Safety, efficacy and total cost of point-of-care manufactured anti-CD19 CAR-T cell therapy in India: VELCART trial.

Background Chimeric antigen receptor (CAR) T-cell immunotherapy is increasingly used for refractory lymphoma but may lead to cytokine release syndrome (CRS) and immune effector cell-associated neurotoxicity syndrome (ICANS). Imaging may assist in clinical management. Associations between CRS or ICANS grade and imaging findings remain not fully established. Purpose To determine associations between imaging findings and clinical grade of CRS or ICANS, evaluate response patterns, and assess imaging use following CAR T-cell treatment. Materials and Methods Patients with refractory B-cell lymphoma who received CAR T-cell infusion between 2018 and 2020 at a single center were analyzed retrospectively. Clinical CRS or ICANS toxicity grade was assessed using American Society for Transplantation and Cellular Therapy, or ASTCT, consensus grading. Thoracic and head images (radiographs, CT scans, MRI scans) were evaluated. Associations between imaging findings and clinical CRS or ICANS grade were analyzed. Wilcoxon signed-rank and χ2 tests were used to assess associations between thoracic imaging findings, clinical CRS toxicity grade, and imaging-based response. Response to therapy was evaluated according to Deauville five-point scale criteria. Results A total of 38 patients (mean age ± standard deviation, 59 years ± 10; 23 men) who received CAR T-cell infusion were included. Of these, 24 (63% [95% CI: 48, 79]) and 11 (29% [95% CI: 14, 44]) experienced clinical grade 1 or higher CRS and ICANS, respectively. Patients with grade 2 or higher CRS were more likely to have thoracic images with abnormal findings (10 of 14 patients [71%; 95% CI: 47, 96] vs five of 24 patients [21%; 95% CI: 4, 37]; P = .002) and more likely to have imaging evidence of pleural effusions (five of 14 [36%; 95% CI: 10, 62] vs two of 24 [8.3%; 95% CI: 0, 20]; P = .04) and atelectasis (eight of 14 [57%; 95% CI: 30, 84] vs six of 24 [25%; 95% CI: 7, 43]; P = .048). Positive imaging findings were identified in three of seven patients (43%) with grade 2 or higher ICANS who underwent neuroimaging. The best treatment response included 20 of 36 patients (56% [95% CI: 39, 72]) with complete response, seven of 36 (19% [95% CI: 6, 33]) with partial response, one of 36 (2.8% [95% CI: 0, 8]) with stable disease, and eight of 36 (22% [95% CI: 8, 36]) with progressive disease. Conclusion Thoracic imaging findings, including pleural effusions and atelectasis, correlated with cytokine release syndrome grade following chimeric antigen receptor (CAR) T-cell infusion. CAR T-cell therapy yielded high response rates. © RSNA, 2021 Online supplemental material is available for this article. See also the editorial by Langer in this issue.

Utilization of Investigations for Neurotoxicity in CD19 and BCMA CART Recipients

Age defining immune effector cell associated neurotoxicity syndromes in aggressive large B cell lymphoma patients treated with axicabtagene ciloleucel.

Safety and Antitumor Effects of CD19-Specific Autologous Chimeric Antigen Receptor-Modified T (CAR-T) Cells Expressing the Inducible Caspase 9 Safety Switch (iC9-CAR19 T Cells) in Adult Acute Lymphoblastic Leukemia (ALL)

Outcomes of Patients Requiring ICU Admission after CD19 Directed CAR T-Cells

Unbiased Metabolomic Screening Reveals Pre-Existing Plasma Signatures in Large B-Cell Lymphoma Patients Treated with Anti-CD19 Chimeric Antigen Receptor (CAR) T-Cells: Association with Cytokine Release Syndrome (CRS) and Neurotoxicity (ICANS)

Impact of Icans on Long-Term Neurocognitive Function in Patients with Diffuse Large B-Cell Lymphoma Receiving CAR T-Cell Therapy

CAR T-cell therapy for solid tumours

Chimeric Antigen Receptor T Cells: Toxicity and Management Considerations

Pre-CAR-T GTE Scoring of Electroencephalogram Abnormalities As Predictive Biomarkers for Icans

Risk factors for cytokine release syndrome and neurotoxicity in patients receiving epcoritamab or glofitamab for large B cell lymphoma: A multi-center, retrospective, real world analysis.

