Data from ongoing Phase 1 expansion trial using nanoplasmid demonstrated an improvement in efficacy over standard plasmid and a potentially best-in-class safety profile
SAN DIEGO, CA, USA I December 5, 2020 I Poseida Therapeutics, Inc. (NASDAQ:PSTX), a clinical-stage biopharmaceutical company utilizing proprietary gene engineering platform technologies to create cell and gene therapeutics with the capacity to cure, today reported results of an ongoing Phase 1 clinical trial of P-BCMA-101, an autologous chimeric antigen receptor T-cell (CAR-T) product candidate in relapsed/refractory multiple myeloma, during an oral presentation at the 2020 American Society of Hematology (ASH) Annual Meeting. The results show that patients treated with equivalent doses of product manufactured with a modified nanoplasmid process in the expanded Phase 1 trial achieved deeper responses while maintaining a similar safety profile compared to product manufactured with the Company’s legacy plasmid.
“Based on the dual benefits of improved efficacy and consistent safety demonstrated with the new nanoplasmid, we are moving forward with this optimized manufacturing method in all of our CAR-T programs,” said Eric Ostertag, M.D., Ph.D., chief executive officer of Poseida Therapeutics. “Furthermore, using our first-generation plasmid, we saw higher response rates as we escalated to higher dose cohorts not yet reached with the nanoplasmid product. We are currently moving into higher dosing cohorts with the nanoplasmid manufactured P-BCMA-101 product candidate and are optimistic further increases in effectiveness and durability are possible at these higher doses. We expect to finalize our Phase 2 dose in the first quarter of 2021.”
The Phase 1 dose escalation trial initially included five cohorts with a product candidate created using a standard plasmid process. The trial was expanded in 2020 to include cohorts utilizing a new nanoplasmid manufacturing process. The nanoplasmid technology allows for a reduction in the plasmid backbone size, enhancing the transposition efficiency during manufacturing and improving the final CAR-T product performance. The expansion part of the trial is also evaluating several novel dosing strategies with 19 patients treated as of the data cutoff with a variety of dosing regimens, including single administration, cyclic dosing, combination with rituximab, and combination with lenalidomide.
Using the new manufacturing process, a dose of 0.75 x 106 cells/kg was administered to eight patients in the initial P-BCMA-101 nanoplasmid expansion cohorts. Patients treated in this cohort and evaluable by International Myeloma Working Group (IMWG) criteria (n=6) showed a higher response rate, with an ORR of 67 percent as compared to an ORR of 50 percent for the same dosing cohort using the standard P-BCMA-101 plasmid (n=2). Additionally, as of the cutoff date, three patients achieved deeper responses of either very good partial response (VGPR) or complete response (CR) in the nanoplasmid expansion cohort as compared to no patients reaching a VGPR or CR in the standard plasmid group at the Cohort 1 dose. As of the data cutoff date, two of the three nanoplasmid patients who reached VGPR or CR remained in durable responses at approximately 6 months.
“We observed an excellent efficacy and safety profile with a single dose escalation. There were very low rates of CRS with no ICU admissions for CRS, resulting in a safety profile suggesting this therapy could be delivered to a greater number of patients in a community hospital or outpatient setting,” said Caitlin Costello, MD, Associate Clinical Professor of Medicine and member of the Division of Blood and Marrow Transplantation at University of California, San Diego. Dr. Costello is the principal investigator in the study, who presented the data during the ASH meeting.
At the 0.75 x 106 cells/kg dose, cytokine release syndrome (CRS) was seen in just one, or 12.5%, of evaluable Phase 1 nanoplasmid patients (n=8) and neurotoxicity was not seen in any patients, demonstrating the preservation of the product safety profile within the expansion cohort. The Company believes this highly favorable safety profile can be attributed to the gradual expansion of stem cell memory T (Tscm) cells when compared with published data from competitor products comprised of a higher percentage of T effector and other differentiated T cells (2-3 weeks to peak versus 3-7 days for most CAR-T cells). There have been no patient deaths, dose limiting toxicities or unexpected/off-target toxicities related to P-BCMA-101. The most common adverse events were cytopenias and infections generally attributable to lymphodepleting chemotherapy regimens. Based on the safety results, the protocol was amended to allow fully outpatient CAR-T cell administration.
The median patient age was 60, with a median time since diagnosis of approximately five years. Patients were heavily pre-treated, with a median of eight prior lines of therapy (2-18). All patients had received a protease inhibitor or at least one IMid, and nearly all patients had been previously treated with a CD38 monoclonal antibody. Sixty percent of the patients were refractory to all three drug classes, and four patients had previously received an anti-BCMA targeted therapy.
