relapsed and Refractory B-ALL

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 1737-1737
Author(s):  
Olga Molostova ◽  
Larisa Shelikhova ◽  
Yakov Muzalevsky ◽  
Alexey Kazachenok ◽  
Rimma Khismatullina ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
T Cell ◽  
Point Of Care ◽  
Mitigation Strategy ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell Therapy ◽  
Car T

Abstract Introduction CD19 CAR-T is a highly effective therapy among children with relapsed/refractory B-ALL. The optimal approach to delivery of this therapy and the best post-remission strategy remain to be established. We have tested in a prospective academic trial CD19 CAR-T cells manufactured at the point-of-care based on the automatic bioreactor platform. Based on the results of the first part of the trial, a toxicity mitigation strategy with conditional split dosing and refined post-remission therapy based on allogeneic HSCT was implemented. We report here the results of toxicity mitigation strategy approach as well as the long-term outcome with regard to the HSCT consolidation. Patients and methods A total of 57 pts with relapsed/refractory B-ALL were screened, 54 pts were included in the trial, and additional 3 pts were eligible for compassionate use of CD19 CAR-T cell therapy. The CliniMACS Prodigy T-cell transduction process with lentiviral second generation CD19.4-1BB zeta vector (Lentigen, Miltenyi Biotec) was used for CAR-T manufacturing. All patients received prophylactic tocilizumab before CAR-T cells infusion. In the first part of trial 33 pts received lymphodepleting chemotherapy containing cyclophosphamide (750 mg/m2) and fludarabine (120 mg/m2), CAR-T cells was administered in dose-escalating regimen (0.1, 0.5, 1, and 3х10 6/kg b.w.). After the interim analysis, treatment scheme was modified to adapt the lymphodepletion therapy and the starting CAR-T dose to the leukemia burden. Twenty-four consecutive pts were divided into "low leukemia burden" (n=10) and "highleukemia burden" (n=14) groups, based on the threshold of 15% leukemic cells in the bone marrow. Patients with low leukemia burden received the same lymphodepletion chemotherapy as in the first part of the trial, and a single fixed dose of CAR-T cells at 1x10 6/kg b.w. Patients with high leukemia burden received an escalated lymphodepletion (fludarabine 120 mg/m 2, cyclophosphamide 750 mg/m 2, cytarabine 900 mg/m 2, etoposide 450 mg/m 2, dexamethasone 30 mg/m 2) and a divided dose of CAR-T. Day 0 CAR-T dose was set at 0.1 x10 6/kg. The second dose of 0.9x10 6/kg b.w. was administered between day 7 and day 14 if the following criteria were met: bone marrow leukemia burden by flow cytometry < 15% and CRS and/or ICANS grade within 3 previous days does not exceed grade 2. Results Thirty patients included in the first part of the trial, were evaluable for response at day 28, and 27 (90%) of them had MRD-negative remission. Interim analysis showed that grade 3-5 CRS and neurotoxicity were associated exclusively with large leukemia burden (>15% blasts in the bone marrow) at the enrollment (p=0,003). With the risk-adapted strategy (part 2 of the trial), 8 patients (80%) with low leukemic burden achieved CR at day 28, and all patients (100%) with high leukemic burden achieved complete remission on day 28. In the high burden cohort 4 patients received the second CAR-T infusion, while the remaining 10 patients did not receive second dose due to either toxicity grade ³2 (4 pts), or persistence of >15% blast cells in bone marrow (6 pts). There were no cases of grade IV-V toxicity among patients with high leukemia burden, Table 1. For all patients the median follow-up for survivors was 490 days (287-1193), the cumulative incidence of relapse after initial response was 69.6%, median time to relapse was 250 days (58-696). HSCT during the CR was performed in 15 patients. The median time between first CAR-T infusion and HSCT was 96 days (41-292). Three patients (20%) relapsed early after HSCT (88, 114 and 155 days). Event-free and overall survival for the total cohort was 19.6% and 56.4%, respectively. Among the 34 pts, who did not receive HSCT in CR after CAR-T therapy, EFS and OS were 14.7% and 55.7%. Among the 15 pts, who received HSCT as consolidation, EFS and OS were 86.1% and 80%, p-value for HSCT vs no HSCT 0.125 (OS) and 0.0001 (EFS). Conclusion Low doses of non-cryopreserved CAR-T cells (0.1*10 6/kg), manufactured at the point-of-care, demonstrated high efficacy in patients with high initial leukemia burden, as well as favorable profile of life-threatening toxicity. The proposed risk-adapted strategy of CAR-T dosing allows to achieve high remission rate in all patients (with high and low leukemic mass). HSCT is likely to be a necessary modality for consolidation and long-term maintenance of remission after CAR-T therapy among a majority of patients with advanced B-ALL. Figure 1 Figure 1. Disclosures Maschan: Miltenyi Biotec: Speakers Bureau.

