scholarly journals 4321 Personalization of T cell production for cellular immunotherapy

2020 ◽  
Vol 4 (s1) ◽  
pp. 15-15
Author(s):  
Dennis Jinglun Yuan ◽  
Shuai Shao ◽  
Joanne H Lee ◽  
Stacey M Fernandes ◽  
Jennifer R Brown ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Cell Expansion ◽  
Lymphocytic Leukemia ◽  
Cellular Immunotherapy ◽  
T Cell Therapy ◽  
Clinical Biomarkers ◽  
T Cell Expansion ◽  
Fiber Scaffolds

OBJECTIVES/GOALS: Utilize polymer-based fiber scaffolds and machine learning methods applied to patient biomarker data to enhance and personalize T cell expansion and production for T cell therapy in chronic lymphocytic leukemia. METHODS/STUDY POPULATION: Scaffolds are 1) generated from a co-polymer blend of PDMS and PCL with controlled fiber diameters and pore size, 2) coated with activating antibodies to CD3 and CD28, and 3) used to stimulate T cells from both healthy donors and CLL patients. CLL patients have pre-annotated mutation burdens and clinical biomarkers. T cell populations will be analyzed for exhaustion markers and phenotypes before, during, and after expansion. Cell functionality will be measured by cytokine secretion, cell cycle analysis, and fold expansion, with respect to platform parameters, and analyzed with inputs of disease markers and exhaustion profile of isolated T cells using regression and random forest classifiers. RESULTS/ANTICIPATED RESULTS: We previously showed that engineering the mechanical rigidity of activating substrates can enhance and rescue T cell expansion from exhausted populations. Now we aim to study a broader range of compositions and geometry of scaffolds with respect to capacity to expand CLL T cells. Preliminary data with fiber diameters ranging from 300 nm to 6 um confirm the effect of geometry in modulating expansion. A biorepository of T cells from 80 CLL patients have been isolated concurrently. Anticipated results include correlating exhaustion profile of T cells with clinical biomarkers and identifying markers associated with expansion on panel of platform parameters. DISCUSSION/SIGNIFICANCE OF IMPACT: T cell therapy has shown particular promise in treating blood cancers, yet significant percentage of T cells isolated from patients undergoing treatments are unresponsive to activation. A powerful tool is to predict if and how patient T cells can be robustly expanded on a personalized approach.

scholarly journals First-in-Human Study of ET019003, a Next Generation Anti-CD19 T-Cell Therapy, in Patients with Relapsed/Refractory Diffuse Large B Cell Lymphoma (r/r DLBCL)

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2870-2870 ◽  
Author(s):  
Pengcheng He ◽  
Hong Liu ◽  
Haibo Liu ◽  
Mina Luo ◽  
Hui Feng ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Cell Expansion ◽  
T Cell Therapy ◽  
Car T ◽  
Equity Ownership ◽  
T Cell Expansion ◽  
The Absolute