This open label, multicenter Phase 1 study is designed to assess the safety of P-BCMA-101 in subjects with relapsed and/or refractory multiple myeloma and includes multiple exploratory cohorts to evaluate the administration of P-BCMA-101 CAR-T within the framework of moving from the standard plasmid CAR-T product to the nanoplasmid product. The primary objective of this study is to determine the safety and maximum-tolerated dose of P-BCMA-101. Secondary objectives include anti-myeloma effect of P-BCMA-101. Additional information about the Phase 1 clinical study of P-BCMA-101 is available at www.clinicaltrials.gov using identifier: NCT03288493.
About P-BCMA-101
P-BCMA-101 is an autologous CAR-T therapy which is currently being evaluated in an expanded Phase 1 clinical trial for the treatment of patients with relapsed/refractory multiple myeloma to inform the potentially registrational Phase 2 clinical trial. P-BCMA-101 targets cells that express B cell maturation antigen, or BCMA, which is expressed on essentially all multiple myeloma cells. P-BCMA-101 is engineered with Poseida’s non-viral piggyBac® DNA Modification System, resulting in a high percentage of T stem cell memory cells. P-BCMA-101 is composed primarily of Tscm, a very young subset of T cells that are long-lived, self-renewing and multipotent, with the capacity to reconstitute the entire spectrum of T cell subsets, including T effector cells. They also survive for decades, and potentially for entire lifespans, with non-CAR-Tscm cells normally providing lifelong T cell immunity against some infectious agents. P-BCMA-101 received regenerative medicine advanced therapy (RMAT) status and orphan drug designation from the FDA. Preliminary results from the Company’s ongoing Phase 1 clinical trial suggest that P-BCMA-101 may have improved response rates with a favorable safety profile compared to published results from clinical trials of other CAR-T therapies at similar doses. The Phase 1 study is funded in part by the California Institute for Regenerative Medicine.
About Poseida Therapeutics, Inc.
Poseida Therapeutics is a clinical-stage biopharmaceutical company dedicated to utilizing our proprietary gene engineering platform technologies to create next generation cell and gene therapeutics with the capacity to cure. We have discovered and are developing a broad portfolio of product candidates in a variety of indications based on our core proprietary platforms, including our non-viral piggyBac DNA Modification System, Cas-CLOVER™ site-specific gene editing system and nanoparticle- and AAV-based gene delivery technologies. Our core platform technologies have utility, either alone or in combination, across many cell and gene therapeutic modalities and enable us to engineer our wholly-owned portfolio of product candidates that are designed to overcome the primary limitations of current generation cell and gene therapeutics.
SOURCE: Poseida Therapeutics
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Data from ongoing Phase 1 expansion trial using nanoplasmid demonstrated an improvement in efficacy over standard plasmid and a potentially best-in-class safety profile
SAN DIEGO, CA, USA I December 5, 2020 I Poseida Therapeutics, Inc. (NASDAQ:PSTX), a clinical-stage biopharmaceutical company utilizing proprietary gene engineering platform technologies to create cell and gene therapeutics with the capacity to cure, today reported results of an ongoing Phase 1 clinical trial of P-BCMA-101, an autologous chimeric antigen receptor T-cell (CAR-T) product candidate in relapsed/refractory multiple myeloma, during an oral presentation at the 2020 American Society of Hematology (ASH) Annual Meeting. The results show that patients treated with equivalent doses of product manufactured with a modified nanoplasmid process in the expanded Phase 1 trial achieved deeper responses while maintaining a similar safety profile compared to product manufactured with the Company’s legacy plasmid.
“Based on the dual benefits of improved efficacy and consistent safety demonstrated with the new nanoplasmid, we are moving forward with this optimized manufacturing method in all of our CAR-T programs,” said Eric Ostertag, M.D., Ph.D., chief executive officer of Poseida Therapeutics. “Furthermore, using our first-generation plasmid, we saw higher response rates as we escalated to higher dose cohorts not yet reached with the nanoplasmid product. We are currently moving into higher dosing cohorts with the nanoplasmid manufactured P-BCMA-101 product candidate and are optimistic further increases in effectiveness and durability are possible at these higher doses. We expect to finalize our Phase 2 dose in the first quarter of 2021.”
The Phase 1 dose escalation trial initially included five cohorts with a product candidate created using a standard plasmid process. The trial was expanded in 2020 to include cohorts utilizing a new nanoplasmid manufacturing process. The nanoplasmid technology allows for a reduction in the plasmid backbone size, enhancing the transposition efficiency during manufacturing and improving the final CAR-T product performance. The expansion part of the trial is also evaluating several novel dosing strategies with 19 patients treated as of the data cutoff with a variety of dosing regimens, including single administration, cyclic dosing, combination with rituximab, and combination with lenalidomide.
