Safety and cost-effectiveness of outpatient total body irradiation in pediatric patients undergoing stem cell transplantation.

PURPOSE: To determine the feasibility, safety, and cost of delivering total body irradiation (TBI) in an outpatient setting. PATIENTS AND METHODS: The records of 33 pediatric patients with hematopoietic malignancies undergoing TBI in preparation for bone marrow transplantation (BMT) at the Children's Medical Center of Dallas between February 1992 and June 1997 were retrospectively reviewed. Seventeen children received TBI in an outpatient setting, including 7 patients younger than 8 years of age. All patients had a good performance status (Karnofsky index > 90%) and lived or were housed within a 50-mile radius of the hospital. Patients received 1200 cGy or 1350 cGy in 8 or 9 fractions twice daily over 4 to 5 days and were admitted for high-dose chemotherapy after the last TBI fraction. Mean age was 9 years (range 13 months to 16 years). Close contact was maintained with the BMT staff during outpatient TBI. RESULTS: Eleven patients (65%) received oral ondansetron for nausea and vomiting, 6 received promethazine and ondansetron, and 3 required dexamethasone. Only 2 of the 17 children (12%) required admission during TBI for persistent vomiting and poor oral intake. Two other children (12%) required outpatient administration of intravenous fluids. The other 13 patients (76%) tolerated the outpatient TBI regimen well. Taking into account hospitalization and ambulance transport charges, outpatient TBI represented a savings of approximately $3250 per patient compared with inpatient TBI. CONCLUSIONS: Fractionated TBI delivered in an outpatient setting to selected children of all ages is a safe and cost-effective practice.

Administration of iduronate sulfatase by plasma exchange to patients with the Hunter syndrome: a clinical study.

The Hunter syndrome (MPS II) is the only mucopolysaccharidosis in which there is appreciable activity of the deficient enzyme in normal plasma. We performed enzyme-replacement treatment by plasma exchange in five Hunter syndrome children. Carefully monitoring the cardiovascular status, we administered monthly single plasma volume exchanges for a 3 to 8 mo period. The results indicate a substantial gain of enzyme activity, persisting with a t50% = 19 +/- 5 hr. The maximal level and persistence of increased enzyme activity did not change after repeated exchanges, suggesting that immune responses were not elicited. Despite this, no demonstrable clinical benefit was apparent when the study group was compared with an age-matched control group of Hunter syndrome patients.

Cryopreserved autologous bone marrow transplantation in the treatment of selected pediatric malignancies: a preliminary report.

We have shown that it is possible to collect and viably store sufficient numbers of stem cells to hematologically reconstitute patients following marrow-lethal doses of chemoradiotherapy. While no current procedure can be guaranteed to eliminate clonogenic tumor from the bone marrow, the fact that hematopoietic stem cells capable of reconstituting the host can be obtained after intensive chemotherapy makes it possible to clear microscopic foci of tumor from the marrow prior to storage. Such patients are now included in our protocol. The initial treatment results indicate that, in selected circumstances, tumor in otherwise refractory patients can be eliminated or partially controlled by a single intensive pulse of chemoradiotherapy with severe but acceptable extramedullary toxicity. The fact that patients can be rescued from otherwise lethal myelotoxicity by the reinfusion of cryopreserved autologous bone marrow permits wider exploration of new, more intensive cytoreductive regimens in a variety of cancers.

Autologous bone marrow transplantation in the treatment of selected human malignancies: The Johns Hopkins Oncology Center Program.

Preliminary clinical trials using cryopreserved autologous bone marrow reinfusion have now been carried out at our institution in 5 children and 2 adults with advanced stages of neuroblastoma, rhabdomyosarcoma, non-Hodgkin's lymphoma and small cell carcinoma of the lung. Normal numbers of in vitro colony forming cells (CFU-C) were obtained from these patients despite prior courses of combination chemotherapy. The dose of marrow cells cryopreserved ranged from 1-6 X 10(8) cells/kg and recovery of CFU-C after thawing averaged 50%. Partial or complete hematologic reconstitution was achieved in all patients. The time for recovery ranged from 10-43 days for leukocytes (greater than 1000 cells/mm3) and 23-45 days for platelets (greater than 50,000/mm3). Two patients have died of interstitial pneumonitis due to cytomegalovirus. Three patients have died of recurrent tumor at 40, 48 and 156 days post-transplant. Two patients have had significant therapeutic benefit. One of these had a stable partial response permitting the use of further post-transplant therapy and is alive and well 16+ months post-transplant. The other patient had a complete response and remains tumor-free 25+ months following therapy. We conclude: 1) Autologous bone marrow reinfusion permits hematologic reconstitution following marrow-ablative therapy. 2) A quantity of marrow sufficient for this purpose remains viable following cryopreservation even when obtained from patients previously exposed to chemotherapy. 3) Autologous bone marrow reinfusion now allows the exploration of more intensive cytoreductive therapy in selected malignancies.