ABSTRACT
Background & Aim: Immunocompromised patients are susceptible to high-risk opportunistic infections and malignant diseases. If available, most antiviral and antifungal drugs are quite toxic, relatively ineffective, and induce resistance in the long term. Methods, Results & Conclusion(s): We have previously demonstrated the safety of adoptive cell therapy for COVID-19 patients with CD45RA negative cells containing SARS-CoV-2-specific T cells from a donor, chosen based on HLA compatibility and cellular response to SARS-CoV-2 peptide pools. After finishing a Phase 2 randomized multicenter clinical trial (RELEASE, NCT04578210), we concluded that the infusion is safe, effective, accelerates lymphocyte recovery and shows hallmarks of an immune response. To use adoptive cell therapy to treat COVID-19 it would be necessary to develop a biobank of living drugs. For that, we examined the immune evolution performing a longitudinal analysis from previously SARS-CoV-2 infected and infection- naive individuals covering 21 months from infection. Cellular responses were maintained over time while humoral responses increased after vaccination but were gradually lost. Therefore, the best donors would be recovered individuals and two months after vaccination. We also evaluated the effect of dexamethasone (current standard of care treatment for COVID-19 and other infections involving lymphopenia) and Interleukin-15 (cytokine involved in T-cell maintenance and survival) on CD45RA negative. Dexamethasone did not alter cell functionality, proliferation or phenotype at a clinical-practice concentration, while interleukin-15 increased the memory T-cell and T-regulatory cell activation state, and interferon gamma release. Furthermore, we applied the adoptive passive transfer of CD45RA negative cells containing pathogen-specific memory T-cells to other infectious diseases characterized by sustained lymphopenia. We infused six immunocompromised patients with Cytomegalovirus, BK virus, Aspergillus, and Epstein-Barr virus lymphoproliferative disease. Patients experienced pathogen clearance, resolution of symptoms and lymphocyte increase. Transient microchimerism was detected in three patients. The use of CD45RA negative cells containing specific memory T cells of a third-party donor for treating severe pathogenic diseases in immunocompromised patients is feasible, safe, and effective, and has an advantage over other cell therapies such as lower costs and a less complex regulatory environment.Copyright © 2023 International Society for Cell & Gene Therapy
ABSTRACT
Background & Aim: The COVID-19 pandemic has resulted in significant morbidity and mortality worldwide. The vaccines had dramatically decreased infection rates, number of deaths, and hospitalizations, but they are not 100% effective and immunity is lost gradually over time. We have previously shown how we are able to detect, isolate and produce at clinical scale SARS-CoV-2-specific T cells within CD45RA-memory T cells from COVID-19 convalescent donors. In a phase I clinical trial we have proved that treatment with these cells of hospitalized patients with moderate/severe COVID-19 is safe and feasible. Understanding the durability and the level of cellular immunity within the CD45RA- memory T cells and how changes with immunization are critical for the development of a biobank of living drugs to treat future COVID-19 patients. We performed a longitudinal exploratory analysis of the SARS-CoV-2 specific humoral and cellular immunity within the memory CD45RA- T cells in naive and previously infected individuals at different time points after two doses of BNT162b2 BioNTech/Pfizer vaccine Methods, Results & Conclusion: We studied the cellular and humoral response of SARS-CoV-2 specific memory T cells from recovered patients and controls at different time points: 2 weeks after recovering from COVID-19, 9 months after the infection/just before mRNA immunization, 10 and 65 days after full immunization. Detection of SARSCoV- 2- Specific Memory T Cells was performed by IFNg assay after exposure of cells to the M, N, and S SARS-CoV-2 peptides. Our data shows that memory T cell responses within the CD45RA- memory T cell subpopulation and most of the subsets tend to be higher in recovered individuals at all time points. The cellular response produced by control individuals to the S peptide is like the one from recovered patients at the same time point. Humoral responses were higher in recovered individuals after full immunization. Antibodies titer was not boosted after the late vaccine time point. An exploratory analysis of non-parametric Spearman’s rho correlation of humoral and cellular responses shows a positive correlation after infection with the 3 peptides and 65 days after immunization. In conclusion: We have analyzed the SARS-COV-2 specific T cells within the CD45RA- memory T cell subpopulation and the different subsets at different time points after (Figure Presented) (Figure Presented) infection and fully vaccinated. We claim that the best donors would be immunized individuals recovered from COVID-19 ideally in a time frame not higher than 6 months.