scholarly journals Allogeneic CAR-T Cell Therapy for Treatment of Relapse after Allo-HSCT in Patients with Refractory CML Lymphoid Blast Crisis: Significance of HLA Matched Donor/Patient Pair in the Safety/Efficacy of CAR-T Cell Therapy

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 4275-4275 ◽  
Author(s):  
Kai Sun ◽  
Xuejun Zhang ◽  
Zhen Wang ◽  
Yuqing Chen ◽  
Lei Zhang ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Blast Crisis ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T Cell Therapy ◽  
Car T

Abstract Introduction: CD19-specific CAR-T cells have shown promise in the treatment of relapsed or refractory Ph+ ALL. It remains to be established whether allogeneic CAR-T cells have clinical activity in patients with relapsed CML lymphoid blast crisis with a history of allo-HSCT. Here we report our experience in two cases of allogeneic CAR-T cell therapy for treatment of relapse after allo-HSCT in patients with refractory CML lymphoid blast crisis. Methods: For manufacture of allogeneic CAR-T cells, peripheral blood mononuclear cells were collected from the same stem cell donor. Lentiviral construction and generation of CAR-T cells, clinical protocol design, assessment and management of cytokine release syndrome (CRS), were performed as described in our previous report (Leukemia. 2017;31:2587-2593). Fludarabine and cyclophosphamide had been administered for lymphocyte depletion before allogeneic CAR-T cells infusion. Patients: Patient 1 was a 52-year-old woman with refractory CML lymphoid blast crisis, who had a relapse after undergoing allo-HSCT from her daughter (HLA-10/10). Her initial examinations of peripheral blood and bone marrow were consistent with the diagnosis of CML lymphoid blast crisis. Cytogenetics and molecular analysis confirmed the presence of t(9;22)(q34;q11) and BCR-ABL1 210 fusion protein. In February 2017, examination of bone marrow revealed a further increase of lymphoblasts to 83.2%. In addition, ABL1 kinase mutations (Y253H and E255K/V) were identified. The patient underwent HLA 10/10-matched allo-HSCT without acute GVHD. A remission with a negative test for BCR-ABL1 210 and 99.62% donor chimerism had been achieved, then she had a lymphoblastic relapse occurred 2 months after allo-HSCT. Consistently, BCR-ABL1 210 turned positive, and chimerism analysis showed 67.4% donor chimerism. 3 weeks after relapse, allogeneic CAR-T cells were infused at the dose of 5×106 /kg CD19-specific CAR-T cells. Patient 2 was a 39-year-old male patient with relapsed CML lymphoid blast crisis with a history of allo-HSCT. He had received a diagnosis of CML chronic phase 7 years earlier. Bone marrow revealed a karyotype of 46, XY, t(3;9;22)(q27;q34;q11) and BCR-ABL mRNA transcript. From April 2011 to September 2012, the patient was treated with nilotinib. In September 2012, bone marrow examination revealed 78% lymphoblasts, thus the diagnosis of CML lymphoid blast crisis was established. In December 2012, the patient underwent HLA 7/10-matched sibling allo-HSCT (from his brother) without evidence of GVHD and maintained CR for 2 years. In December 2014, the patient developed bone marrow relapse (lymphoblast 9.5%) and extramedullary leukemia (testicular involvement) harboring the BCR-ABL-T315I mutation. During 2014 to 2018, the patient received multiple courses of CIKs, HDMTX and DLI, but failed to achieve CR. In March 2018, the patient received healthy donor derived allogeneic CAR19 T cells (2×105/kg) therapy. Result: Before CAR-T cells infusion, both patients with refractory CML lymphoid blast crisis had a relapse after successful allo-HSCT. Approximately 1 month after CAR-T cells infusion, a persistent morphologic remission, a recovering BM, and complete absence of BCR-ABL mRNA transcripts confirmed morphologic and molecular remission in both patients. Consistent with this, flow cytometry could not detect blasts or CD19+ B lineage cells. Patient 1 did not experience toxicities and allogeneic CAR-T cell therapy was well tolerated. Patient 2 developed severe CRS (Gr 4) including high-grade fevers (>40°C), hypotension, hypoxia, mental status changes, and seizures. These episodes ran for approximately 1 week before they were halted by treatment with steroids plus tocilizumab, and plasma exchange. The toxicity of allogeneic CAR-T cells is correlated with high levels of IL-6, IFN-γ, TNF-a, and CRP. Conclusion: The clinical outcomes from these 2 patients demonstrate the in vivo efficacy of allogeneic CD19-targeted T cells to induce clinical, morphology and molecular remissions as well as B cell aplasia in adults with relapsed CML lymphoid blast crisis with a history of allo-HSCT. The efficacy of allogeneic CAR-T cell therapy may not always be related to the risk of severe CRS. The degree of HLA matching may have a major impact on the prevention of CRS after allogeneic CAR-T cell therapy. Fully HLA-matched-pair may increase the safety and efficacy of the allogeneic CAR-T cell therapy. Disclosures No relevant conflicts of interest to declare.

