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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)
The treatment of cutaneous T cell lymphoma (CTCL), which includes mycosis fungoides and
Sezary syndrome
, has been in a state of continual change over recent decades, as new therapies are constantly emerging in the search for more effective treatments for the disease. However, prognosis and survival of patients with CTCL remains dependent upon overall clinical stage (stage IA-IVB) at presentation, as well as response to therapy. Past therapies have been limited by toxicity or the lack of consistently durable responses, and few treatments have been shown to actually alter survival, especially in the late stages of disease. Even aggressive chemotherapy has not been shown to improve overall survival compared to conservative sequential therapy in advanced disease, and adds the risk of immunosuppressive complications. Over the last decade, extracorporeal photopheresis has been the only single treatment that has been shown to improve survival in patients with
Sezary syndrome
, although its true efficacy and place in combination therapy remain unclear. Much of the focus of current research has been on combinations of skin-directed therapies and biological response modifiers, which improve response rates. The results of various trials over the years have also brought into favor the use of post-remission maintenance therapy with topical corticosteroids, topical mechlorethamine (nitrogen mustard), interferon-alpha, or phototherapy to prevent disease relapse. Recent novel developments in CTCL therapy include oral bexarotene, a retinoid X receptor-selective retinoid that has activity in all stages of CTCL, and the topical gel formulation of bexarotene, which plays a role in treating localized lesions. US Food and Drug Administration (FDA)-approved, oral systemic bexarotene has the advantage of a 48% overall response rate at a dosage of 300 mg/m(2)/day, and avoids immunosuppression and risk of central line and catheter-related infectious complications that are associated with other systemic therapies. Monitoring of triglycerides and use of concomitant lipid-lowering agents and thyroid replacement is required in most patients. Also recently FDA-approved, denileukin diftitox is the first of a novel class of fusion toxin proteins and is selective for interleukin-2R (CD25+) T cells, targeting the malignant T cell clones in CTCL. Denileukin diftitox is associated with capillary leak syndrome in 20 to 30% of patients, which may be ameliorated by hydration and corticosteroids. Higher response rates are possible by combining bexarotene with "statin" drugs and active CTCL therapies. Studies are being conducted on combining bexarotene and denileukin diftitox with other modalities. Biological response modifier therapies that are in current or future investigational trials include topical tazarotene, pegylated interferon, interleukin-2, and interleukin-12. At the forefront of systemic chemotherapy development, pegylated liposomal doxorubicin, gemcitabine, and pentostatin appear to have the greatest potential for success in CTCL therapy. Bone marrow transplantation, which is currently limited by the risk of
graft-versus-host disease
, offers the greatest potential for disease cure. Further developments for CTCL may include more selective immunomodulatory agents, vaccines, and monoclonal antibodies.
...
PMID:Treatment of cutaneous T cell lymphoma: current status and future directions. 1197 40
Extracorporeal photochemotherapy (ECP) has been shown to be effective in variety of pathologic diseases such as
Sezary syndrome
, autoimmune diseases, organ graft rejection and
graft versus host disease
. However, its mechanism of action has remained elusive. Understanding of its mechanisms may be useful to identify the best indications, treatment regimes and to optimize the ECP technique. The first step of the ECP procedure is collection of peripheral mononuclear cells. In this step, several cell environment changes occur. These conditions have been suggested to increase monocyte activation and possibly drive dendritic cell differentiation. The second step of ECP is the cell radiation by UVA in presence of 8-MOP which is presumed to induce cell membrane damage, DNA crosslinking and binding to a variety of cytosolic proteins leading to apoptosis, modification of membrane antigenicity and antigen presenting cell activation. The third step of ECP is the reinfusion of the treated cells to the patient. While it is unclear what exactly occurs in vivo, it is thought that DCs play a critical role by inducing an immunological response against pathogenic cells. The immature DC, activated by ECP, phagocytizes and internalizes the apoptotic cells; processes the antigens and increases the synthesis of class I and II Major Histocompatibility Complex (MHC) molecules. The peptides associated with class II MHC are presented to the CD4+ T helper cells. The final maturation of DC is completed in vivo with the help of these activated T helper cells using a variety of mechanisms including CD40 ligation. Finally, the mature DCs fully loaded with pathogenic T cell peptides migrate to secondary lymphoid organs stimulate the naive CD8+ T cells and induce a cytotoxic response (Th1 immune response) directed against pathogenic clones (tumoral cells of
Sezary syndrome
). Clinical and haematological improvement after ECP in
Sezary syndrome
is associated with a shift in Th1/Th2 balance and the increase of Th1 cytokines and IL12. ECP can also down regulate the allo or autoimmune response and induces tolerance by regulatory T cells. The clinical response to ECP in patients with chronic GvHD is associated with increase in NK cells and a shift from DC1 to DC2 and a shift from predominantly Th1 to Th2 immune response. Recruitment and involvement of other immune cells in the mechanism of ECP have been suggested and merit more studies. This immunostimulatory capacity of ECP is the most probable hypothesis of its mechanism but further investigations are necessary to determine the precise players important for this activity.