CAR-T Cell Subsets and Immune Repertoire Are Associated with Immune-Related Adverse Events and Efficacy after CD19 CAR T-Cell Therapy in B Cell Lymphoma

A Phase 1 Dose Escalation Trial of Third-Generation CD19-Directed CAR T-Cells Incorporating CD28 and Toll-like Receptor 2 (TLR2) Intracellular Domains for Relapsed or Refractory B-Cell Non-Hodgkin Lymphomas (ENABLE)

Acute kidney injury (AKI) occurs in 30% of patients infused with chimeric antigen receptor (CAR) T-cells. The purpose of this study was to identify risk factors and long-term outcomes after AKI in patients who received CAR T-cell therapy. Medical records of 115 adult patients with R/R hematological malignancies treated with CD19-targeted CAR T-cells at Vall d'Hebron University Hospital between July 2018 and May 2021. Baseline demographic data including age, gender, ethnicity, body mass index (BMI), and co-morbidities, as well as the type of hematological neoplasia and prior lines of therapy were collected. Laboratory parameters including serum creatinine and whole blood hemoglobin were retrospectively reviewed and values were gathered for days +1, +7, +14, +21, and +28 post-infusion. A total of 24/115 (21%) patients developed AKI related to CAR T-cell therapy; 6/24 with AKI over chronic kidney disease (CKD). Two patients had AKI in the context of lymphodepleting (LD) chemotherapy and the other 22 after CAR T-cell infusion, starting at day+1 in 3 patients, day+7 in 13 patients, day +14 in 1 patient, day+21 in 2 patients, and day+28 in 3 patients. Renal function was recovered in 19/24 (79%) patients within the first month after infusion. Male gender, CKD, cytokine release syndrome (CRS), and immune effector cell-associated neurotoxicity syndrome (ICANS) were associated with AKI. Male gender, CKD, ICANS grade ≥3 and CRS grade ≥2 were identified as independent risk factors for AKI on multivariable analysis. In terms of the most frequent CAR T-cell related complications, CRS was observed in 95 (82%) patients and ICANS in 33 (29%) patients. Steroids were required in 34 (30%) patients and tocilizumab in 37 (32%) patients. Six (5%) patients were admitted to the intensive care unit (1 for septic shock, 4 for CRS grade ≥2 associated to ICANS grade ≥2, and 1 for CRS grade ≥3). A total of 5 (4.4%) patients died in the first 30 days after CAR T-cell infusion for reasons other than disease progression, including 4 cases of infectious complications and 1 of heart failure. Our results suggest that AKI is a frequent but mild adverse event, with fast recovery in most patients.

e19506 Background: Chimeric antigen receptor (CAR) T-cell immunotherapy is a revolutionary treatment modality which has gained attention for its potential in treating multiple refractory hematological malignancies. Significant toxicities associated with CAR T- cell therapy remain a major concern. Cytokine release syndrome (CRS) and Immune Effector Cell Associated Neurotoxicity Syndrome (ICANS) are seen early on post CAR-T cell therapy. To date, the treatment of ICANS has largely been limited to supportive care and corticosteroids. More recently, some early clinical data investigated the use of Anakinra as a promising agent in prevention and treatment of severe ICANS. Methods: We analyze three cases in which Anakinra was used to treat high-grade ICANS concurrently with high dose steroids. Results: A 51-year-old woman with high grade DLBCL and secondary CNS involvement was treated with Tisagenlecleucel CAR-T therapy. On day 2, patient became altered and was diagnosed with ICANS Grade II. High dose steroids were started leading to resolution of ICANS. However, patient’s mentation worsened by day 7, progressing to ICANS Grade IV by day 8, and Anakinra 100 mg IV was added to the steroid regimen. By day 11, after 4 doses of Anakinra, patient’s neurotoxicity completely resolved. Patient achieved a PR by day 30 after CAR-T cell infusion. In the second case, a 65-year-old man with DLBCL and leptomeningeal involvement developed ICANS Grade II on day 1 after Tisagenlecleucel CAR-T therapy and was started on high dose steroids. By day 4, neurotoxicity worsened and progressed to ICANS Grade IV. On day 5 patient was transferred to ICU for a mechanical ventilation, and Anakinra 100 mg IV was added and continued daily for 7 days. By day 12, neurotoxicity improved to ICANS grade II and patient was extubated. Meanwhile, high dose steroids were tapered. His condition acutely worsened by day 19, prompting transfer to the ICU and re-initiation of Anakinra concurrently with steroids. His family decided against further escalation of care on day 22. Patient was transitioned to comfort care and died 23 days post CAR-T cell infusion. In the third case, a 65-year-old man with mantle cell lymphoma was treated with Brexucabtagene autoleucel CAR-T therapy. On day 8, patient developed ICANS Grade I which rapidly progressed to Grade IV. High dose steroids were started and ICANS improved to Grade II on Day 9. However, on Day 10 patient’s mentation again worsened and one dose of Anakinra 100mg IV was added to the steroid regimen. By day 11, ICANS completely resolved, and patient was ultimately discharged home on day 15. Patient was able to achieve interval CR by day 30 after CAR-T cell infusion. Conclusions: In the reported cases, ICANS improved following administration of Anakinra, adding support to the idea that Anakinra may be beneficial in treatment of high-grade ICANS. Future studies are needed to better understand the overall efficacy and the ideal timeline for administration.