scholarly journals A Mathematical Description of the Bone Marrow Dynamics of CAR T-Cell Therapy in B-cell Childhood Acute Lymphoblastic Leukemia

2021 ◽  
Author(s):  
Álvaro Martínez-Rubio ◽  
Salvador Chulián ◽  
Cristina Blázquez Goñi ◽  
Antonio Pérez Martínez ◽  
Manuel Ramírez Orellana ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
B Cells ◽  
B Cell ◽  
Lymphoblastic Leukemia ◽  
Leukemic Cells ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell Therapy ◽  
Car T

Chimeric Antigen Receptor (CAR) T-cell therapy has demonstrated high rates of response in recurrent B-cell Acute Lymphoblastic Leukemia in children and young adults. Despite this success, a fraction of patients experience relapse after treatment. Relapse is often preceded by recovery of healthy B cells, which suggests loss or dysfunction of CAR T cells in bone marrow. This site is harder to access, and thus is not monitored as frequently as peripheral blood. Understanding the interplay between B cells, leukemic cells and CAR T cells in bone marrow is paramount in ascertaining the causes of lack of response. In this paper, we put forward a mathematical model representing the interaction between constantly renewing B cells, CAR T cells and leukemic cells in the bone marrow. Our model accounts for the maturation dynamics of B cells and incorporates effector and memory CAR T cells. The model provides a plausible description of the dynamics of the various cellular compartments in bone marrow after CAR T infusion. After exploration of the parameter space, we found that the dynamics of CAR T product and disease were independent of the dose injected, initial B-cell load and tumor burden. We also show theoretically the importance of CAR T product attributes in determining therapy outcome, and have studied a variety of possible response scenarios, including second dosage schemes. We conclude by setting out ideas for the refinement of the model.

scholarly journals CD19-Directed Fast CART Therapy for Relapsed/Refractory Acute Lymphoblastic Leukemia: From Bench to Bedside

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 1340-1340 ◽  
Author(s):  
Cheng Zhang ◽  
Jiaping He ◽  
Li Liu ◽  
Jishi Wang ◽  
Sanbin Wang ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
Lymphoblastic Leukemia ◽  
Preclinical Study ◽  
Car T Cells ◽  
Car T ◽  
Manufacturing Time ◽  
Grade Iii