ABSTRACT
Introduction COVID-19 is usually a mild disease in immunocompetent children, with ~1% requiring intensive care unit (ICU) admission and <0.1% mortality. Data on its course in children following hematopoietic cell transplantation (HCT) is limited. Methods Data on children following HCT who developed COVID-19 (diagnosed by positive SARS-CoV-2 PCR on respiratory tract samples) during 3.2020-4.2021 were prospectively collected by EBMT and GETH, including demography, HCT data, COVID-related manifestations, ICU admission and mortality. Factors associated with worse outcomes (ICU admission or mortality) were characterized. Results Sixty-two children (34 boys;median age 9;min-max;0.7-17 years) were reported from 27 centers, 16 countries;57 (92%) following allogeneic and 5 (8%) following autologous HCT. Underlying diseases were acute leukemia (23;37%), inherited disorders (9;15%), hemoglobinopathies (7;11%), solid tumor (6;10%), bone marrow failure (5;8%), other malignant (8;13%) and non-malignant (4;6%) diseases. Five (8%) children had high blood pressure;6 (10%) had underlying lung pathology. The median time from the most recent HCT to COVID was 5 months (min-max;0-169). The stem cell source was bone marrow (33);peripheral (22) or cord blood (1). Among the patients with information available, 34 (62%) underwent in-vivo T cell depletion, 20 (33%) received corticosteroids, and 36 (60%) other immunosuppressant drugs(s) within two months prior to and after the COVID-19 episode. The presence of acute grade 2-4 or chronic graft versus host disease (GVHD) was reported in 12/54 (23%) and 8/51 (16%) children, respectively. Clinical presentation (n=57) included fever (28;49%), cough (18;32%), diarrhea (8;14%), upper respiratory tract disease (as rhinorrhea, sinusitis, otitis, or pharyngitis;12;21%);six (10%) required oxygen to maintain oxygen saturation above 92%;20 children (35%) were asymptomatic. The median time from symptoms onset to COVID diagnosis was 1 day (-43-40). Sixty-three percent of patients were hospitalized;43% due to COVID. The proportion of children with neutropenia or lymphocytopenia (<500 cells/mm 3) was 75% and 73%, respectively. Sixteen children (26%) had evidence of viral (n=10), bacterial (n=6) or fungal (n=2) coinfections. The median time from COVID diagnosis to the last follow-up in alive patients was 69 days (min-max;2 - 294). Six (10%) children who developed COVID at a median 6.5 (min-max;2- 16) months following allo-HCT (median age 6 years;5 boys) required ICU care within a median 6 (min-max;-5-15) days after diagnosis. All of them were neutropenic, received steroids, and other immunosuppressive drugs at COVID diagnosis;5 had undergone in-vivo T cell depletion;5 were lymphocytopenic, 5 had GVHD (2 acute and 3 chronic);3 received non-invasive and 2 invasive ventilation. Three children had viral or bacterial coinfections. Three children died. Six (10%) children (5 boys, median age 10.5 years;min-max;4-13) who developed COVID at median 2 (min-max;0-147) months following allo-HCT died within median 35 days (min-max;5-54) after diagnosis. One had high blood pressure, and none suffered from underlying lung pathology. At the time of COVID, 3 were neutropenic, 2 lymphocytopenic;4 had GVHD (2 acute, 2 chronic);3 received steroids and 4 immunosuppressive drugs. Two had viral or bacterial coinfections. Five had positive SARS-CoV-2 PCR at the time of death. In 3, COVID was the primary cause of death. We compared nine children with the worse outcomes to 53 children with benign course. Among patients alive at 100-day post HCT, the probability of worse outcomes was higher in patients with vs. without chronic GVHD (Figure). No other significant differences were observed in demographic, underlying disease, and HCT-related characteristics. Compared to adults following HCT (Ljungman, Leukemia 2021), children had: - Shorter median time from HCT to COVID diagnosis, 5 vs 18 months;- Higher proportion of asymptomatic infections, 35% vs 9%;- Lower proportion of those who required oxygen, 10% vs 35%;- Lower all-cause mortality, 10% vs 29%. Conclusions Children following HCT with COVID-19 have a higher risk of ICU admission and mortality compared to immune competent children. The presence of chronic GVHD at COVID diagnosis was associated with worse outcomes. COVID course following HCT is milder in children compared to adults. [Formula presented] Disclosures: Averbuch: Takeda: Consultancy;Pfizer: Consultancy;GSK: Speakers Bureau. De La Camara: Roche: Consultancy;IQONE: Consultancy. Corbacioglu: Gentium/Jazz Pharmaceuticals: Consultancy, Honoraria. Mikulska: Pfizer: Membership on an entity's Board of Directors or advisory committees, Speakers Bureau;Gilead: Speakers Bureau;MSD: Speakers Bureau;Janssen: Speakers Bureau;Biotest: Speakers Bureau. Kulagin: Roche: Speakers Bureau;Sanofi: Speakers Bureau;Generium: Speakers Bureau;Biocad: Research Funding;Apellis: Research Funding;Alexion: Research Funding;X4 Pharmaceuticals: Research Funding;Novartis: Speakers Bureau;Johnson & Johnson: Speakers Bureau;Pfizer: Speakers Bureau. Cesaro: Sobi: Membership on an entity's Board of Directors or advisory committees;Gilead: Speakers Bureau. Lawson: Alexion: Honoraria. Kroeger: Neovii: Honoraria, Research Funding;Sanofi: Honoraria;Jazz: Honoraria, Research Funding;Celgene: Honoraria, Research Funding;Riemser: Honoraria, Research Funding;Gilead/Kite: Honoraria;AOP Pharma: Honoraria;Novartis: Honoraria. Styczynski: MSD, Pfizer, Giled, TEVA, Jazz, Novartis: Honoraria, Speakers Bureau. Ljungman: Takeda: Consultancy, Other: Endpoint committee, speaker;Enanta: Other: DSMB;Janssen: Other: Investigator;OctaPharma: Other: DSMB;Merck: Other: Investigator, speaker;AiCuris: Consultancy.
ABSTRACT
Background: Adoptive cell immunotherapies for opportunistic virus in immunocompromised patients using haploidentical memory T cells have shown to be safe and effective. Since severe cases of COVID-19 present a dysregulated immune system with T cell lymphopenia and a hyper-inflammatory state we have proposed that a similar strategy could be proven to be efficient for COVID-19 patients. This is a study protocol of an open-label, multicenter, double-arm, randomized, dose-finding phase I/II clinical trial to evaluate the feasibility, safety, tolerability, and efficacy of the administration of a single dose of allogenic SARS-CoV-2 specific memory CD45RA - T cells and Natural Killer (NK) cells in COVID-19 patients with lymphopenia and pneumonia. The aim of the study is to find efficient treatments for patients with moderate/severe COVID-19. Identification of Specific memory T cells and NK cells: i)Memory T Cells: we first determined the existence of SARS-CoV-2 specific T cells within the CD45RA - T memory cells of the blood of convalescent donors. Memory T cells can respond quickly to the infection and provide long-term immune protection to reduce the severity of the COVID-19 symptoms without inducing classically T cell alloreactivity. Also, CD45RA - memory T cells confer protection for other pathogens the donors encountered in their life. ii)NK cells: we determined the phenotype of NK cells after COVID-19 and the main characteristic of SARS-CoV-2 specific NK population in the blood of convalescent donors, as it has been shown for cytomegalovirus infections. Also, NK cells confer protection for other pathogens the donors encountered in their life. Pilot Phase I- Safety, feasibility, and dose escalation: Between September and November 2020 a phase 1, dose-escalation, single-center clinical trial was conducted to evaluate the safety and feasibility of the infusion of CD45RA - memory T cells containing SARS-CoV-2 specific T cells as adoptive cell therapy against moderate/severe cases of COVID-19. Nine participants with pneumonia and/or lymphopenia and with at least one human leukocyte antigen (HLA) match with the donor were infused. The first three subjects received the lowest dose (1x10 5 cells/kg), the next three received the intermediate dose (5x10 5 cells/kg) and the last three received the highest dose (1x10 6 cells/kg) of CD45RA - memory T cells. Clinicaltrials.gov registration: NCT04578210. Findings: All participants' clinical status measured by National Early Warning Score (NEWS) and 7-category point ordinal scales showed improvement six days after infusion. No serious adverse events were reported. Inflammatory parameters were stabilized post-infusion and the participants showed lymphocyte recovery two weeks after the procedure. Donor microchimerism was observed at least for three weeks after infusion in all patients. Interpretation: This study provides preliminary evidence supporting the idea that treatment of COVID-19 patients with moderate/severe symptoms using convalescent SARS-CoV-2 specific CD45RA - memory T cells is feasible and safe. We did not find dose-liming toxicity. The Recommended Phase 2 dose was 1x10 6 CD45RA - T cells. Phase II- Efficacy: Between January 2021 and July 2021 patients have been enrolled based on the matched with the HLA genotype of the convalescent donors and following the protocol inclusion/exclusion criteria. The primary outcome is the incidence of patient recovery at day 14, defined as normalization of fever and oxygen saturation or lymphopenia recovery. Secondary outcomes are the time to normal level of lymphocytes, the proportion of patients showing clinical improvement at day 7, time to first negative