Using the new manufacturing process, a dose of 0.75 x 106 cells/kg was administered to eight patients in the initial P-BCMA-101 nanoplasmid expansion cohorts. Patients treated in this cohort and evaluable by International Myeloma Working Group (IMWG) criteria (n=6) showed a higher response rate, with an ORR of 67 percent as compared to an ORR of 50 percent for the same dosing cohort using the standard P-BCMA-101 plasmid (n=2). Additionally, as of the cutoff date, three patients achieved deeper responses of either very good partial response (VGPR) or complete response (CR) in the nanoplasmid expansion cohort as compared to no patients reaching a VGPR or CR in the standard plasmid group at the Cohort 1 dose. As of the data cutoff date, two of the three nanoplasmid patients who reached VGPR or CR remained in durable responses at approximately 6 months.
“We observed an excellent efficacy and safety profile with a single dose escalation. There were very low rates of CRS with no ICU admissions for CRS, resulting in a safety profile suggesting this therapy could be delivered to a greater number of patients in a community hospital or outpatient setting,” said Caitlin Costello, MD, Associate Clinical Professor of Medicine and member of the Division of Blood and Marrow Transplantation at University of California, San Diego. Dr. Costello is the principal investigator in the study, who presented the data during the ASH meeting.
At the 0.75 x 106 cells/kg dose, cytokine release syndrome (CRS) was seen in just one, or 12.5%, of evaluable Phase 1 nanoplasmid patients (n=8) and neurotoxicity was not seen in any patients, demonstrating the preservation of the product safety profile within the expansion cohort. The Company believes this highly favorable safety profile can be attributed to the gradual expansion of stem cell memory T (Tscm) cells when compared with published data from competitor products comprised of a higher percentage of T effector and other differentiated T cells (2-3 weeks to peak versus 3-7 days for most CAR-T cells). There have been no patient deaths, dose limiting toxicities or unexpected/off-target toxicities related to P-BCMA-101. The most common adverse events were cytopenias and infections generally attributable to lymphodepleting chemotherapy regimens. Based on the safety results, the protocol was amended to allow fully outpatient CAR-T cell administration.
The median patient age was 60, with a median time since diagnosis of approximately five years. Patients were heavily pre-treated, with a median of eight prior lines of therapy (2-18). All patients had received a protease inhibitor or at least one IMid, and nearly all patients had been previously treated with a CD38 monoclonal antibody. Sixty percent of the patients were refractory to all three drug classes, and four patients had previously received an anti-BCMA targeted therapy.
This open label, multicenter Phase 1 study is designed to assess the safety of P-BCMA-101 in subjects with relapsed and/or refractory multiple myeloma and includes multiple exploratory cohorts to evaluate the administration of P-BCMA-101 CAR-T within the framework of moving from the standard plasmid CAR-T product to the nanoplasmid product. The primary objective of this study is to determine the safety and maximum-tolerated dose of P-BCMA-101. Secondary objectives include anti-myeloma effect of P-BCMA-101. Additional information about the Phase 1 clinical study of P-BCMA-101 is available at www.clinicaltrials.gov using identifier: NCT03288493.
About P-BCMA-101
P-BCMA-101 is an autologous CAR-T therapy which is currently being evaluated in an expanded Phase 1 clinical trial for the treatment of patients with relapsed/refractory multiple myeloma to inform the potentially registrational Phase 2 clinical trial. P-BCMA-101 targets cells that express B cell maturation antigen, or BCMA, which is expressed on essentially all multiple myeloma cells. P-BCMA-101 is engineered with Poseida’s non-viral piggyBac® DNA Modification System, resulting in a high percentage of T stem cell memory cells. P-BCMA-101 is composed primarily of Tscm, a very young subset of T cells that are long-lived, self-renewing and multipotent, with the capacity to reconstitute the entire spectrum of T cell subsets, including T effector cells. They also survive for decades, and potentially for entire lifespans, with non-CAR-Tscm cells normally providing lifelong T cell immunity against some infectious agents. P-BCMA-101 received regenerative medicine advanced therapy (RMAT) status and orphan drug designation from the FDA. Preliminary results from the Company’s ongoing Phase 1 clinical trial suggest that P-BCMA-101 may have improved response rates with a favorable safety profile compared to published results from clinical trials of other CAR-T therapies at similar doses. The Phase 1 study is funded in part by the California Institute for Regenerative Medicine.
About Poseida Therapeutics, Inc.
Poseida Therapeutics is a clinical-stage biopharmaceutical company dedicated to utilizing our proprietary gene engineering platform technologies to create next generation cell and gene therapeutics with the capacity to cure. We have discovered and are developing a broad portfolio of product candidates in a variety of indications based on our core proprietary platforms, including our non-viral piggyBac DNA Modification System, Cas-CLOVER™ site-specific gene editing system and nanoparticle- and AAV-based gene delivery technologies. Our core platform technologies have utility, either alone or in combination, across many cell and gene therapeutic modalities and enable us to engineer our wholly-owned portfolio of product candidates that are designed to overcome the primary limitations of current generation cell and gene therapeutics.
SOURCE: Poseida Therapeutics
Post Views: 18
