Lung dose rate and interstitial pneumonitis in total body irradiation for bone marrow transplantation

The effect of dose rate to the lungs and development of interstitial pneumonitis (IP) was evaluated in 114 bone marrow transplant patients receiving fractionated total body irradiation (TBI) (1200 rads TD in 6 fractions twice daily over 3 days) as part of their pre-conditioning regimen. The tumour dose (TD) was calculated as the mean lung dose as previously described (1). A 6MV linear accelerator at a mid-line dose rate of 7.5 rads/minute was used between March 1981 and June 1985 and a Co-60 source at 5 rads/minute thereafter. This resulted in a range of dose rates to the lung of between 6.9 and 8.9 rads/minute and 2.9 and 6.5 rads/minute respectively. In the majority of patients the aetiology of IP was investigated by lung biopsy with histology and culture. There was no statistically significant difference in the incidence of IP over the two sets of dose rates. Our study suggests tat the incidence of IP using fractionated TBI is not influenced by dose rates below 8.9 rads per minute.     

Interstitial pneumonitis following total body irradiation for bone marrow transplantation using two different dose rates

A total of 22 patients with leukemia (10 ALL, 11 AML, 1 CML) have undergone allogeneic bone marrow transplantation (BMT) by the Quebec Co-operative Group for Marrow Transplantation from 1980 to 1982. All patients received 900 cGy total body irradiation (TBI), in a single fraction, on the day preceding BMT. The first 11 patients were treated on a cobalt unit at a constant dose rate of 4.7 to 6.3 cGy/min. Six of these patients developed interstitial pneumonitis (IP). The clinical course of three patients, two with idiopathic and one with drug-induced pneumonitis, was mild and recovery was complete in all. The other three patients developed severe infectious IP and two died. The next 11 patients were treated with a sweeping beam technique on a 4 MV linear accelerator delivering a total tumor dose of 900 cGy at an average dose rate of 6.0 to 6.5 cGy/min but an instantaneous dose rate of 21.0 to 23.5 cGy/min. Eight patients developed severe IP. Five of these were idiopathic and four died. Three were infectious and all died. The fatality of interstitial pneumonitis appeared to be greater in the group treated with the sweeping beam technique.     

Lung damage following bone marrow transplantation: I. The contribution of irradiation

High dose whole body irradiation is commonly included in conditioning regimens for bone marrow transplantation for treatment of patients with hematological malignancies. Interstitial pneumonitis is a major complication after BMT. About one-fourth of all BMT patients die from IP. In about half of these cases, an infectious agent, particularly cytomegalovirus, is involved. When no infectious cause is found, it is classified as idiopathic IP (IIP). Total body irradiation is often associated with the induction of IIP; however, extrapolation of animal data from the experiments presented indicates that this is not the only factor contributing to IIP in man. Brown Norway (BN/Bi) rats were bilaterally irradiated to the lungs with 300 kV X rays at a high dose rate (HDR; 0.8 Gy/min) and at a low dose rate (LDR; 0.05 Gy/min). The dose-response curves found were very steep. In the LDR group, lung function studies were performed. There was a strong correlation between the increase in ventilation rate and the death pattern. The LD50 at 180 days was 13.3 Gy for HDR and 22.7 Gy for LDR. The ratios of LD50/180 at 0.05 Gy/min to that at 0.8 Gy/min is 1.7, which indicates a great repair capacity of the lungs. Extrapolation of animal data to patient data leads to an estimated dose of about 15-16 Gy at a 50% radiation pneumonitis induction for low dose rate TBI. As the absorbed dose in the lungs of BMT patients rarely exceeds 10 Gy, additional factors such as remission-induction chemotherapy, cyclophosphamide, methotrexate, cyclosporin A, graft-versus-host disease, etc., might be involved in the high incidence of IIP in man after BMT.     