...
PMID:Mechanisms of action of extracorporeal photochemotherapy. 1287 96
Extracorporeal photochimiotherapy (ECP) is based on the exposure of peripheral blood mononuclear cells to the photosensitizing agent (psoralen or 8MOP) and UVA radiation. Mononuclear cells are harvested by cytapheresis and reinfused to the patient after irradiation. This cell therapy has been shown to be effective in the treatment of selected diseases mediated by clonal T cells proliferation such as
Sezary
T cells lymphoma, rejection after solid organ transplantation and
graft-versus-host disease
but results obtained in autoimmune diseases are less convincing. ECP is well tolerated with very few side effects and can be combined with immunosuppressive drugs. Two methods of ECP are currently used: in the first one, the whole procedure is performed with the same equipment whereas in the second one, the cytapheresis is performed on a conventional cell separator and treated with an independent UVA irradiation: Experimental data and clinical results suggest that PCE might induced an immune response against pathological T cells clones. However, technical differences in the methods of PCE and weak knowledge on its mechanism of action impair the standardization and evaluation of this cell therapy process as well as its clinical development.
...
PMID:[Extracorporeal photochemotherapy for treatment of clonal T cell proliferations]. 1460 67
Extracorporeal photoimmunotherapy-photopheresis (ECP) is an immunomodulatory therapy, which basically consists of separating the patient's leucocyte rich plasma from the red blood cell fraction, followed by extracorporeal administration of a photosensitizer and UVA light prior to reinfusion of the treated cells. Successful use of ECP has been reported in patients with cutaneous T cell lymphoma, the
Sezary syndrome
variant,
graft-versus-host disease
, cardiac transplant rejection and other T cell mediated/autoimmune and autoimmune diseases. Apoptosis of malignant lymphocytes and presentation of their antigens to anti-tumor CD8+ T cells with induction of an anticlonotypic response by CD8+ effector cells against the CD4+ neoplastic T cells was one of the intial mechanisms of action proposed. The exact mechanism by which ECP exerts its therapeutic effect remains to be further explored and is still uncertain. The better understanding of its mode of action and the clinical benefits of ECP are important findings that provide additional tools to increase the therapeutic armamentarium in a number of acute and chronic T cell mediated diseases.
...
PMID:Extracorporeal photoimmunotherapy-photopheresis. 1927 88
Photopheresis or extracorporeal photochemotherapy (ECP) is a cellular therapy which combines a leukapheresis followed by ex vivo treatment using psoralen and ultraviolet A irradiation before reinfusion into the patient. Its mechanisms of action remain unclear and selective photodestruction of leukocytes cannot explain the long-lasting immunomodulatory effects. Recent studies demonstrated that ECP down regulates the immune response and induces tolerance through the maturation of dendritic cells and the production of regulatory T cells. Based on these effects, ECP is mainly used for treatment of
Sezary syndrome
,
graft-versus-host disease
, organ graft rejection and autoimmune diseases. However, it is still not clear how ECP both activates tumor immunity against cutaneous T-cell lymphoma and induces tolerance in autoreactive disorders. In addition, the use of adjuvant therapies, the long-term effects and various treatment protocols remain to be investigated along with the specific indications.
...
PMID:[Extracorporeal photochemotherapy]. 2004 57
Posttransplant lymphoproliferative disorders (PTLDs) of T-cell orgin are rare biologically heterogeneous diseases of mature lymphoid cells manifesting in immunosuppressed patients. Only a few cases of mycosis fungoides diagnosed post allogeneic hematopoietic cell transplant (alloHSCT) have been described so far. We present a patient with myelodysplastic syndrome (MDS) post matched unrelated donor alloHSCT who was on long-term immunosuppressive therapy due to
graft versus host disease
. Three years after an alloHSCT, she developed generalized erythroderma and peripheral blood lymphocytosis. Both skin biopsy and peripheral blood flow cytometry revealed atypical CD4+ T-cell population consistent with diagnosis of
Sezary syndrome
. Chimerism studies revealed 100% donor engraftment. Therapy with extracorporeal photopheresis resulted in complete response in blood and skin.
...
PMID:Sezary syndrome manifesting as posttransplant lymphoproliferative disorder. 2976 Oct 72