Background : CD19-targeted CAR-T therapies have shown promising efficacy in treating B-cell malignancies. However, treatment-related toxicities, such as cytokine-release syndrome (CRS) and CAR T-cell-related encephalopathy syndrome (CRES), have been one of the major obstacles limiting the use of CAR-T therapies. How to minimize occurrence and severity of toxicity while maintaining efficacy is a major focus for T-cell therapies in development. ET019003 is a next generation CD19-targeted T-cell therapy developed by Eureka Therapeutics, built on the proprietary ARTEMISTM T-cell platform. The ET019003 construct is optimized with the co-expression of an ET190L1 Antibody-TCR (Xu et al, 2018) and novel co-stimulation molecule. We are conducting a First-in-human (FIH) study of ET019003 T cells in CD19+ r/r DLBCL patients. Methods: This FIH study aims to evaluate the safety and efficacy of ET019003 T-cell therapy in CD19+ patients with r/r DLBCL. As of July 2019, six subjects were administered ET019003 T cells. These subjects were pathologically confirmed with DLBCL that is CD19+ (by immunohistochemistry), whose disease have progressed or relapsed after 2-5 lines of prior therapies. All were high-risk patients with rapid tumor progression and heavy tumor burden. Each subject had a Ki67 proliferative index over 60%, 2/6 of the subjects had a Ki67 proliferative index over 90%. Moreover, 5/6 of the subjects had extra-nodal involvement. Following a 3-day preconditioning treatment with Fludarabine (25mg/m2/day)/ Cyclophosphamide (250mg/m2/day), patients received i.v. infusions of ET019003 T cells at an initial dose of 2-3×106 cells/kg. Additional doses at 3×106 cells/kg were administered at 14 to 30-day intervals. Adverse events were monitored and assessed based on CTCAE 5.0. Clinical responses were assessed based on Lugano 2014 criteria. Results: As of July 2019, six subjects have received at least one ET019003 T-cell infusion, and four subjects have received two or more ET019003 T-cell infusions. No Grade 2 or higher CRS was observed in the six subjects. One subject developed convulsions and cognitive disturbance. This subject had lymphoma invasion in the central nervous system before ET019003 T-cell therapy. The subject was treated with glucocorticoid and the symptoms resolved within 24 hours. Other adverse events included fever (6/6, 100%), fatigue (3/6, 50%), thrombocytopenia (3/6, 50%), diarrhea (2/6, 33%), and herpes zoster (1/6, 17%). ET019003 T-cell expansion in vivo (monitored by flow cytometry and qPCR) was observed in all six subjects after first infusion. The absolute peak value of detected ET019003 T cells ranged between 26,000 - 348,240 (median 235,500) per ml of peripheral blood. Tmax (time to reach the absolute peak value) was 6 - 14 days (median 7.5 days). For the four subjects who received multiple ET019003 T-cell infusions, the absolute peak values of detected ET019003 T cells after the second infusion were significantly lower than the absolute peak values achieved after the first infusion. For the two subjects who received three or more infusions of ET019003 T cells, no significant ET019003 T-cell expansion in vivo was observed after the third infusion. All six subjects completed the evaluation of clinical responses at 1 month after ET019003 T-cell therapy. All subjects responded to ET019003 T cells and achieved either a partial remission (PR) or complete response (CR). Conclusions: Preliminary results from six CD19+ r/r DLBCL patients in a FIH study show that ET019003 T-cell therapy is safe with robust in vivo T-cell expansion. The clinical study is on-going and we are monitoring safety as well as duration of response in longer follow-up. Reference: Xu et al. Nature Cell Discovery, 2018 Disclosures Liu: Eureka Therapeutics: Employment, Equity Ownership. Chang:Eureka Therapeutics: Equity Ownership. Liu:Eureka Therapeutics: Employment, Equity Ownership.

scholarly journals Optimization of Culture Media for T Cell Expansion: T Cell Expansion Is a Bottle Neck in Adoptive T Cell Therapy

2021 ◽  
Author(s):  
Ilnaz Rahimmanesh ◽  
Hossein Khanahmad
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Cell Expansion ◽  
Culture Media ◽  
Adoptive Cell Therapy ◽  
Interleukin 2 ◽  
Adoptive T Cell Therapy ◽  
T Cell Therapy ◽  
T Cell Expansion

Abstract Adoptive T cell therapy is a promising treatment strategy for cancer immunotherapy. The methods used for the expansion of high numbers of T cells are essential steps for adoptive cell therapy. In this study, we evaluated the expansion, proliferation, activation, and anti-tumor response of T lymphocytes, in presence of different concentrations of interleukin-2, phytohemagglutinin, and insulin. Our results showed that supplemented culture media with an optimized concentration of phytohemagglutinin and interleukin-2 increased total fold expansion of T cells up to 500-fold with about 90% cell viability over 7 days. The quantitative assessment of Ki-67 in expanded T cells showed a significant elevation of this proliferation marker. In addition, the proportion of CD4+ and CD8+ cells were evaluated using flow cytometry, and data showed that both cells were present in the expanded population. Finally, we assessed the activation and tumor cytotoxicity of expanded T cells against target cells. Overexpression of CD107a, as a functional marker of T cell degranulation on expanded T cells and their ability to induce cell death in tumor cells, was observed in the co-cultured experiment. Based on these data we have developed a cost-effective and rapid method to support the efficient expansion of T cells for adoptive cell therapy.