Late tissue-specific toxicity of total body irradiation and busulfan in a murine bone marrow transplant model

Total body irradiation (TBI) and busulfan were compared for late effects in a murine model of bone marrow transplantation (BMT). Male C57BL/6 mice were given fractionated TBI or busulfan given in 4 equal daily doses followed by infusion of 10(7) syngeneic bone marrow cells. Total doses of 16.4 Gy TBI and 3.4 mg busulfan were chosen for their equivalence in inducing near complete engraftment of allogeneic marrow from donor mice of the LP strain. The two treatment groups had a late wave of mortality starting at about 80 weeks after transplantation. Specific tissue damage was manifested in bone marrow stem cells, splenic T-cell precursors, hair greying and cataract formation for both TBI and busulfan but to varying degrees. Severe nephrotoxicity and anemia were observed only after TBI. Although both busulfan and TBI kill early marrow stem cells and are effective preparative agents in bone marrow transplantation, their effects on other stem cell and organ systems are not similar. In addition, many of the injuries seen are late to occur. The delayed expression of injury deserves careful long-term evaluation of BMT recipients before the therapeutic potential of effective preparative regimens can be fully appreciated.     

Effect of radiation dose rate and cyclophosphamide on pulmonary toxicity after total body irradiation in a mouse model

PURPOSE: Interstitial pneumonitis (IP) is still a major complication after total body irradiation (TBI) and bone marrow transplantation (BMT). It is difficult to determine the exact role of radiation in this multifactorial complication, especially because most of the experimental work on lung damage was done using localized lung irradiation and not TBI. We have thus tested the effect of radiation dose rate and combining cyclophosphamide (CTX) with single fraction TBI on lung damage in a mouse model for BMT. METHODS AND MATERIALS: TBI was given as a single fraction at a high dose rate (HDR, 0.71 Gy/min) or a low dose rate (LDR, 0.08 Gy/min). CTX (250 mg/kg) was given 24 h before TBI. Bone marrow transplantation (BMT) was performed 4-6 h after the last treatment. Lung damage was assessed using ventilation rate (VR) and lethality between 28 and 180 days (LD(50/28-180)). RESULTS: The LD50 for lung damage, +/- standard error (SE), increased from 12.0 (+/- 0.2) Gy using single fraction HDR to 15.8 (+/- 0.6) Gy using LDR. Adding CTX shifted the dose-response curves towards lower doses. The LD50 values for the combined treatment were 53 (+/- 0.2) and 3.5 (+/- 0.2) Gy for HDR and LDR, respectively. This indicates that the combined effect of CTX and LDR was more toxic than that of combined CTX and HDR. Lung damage evaluated by VR demonstrated two waves of VR increase. The first wave of VR increase occurred after 6 weeks using TBI only and after 3 weeks in the combined CTX-TBI treatment, irrespective of total dose or dose rate. The second wave of VR elevation resembled the IP that follows localized thoracic irradiation in its time of occurrence. CONCLUSIONS: Lung damage following TBI could be spared using LDR. However, CTX markedly enhances TBI-induced lung damage. The combination of CTX and LDR is more toxic to the lungs than combining CTX and HDR.     

Fractionated total body irradiation and allogeneic bone marrow transplantation for standard risk leukemia

From March 1982 to December 1986, 32 patients with standard risk leukaemia were conditioned for allogeneic bone marrow transplantation (BMT) with low dose fractionated total body irradiation (TBI) after infusion of alkylating agents. This series includes six children and 26 adults. Minimal follow-up was 24 months. The total dose of 11 Gy, given in 5 daily fractions of 2.20 Gy, was given in the lateral position, following chemotherapy with either melphalan or cyclophosphamide. Lungs were shielded for 2 out of the 5 fractions. All patients had in vivo dosimetry. The death rate is 25% without relapse or rejection. Disease-free survival is 73% at 5 years. Toxic deaths are detailed: 2 from sepsis and veino-occlusive disease of the liver, 3 from severe graft versus host disease (GVHD), 2 from GVHD associated with virus pneumonitis and one from HIV infection. Fractionated low dose rate TBI is discussed regarding its decreased toxicity and its efficiency for disease control.     