Background CAR-T targeting CD19 has been a success in treating B-cell acute lymphoblastic leukemia (B-ALL). However, relapse rate is high and the long term survival in pateints is not satisfactory, which is partly due to the limited expansion and persistence of the conventionally-manufactured CAR-T cells. In addition, long manufacturing time and high cost of CAR-T product further limit the wider applications of CAR-T therapy. To solve these issues, we have developed a new manufacturing platform, FasT CAR-T, which shorten the manufacturing time to one day as compared to the conventional CAR-T manufacturing time of 9-14 days, which is critical for patients with rapidly progressing disease. More importantly, CD19-directed FasT CAR-T has been shown to have superior expansion capability, younger and less exhausted phenotype, and higher potency in eliminating B-ALL both in vitro and in vivo. Based on the preclinical study, we initiated a multi-center clinical study to determine the safety, feasibility and efficacy of CD19-FasT CAR-T in treating patients with CD19+ relapsed/refractory B-ALL. Methods CD19-directed CAR-T was manufactured using the FasT CAR-T platform. Peripheral blood (PB) mononuclear cells were obtained by leukapheresis and T cells were separated. CD19-FasT CAR-T manufacturing were all successful. Conventional CAR-T (C-CAR-T) from healthy donor were also made in parallel for comparison in preclinical study. From Dec. 2018 to July 2019, 10 adult CD19+ R/R ALL patients were recruited and all patients received fludarabine and cyclophosphamide as pre-conditioning followed by a single CAR-T infusion 48-72 hours later. Doses used in this study were: 3 DL1 (5 x 104 CAR+ T/kg), 4 DL2 (1 x 105 CAR+ T/kg), and 3 DL3 (1.5 x 105 CAR+ T/kg). The endpoints of the study were clinical toxicity, feasibility, PK of CAR-T and efficacy. Results: In comparison to conventional CAR-T cells, CD19-FasT CAR-T cells had several key features (Table 1). 1) More robust expansion. Upon antigen stimulation, the FasT CAR-T proliferated 5-30 times stronger than that of C-CAR-T. 2) Higher percentage of CD62L+CD45RO- (Tscm) and CD62L+CD45+ (Tcm) population in FasT CAR-T. 3) Lower expression of PD-1+, LAG3+ and Tim3+ in FasT CAR-T. 4). More potent in eliminating Raji tumor in an in vivo xenograft mouse model. 5) More efficient migration to bone marrow which is likely due to the higher expression of CXCR4 on the FasT CAR-T cells. The trial was conducted during Dec. 2018 to July 2019. The pre-treatment bone marrow (BM) blasts were < 5% in 5 cases, 5%-50% in 3 cases, and >50% in 2 cases (Table 2). All 10 patients achieved complete remission (CR) 4 weeks after FasT CAR-T infusion, and 9 were with negative minimal residual disease (MRD-). CAR-T cells proliferation and persistence in peripheral blood (PB) were monitored by qPCR and flow cytometry. CAR-T cells peaked at Day 10 (range Day 8-13) after infusion. The median persistence period of CAR-T in PB was 56 days ((range 28-212 days) after infusion, and the longest persistence is 7 months and still being monitored at the last follow-up. The median peak of CAR copy number is 90,446/mg DNA (range 4,670-247,507/mg DNA) (Figure). The major adverse event was cytokine release syndrome (CRS) which was observed in 9 patients, including 1 patient with grade IV in DL3 group, 3 grade III, 4 grade II and 1 grade I. The clinical manifestation of CRS mainly included fever and hypotension. The median time to the development of CRS was 5 days (2-10 days), and the peak body temperature was at Day 7 (Day 5- 11) and fever lasted for an average of 5 days (3-8 days). Serum IL-6 level increased and peaked on Day 7 post-infusion, which coincided with fever but slightly preceded the CAR-T expansion peak. Three patients experienced CAR-related encephalopathy syndrome (CRES) after CAR-T infusion, in which 1 was grade III CRES. All patients who developed CRS or CRES recovered after intervention. Conclusion FasT CAR-T have superior expansion capacity with younger and less exhausted phenotype, and more potent cytotoxicity against B-ALL. This first-in-human clinical study in China showed CD19-directed FasT CAR-T therapy is highly effective in treating R/R B-ALL with manageable toxicity. The safety, efficacy and potential long-term clinical benefit of FasT CAR-T therapy will be further evaluated in large multi-center trial. (http://www.chictr.org.cn/listbycreater.aspx:ChiCTR1900023212) Disclosures No relevant conflicts of interest to declare.

scholarly journals CAR2.0 Therapy for the Management of Post-Transplantation Relapse of B-Cell Acute Lymphoblastic Leukemia

Blood ◽  
2020 ◽  
Vol 136 (Supplement 1) ◽  
pp. 7-7
Author(s):  
Rui Zhang ◽  
Juan Xiao ◽  
Zhouyang Liu ◽  
Yuan Sun ◽  
Sanfang Tu ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Flow Cytometry ◽  
T Cells ◽  
T Cell ◽  
Lymphoblastic Leukemia ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Cell Acute Lymphoblastic Leukemia