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.

scholarly journals Long-Term T Cell Expansion Results in Increased Numbers of Central Memory T Cells with Sustained Functional Properties for Adoptive T Cell Therapy

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 1943-1943
Author(s):  
Stefanie Herda ◽  
Andreas Heimann ◽  
Stefanie Althoff ◽  
Josefine Ruß ◽  
Lars Bullinger ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Cell Expansion ◽  
Adoptive T Cell Therapy ◽  
T Cell Therapy ◽  
Human T Cells ◽  
Healthy Donors ◽  
T Cell Expansion

Success of adoptive T cell therapy (ATT) is dependent on sufficient numbers of T cells and the characteristics of the final T cell product. In several studies, clinical grade CD19 CAR T cell products could not be generated from about 6-30% patients, particularly if they were isolated from older or heavily pretreated diffuse large B cell lymphoma (DLBCL) patients. In cyclophosphamide/fludarabine-lymphodepleted patients with persistent or progressive disease a sequential second dose of T cells has been shown to be effective resulting in tumor regression. Here we investigated to what extend T cell numbers could be increased via prolonged expansion with standard cytokines IL-7/IL-15 and how transcriptome and function of central memory T cells (Tcm) longitudinally change during culture. Method: Murine and human T cells were cultured with the cytokine combination IL-7/IL-15. Short-term expanded (ST, one week) and long-term expanded (LT) CD8+ (4 weeks) and CD4+ (3 weeks) T cells were compared for proliferation capacity (CFSE), extent of apoptosis (AnnexinV), up-regulation of T cell inhibitory receptors (TIRs) and cytokine expression pattern after in vitro re-stimulation upon anti-CD3/CD28 stimulation. Further, RNA sequencing of ST and LT expanded murine CD8+ and CD4+ Tcm followed by unsupervised hierarchical clustering, principal component analysis (PCA) and differential expression analysis was performed. In vivo mouse models were used to analyze engraftment, persistence and anti-tumor capacity applying our bioluminescent dual-luciferase reporter mouse (BLITC - bioluminescent imaging of T cells) allowing us to monitor migration, expansion (RLuc luciferase) and activation (NFAT-driven Click-beetle luciferase) of adoptively transferred T cells in vivo. Finally, we analyzed the expansion and in vitro properties of T cells from healthy donors and DLBCL patients. Results: There was a 50-fold increase of T cells in LT vs. ST culture, the Tcmproportion was extended and stem cell markers were comparable or even higher expressed in LT expanded T cells. Differential analysis revealed 2786 (CD8) and 912 (CD4) with statistically significant expression alterations with generally only moderate effect size when comparing LT and ST expanded T cells. Interestingly, the dynamically modified genes largely overlapped for CD8 and CD4 T cells suggesting culture-associated changes. Comparable RLuc signals and T cells counts in peripheral lymph nodes (LN) and spleen indicate similar engraftment (4 weeks post ATT) and persistence capacities (up to 6 months post ATT) of transferred ST and LT T cells. SV40-TAg+ tumor bearing mice were treated with TCR-I retrovirally transduced CD8+ BLITC T cells, which were ST or LT expanded. The T cells infiltrated rapidly in the tumor where they got similarly activated resulting in a complete tumor rejection in all recipient mice. Finally, we analyzed the expansion and in vitro properties of T cells from healthy donors (n=3-5) and DLBCL patients (n=3) who were eligible for CAR T cell therapy. LT T cell expansion from healthy donors resulted in a 10.000-fold increase of CD8+CD45RO+CCR7+ T cells. In vitro assays showed comparable apoptosis and expression of TIRs between ST and LT CD8 T cells and stable expression of IFN-g and TNF-a within the first 3 weeks. The CD8+CD45RO+CCR7+ T cell expansion from DLBCL patients was weaker in comparison to healthy donors. The extent of cell death and up-regulation of TIRs after re-stimulation was comparable between ST and LT T cells, whereas cytokine expression varied individually. Conclusion: Our data suggest that it is feasible to expand CD8+ and CD4+ murine and human T cells up to a month, thereby increasing numbers of T cells with Tcm/Tscm properties and with sustained function for murine and human T cells from healthy donors, whereas there seems to be a high individual variance for DLBCL patients, which warrants further investigation in larger patient cohorts. Disclosures Bullinger: Bayer: Other: Financing of scientific research; Abbvie: Honoraria; Seattle Genetics: Honoraria; Sanofi: Honoraria; Pfizer: Honoraria; Novartis: Honoraria; Menarini: Honoraria; Jazz Pharmaceuticals: Honoraria; Janssen: Honoraria; Hexal: Honoraria; Gilead: Honoraria; Daiichi Sankyo: Honoraria; Celgene: Honoraria; Bristol-Myers Squibb: Honoraria; Astellas: Honoraria; Amgen: Honoraria.

scholarly journals Bioprocess considerations for T‐cell therapy: Investigating the impact of agitation, dissolved oxygen, and pH on T‐cell expansion and differentiation

