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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)

A combination of density flotation centrifugation and counterflow centrifugation (elutriation) allows the elimination of 98% of the T-lymphocytes, present in a marrow aspirate. This reduces substantially the occurrence of graft versus host disease (GvHD) after transplantation without loss of the repopulation capacity. A limitation of the traditional Beckman elutriator rotor is the relatively small size of the elutriation chamber, which makes five to six runs, of one hour each, necessary to process the whole bone marrow graft. We developed a new elutriator rotor, containing four disposable elutriator chamber (Dijkstra BV, Amsterdam, The Netherlands), which allows to complete the lymphocyte elimination from the bone marrow graft within 2 hours. Ninety-nine consecutive patients were transplanted with elutriated MLC-negative bone marrow grafts from histocompatible siblings. Indications for transplantation were: AML (n = 32), ALL (n = 34) and CML (n = 33). The grafts contained after counterflow centrifugation a mean of 12.1 (+/- 2.4)% of the nucleated cells, 1.9 (+/- 1.4)% of the T-lymphocytes, and 93.5 (+/- 59.4)% of the CFU-GM, originally present in the collected bone marrow. Immunoprophylaxis post grafting was given to 97 BMT recipients. Primary graft failure occurred in 5 of 95 evaluable patients (5%). The probability of acute GvHD greater than grade 1 at day 100 after BMT was 16%. The projected 3-year estimate of extensive chronic GvHD was 13%. The low incidence of GvHD was associated with a relatively low transplant related mortality in patients above the age of 40 years.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Prevention of graft-versus-host disease by lymphocyte depletion of the bone marrow graft with use of counterflow centrifugation. 186 51

The data we review indicate that in adults with ALL in first remission intensive chemotherapy and radiation given before a transplant is more effective in eradicating leukaemia than current chemotherapy. This is not so in adults with AML in first remission where more intensive therapy does not reduce the likelihood of relapse. Furthermore, leukaemia relapse because of re-infused leukaemia cells is an important issue in autotransplants for ALL. Whether re-infusing leukaemia cells would be important in AML were more effective pretransplant therapy developed is unknown. Presently, there appears to be little sense to test in vitro approaches to remove leukaemia cells in autotransplants for AML because efficacy cannot be evaluated. (A randomized trial is an exception but would not be expected to show a difference.) Another conclusion is that attempts to induce GVHD in autotransplant recipients, such as by using cyclosporine post-transplant (Jones et al, 1989), are more likely to succeed in AML than ALL since the impact of GVHD is substantially greater (Horowitz et al, 1990). However, the GVHD-related antileukaemia effect in AML is associated with chronic GVHD whereas cyclosporine treatment of autotransplant recipients results in acute GVHD. Also, attempts to separate clinical and antileukaemia effects of GVHD were unsuccessful (Sullivan et al, 1989). Another caution is that in AML we detected an immune antileukaemia effect distinct from GVHD (termed GVL) only after HLA-identical sibling transplants. Since GVL was absent in twins it is unlikely to operate after autotransplants. In summary, there is sense in studying autotransplants in adults with acute leukaemia in first remission. However, there are currently no convincing data that autotransplants are superior to current therapy. More intensive treatment seems effective in ALL; the focus should be on increasing the antileukaemia efficacy of pretransplant therapy and on attempts to remove leukaemia cells from the graft. In AML, there is no evidence that more intensive therapy is more effective. This problem needs resolution before evaluating attempts to remove leukaemia cells from the graft. The best place to test new pretransplant regimens is in twins and recipients of HLA-identical sibling transplants without GVHD. The data and ideas we review and discuss should be useful in planning clinical trials.
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PMID:Autotransplants in acute leukaemia. 204 73

From a bank of 50,000 HLA typed French bone marrow donors, 125 transplants have been performed since 1986, with HLA AB and DR--identical MLC--negative donors. The median age was 25 years and the diagnosis was CGL in 59 cases, ALL in 22 cases, AML in 17 cases, SAA in 7 cases, inborn errors in 7 cases and others in 13 cases. Most of the patients received a standard conditioning regimen according to their diagnosis. The prophylaxis of GVHD was methotrexate and cyclosporine A in 77 cases; in addition to this combination 44 patients received an anti-IL2 receptor monoclonal antibody from day +1 to day +28. There was no difference between the two groups as regards the incidence and severity of GVH or survival. The actuarial survival was 36% with a median follow up of 300 days. Unlike matched sibling grafts, the usual prognostic factors such as stage of disease or age were not found to significantly modify the incidence of GVHD, which was 75%. The results of matched unrelated donor transplants are reasonably good, but must be improved by a better selection of donors and better prevention of GVHD.
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PMID:Matched unrelated bone marrow transplants. Results from the French group (GEGMO). 209 99

