Efficient manufacturing of CAR-T cells from whole blood: a scalable approach to reduce costs and enhance accessibility in cancer therapy

Efficient manufacturing of CAR-T cells from whole blood: a scalable approach to reduce costs and enhance accessibility in cancer therapy

Chimeric antigen receptor T (CAR-T) cells have significantly advanced the treatment of cancers such as leukemia and lymphoma. Traditionally, T cells are collected from patients through leukapheresis, an expensive and potentially invasive process that requires specialized equipment and trained person...

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Veröffentlicht in:Cytotherapy (Oxford, England) England), 2024-12
Hauptverfasser: Traynor, Roshini, Vignola, Isabella, Sarkar, Sarmila, Prochazkova, Michaela, Cai, Yihua, Shi, Rongye, Underwood, Sarah, Ramanujam, Supriya, Yates, Bonnie, Silbert, Sara, Jin, Ping, Dreyzin, Alexandra, Shah, Nirali N., Somerville, Robert P., Stroncek, David F., Song, Hannah W., Highfill, Steven L.
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cell manufacturing
cellular therapy
chimeric antigen receptor
peripheral blood mononuclear cells
whole blood
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container_title Cytotherapy (Oxford, England)
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creator Traynor, Roshini
Vignola, Isabella
Sarkar, Sarmila
Prochazkova, Michaela
Cai, Yihua
Shi, Rongye
Underwood, Sarah
Ramanujam, Supriya
Yates, Bonnie
Silbert, Sara
Jin, Ping
Dreyzin, Alexandra
Shah, Nirali N.
Somerville, Robert P.
Stroncek, David F.
Song, Hannah W.
Highfill, Steven L.
description Chimeric antigen receptor T (CAR-T) cells have significantly advanced the treatment of cancers such as leukemia and lymphoma. Traditionally, T cells are collected from patients through leukapheresis, an expensive and potentially invasive process that requires specialized equipment and trained personnel. Although whole blood collections are much more technically straightforward, whole blood starting material has not been widely utilized for clinical CAR-T cell manufacturing, in part due to lack of manufacturing processes designed for use in a good manufacturing practice (GMP) environment. Collecting cellular starting material from whole blood without leukapheresis could reduce manufacturing complexity and cost, thereby improving accessibility to CAR-T cell therapy. Whole blood samples were collected from eight healthy donors and one pediatric B-cell acute lymphoblastic leukemia (B-ALL) patient. These samples were processed using the Sepax C-Pro (Cytiva) instrument to isolate mononuclear cells (MNCs) via density gradient separation. CAR-T cells were then manufactured from the isolated MNCs using a GMP-compliant 7-day protocol, whereby T cells were activated with anti-CD3 and IL-2, transduced with GMP lentiviral vector encoding a CD19/CD22 bispecific CAR, and expanded in gas permeable cell culture bags. The resulting CAR-T cells were then evaluated for their phenotypic and functional properties using flow cytometry, cytokine release and cytotoxicity assays. From an average 77.7 mL of whole blood from healthy donors (range = 29–96 mL), we isolated an average of 42.2 × 106 CD3⁺ T cells (range 7.3–63.0) postprocessing. CAR-T cell cultures were initiated from thaw using 1–10 × 106 starting CD3+ T cells, yielding a median T cell number of 105 × 106 cells on day 7 (range 61–188 × 106). We observed 66 ± 11% mean transduction efficiency and produced a mean of 77.4 × 106 transduced CAR-T cells (range 30.8–143.5 × 106). Similar results were obtained when using a blood sample (28mL) obtained from a patient with relapsed B-ALL who had received recent chemotherapy. Therapeutically relevant doses of CD19/CD22 CAR-T cells can be successfully manufactured from whole blood. On average, 80 mL of whole blood yields enough CAR-T cells to create a single dose for a pediatric patient (50 kg) at a dosage of 1 × 106 CAR-T cells/kg. For larger patients, scaling up is straightforward by collecting a larger blood volume. This method also demonstrates a cost-effective approach to T cell
doi_str_mv 10.1016/j.jcyt.2024.11.013
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Traditionally, T cells are collected from patients through leukapheresis, an expensive and potentially invasive process that requires specialized equipment and trained personnel. Although whole blood collections are much more technically straightforward, whole blood starting material has not been widely utilized for clinical CAR-T cell manufacturing, in part due to lack of manufacturing processes designed for use in a good manufacturing practice (GMP) environment. Collecting cellular starting material from whole blood without leukapheresis could reduce manufacturing complexity and cost, thereby improving accessibility to CAR-T cell therapy. Whole blood samples were collected from eight healthy