UMLS:C0018133 - FACTA Search

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Query: UMLS:C0018133 (graft-versus-host disease)
18,032 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Bone marrow mesenchymal stem cells (BM-MSC) have the characteristics of self-renewal and multipotency. They secrete a variety of cytokines and provided and ideal microenvironment for the division, proliferation and differentiation of hematopoietic stem cells (HSC) through the interaction with other stromal cells. Previous studies indicated that MSC could enhance engrafment and alleviate GVHD in allo-HSC and MSC co-transplantation. This effect on transplantation immunity may associate with escaping MHC compatible HSC from antigen recognition and suppressing activation and proliferation of nonspecific lymphocytes. In this paper, the characteristics of BM-MSC influencing transplantation immunity and its mechanism were reviewed.
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PMID:[Immunomodulation of bone marrow mesenchymal stem cells in hematopoietic stem cell transplantation--review]. 1627 69

MSCs have received attention for their therapeutic potential in a number of disease states, including bone formation, diabetes, stem cell engraftment after marrow transplantation, graft-versus-host disease, and heart failure. Despite this diverse interest, the molecular signals regulating MSC trafficking to sites of injury are unclear. MSCs are known to transiently home to the freshly infarcted myocardium. To identify MSC homing factors, we determined chemokine expression pattern as a function of time after myocardial infarction (MI). We merged these profiles with chemokine receptors expressed on MSCs but not cardiac fibroblasts, which do not home after MI. This analysis identified monocyte chemotactic protein-3 (MCP-3) as a potential MSC homing factor. Overexpression of MCP-3 1 month after MI restored MSC homing to the heart. After serial infusions of MSCs, cardiac function improved in MCP-3-expressing hearts (88.7%, p < .001) but not in control hearts (8.6%, p = .47). MSC engraftment was not associated with differentiation into cardiac myocytes. Rather, MSC engraftment appeared to result in recruitment of myofibroblasts and remodeling of the collagen matrix. These data indicate that MCP-3 is an MSC homing factor; local overexpression of MCP-3 recruits MSCs to sites of injured tissue and improves cardiac remodeling independent of cardiac myocyte regeneration.
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PMID:Monocyte chemotactic protein-3 is a myocardial mesenchymal stem cell homing factor. 1705 10

Strong proliferative capacity and the ability to differentiate into the derivative cell types of three embryonic germ layers are the two important characteristics of embryonic stem cells. To study whether the mesenchymal stem cells from human fetal bone marrow (hfBM-MSCs) possess these embryonic stem cell-like biological characteristics, hfBM-MSCs were isolated from bone barrows and further purified according to the different adherence of different kinds of cells to the wall of culture flask. The cell cycle of hfBM-MSCs and MSC-specific surface markers such as CD29, CD44, etc were identified using flow cytometry. The expressions of human telomerase reverse transcriptase (hTERT), the embryonic stem cell-specific antigens, such as Oct4 and SSEA-4 were detected with immunocytochemistry at the protein level and were also tested by RT-PCR at the mRNA level. Then, hfBM-MSCs were induced to differentiate toward neuron cells, adipose cells, and islet B cells under certain conditions. It was found that 92.3% passage-4 hfBM-MSCs and 96.1% passage-5 hfBM-MSCs were at G(0)/G(1) phase respectively. hfBM-MSCs expressed CD44, CD106 and adhesion molecule CD29, but not antigens of hematopoietic cells CD34 and CD45, and almost not antigens related to graft-versus-host disease (GVHD), such as HLA-DR, CD40 and CD80. hfBM-MSCs expressed the embryonic stem cell-specific antigens such as Oct4, SSEA-4, and also hTERT. Exposure of these cells to various inductive agents resulted in morphological changes towards neuron-like cells, adipose-like cells, and islet B-like cells and they were tested to be positive for related characteristic markers. These results suggest that there are plenty of MSCs in human fetal bone marrow, and hfBM-MSCs possess the embryonic stem cell-like biological characteristics, moreover, they have a lower immunogenic nature. Thus, hfBM-MSCs provide an ideal source for tissue engineering and cellular therapeutics.
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PMID:[Proliferative capacity of mesenchymal stem cells from human fetal bone marrow and their ability to differentiate into the derivative cell types of three embryonic germ layers]. 1856 Jul 36