Short term clinical results of bone marrow transplantation on 66 patients conditioned with fractionated total body irradiation (12 Gy in 6 fractions and 3 days) are presented here. An acute toxic effects incident, similar to that obtained previously, a 27.6% interstitial pneumonitis associated with acute severe graft versus host disease in 77% of cases, 19.2% relapses, and 41% total crude survival with an actuarial probability of surviving for more than two years of 46% for ALL, 64% for AML and 28% for CML, are the results obtained since now.
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PMID:Fractionated total body irradiation for bone marrow transplantation: clinical results on 66 patients. 224 43

The indications and results of allogeneic bone marrow transplantation are well known by the analyses of European and International registries. In acute non-lymphoblastic leukemia in first complete remission (CR), the disease-free survival (DFS) is 45%, with a risk of relapse (RR) of 15%; in ALL in first CR the DFS is 60% with a RR of 15%; in ALL in second CR the DFS in 40%, with a RR of 30%; in CML in chronic phase the DFS is 60%, with a RR of 20%. These results have to be adjusted with other risk factors such as age, sex mismatch, disease status, CMV serology, and GVH. The use of donors different from a genotypically matched related donor is currently under investigation. Mismatched related transplants give disappointing results except in the case of one HLA mismatch. Unrelated HLA matched donor panels have been recently established in various countries with 200 transplants performed with a DFS of approximately 40%. Current research tries to reduce the risk of relapse by intensifying the conditioning or using the GVL effect of allogeneic T cells, to reduce GVH by the use of monoclonal antibodies and to improve the engraftment by the use of growth factors.
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PMID:Recent trends in allogeneic bone marrow transplantation. 225 66

Allogeneic bone marrow transplantation is the only therapy introduced in the past 2 decades that has offered a better prognosis for children with ALL who have suffered a marrow relapse within 18 months of starting therapy. Currently, 40 to 50% of such patients are obtaining long remissions and are potentially cured by marrow transplantation. This therapy's effectiveness, however, is diminished by the problems of acute and chronic graft-versus-host disease, infection, and relapse. Further impact of marrow transplantation in the treatment of ALL awaits (1) more effective antileukemic preparative regimens or post-transplant antileukemic strategies, (2) less toxic preparative regimens to decrease the incidence of early and late effects, (3) more effective means of preventing and treating graft-versus-host disease, (4) the ability to safely perform mismatched marrow transplantation, and (5) more effective means of purging leukemic cells from remission bone marrow to expand the role of autologous marrow transplantation.
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PMID:Role of bone marrow transplantation in childhood lymphoblastic leukemia. 226 89

Eighty consecutive patients were transplanted with human leukocyte antigen (HLA)-identical sibling marrow for acute myelogenous leukemia (AML, N = 29), acute lymphoid leukemia (ALL, N = 23), or chronic myelogenous leukemia (CML, N = 28). Donor marrow was depleted of lymphocytes using counterflow centrifugation. Median age of the recipients was 31 years. Pretransplant conditioning consisted of cyclophosphamide and fractionated total body irradiation (TBI) with a low (4.1 +/- 0.3 cGy/min) or high (13.1 +/- 1.6 cGy/min) midline average dose rate. In 43 patients, cytosine-arabinoside or anthracyclines were added to the conditioning regimen. Immunoprophylaxis posttransplant consisted of methotrexate (MTX) alone, cyclosporine A (CsA) in combination with MTX, or CsA alone; two patients received no immunoprophylaxis at all. Graft failure occurred in 4 of 77 evaluable patients (5%). The probability of acute graft-versus-host disease (GVHD) greater than or equal to grade 2 at day 100 after transplantation was 15%. The projected 3-year estimate of extensive chronic GVHD was 12%. Only three patients died of cytomegalovirus-interstitial pneumonitis. The projected 3-year probability of relapse was 30% (95% confidence interval [CI], range 8% to 53%) in transplants for AML in first complete remission (CR1), 35% (95% CI, 1% to 69%) after transplantation for ALL in CR1, and 38% (95% CI, 2% to 74%) after transplantation for CML in first chronic phase (CP1). The projected 3-year probability of leukemia-free survival (LFS) was 56% (95% CI, 35% to 77%) after transplantation for AML-CR1, 42% (95% CI, 16% to 69%) in patients transplanted for ALL-CR1, and 49% (95% CI, 18% to 80%) after transplantation for CML-CP1. After transplantation for AML-CR1, ALL-CR1, or CML-CP1, the median follow-up time for leukemia-free survivors was 31+, 30+, and 21+ months, respectively. Probabilities of relapse, survival, and LFS in AML-CR1 and ALL-CR1 transplants were comparable with those reported in recipients of untreated grafts. In patients transplanted for CML-CP1, probability of relapse was higher and probability of LFS was lower than in recipients of untreated grafts. In transplants for leukemia in CR1 and CP1, preparative regimen and immunoprophylaxis posttransplant were not associated significantly with the probability of acute GVHD greater than or equal to grade 2, extensive chronic GVHD, relapse, survival, or LFS. In bone marrow transplantation for leukemia, counterflow centrifugation is a useful technique for the prevention of GVHD.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Allogeneic bone marrow transplantation for leukemia with marrow grafts depleted of lymphocytes by counterflow centrifugation. 231 Aug 32

