Browsing by Subject "Transplantation"
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Item Open Access Cultured thymus tissue implementation promotes donor-specific tolerance to allogeneic heart transplants.(JCI insight, 2020-04-30) Kwun, Jean; Li, Jie; Rouse, Clay; Park, Jae Berm; Farris, Alton B; Kuchibhatla, Maragatha; Turek, Joseph W; Knechtle, Stuart J; Kirk, Allan D; Markert, M LouiseEighty-six infants born without a thymus have been treated with allogeneic cultured thymus tissue implantation (CTTI). These infants, who lack T cells and are profoundly immunodeficient at birth, after CTTI from an unmatched donor develop genetically-recipient T cells that are tolerant to both their own major histocompatibility antigens and those of the donor. We tested use of CTTI with the goal of inducing tolerance to unmatched heart transplants in immunocompetent rats. We thymectomized and T cell depleted Lewis rats. The rats were then given Lewis x Dark Agouti (LWxDA) CTTI under the kidney capsule and vascularized DA heart transplants in the abdomen. Cyclosporine was administered for 4 months. The control group did not receive CTTI. Recipients with CTTI showed repopulation of naïve and recent thymic emigrant CD4 T cells; controls had none. Recipients of CTTI did not reject DA cardiac allografts. Control animals did not reject DA grafts, due to lack of functional T cells. To confirm donor-specific unresponsiveness, MHC-mismatched Brown Norway (BN) hearts were transplanted 6 months after the initial DA heart transplant. LW rats with (LWxDA) CTTI rejected the third-party BN hearts (mean survival time 10d; n=5). Controls did not (n=5). CTTI recipients produced antibody against third party BN donor but not against the DA thymus donor demonstrating humoral donor-specific tolerance. Taken together, F1(LWxDA) CTTI given to Lewis rats resulted in specific tolerance to the allogeneic DA MHC expressed in the donor thymus with resulting long-term survival of DA heart transplants after withdrawal of all immunosuppression.Item Open Access Emerging approaches and technologies in transplantation: the potential game changers.(Cellular & molecular immunology, 2019-02-13) Dangi, Anil; Yu, Shuangjin; Luo, XunrongNewly emerging technologies are rapidly changing conventional approaches to organ transplantation. In the modern era, the key challenges to transplantation include (1) how to best individualize and possibly eliminate the need for life-long immunosuppression and (2) how to expand the donor pool suitable for human transplantation. This article aims to provide readers with an updated review of three new technologies that address these challenges. First, single-cell RNA sequencing technology is rapidly evolving and has recently been employed in settings related to transplantation. The new sequencing data indicate an unprecedented cellular heterogeneity within organ transplants, as well as exciting new molecular signatures involved in alloimmune responses. Second, sophisticated nanotechnology platforms provide a means of therapeutically delivering immune modulating reagents to promote transplant tolerance. Tolerogenic nanoparticles with regulatory molecules and donor antigens are capable of targeting host immune responses with tremendous precision, which, in some cases, results in donor-specific tolerance. Third, CRISPR/Cas9 gene editing technology has the potential to precisely remove immunogenic molecules while inserting desirable regulatory molecules. This technology is particularly useful in generating genetically modified pigs for xenotransplantation to solve the issue of the shortage of human organs. Collectively, these new technologies are positioning the transplant community for major breakthroughs that will significantly advance transplant medicine.Item Open Access Invasive non-Aspergillus mold infections in transplant recipients, United States, 2001-2006.(Emerging infectious diseases, 2011-10) Park, Benjamin J; Pappas, Peter G; Wannemuehler, Kathleen A; Alexander, Barbara D; Anaissie, Elias J; Andes, David R; Baddley, John W; Brown, Janice M; Brumble, Lisa M; Freifeld, Alison G; Hadley, Susan; Herwaldt, Loreen; Ito, James I; Kauffman, Carol A; Lyon, G Marshall; Marr, Kieren A; Morrison, Vicki A; Papanicolaou, Genovefa; Patterson, Thomas F; Perl, Trish M; Schuster, Mindy G; Walker, Randall; Wingard, John R; Walsh, Thomas J; Kontoyiannis, Dimitrios PRecent reports describe increasing incidence of non-Aspergillus mold infections in hematopoietic cell transplant (HCT) and solid organ transplant (SOT) recipients. To investigate the epidemiology of infections with Mucorales, Fusarium spp., and Scedosporium spp. molds, we analyzed data from the Transplant-Associated Infection Surveillance Network, 23 transplant centers that conducted prospective surveillance for invasive fungal infections during 2001-2006. We identified 169 infections (105 Mucorales, 37 Fusarium spp., and 27 Scedosporium spp.) in 169 patients; 124 (73.4%) were in HCT recipients, and 45 (26.6%) were in SOT recipients. The crude 90-day mortality rate was 56.6%. The 12-month mucormycosis cumulative incidence was 0.29% for HCT and 0.07% for SOT. Mucormycosis incidence among HCT recipients varied widely, from 0.08% to 0.69%, with higher incidence in cohorts receiving transplants during 2003 and 2004. Non-Aspergillus mold infections continue to be associated with high mortality rates. The incidence of mucormycosis in HCT recipients increased substantially during the surveillance period.Item Open Access Translating Organoids into Artificial Kidneys.(Current transplantation reports, 2022-01) Kalejaiye, Titilola D; Barreto, Amanda D; Musah, SamiraPurpose of review
Kidney disease affects more than 13% of the world population, and current treatment options are limited to dialysis and organ transplantation. The generation of kidney organoids from human-induced pluripotent stem (hiPS) cells could be harnessed to engineer artificial organs and help overcome the challenges associated with the limited supply of transplantable kidneys. The purpose of this article is to review the progress in kidney organoid generation and transplantation and highlight some existing challenges in the field. We also examined possible improvements that could help realize the potential of organoids as artificial organs or alternatives for kidney transplantation therapy.Recent findings
Organoids are useful for understanding the mechanisms of kidney development, and they provide robust platforms for drug screening, disease modeling, and generation of tissues for organ replacement therapies. Efforts to design organoids rely on the ability of cells to self-assemble and pattern themselves into recognizable tissues. While existing protocols for generating organoids result in multicellular structures reminiscent of the developing kidney, many do not yet fully recapitulate the complex cellular composition, structure, and functions of the intact kidney. Recent advances toward achieving these goals include identifying cell culture conditions that produce organoids with improved vasculature and cell maturation and functional states. Still, additional improvements are needed to enhance tissue patterning, specialization, and function, and avoid tumorigenicity after transplantation.Summary
This report focuses on kidney organoid studies, advancements and limitations, and future directions for improvements towards transplantation.