Total body irradiation in bone marrow transplantation: fractionated vs single dose. Acute toxicity and preliminary results

The usefulness of total body irradiation (TBI) plus chemotherapy as a preparative regimen prior to bone marrow transplantation has been widely documented. However, the procedure can be highly toxic. Fractionated and low dose rate TBI has been said to enhance therapeutic ratio by increasing normal tissue tolerance and increasing leukemic cell kill. We report here the acute toxic effects and preliminary results on 2 consecutively groups of patients, treated with bone marrow transplantation (BMT) for leukemia or multiple myeloma, and conditioned by 2 TBI regimens. Group A patients received 10 Gy-Co-60 single dose of TBI plus 120 mg/kg of cyclophosphamide over a period of 2 days (8 Gy lungs). Group B received 12 Gy Co-60 of TBI in 6 fractions (2/day), (8 Gy lungs) plus 120 mg/kg of cyclophosphamide over a period of 3 days. The acute toxic effects recorded were similar in both groups. Only a 40% vs 0% (P = 0.02) incidence of parotiditis in groups A and B favors fractionation. Other results obtained to date are as follows: an incidence of interstitial pneumonitis of 39% and 31% (ns); relapses of 10% and 20% (ns), and mortality of 55% and 60% for each group respectively. An interesting finding was that IP was associated with acute grade II-IV graft vs host disease in 87% and 100% of cases of group A and B, respectively. We conclude that fractionated TBI is at least as effective as single dose TBI as a conditioning regimen; however, only randomized trials would allow definitive conclusions.     

Dose response and factors related to interstitial pneumonitis after bone marrow transplant

PURPOSE: Total body irradiation (TBI) and chemotherapy are common components of conditioning regimens for bone marrow transplantation. Interstitial pneumonitis (IP) is a known regimen-related complication. Using published data of IP in a multivariate logistic regression, this study sought to identify the parameters in the bone marrow transplantation conditioning regimen that were significantly associated with IP and to establish a radiation dose-response function. METHODS AND MATERIALS: A retrospective review was conducted of articles that reported IP incidence along with lung dose, fractionation, dose rate, and chemotherapy regimen. In the final analysis, 20 articles (n = 1090 patients), consisting of 26 distinct TBI/chemotherapy regimens, were included in the analysis. Multivariate logistic regression was performed to determine dosimetric and chemotherapeutic factors that influenced the incidence of IP. RESULTS: A logistic model was generated from patients receiving daily fractions of radiation. In this model, lung dose, cyclophosphamide dose, and the addition of busulfan were significantly associated with IP. An incidence of 3%-4% with chemotherapy-only conditioning regimens is estimated from the models. The alpha/beta value of the linear-quadratic model was estimated to be 2.8 Gy. The dose eliciting a 50% incidence, D50, for IP after 120 mg/kg of cyclophosphamide was 8.8 Gy; in the absence of chemotherapy, the estimated D50 is 10.6 Gy. No dose rate effect was observed. The use of busulfan as a substitute for radiation is equivalent to treating with 14.8 Gy in 4 fractions with 50% transmission blocks shielding the lung. The logistic regression failed to find a model that adequately fit the multiple-fraction-per-day data. CONCLUSIONS: Dose responses for both lung radiation dose and cyclophosphamide dose were identified. A conditioning regimen of 12 Gy TBI in 6 daily fractions induces an IP incidence of about 11% in the absence of lung shielding. Shielding the lung to receive 50% of this dose lowers the estimated incidence to about 2.3%. Because the lungs can be adequately shielded, we recommend against using busulfan as a substitute for fractionated TBI with cyclophosphamide.     

Effects of regimens of total body irradiation on interstitial pneumonitis after bone marrow transplantation

Data from 224 patients with leukemia who received TBI followed with allogeneic BMT between 1975 and 1985 were retrospectively analyzed to determine the effects of dose-fractionation factors on the incidences of interstitial pneumonitis (IP). Among several factors examined, the fraction size most predominantly correlated with the IP rate. The selection of the optimal dose rate adjusted to the fraction size also contributed to decreasing the rate of the IP. The total lung dose significantly correlated with the IP rate on a single dose, and the fractionated TBI with a high fraction dose. The dose-response curves of idiopathic IP, derived by a multivariate analyses using the three factors mentioned above, have been presented.     