donors and one pediatric B-cell acute lymphoblastic leukemia (B-ALL) patient. These samples were processed using the Sepax C-Pro (Cytiva) instrument to isolate mononuclear cells (MNCs) via density gradient separation. CAR-T cells were then manufactured from the isolated MNCs using a GMP-compliant 7-day protocol, whereby T cells were activated with anti-CD3 and IL-2, transduced with GMP lentiviral vector encoding a CD19/CD22 bispecific CAR, and expanded in gas permeable cell culture bags. The resulting CAR-T cells were then evaluated for their phenotypic and functional properties using flow cytometry, cytokine release and cytotoxicity assays. From an average 77.7 mL of whole blood from healthy donors (range = 29–96 mL), we isolated an average of 42.2 × 106 CD3⁺ T cells (range 7.3–63.0) postprocessing. CAR-T cell cultures were initiated from thaw using 1–10 × 106 starting CD3+ T cells, yielding a median T cell number of 105 × 106 cells on day 7 (range 61–188 × 106). We observed 66 ± 11% mean transduction efficiency and produced a mean of 77.4 × 106 transduced CAR-T cells (range 30.8–143.5 × 106). Similar results were obtained when using a blood sample (28mL) obtained from a patient with relapsed B-ALL who had received recent chemotherapy. Therapeutically relevant doses of CD19/CD22 CAR-T cells can be successfully manufactured from whole blood. On average, 80 mL of whole blood yields enough CAR-T cells to create a single dose for a pediatric patient (50 kg) at a dosage of 1 × 106 CAR-T cells/kg. For larger patients, scaling up is straightforward by collecting a larger blood volume. This method also demonstrates a cost-effective approach to T cell activation and expansion which, alongside a more straightforward collection of whole blood, makes it more widely accessible especially for middle- and low-income countries. 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CAR-T cells were then manufactured from the isolated MNCs using a GMP-compliant 7-day protocol, whereby T cells were activated with anti-CD3 and IL-2, transduced with GMP lentiviral vector encoding a CD19/CD22 bispecific CAR, and expanded in gas permeable cell culture bags. The resulting CAR-T cells were then evaluated for their phenotypic and functional properties using flow cytometry, cytokine release and cytotoxicity assays. From an average 77.7 mL of whole blood from healthy donors (range = 29–96 mL), we isolated an average of 42.2 × 106 CD3⁺ T cells (range 7.3–63.0) postprocessing. CAR-T cell cultures were initiated from thaw using 1–10 × 106 starting CD3+ T cells, yielding a median T cell number of 105 × 106 cells on day 7 (range 61–188 × 106). We observed 66 ± 11% mean transduction efficiency and produced a mean of 77.4 × 106 transduced CAR-T cells (range 30.8–143.5 × 106). 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Traditionally, T cells are collected from patients through leukapheresis, an expensive and potentially invasive process that requires specialized equipment and trained personnel. Although whole blood collections are much more technically straightforward, whole blood starting material has not been widely utilized for clinical CAR-T cell manufacturing, in part due to lack of manufacturing processes designed for use in a good manufacturing practice (GMP) environment. Collecting cellular starting material from whole blood without leukapheresis could reduce manufacturing complexity and cost, thereby improving accessibility to CAR-T cell therapy. Whole blood samples were collected from eight healthy donors and one pediatric B-cell acute lymphoblastic leukemia (B-ALL) patient. These samples were processed using the Sepax C-Pro (Cytiva) instrument to isolate mononuclear cells (MNCs) via density gradient separation. 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Similar results were obtained when using a blood sample (28mL) obtained from a patient with relapsed B-ALL who had received recent chemotherapy. Therapeutically relevant doses of CD19/CD22 CAR-T cells can be successfully manufactured from whole blood. On average, 80 mL of whole blood yields enough CAR-T cells to create a single dose for a pediatric patient (50 kg) at a dosage of 1 × 106 CAR-T cells/kg. For larger patients, scaling up is straightforward by collecting a larger blood volume. This method also demonstrates a cost-effective approach to T cell activation and expansion which, alongside a more straightforward collection of whole blood, makes it more widely accessible especially for middle- and low-income countries. 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subjects cell manufacturing
cellular therapy
chimeric antigen receptor
peripheral blood mononuclear cells
whole blood
title Efficient manufacturing of CAR-T cells from whole blood: a scalable approach to reduce costs and enhance accessibility in cancer therapy
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