2020 ◽  
Vol 117 (10) ◽  
pp. 3018-3028 ◽  
Author(s):  
Arman Amini ◽  
Vincent Wiegmann ◽  
Hamza Patel ◽  
Farlan Veraitch ◽  
Frank Baganz
Keyword(s):  
T Cell ◽  
Cell Therapy ◽  
Dissolved Oxygen ◽  
Cell Expansion ◽  
T Cell Therapy ◽  
T Cell Expansion ◽  
The Impact

Selecting T-Cell Subsets for Adoptive T-Cell Therapy to Optimize Potency and Persistence

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. SCI-39-SCI-39 ◽  
Author(s):  
Stanley Riddell ◽  
Cameron Turtle ◽  
Michael Hudecek ◽  
Daniel Sommermeyer ◽  
Michael C. Jensen
Keyword(s):  
T Cells ◽  
T Cell ◽  
Gene Transfer ◽  
Cell Therapy ◽  
Mononuclear Cells ◽  
Clinical Care ◽  
Lymphocytic Leukemia ◽  
Adoptive T Cell Therapy ◽  
T Cell Subsets ◽  
T Cell Therapy

Abstract Adoptive T-cell therapy with tumor-reactive T cells is emerging as a highly effective strategy for eliminating even the most advanced chemotherapy refractory malignancies. Endogenous T cells specific for tumor-associated antigens can sometimes be isolated and expanded from the patient’s blood or tumor infiltrate, or more expeditiously can be engineered by gene transfer to express a T-cell receptor specific for a tumor associated MHC/peptide complex or a synthetic chimeric antigen receptor (CAR) specific for a tumor associated cell surface molecule. The remarkable regression of advanced acute lymphocytic leukemia and lymphoma in patients treated with T cells engineered to express CD19-specific CARs illustrates the potential for this approach to transform clinical care. Therapeutic activity is variable in individual patients, however, and this appears to correlate with the ability of transferred, tumor-reactive T cells to persist and proliferate in vivo, and to retain effector function. These attributes may reflect both the qualities of the T cells that are isolated or engineered for therapy, and the local tumor microenvironment that may contain regulatory T cells; cells that express ligands that engage inhibitor receptors on effector T cells or cytokines that inhibit effector T-cell proliferation. The CD4+ and CD8+ T cell pools in normal individuals contain a variety of naïve, memory, and regulatory T-cell subsets that differ in epigenetic, transcriptional, and functional properties. Because most clinical protocols have used polyclonal peripheral blood mononuclear cells as recipients for CAR gene transfer, the composition of T-cell products that are being administered is highly variable, particularly when the T cells are obtained from cancer patients that have received prior cytotoxic chemotherapy that can skew the phenotypic composition of the peripheral T-cell pool. As a consequence, transferring tumor-targeting receptors into polyclonal unselected cell populations provides poor control over the cellular composition of the final T-cell product, which may in part explain the marked differences in efficacy and toxicity that have been observed in the clinic, and may complicate regulatory approval of these novel therapies. Methods to derive T cells from distinct naïve and memory T-cell subsets have been developed, enabling the rapid production of therapeutic T cells of uniform composition. The results of preclinical studies that illustrate the improved potency of defined T-cell products that are engineered with tumor-specific CARs, and the clinical implementation of this approach in B-cell malignancies will be presented. Disclosures: Riddell: Cell Medica: Consultancy, Membership on an entity’s Board of Directors or advisory committees; ZetaRx: Consultancy.

Patient specific characteristics associated with T-cell expansion for HER2/neu vaccine-primed autologous adoptive T-cell therapy.

2018 ◽  
Vol 36 (15_suppl) ◽  
pp. e15041-e15041
Author(s):  
Lisa May Ling Tachiki ◽  
Yushe Dang ◽  
Jennifer Childs ◽  
Doreen Higgins ◽  
Kelsey K. Baker ◽  
...  
Keyword(s):  
T Cell ◽  
Cell Therapy ◽  
Cell Expansion ◽  
Adoptive T Cell Therapy ◽  
Patient Specific ◽  
T Cell Therapy ◽  
T Cell Expansion

scholarly journals Elucidation of CRISPR-Cas9 Application in Novel Cellular Immunotherapy.