BACKGROUND: Allogeneic haematopoietic stem cell transplantation (allo-HCT) is a standard treatment for relapsed/refractory B-cell acute lymphoblastic leukemia (r/r B-ALL). However ~30-40% of patients (pts) still relapse after HCT. We report a cohort of 20 r/rB-ALL pts, who relapsed after HCT, and enrolled in the CAR2.0 study receiving one or two types of CAR-T cells targeting various B-ALL antigens. METHOD: Pts with r/r B-ALL who relapsed after allo-HCT and did not have significant active comorbiditeis, were enrolled in the study. The target antigens were determined based on immunostaining of each pt's leukemia cells, and CAR-T infusions included a single, or a combination of CAR-Ts targeting the following antigens: CD19, CD22, CD123 and CD38. T cells were collected from pts (N=4) or their allogeneic donors (N=16) and transduced with an apoptosis-inducible, safety-engineered lentiviral CAR with the following intracellular signaling domains: CD28/CD27/CD3ζ-iCasp9 (4SCAR). Pts received cyclophosphamide/fludarabine lymphodepleting therapy before infusion of 0.2-5.8x106 CAR-T/kg per infusion. In addition to disease response, we carefully monitored the quality of apheresis cells, efficiency of gene transfer, T cell proliferation rate, CAR-T infusion dose, and the CAR-T copy number in peripheral blood. RESULTS: Among the 20 enrolled pts, 11 were <18 years of age, and 7 were BCR- ABL (P190) positive. Before CAR-T treatment, 7 pts had ≤grade 2 active graft-versus-host disease (GVHD), and 13 pts received chemotherapy or targeted therapy after their relapse post HCT. Six pts had extramedullary relapse and 2 of them also had bone marrow relapse. The tumor burden in bone marrow ranged from minimal residual disease (MRD) negative to 66% of blasts, based on flow cytometry before CAR-T therapy. Five pts had >10% blasts in bone marrow, 8 pts had <3% blasts, and 7 pts had MRD negative bone marrow (summarized in the Table below). Based on the GVHD history, chimerism state and the available T-cell sources, 16 pts used allogeneic HCT donor T-cells for CAR-T preparation. All pts were full donor chimeras prior to CAR-T infusion, except one pt who had 41% donor cells in bone marrow. Eleven pts received a single CD19 CAR-T infusion, with a mean dose of 1.6x106 CAR-T/kg, and ten achieved an MRD remission and one had progressive disease (PD) within 60 days by flow cytometry. The remaining 9 pts received 2 CAR-Ts (CD19 plus CD22, CD123 or CD38 CAR-Ts) given on the same day, and resulted in 8 CR and 1 PD within 60 days. After CAR-T infusion, no cytokine release syndrome (CRS) was observed in 8 pts, and 12 pts experienced CRS of grade 1, which was consistent with the previously described low toxicity profile of the 4SCAR design. Acute GVHD ≤ grade 2 developed in 5 pts within one month following CAR-T cell infusion but all responded well to supportive care and/or cyclosporine infusion. The 2 pts who developed PD after CAR-T infusion included the one with 41% donor chimerism and had grade 2 GVHD and active infections before CAR-T infusion. The other pt with PD following CAR-T had severe bone marrow suppression, low leukocyte count, infections and was transfusion dependent before enrollment. This emphasizes the need for controlling comorbidities before infusion of CAR-T cells. In summary, total 18 patients (90%) achieved negative MRD remission within 2 months of therapy with acceptable CRS. Four pts relapsed (after being in remission for 3 months) and 14 pts are in continued remission, 6 of which for > 1 year. None of these 20 pts received a second HCT after CAR-T infusion. GVHD developed in 5/16 (31%) pts after donor source CAR-T cell infusion within one month, but all responded well to treatment. CONCLUSION: This study focuses on CAR-T cell therapy following relapse after HCT. While the expanded study is ongoing, we present results of the first 20 pts. Use of donor-derived or recipient-derived CAR-T products in pts who relapsed after allo-HCT is well tolerated and it may prolong life expectancy of these pts while maintaining good quality of life. Table Disclosures No relevant conflicts of interest to declare.

scholarly journals Local Manufacture of CD19 CAR-T Cells Using an Automated Closed-System: Robust Manufacturing and High Clinical Efficacy with Low Toxicities