The probability of long term survival for allogeneic graft patients was 63% for ALL, 64% for ANL and 40% for CML in the 1st remission or 1st chronic phase of each leukemia. The major causes of death were interstitial pneumonia, relapse of leukemia and infections. On relationship of GVHD and the long term survival, the probability of 5 years survival was 38%, 47% and 25% in grade O, I and II-IV of acute GVHD respectively. And the relationship between the relapse rate and GVHD, the patients with both of acute and chronic GVHD showed the lowest relapse rate 15.9%, the patients without GVHD showed the highest relapse rate 37.8% and the patients with either of GVHD showed the rate of between those of two groups. This may suggest that GVHD both acute and chronic might have an ability that can suppress the relapse of leukemia, i.e. GVL reaction. Interstitial pneumonia occurred in 32% of allograft patients and was often lethal complication (53%). Among many of prophylaxis tested, the followings were effective, a lower dose rate of total body irradiation, the selection of CMV-seronegative platelets donor, and the prophylactic administration of anti-CMV high titer globulin. Colony stimulating factor of human urine was also effective for shortening the granulopenic period after transplantation to prevent severe infections.
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PMID:[Allogeneic bone marrow transplantation]. 260 Oct 39

We report a single center experience of 222 patients (pts) less than 18 years old transplanted from 1973 to 1987. The median age was 11 years (1-18). The donor was a monozygotic twin (9 pts), an HLA-id sibling (193 pts), an HLA-id, parent (9 pts), a mismatched related donor (9 pts) and a matched unrelated donor (1 pt). Ninety-six pts were transplanted for SAA. Conditioning varied with time but the majority (59 pts) received CY 150 mg/kg and 6 Gy TAI. The long term actuarial survival is 66% with a median follow-up of 3 years. The group who received CY 200 mg/kg and MTX had a 33% long term survival (LTS). GVH was the main complication with 40% acute and 37% chronic GVHD. Chronic GVHD tended to improve with time after 2 to 4 years of evolution. Ninety pts were transplanted for leukemia (35 AML, 45 ALL and 11 CGL), 20 pts were in relapse. Pts in CR had a LTS of 40%, in pts in relapse, it was 12%. The main causes of death were: interstitial pneumonitis (30%), relapse (27%), GVH (15%). Thirty-five pts were transplanted for constitutional disease: Fanconi anemia (FA) (26 pts), Dyskeratosis congenita (2 pts), Blackfan-Diamond erythroblastopenia (2 pts), Glanzmann thrombasthenia (1 pt), osteopetrosis (1 pt) and Gaucher's disease (1 pt). In FA, the LTS is 70% with a CY 20 mg/kg, 5 Gy TAI regimen. In all disease categories, we did not find any influence of donor's sex on GVH and survival.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Pediatric bone marrow transplantation for leukemia and aplastic anemia. Report of 222 cases transplanted in a single center. 267 24

A 12-year-old boy with Philadelphia chromosome positive acute lymphoblastic leukemia received bone marrow transplantation (BMT) from an HLA identical sibling during the second remission. The diagnosis was made at the age of nine. Laboratory examination on admission revealed remarkable leukocytosis (92,000/microliters) with 93% lymphoblasts in the peripheral blood. Blastic cells were FAB L1 common ALL. Chromosomal study on both peripheral blood and bone marrow cells showed that lymphoblasts had an abnormal karyotype of 47, XY, inv (9), t(9; 22), +17. One month later he achieved remission by induction therapy consisting of vincristine, L-asparaginase, doxorubicin, and prednisolone. He was given intrathecal injection of methotrexate and cranial irradiation of 24 Gy for CNS prophylaxis. The cells with Philadelphia chromosome disappeared during remission. Hematological relapse occurred twenty one months later after first remission on April, 1986. He received re-induction therapy including L-Asp VDP, and high-doses of cyclophosphamide, methotrexate and araC. He obtained karyotypic remission on October 1986. Subsequently, bone marrow transplantation was performed following high-dose araC, CY and TBI as preconditioning on December 18, 1986. Methotrexate and cyclosporin A were given intravenously to prevent GVHD. On day 14, karyotypic conversion was detected, suggesting the successful bone marrow grafting. Acute GVHD appeared on day 25, and was treated with prednisolone and cyclosporin A. Prednisolone was tapered by day 80. On day 91, cyclosporin A was discontinued because herpes zoster occurred. Acyclovir was effective, but skin GVHD reappeared. With low-dose prednisolone, skin GVHD improved. Sicca syndrome soon appeared and was followed by chronic GVHD.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Allogeneic bone marrow transplantation in a case of acute lymphoblastic leukemia with positive Philadelphia chromosome]. 279 82


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