2021 ◽  
Author(s):  
Sameer Quazi
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Genome Editing ◽  
High Efficiency ◽  
Tumor Formation ◽  
Cellular Immunotherapy ◽  
Severe Toxicity ◽  
T Cell Therapy ◽  
Car T

Novel Cellular Immunotherapy with engineered T cells has improved cancer treatment and established therapeutic promises to prevent tumor formation in clinical studies. Due to certain restrictions and difficulties, CAR and TCR T cells therapies were inadequate at points. CRISPR Cas9 genome-editing tool has a significant potential for these two cell-based therapies. As a specialized gene-editing technique, CRISPR Cas9 is used to repair genetic alternation with minimum damage. It is used as an adjunct to Immunotherapy to stimulate a more robust immune response. CRISPR has long outpaced other target-specific genome editing methods such as ZFNs and TALEN due to its high efficiency, competence in targeting, and stable operating condition. CRISPR can overcome the two major drawbacks of universal CAR T cells: allorejection and graft-vs-host disease. TCR-based T cell treatment can reduce inappropriate binding between endogenous and transgenic TCR, resulting in a reduction of severe toxicity. The CAR and TCR T based cell therapies uphold an excellent future for tumor malignancies This article has elucidated the administration of CRISPR Cas9 in Novel Cellular Immunotherapy, CAR, and TCR T cell therapy. However, this article did not fail to observe this technology's ethical concerns, limitations, and challenges. Furthermore, the article compares CRISPR-mediated allogeneic CAR T cell to TCR-T cell therapy.

Phase I Studies of Cellular Immunotherapy Using Central Memory Derived-CD19-Specific T Cells Following Autologous Stem Cell Transplantation for Patients with High-Risk Intermediate Grade B-Lineage Non-Hodgkin Lymphoma

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 930-930 ◽  
Author(s):  
Leslie Popplewell ◽  
Xiuli Wang ◽  
Araceli Naranjo ◽  
Suzette Blanchard ◽  
Jamie Wagner ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Phase I ◽  
Research Funding ◽  
Median Number ◽  
Cellular Immunotherapy ◽  
T Cell Therapy ◽  
Phase I Studies

