Alaa Alzhrani scite author profile

Short‐term outcomes in kidney transplantation are marred by progressive transplant failure and mortality secondary to immunosuppression toxicity. Immune modulation with autologous polyclonal regulatory T cell (Treg) therapy may facilitate immunosuppression reduction promoting better long‐term clinical outcomes. In a Phase I clinical trial, 12 kidney transplant recipients received 1–10 × 106 Treg per kg at Day +5 posttransplantation in lieu of induction immunosuppression (Treg Therapy cohort). Nineteen patients received standard immunosuppression (Reference cohort). Primary outcomes were rejection‐free and patient survival. Patient and transplant survival was 100%; acute rejection‐free survival was 100% in the Treg Therapy versus 78.9% in the reference cohort at 48 months posttransplant. Treg therapy revealed no excess safety concerns. Four patients in the Treg Therapy cohort had mycophenolate mofetil withdrawn successfully and remain on tacrolimus monotherapy. Treg infusion resulted in a long‐lasting dose‐dependent increase in peripheral blood Tregs together with an increase in marginal zone B cell numbers. We identified a pretransplantation immune phenotype suggesting a high risk of unsuccessful ex‐vivo Treg expansion. Autologous Treg therapy is feasible, safe, and is potentially associated with a lower rejection rate than standard immunosuppression. Treg therapy may provide an exciting opportunity to minimize immunosuppression therapy and improve long‐term outcomes.

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Identification, selection, and expansion of non-gene modified alloantigen-reactive Tregs for clinical therapeutic use

Alzhrani

Bottomley

Wood

et al. 2020

Cellular Immunology

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Highlights Tregs are a major focus of investigation in transplantation for immunosuppression minimisation. Development of alloantigen-specific Tregs has the potential to improve efficacy and safety. A number of methodologies for production exist including culture with donor alloantigen. Clinical trials of polyclonal Treg therapy are now moving into Phase II and beyond.

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Immune Monitoring for Advanced Cell Therapy Trials in Transplantation: Which Assays and When?

et al. 2021

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A number of immune regulatory cellular therapies, including regulatory T cells and mesenchymal stromal cells, have emerged as novel alternative therapies for the control of transplant alloresponses. Clinical studies have demonstrated their feasibility and safety, however developing our understanding of the impact of cellular therapeutics in vivo requires advanced immune monitoring strategies. To accurately monitor the immune response, a combination of complementary methods is required to measure the cellular and molecular phenotype as well as the function of cells involved. In this review we focus on the current immune monitoring strategies and discuss which methods may be utilized in the future.

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Mammalian-specific decellularized matrices derived bioink for bioengineering of liver tissue analogues: A review

Mir¹,

Nakamura²,

Sakai³

et al. 2023

IJB

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The absolute shortage of compatible liver donors and the growing number of potential recipients have led scientists to explore alternative approaches to providing tissue/ organ substitutes from bioengineered sources. Bioartificial regeneration of a fully functional tissue/organ replacement is highly dependent on the right combination of engineering tools, biological principles, and materiobiology horizons. Over the past two decades, remarkable achievements have been made in hepatic tissue engineering by converging various advanced interdisciplinary research approaches. Three-dimensional (3D) bioprinting has arisen as a promising state-of-the-art tool with strong potential to fabricate volumetric liver tissue/organ equivalents using viscosity- and degradation-controlled printable bioinks composed of hydrous microenvironments, and formulations containing living cells and associated supplements. Source of origin, biophysiochemical, or thermomechanical properties and crosslinking reaction kinetics are prerequisites for ideal bioink formulation and realizing the bioprinting process. In this review, we delve into the forecast of the potential future utility of bioprinting technology and the promise of tissue/organ-specific decellularized biomaterials as bioink substrates. Afterward, we outline various methods of decellularization, and the most relevant studies applying decellularized bioinks toward the bioengineering of in vitro liver models. Finally, the challenges and future prospects of decellularized material-based bioprinting in the direction of clinical regenerative medicine are presented to motivate further developments.

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Alaa Alzhrani

Feasibility, long-term safety, and immune monitoring of regulatory T cell therapy in living donor kidney transplant recipients

Identification, selection, and expansion of non-gene modified alloantigen-reactive Tregs for clinical therapeutic use

Immune Monitoring for Advanced Cell Therapy Trials in Transplantation: Which Assays and When?

Mammalian-specific decellularized matrices derived bioink for bioengineering of liver tissue analogues: A review

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