Uppsala University Hospital and Sana Biotechnology Announce Authorization of the First-in-Human Clinical Trial Application for a Primary Islet Cell Treatment for Patients with Type 1 Diabetes
Goal is to report UP421 proof of concept data in 2023 and 2024
Potential to remove immunosuppression from islet cell transplantation
SEATTLE, Nov. 17, 2023 (GLOBE NEWSWIRE) -- Sana Biotechnology, Inc. (NASDAQ: SANA), a company focused on changing the possible for patients through engineered cells, and Uppsala University Hospital in Sweden today announced the Swedish Medical Products Agency has authorized Uppsala University’s Clinical Trial Application (CTA) to initiate an investigator-sponsored, first-in-human study of UP421, an allogeneic, primary islet cell therapy engineered with Sana’s hypoimmune (HIP) technology, in patients with type 1 diabetes.
The goal of UP421 treatment is to provide proof of concept for transplanting functional islet cells without immunosuppression. UP421 is engineered using Sana’s hypoimmune platform modifications with the goal of evading both allogeneic and autoimmune rejection. The study is designed with endpoints of safety, cell survival, immune evasion, and C-peptide production. Insights from this study may inform development of Sana’s SC451, a hypoimmune-modified stem-cell derived islet cell therapy for patients with type 1 diabetes.
“Islet cell transplantation has shown curative potential for patients with type 1 diabetes, but the need for concurrent immunosuppression has led to side effects, limited efficacy, and decreased utilization. Sana’s hypoimmune platform has shown the potential to evade both allogeneic and autoimmune rejection in preclinical models, and we look forward to seeing if these insights translate into patients, providing a path to cell transplantation without immunosuppression,” said Steve Harr, Sana’s President and CEO. “The team at Uppsala has significant experience in primary islet cell manufacturing, transplantation, and clinical care of these patients, and we look forward to seeing the results from this clinical study and applying learnings to SC451.”
“We are pleased with the authorization of the CTA and look forward to treating a patient with cells engineered with this novel technology,” said Per-Ola Carlsson, Study Principal Investigator, Senior Physician and Professor of Diabetes at Uppsala University Hospital. “We have performed approximately 165 allogeneic, primary islet cell transplants and have seen the benefits for patients, but the complications of immunosuppression inhibit broader use of this procedure. Combining Sana’s hypoimmune technology with primary islet cell transplantation therapy can generate important first-in-human data that may be a step to removing immunosuppression from allogeneic cell transplant in the type 1 diabetes setting. The long-term hope is that all patients with type 1 diabetes can be cured of the disease by replacing their destroyed insulin-producing cells with new ones.”
Primary islet cell transplantation is an established procedure in type 1 diabetes, where allogeneic islet cells are isolated from a cadaver and transplanted into a patient with a goal of blood glucose control without the need for insulin. As with any organ transplant, suppression of the recipient’s immune system is required to prevent immune rejection of the transplanted cells. In addition to complications from this immune suppression, inadequate immunosuppression has limited uptake and durability of effect, as most patients eventually reject the transplanted islets over months to years, lose glucose control, and become insulin-dependent again, primarily due to immune rejction of the allogeneic islets from inadequate immunosuppression.
Sana’s hypoimmune technology seeks to overcome the immunologic rejection of allogeneic cells via disruption of human leukocyte antigen (HLA) class I and class II expression to allow cells to evade the adaptive immune system, including antibody and T cell responses, as well as overexpression of CD47 to allow cells to evade the innate immune cell system, in particular macrophages and natural killer (NK) cells. If UP421 successfully overcomes immunologic rejection, it may result in engraftment, survival, and C-peptide production in patients with type 1 diabetes following transplantation without immune suppression. Sana’s prior presentations across multiple preclinical models have highlighted the potential of this platform to enable allogeneic cells to evade immune recognition and the potential of hypoimmune-modified cells as a therapeutic for patients.
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