MSC have been suggested to be the precursor cells in the bone marrow stroma that provide a scaffold and promote hematopoiesis. They have therefore been suggested to enhance engraftment after autologous and allogeneic HSC transplantation. In patients undergoing transplantation, MSC infusion was shown to be safe and to enhance engraftment of HSC, as well as to reduce the incidence of both acute and chronic GVHD. We cotransplanted haploidentical AMSC with HLA-identical sibling-matched PBSC in two pediatric patients with refractory SAA after primary or secondary graft failure. At present, the two patients are more than two yr after cotransplantation without any treatment, transfusion-independent and in good condition. Thus, cotransplantation of MSC might enhance engraftment of HSC in patients regrafted for graft failure.
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PMID:Cotransplantation of haploidentical mesenchymal stem cells to enhance engraftment of hematopoietic stem cells and to reduce the risk of graft failure in two children with severe aplastic anemia. 1867 58

Natural killer (NK) cell-mediated cytotoxicity can control leukemia relapse while protecting patients from graft-versus-host disease (GVHD) after allogeneic stem cell transplant. Cord blood (CB) is rich in NK cell progenitors with similar properties of proliferation and cytotoxicity as adult blood NK cells. Hence, it is attractive to expand and potentially utilize these cells for adoptive immunotherapy. In this study, CB mononuclear cells were CD3-depleted by immunomagnetic microbead selection to remove T cells. This CD3(dep) CB-MNC fraction was then plated for ex vivo expansion, with or without a feeder layer of irradiated umbilical cord mesenchymal stem cells (UC-MSC), with or without cytokines that have been shown to be critical for NK expansion: IL-2, IL-15, IL-3, and FLT-3L. At an average of 2 weeks of culture, there was significantly higher expansion (64.7 +/- 8.4-fold) of CD56(+)/CD3(-) NK cells in the presence of the UC-MSC feeder layer and cytokines compared to controls (no increase with feeder layer only and 6.4 +/- 1.5-fold increase with cytokines only, P < .05). Contact between CD3(dep) CB-MNC cells and UC-MSC augmented NK expansion. The combination of all 4 cytokines was superior to IL-2 alone or 2 cytokines combinations: mean 64.7 +/- 8.4-fold expansion with 4 cytokines combination versus IL-2 alone, IL-2 + FLT-3L, IL-2 + IL-15 or IL-2 + IL-3 (12.2 +/- 2.0, 14.4 +/- 2.4, 10.4 +/- 4.1, 25.2 +/- 8.1 respectively). We also observed that only fresh CD3(dep) CB-MNC preparations could be expanded reliably, whereas frozen and thawed CD3(dep) CB-MNC cells did not expand consistently (mean fold increase 6.5 +/- 3.2). Cytotoxicity of expanded NK cells was compared with NK cells from fresh and overnight IL-2 activated CD3(dep) CB-MNC. Whereas fresh cells displayed no discernible killing, strong cytotoxicity against K562, Raji, REH, and SUP-B15 cells lines was noted after overnight activation in IL-2. Cytotoxicity of expanded NK cells against Raji, REH, and SUP-B15 was lower, which, however, correlated with a predominant expansion of CD56(+)/CD16(-) cells known to have less cytolytic activity than CD56(+)/CD16(+). To test the transfection efficiency in NK cells, fresh or expanded CD3(dep) CB-MNC cells were electroporated with either DNA or mRNA constructs for GFP. DNA had a low transfection efficiency (<10%), whereas the one for mRNA reached 52%, but at the cost of significant cell death. Our results suggest that CB NK cell progenitors can be expanded to obtain large numbers by using an irradiated feeder of UC-MSC. They maintain an elevated cytotoxic profile, and may be genetically manipulated-all characteristics that make them suitable for cellular therapies.
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PMID:Umbilical cord mesenchymal stem cells increase expansion of cord blood natural killer cells. 1872 66

Mesenchymal stem cells have been shown to mediate immunomodulatory effects. They have been used in patients with steroid-refractory acute GVHD (aGVHD), but their relevance as a therapeutic agent targeting aGVHD has still to be defined. In this case series, we report 13 patients with steroid-refractory aGVHD who received BM-derived MSC expanded in platelet lysate-containing medium from unrelated HLA disparate donors. MSC were characterized by their morphological, phenotypical and functional properties. All tested preparations suppressed the proliferation of in vitro activated CD4+ T cells. MSC were transfused at a median dosage of 0.9 x 10(6)/kg (range 0.6-1.1). The median number of MSC applications was 2 (range 1-5). Only two patients (15%) responded and did not require any further escalation of immunosuppressive therapy. Eleven patients received additional salvage immunosuppressive therapy concomitant to further MSC transfusions, and after 28 days, five of them (45%) showed a response. Four patients (31%) are alive after a median follow-up of 257 days, including one patient who initially responded to MSC treatment. In our patient cohort, response to MSC transfusion was lower than in the series reported earlier. However, our experience supports the potential efficacy of MSC in the treatment of steroid-refractory aGVHD.
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PMID:Treatment of refractory acute GVHD with third-party MSC expanded in platelet lysate-containing medium. 1882 Jul 9