Abstract Introduction Efforts to improve the survival of non-Hodgkin lymphoma (NHL) patients with recurrent disease have focused primarily on the use of consolidative myeloablative autologous hematopoietic stem cell transplantation (HSCT). However, the major limitation of HSCT for NHL is the high incidence of relapse, even at maximally tolerated preparative regimen intensities. In a series of phase I studies designed to improve HSCT longterm remission rates, we have assessed the safety and feasibility of cellular immunotherapy utilizing ex vivo expanded autologous central memory (Tcm)-enrichedT cells that are genetically modified to express CD19-specific chimeric antigen receptors (CD19CAR), given in conjunction with standard of care myeloablative HSCT. Methods Here we present results from the first two studies investigating different starting cell populations and CAR constructs. The NHL1 trial utilized a starting population of CD8+ Tcm and transduced with a lentiviral vector encoding the 1st-generation CD19CAR (CD19R:zeta), consisting of a CD19-specific scFv linked to a CD3-zeta (CD19R:zeta) signaling domain. The NHL2 trial used a bulk Tcm population including both CD4+ and CD8+cells, which were transduced with lentiviral vectors encoding a 2nd-generation CD19CAR that added a CD28 costimulatory domain (CD19R:CD28:zeta) and a selectable marker for cell tracking (EGFRt). Engineered Tcm-derived CD19CAR T cells were infused 2 days after HSCT at dose levels of 25-200 x10^6 CAR T cells (dose levels in table), and all participants were followed for dose limiting toxicity (DLT) for 28 days. Both phase I studies utilized the target equivalence range design, which defines the dose escalation and de-escalation rules for determining maximum tolerated dose based on a target range of acceptable toxicity. Results NHL1 protocol (NCT01318317): Eight participants were consented and received CD8+ Tcm -derived CD19R:zeta T cell therapy. Seven patients had a diagnosis of diffuse large B cell lymphoma (DLBCL) and 1 had mantle cell lymphoma (MCL). Four of the 8 were female, and 3/8 were ≥ age 65 years. The mean age was 62 years (50-75). The median number of prior chemo/immunotherapy regimens was 3 (2-4). Two of the 8 (25%) participants had prior radiation. Five of 8 (63%) participants on NHL1 achieved a best response of CR or continuing CR. Four of 8 (50% 95% CI [16%, 84%]) participants have progressed. The progression free survival (PFS) at both 1 and 2 years is 50%, 95% CI[16%,84%] with a median follow-up of 24.7 (min=24.0, max=26.7) months. There were 2 deaths, both from disease progression. NHL2 protocol (NCT 01815749): Eight participants were consented and received Tcm-derived CD19R:CD28:zeta/EGFRt T cell therapy. Four patients had MCL, 4 had DLBCL, 3/8 were female, 2/8 were ≥ age 65 years. The mean age was 58 years (23-71). The median number of prior chemo/immunotherapy regimens was 2 (1-3). All eight NHL2 participants achieved a best response of CR or continuing CR. The PFS at 6 months is 100%, 95% CI[63%, 100%] with a median follow-up of 12.2 (min=10.0, max=14.1) months. To date 2 participants of the 8 (25%, 95% CI [3%, 65%]) have progressed (one at 6.4 months and one at 12.6 months). There was 1 death from disease progression. Both NHL1 and NHL2 trials demonstrated safety and feasibility. There were no DLTs, delayed hematopoietic reconstitution, or non-relapse mortality on either study. In NHL2, we employed bulk Tcm including both CD4+ and CD8+ cells in the CAR transduction and also added a CD28 co-stimulatory domain in the CAR design, to enhance persistence and antitumor activity. NHL2 exhibited better CAR T cell persistence compared to NHL1 T cell therapy based on area under the curve of log10copies/µg of genomic DNA from day 1 to 25 post infusion (mean difference = 14.8, 95% CI [7.4, 22.3], P<0.001) based on analysis of WPRE PCR data. Conclusions We conclude that Tcm-derived CD19CAR T cell therapy is very safe for treatment of poor-risk NHL patients undergoing autologous HSCT. We continue follow-up of these patients long-term to assess efficacy, and preliminary data are promising. Meanwhile we are exploring CAR vector design and T cell population modifications to improve the duration of anti-tumor immunity in the setting of immune reconstitution following engineered autograft. Table. Trial CAR+ Cell Dose # of Patients NHL1 25 x 10^6 1 50 x 10^6 4 100 x 10^6 3 NHL 2 50 x 10^6 3 200 x 10^6 5 Disclosures Khaled: Sequenom: Research Funding. Siddiqi:Pharmacyclics/Jannsen: Speakers Bureau; Kite pharma: Other: attended advisory board meeting; Seattle Genetics: Speakers Bureau. Riddell:Juno Therapeutics: Equity Ownership, Patents & Royalties, Research Funding; Adaptive Biotechnologies: Consultancy; Cell Medica: Membership on an entity's Board of Directors or advisory committees. Jensen***:Juno Therapeutics: Equity Ownership, Patents & Royalties, Research Funding. Forman***:Amgen: Consultancy; Mustang: Research Funding.

scholarly journals Application of Chimeric Antigen Receptor T Cells in the Treatment of Hematological Malignancies

2020 ◽  
Vol 2020 ◽  
pp. 1-9
Author(s):  
Weiqi Yan ◽  
Zhuojun Liu ◽  
Jia Liu ◽  
Yuanshi Xia ◽  
Kai Hu ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Therapy ◽  
Hematological Malignancies ◽  
Lymphocytic Leukemia ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T Cell Therapy ◽  
Car T

T cell immune protection plays a pivotal role in the treatment of patients with hematological malignancies. However, T cell exhaustion might lead to the possibility of immune escape of hematological malignancies. Adoptive cell therapy (ACT) with chimeric antigen receptor T (CAR-T) cells can restore the activity of exhausted T cell through reprogramming and is widely used in the treatment of relapsed/refractory (r/r) hematological malignancies. Of note, CD19, CD20, CD30, CD33, CD123, and CD269 as ideal targets have shown extraordinary potential for CAR-T cell therapy and other targets such as CD23 and SLAMF7 have brought promising future for clinical trials. However, CAR-T cells can also produce some adverse events after treatment of hematological malignancies, such as cytokine release syndrome (CRS), neurotoxicity, and on-target/off-tumor toxicity, which may cause systemic immune stress inflammation, destruction of the blood-brain barrier, and even normal tissue damage. In this review, we aim to summarize the composition of CAR-T cell and its application in the treatment of acute lymphocytic leukemia (ALL), chronic lymphocytic leukemia (CLL), non-Hodgkin’s lymphoma (NHL), Hodgkin’s lymphoma (HL), multiple myeloma (MM), and acute myeloid leukemia (AML). Moreover, we will review the disadvantages of CAR-T cell therapy and propose several comprehensive recommendations which might guide its development.

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