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2625-2625
Author(s):  
Olga Molostova ◽  
Larisa Shelikhova ◽  
Dina Schneider ◽  
Rimma Khismatullina ◽  
Yakov Muzalevsky ◽  
...  
Keyword(s):  
Bone Marrow ◽  
T Cells ◽  
T Cell ◽  
Brain Edema ◽  
Transmembrane Domain ◽  
Lymphoblastic Leukemia ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Grade Iii

Introduction CD19 CAR-T cell products were recently approved as therapy for B-lineage malignancies. We initiated an IIT trial where manufacture of CAR-T cells was performed locally using a unique CD19 CAR with potent anti-leukemic effects. Patients and methods A total of 37 pts with relapsed/refractory B-acute lymphoblastic leukemia (12 female, 25 male, median age 10 y) were screened, 27 pts were enrolled for a trial, 10 were eligible for compassionate use of CD19 CAR-T cell therapy. Sixteen patients had relapsed B-ALL after haploidentical HSCT, 19 pts refractory relapse, 2 induction failure, 13 patients had previous blinatumomab infusion. Eighteen patients had >20% blast cells, median bone marrow leukemia burden for patients with full blown disease was 89%, 19 pts had minimal residual disease (MRD) >0.1% in BM, 3 had skeletal involvement with multiple mass lesions, one had CNS involvement. The CliniMACS Prodigy T cell transduction (TCT) process was used to produce CD19 CAR-T cells. The automated production included CD4/CD8 selection, CD3/CD28 stimulation with MACS GMP T Cell TransAct and transduced with lentiviral vector expressing the CD19CAR gene (second generation CD19.4-1BB zeta with alternate transmembrane domain derived from the TNF superfamily) (Lentigen, Miltenyi Biotec company). T cells were expansion over 10 days in the presence of serum-free TexMACS GMP Medium supplemented with MACS GMP IL-7 and IL-15. Final product was administered without cryopreservation to the patients after fludarabine/cyclophosphamide preconditioning. All patients received prophylactic tocilizumab at 8mg/kg before CAR-T cell infusion. Patients did not receive HSCT as consolidation after CAR-T therapy. Results Thirty-five manufacturing cycles were successful. Median transduction efficacy was 60% (20-80). Median expansion of T cells was x 46 (18-51). CD4:CD8 ratio in the final product was 0.73. The cell products were administered at a dose of 3*106/kg of CAR-T cells in 4 pts, 1*106/kg in 9 pts, 0.5*106/kg in 14 pts, 0.1*106/kg in 8 pts. Two patients received 0.1*106/kg of CAR-T cells produced from haploidentical donors. The cytokine release syndrome (CRS) occurred in 22 (59%) pts and was mostly mild and moderate: grade I - 15 pts, grade II- 4 pts, grade III - 2 pt, grade IV - 1 pt. CAR-T cell related encephalopathy occurred in 15 (40%). Grade I-II neurotoxicity developed in 10 pts, grade III - in 2 pt, grade IV - 1 pt, grade V - 2 pt. In one patient with grade V neurotoxicity concomitant K. pneumonia encephalitis was documented. Severe (grade 3-5) CRS and neurotoxicity were associated exclusively with large leukemia burden (>20% in the bone marrow) at enrollment, p=0,002. Thirty-one patient was evaluable for response at day 28. Four pts had persistent leukemia. In 27 (87%) cases Flow MRD-negative remission was achieved. Disease relapse after initial response was registered in 9 (33%) cases (7 patients had CD19 negative, 2 had CD19 positive relapse). At the moment of reporting, 10 patients have died (3 due to sepsis, 1 due to brain edema, 1 due to brain edema and K. pneumonia encephalitis, 5 due to progression of disease or relapse). Twenty-seven pts are alive, 19 in complete remission with a median follow up of 223 days (41-516 days). Conclusion CliniMACS Prodigy TCT process is a robust CAR-T cell manufacturing platform that enables rapid and flexible provision of CAR-T cells to patients in need. Significant toxicity of CD19 CAR-T cells was associated exclusively with high leukemia burden at enrollment. In the absence of HSCT consolidation relapse rate exceeds 30%. Disclosures Schneider: Lentigen Technology, A Miltenyi Biotec Company: Employment. Preussner:Miltenyi Biotec: Employment. Rauser:Miltenyi Biotec: Employment. Orentas:Lentigen Technology Inc., a Miltenyi Biotec Company: . Dropulic:Lentigen Technology, A Miltenyi Biotec Company: Employment. Maschan:Miltenyi Biotec: Other: lecture fee.

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