SARS-CoV-2 PCR, the incidence of treatment-related adverse events, duration of hospitalization, time to discharge, time to improvement by one category a 7-point ordinal scale or NEWS score, the proportion of patients requiring intensive care unit, and all-cause mortality. In addition, lymphocyte recovery by multiparametric flow cytometry and donor chimerism by real-time PCR in the e perimental arm was monitored weekly during the first month. This study provides preliminary evidence supporting the idea that treatment of COVID-19 patients with moderate/severe symptoms using convalescent CD45RA - memory T cells is safe and feasible. The phase II clinical trial is ongoing to demonstrate efficacy. [Formula presented] Disclosures: Soria: Celgene: Other: Fees;Gilead: Other: Fees;AbbVie: Other: Fees.
ABSTRACT
BACKGROUND: Effective treatments are still needed to reduce the severity of symptoms, time of hospitalization, and mortality of COVID-19. SARS-CoV-2 specific memory T-lymphocytes obtained from convalescent donors recovered can be used as passive cell immunotherapy. METHODS: Between September and November 2020 a phase 1, dose-escalation, single centre clinical trial was conducted to evaluate the safety and feasibility of the infusion of CD45RA- memory T cells containing SARS-CoV-2 specific T cells as adoptive cell therapy against moderate/severe cases of COVID-19. Nine participants with pneumonia and/or lymphopenia and with at least one human leukocyte antigen (HLA) match with the donor were infused. The first three subjects received the lowest dose (1 × 105 cells/kg), the next three received the intermediate dose (5 × 105 cells/kg) and the last three received the highest dose (1 × 106 cells/kg) of CD45RA- memory T cells. Clinicaltrials.gov registration: NCT04578210. FINDINGS: All participants' clinical status measured by National Early Warning Score (NEWS) and 7-category point ordinal scales showed improvement six days after infusion. No serious adverse events were reported. Inflammatory parameters were stabilised post-infusion and the participants showed lymphocyte recovery two weeks after the procedure. Donor microchimerism was observed at least for three weeks after infusion in all patients. INTERPRETATION: This study provides preliminary evidence supporting the idea that treatment of COVID-19 patients with moderate/severe symptoms using convalescent CD45RA- memory T cells is feasible and safe. FUNDING: Clinical Trial supported by Spanish Clinical Research Network PT17/0017/0013. Co-funded by European Regional Development Fund/European Social Fund. CRIS CANCER Foundation Grant to AP-M and Agencia Valenciana de Innovación Grant AVI-GVA COVID-19-68 to BS.
ABSTRACT
BACKGROUND: Moderate/severe cases of COVID-19 present a dysregulated immune system with T cell lymphopenia and a hyper-inflammatory state. This is a study protocol of an open-label, multi-center, double-arm, randomized, dose-finding phase I/II clinical trial to evaluate the safety, tolerability, alloreactivity, and efficacy of the administration of allogeneic memory T cells and natural killer (NK) cells in COVID-19 patients with lymphopenia and/or pneumonia. The aim of the study is to determine the safety and the efficacy of the recommended phase 2 dose (RP2D) of this treatment for patients with moderate/severe COVID-19. METHODS: In the phase I trial, 18 patients with COVID-19-related pneumonia and/or lymphopenia with no oxygen requirement or with an oxygen need of ≤ 2.5 liters per minute (lpm) in nasal cannula will be assigned to two arms, based on the biology of the donor and the patient. Treatment of arm A consists of the administration of escalating doses of memory T cells, plus standard of care (SoC). Treatment of arm B consists of the administration of escalating doses of NK cells, plus SoC. In the phase II trial, a total of 182 patients with COVID-19-related pneumonia and/or lymphopenia requiring or not oxygen supplementation but without mechanical ventilation will be allocated to arm A or B, considering HLA typing. Within each arm, they will be randomized in a 1:1 ratio. In arm A, patients will receive SoC or RP2D for memory T cells plus the SoC. In arm B, patients will receive SoC or RP2D for NK cells plus the SoC. DISCUSSION: We hypothesized that SARS-CoV-2-specific memory T-lymphocytes obtained from convalescent donors recovered from COVID-19 can be used as a passive cell immunotherapy to treat pneumonia and lymphopenia in moderate/severe patients. The lymphopenia induced by COVID-19 constitutes a therapeutic window that may facilitate donor engraftment and viral protection until recovery. TRIAL REGISTRATION: ClinicalTrials.gov NCT04578210 . First Posted : October 8, 2020.
