L.A. Baxter-Lowe

Successful Allogeneic Transplantation of T-Cell–Depleted Bone Marrow from Closely HLA-Matched Unrelated Donors

We describe a four-year experience with bone marrow transplantation involving closely HLA-matched unrelated donors and 55 consecutive patients with hematologic disease who were seven months to 48.6 years old (median, 18 years). An intensive pretransplantation conditioning regimen and graft-versus-host disease (GVHD) prophylaxis with CD3-directed T-cell depletion and cyclosporine were employed. Durable engraftment was achieved in 50 of 53 patients who could be evaluated (94 percent; 95 percent confidence interval, 83 to 98 percent). Acute GVHD of Grade II to IV developed in 46 percent of the patients (confidence interval, 27 to 66 percent). The incidence and severity of acute GVHD were increased in recipients of HLA-mismatched marrow as compared with recipients of phenotypically matched marrow (incidence of 53 percent [confidence interval, 37 to 68 percent] vs. 17 percent [confidence interval, 5 to 45 percent]; P less than 0.05). Extensive chronic GVHD and deaths not due to relapse also tended to be more frequent when HLA-mismatched marrow was used, but not significantly so. With a median follow-up of more than 19 months (range, greater than 9 to greater than 39), the actuarial disease-free survival of transplant recipients with leukemia and a relatively good prognosis (acute leukemia in first remission and chronic myelogenous leukemia in chronic phase) was 48 percent (confidence interval, 24 to 73 percent), and that of recipients with more aggressive leukemia was 32 percent (confidence interval, 18 to 51 percent); the actuarial survival of recipients with non-neoplastic disease was 63 percent (confidence interval, 31 to 86 percent). We conclude that marrow transplantation with closely HLA-matched unrelated donors can be effective treatment for neoplastic and non-neoplastic diseases. Although transplants from phenotypically HLA-matched unrelated donors appear to be most effective, transplants with limited HLA disparity can also be successful in some patients.

Unrelated donor bone marrow transplantation to treat severe aplastic anaemia in children and young adults

Alternative donor bone marrow transplantation (BMT) to treat severe aplastic anaemia (SAA) in children and young adults has been complicated by high rates of graft rejection and severe graft‐versus‐host disease (GVHD). We hypothesized that increased immunosuppression combined with T‐cell depletion of the marrow graft would enable successful use of unrelated donor BMT in this disease. Preconditioning consisted of cytosine arabinoside, cyclophosphamide, and total body irradiation (TBI). T‐cell depletion was with the anti‐CD3 antibody T10B9. GVHD prophylaxis consisted of cyclosporine A. 28 previously transfused patients were transplanted. Nine donor/recipient pairs were HLA matched. As of 1 January 1996, 15/28 (54%) patients are alive, transfusion independent and well with a range of follow‐up of 13 months to 8 years (median 2.75 years). Fatalities include all three patients with non‐engraftment and all three patients with grade III/IV GVHD. Other fatalities were due to infections or therapy‐related toxicity. The incidence ≥ grade II acute GVHD was 28%. These data show that in children with SAA who have failed immunosuppression, unrelated donor BMT offers a reasonable hope of long‐term survival.

BONE MARROW TRANSPLANTATION FOR SEVERE APLASTIC ANEMIA IN CHILDREN

For young adults and children who have a bone marrow donor who is a genotypic or phenotypic sibling match, bone marrow transplantation is now the preferred treatment for severe aplastic anemia. For those who lack such a matched donor, use of matched unrelated donors and family member donors who are mismatched for a single HLA antigen have been successful and appear to be the treatment of choice. Patients lacking either of these alternatives should receive antilymphocyte globulin, either alone or combined with cyclosporine as a first step. Although the success rate of marrow transplants in our series using mismatched family donors is similar to that following treatment with antilymphocyte globulin, several caveats must be kept in mind. First, the results reported with use of alternative donors must be confirmed with study of larger numbers of patients and longer follow-up. Second, the preparative regimen given prior to bone marrow transplantation destroys the patients residual bone marrow, whereas antilymphocyte globulin cyclosporine A and androgens do not. The sequence of immunosuppression followed by transplantation with alternative donor marrow should produce greater long-term hematopoietic improvement. Unfortunately, when marrow transplant follows one or more courses of immunosuppressive therapy, nonengraftment is then a problem because of sensitization to blood cell antigens. It should also be kept in mind that studies done in children, especially in those younger than 6 years old, show that these patients respond better to transplantation than to treatment regimens not including marrow transplantation. Therefore, for the child with severe aplastic anemia, every effort should be made to identify a suitable bone marrow donor. Finally, we need to determine the specific components of the conditioning regimen and the constitution of the donor marrow necessary for engraftment and to minimize potential long-term complications, and there should be only a tolerable degree of graft-versus-host disease. Many of the transplant-related problems that plagued us in the 1970s have still not been fully resolved, but many have shown improvement. As we enter the 1990s, increasing the pool of marrow donors for patients with severe aplastic anemia who lack an HLA-matched sibling will continue to be a top priority for research.