Educed MHC-II but increased CD80 expression, and the ability to suppress T cell responses suggested a new stage for tolerance induction [14].Other critical factors related to islet allografts survivalIn addition to different means of inducing Tol-DCs in allograft survival, there are several other critical factors related to survival: 1) Prior to DC infusion. The source of DCs (donor-derived, recipient-derived, semi-allogeneic), DC subsets (bone-marrow dendritic cells (BMDC), plasmacytoid DCs (pDC), CD4+DC, CD8+DC), recovery, and purity of the DC were important factors [3]. Actually, our outcomes suggested effect interventions with DCs between donor and recipient on graft survival were different, such as for the MSC induction and allopeptide-pulsed groups mentioned previously. BMDC and other derived DCs both prolonged islet graft survival (Table 3). However, it was different between liver-derived DCs and spleen-derived DCs. Rastellini et al. demonstrated liver-derived DCs, but not spleen-derived DCs, prolonged islet graft survival. This is likely because liver-derived DCs express lower levels of MHC-II and CTLA-4CR, which might account for their better effect on graft survival [22]. The inherent tolerogenicity of liver and chimerism were also critical reasons for graft survival [1]. Tol-DCs infusion. The time and route of administration, frequency and dose of Tol-DCs administered, and optimum combined immunosuppression (biological agents, pharmacological agents) should all be considered when evaluating results [3]. Organ specificity. As described above, Chaib et al. Demonstrated that non-parenchymal cells (NPCs) induced organ-specific tolerance in their experiments. Generally, the different organs related to immunogenicity, histology and physiology showed diversity and complexity in the same immune intervention [17]. Non-immunologic factors. These non-immunologic factors play a key role in graft survival, separately or synergistically, such as seen in ischemia-reperfusion injury (IRI), infection, disease stage, graft preservation, and operation difficulty [23,24].translation of Tol-DC in transplantation. Cell therapy with TolDC is already underway in human autoimmune disease [26]. The first Phase I (safety) study of autologous Tol-DCs in T1D patients was published recently [6]. The results show that DCs were tolerated, discernible adverse events did not occur in patients, and DCs up-regulated the frequency of B220+CD11c-B cells [6]. However, there are no reports regarding Tol-DC therapy in clinical islet transplantation. Although it has proven effective in mice [27], small animals and humans are different. There is still much to learn about the optimization of Tol-DC therapy for clinical islet transplantation, such as what dose, frequency, and route of administration to use, and the length of time appropriate for treating with Tol-DC. Even so, small animal models provide important insights into the mechanisms underlying tolerance induction [1,29,30]. We believe that Tol-DCs will one-day play a critical role in the treatment of clinical islet Homatropine methobromide site transplantation for T1D.Limitations of our reviewResearch on adoptive DprE1-IN-2 web infusion of Tol-DCs prolonging islet graft survival is at an early stage, with results available in only a few select studies (13 in 16402044 our systematic review). Descriptive analysis was conducted in this review, but not meta-analysis, due to incomplete data and little similarity between the studies selected. In addition, our results ma.Educed MHC-II but increased CD80 expression, and the ability to suppress T cell responses suggested a new stage for tolerance induction [14].Other critical factors related to islet allografts survivalIn addition to different means of inducing Tol-DCs in allograft survival, there are several other critical factors related to survival: 1) Prior to DC infusion. The source of DCs (donor-derived, recipient-derived, semi-allogeneic), DC subsets (bone-marrow dendritic cells (BMDC), plasmacytoid DCs (pDC), CD4+DC, CD8+DC), recovery, and purity of the DC were important factors [3]. Actually, our outcomes suggested effect interventions with DCs between donor and recipient on graft survival were different, such as for the MSC induction and allopeptide-pulsed groups mentioned previously. BMDC and other derived DCs both prolonged islet graft survival (Table 3). However, it was different between liver-derived DCs and spleen-derived DCs. Rastellini et al. demonstrated liver-derived DCs, but not spleen-derived DCs, prolonged islet graft survival. This is likely because liver-derived DCs express lower levels of MHC-II and CTLA-4CR, which might account for their better effect on graft survival [22]. The inherent tolerogenicity of liver and chimerism were also critical reasons for graft survival [1]. Tol-DCs infusion. The time and route of administration, frequency and dose of Tol-DCs administered, and optimum combined immunosuppression (biological agents, pharmacological agents) should all be considered when evaluating results [3]. Organ specificity. As described above, Chaib et al. Demonstrated that non-parenchymal cells (NPCs) induced organ-specific tolerance in their experiments. Generally, the different organs related to immunogenicity, histology and physiology showed diversity and complexity in the same immune intervention [17]. Non-immunologic factors. These non-immunologic factors play a key role in graft survival, separately or synergistically, such as seen in ischemia-reperfusion injury (IRI), infection, disease stage, graft preservation, and operation difficulty [23,24].translation of Tol-DC in transplantation. Cell therapy with TolDC is already underway in human autoimmune disease [26]. The first Phase I (safety) study of autologous Tol-DCs in T1D patients was published recently [6]. The results show that DCs were tolerated, discernible adverse events did not occur in patients, and DCs up-regulated the frequency of B220+CD11c-B cells [6]. However, there are no reports regarding Tol-DC therapy in clinical islet transplantation. Although it has proven effective in mice [27], small animals and humans are different. There is still much to learn about the optimization of Tol-DC therapy for clinical islet transplantation, such as what dose, frequency, and route of administration to use, and the length of time appropriate for treating with Tol-DC. Even so, small animal models provide important insights into the mechanisms underlying tolerance induction [1,29,30]. We believe that Tol-DCs will one-day play a critical role in the treatment of clinical islet transplantation for T1D.Limitations of our reviewResearch on adoptive infusion of Tol-DCs prolonging islet graft survival is at an early stage, with results available in only a few select studies (13 in 16402044 our systematic review). Descriptive analysis was conducted in this review, but not meta-analysis, due to incomplete data and little similarity between the studies selected. In addition, our results ma.