Transplantation of haploidentical stem cells has become a well-established approach, which makes a potential donor available for almost all patients. This review focuses on current results and new strategies, especially in pediatric patients with malignant diseases. CD34(+) positive selection was the most common procedure for graft manipulation in the past years, whereas T and B cell depletion is a promising new method. GVHD could herewith be effectively reduced and primary engraftment was reported in 83-100% of patients after transplantation of high stem cell doses. For patients with ALL in remission, disease-free survival at 3 years ranged between 22 and 48%. TRM, mainly because of viral infections, was improved by the use of reduced-intensity conditioning (which helped to speed up T cell recovery) and by close monitoring of viral loads and prophylactic/preemptive therapy. The role of donor-derived Ag-specific T cells against viral and fungal antigens is currently under investigation. Patients with active disease at the time of transplantation had a poor outcome and several attempts to improve these results are currently evaluated, such as co-infusion of natural killer cells, co-transplantation of MSC, use of new antileukemic drugs and post-transplant immunotherapy.
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PMID:Haploidentical SCT in children: an update and future perspectives. 1897 46

MSCs, otherwise known as multipotent mesenchymal stromal cells, are being examined for the treatment of autoimmune disease (AD) on the basis of their in vitro antiproliferative properties, efficacy in animal models, apparent low acute toxicity and the early positive anecdotal outcomes in human acute GVHD. Phase I/II clinical trials are underway in Crohn's disease and multiple sclerosis (MS) and are being planned for systemic lupus erythematosus (SLE), systemic sclerosis (SSc), systemic vasculitis and other AD. Open issues include patient selection, disease stage and activity, MSC source and expansion and long-term safety. Multidisciplinary groups are collaborating to ensure maximal use of available resources to establish the place, if any, of MSC in the treatment of AD.
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PMID:Multipotent mesenchymal stromal cells for autoimmune diseases: teaching new dogs old tricks. 1930 35

Human mesenchymal stem cells (hMSCs) are rare progenitor cells present in adult bone marrow that have the capacity to differentiate into a variety of tissue types, including bone, cartilage, tendon, fat, and muscle. In addition to multilineage differentiation capacity, MSCs regulate immune and inflammatory responses, providing therapeutic potential for treating diseases characterized by the presence of an inflammatory component. The availability of bone marrow and the ability to isolate and expand hMSCs ex vivo make these cells an attractive candidate for drug development. The low immunogenicity of these cells suggests that hMSCs can be transplanted universally without matching between donors and recipients. MSCs universality, along with the ability to manufacture and store these cells long-term, present a unique opportunity to produce an "off-the-shelf" cellular drug ready for treatment of diseases in acute settings. Accumulated animal and human data support MSC therapeutic potential for inflammatory diseases. Several phase III clinical trials for treatment of acute Graft Versus Host Disease (GVHD) and Crohn's disease are currently in progress. The current understanding of cellular and molecular targets underlying the mechanisms of MSCs action in inflammatory settings as well as clinical experience with hMSCs is summarized in this review.
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PMID:Treatment of inflammatory diseases with mesenchymal stem cells. 1953 Sep 93

Previously, we demonstrated that several TLRs are expressed on cord blood-derived USSC. Stimulation of USSC with TLR agonists resulted in a marked increase of IL-6 and IL-8 production. Interestingly, TNF was undetectable after TLR stimulation, which appeared to be a result of an inactivated TNF promoter in USSC. Here, we elaborate this study by demonstrating that although USSC do not produce TNF, they are susceptible to TNF stimulation, resulting in NF-kappaB translocation and cytokine production. Additionally, we compared different stem cell sources for their ability to produce TNF. Interestingly, we found that the TNF promoter in BM-MSC is inactivated as well. Like USSC, they are able to respond to TNF stimulation, but they are not able to produce TNF, even not after LPS stimulation. This limited cytokine response in combination with the well-studied immunosuppressive properties of MSC makes these cells ideal for immune-suppressive treatment modalities such as graft-versus-host disease.
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PMID:Mesenchymal stem cells respond to TNF but do not produce TNF. 1989 67

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