Subject(s)
COVID-19 , Lymphopenia , Clinical Trials, Phase I as Topic , Clinical Trials, Phase II as Topic , Humans , Immunologic Memory , Killer Cells, Natural , Lymphopenia/diagnosis , Lymphopenia/therapy , Multicenter Studies as Topic , Randomized Controlled Trials as Topic , SARS-CoV-2 , T-Lymphocytes , Treatment OutcomeABSTRACT
Syndrome coronavirus 2 (SARS-CoV-2) pandemic is causing a second outbreak significantly delaying the hope for the virus' complete eradication. In the absence of effective vaccines, we need effective treatments with low adverse effects that can treat hospitalized patients with COVID-19 disease. In this study, we determined the existence of SARS-CoV-2-specific T cells within CD45RA- memory T cells in the blood of convalescent donors. Memory T cells can respond quickly to infection and provide long-term immune protection to reduce the severity of COVID-19 symptoms. Also, CD45RA- memory T cells confer protection from other pathogens encountered by the donors throughout their life. It is of vital importance to resolve other secondary infections that usually develop in patients hospitalized with COVID-19. We found SARS-CoV-2-specific memory T cells in all of the CD45RA- subsets (CD3+, CD4+, and CD8+) and in the central memory and effector memory subpopulations. The procedure for obtaining these cells is feasible, easy to implement for small-scale manufacture, quick and cost-effective, involves minimal manipulation, and has no GMP requirements. This biobank of specific SARS-CoV-2 memory T cells would be immediately available "off-the-shelf" to treat moderate/severe cases of COVID-19, thereby increasing the therapeutic options available for these patients.
ABSTRACT
From the knowledge of the Behavioral Economy, the present essay aims to analyze the manifestations of the current and future behaviors of individuals, based on the new social conditions generated by the COVID-19 pandemic. To do this, a selection was made of the main authors of behavioral economics. The analytical-synthetic method was applied. The main units of analysis and their causal explanations (rationality, biases, nudges) were then used to interpret social behavior. The results point to the possibilities of using scientific knowledge to obtain good behavioral practices, fostering opportunities to mitigate the effect of the pandemic. The conclusions emphasize the need to overcome positivist, rationalist and deterministic limits in the conception of human nature;the social sciences have to promote the critical analysis of these conditions and project the mechanisms that guarantee an existence in the new environment, based on interdisciplinarity and a complex approach in the analysis of reality. It is concluded that Behavioral Economy has the potential for analysis and adjustment in future public policy decisions, therefore their knowledge and experiences must be applied to minimize the effect on human beings and the economy. © 2020. All Rights Reserved.
ABSTRACT
PURPOSE: The COVID-19 pandemic has forced healthcare stakeholders towards challenging decisions. We analyse the impact of the pandemic on the conduct of phase I-II trials for paediatric cancer during the first month of state of alarm in Spain. METHODS: A questionnaire was sent to all five ITCC-accredited Spanish Paediatric Oncology Early Phase Clinical Trial Units, including questions about impact on staff activities, recruitment, patient care, supply of investigational products, and legal aspects. RESULTS: All units suffered personnel shortages and difficulties in enrolling patients, treatment continuity, or performing trial assessments. Monitoring activity was frequently postponed (73%), and 49% of on-going trials interrupted recruitment. Only two patients could be recruited during this period (75% reduction in the expected rate). CONCLUSIONS: The COVID-19 crisis has significantly impacted clinical research practice and access to innovation for children with cancer. Structural and functional changes are under way to better cope with the expected future restrictions.