Interstitial pneumonitis in acute leukemia patients submitted to t-depleted matched and mismatched bone marrow transplantation

Purpose: To identify factors that could contribute to interstitial pneumonitis (IP), which remains one of the major causes of morbidity and mortality after both matched and mismatched bone marrow transplantation (BMT).Methods and Patients: Ninety acute leukemia patients received an allogeneic T-depleted matched (n = 54) or mismatched (n = 36) BMT. They were preconditioned with total body irradiation (TBI), thiotepa, rabbit anti-thymocyte globulin, and cyclophosphamide. The TBI scheme was hyperfractionated in matched, and a single dose in mismatched patients. The dose to the lungs was reduced in both groups.Results: Five of the 54 matched patients developed IP. All cases were fatal. There were 16 cases of IP, 13 fatal, in the mismatched group. The probability of developing IP was 11.3 ± 4.9% and 48.6 ± 9.0%, respectively. The between-group difference was statistically significant (p < 0.0001). The type of transplant and the TBI scheme were the most important parameters for IP development in univariate analysis, whereas acute graft-versus-host disease, disease stage and sex were nonsignificant. Median follow-up was 342 days (range 17–2900).Conclusions: The low incidence of IP in matched patients and the lack of idiopathic cases are evidence for the validity of the TBI schedule. In contrast, the incidence in mismatched patients remains too high; therefore, new strategies should be studied in an attempt to lower it.     

Lung damage following bone marrow transplantation: II. The contribution of cyclophosphamide

The effect of high-dose cyclophosphamide (Cy), either alone or in combination with irradiation, upon the development of interstitial pneumonitis (IP) after bone marrow transplantation (BMT) was investigated in a Brown Norway rat model. The parameters that were examined included ventilation rate, mortality, and histopathology. No damage to the lungs was observed in rats given Cy alone in supralethal dosages plus BMT, and mortality resulted from severe aplasia of hemopoietic and lymphoid tissues with multifocal hemorrhages, secondary infections, and sepsis. Two separate periods of mortality were observed within the first 180 days following whole thorax irradiation with a high dose rate (HDR; 0.8 Gy/min) or a low dose rate (LDR; 0.05 Gy/min). The addition of Cy prior to irradiation resulted in an increased mortality in the first period (before day 100) in all experimental groups. The influence of Cy on mortality at 180 days however, was different for the HDR and LDR experiments. The LD50-180 after HDR irradiation, dose range 8 to 18 Gy, was not significantly altered by the addition of Cy (100 mg/kg) 1 day prior to irradiation, whereas Cy (100 mg/kg) 1 day prior to LDR irradiation, dose range: 16 to 24 Gy, caused an enhancement of radiation damage with a decrease of the LD50-180 by 1.33 Gy. The dose modification factor (DMF) was 1.07. This enhancement was no longer significant after splitting up the dose of Cy in two dosages of 50 mg/kg given on 2 consecutive days prior to irradiation with a LDR. The extrapolation of the data in this rat model to available dose-response curves on IP after BMT and radiation pneumonitis in humans, implied that non-infectious IP is a radiation pneumonitis that is only slightly enhanced by Cy.     

Total body irradiation and pneumonitis risk: a review of outcomes

A review was undertaken of all patients treated at Royal Adelaide Hospital, South Australia with total body irradiation (TBI) for the purpose of assessing the incidence of interstitial pneumonitis (IP) and possible prognostic factors for its development. The aim was also to assess the impact of IP and other prognostic factors on long-term survival outcome following bone marrow transplantation. A total of 84 patients received TBI, with 12 Gy in six fractions delivered using two different instantaneous dose rates of 7.5 and 15 cGy min(-1). This series included 26 cases of acute lymphoblastic leukaemia, 26 of multiple myeloma and 15 of acute myelogenous leukaemia. On multivariate analysis, a higher dose rate was independently significant for an increased risk of IP.     

Radiobiological considerations in magna-field irradiation

Radiobiological considerations are described for total body irradiation (TBI) as given to patients undergoing bone marrow transplantation (BMT). Although much progress has been made in the use of BMT for refractory leukemias, many patients still die from interstitial pneumonia and relapse. Fractionated TBI has been introduced in order to improve leukemic cell kill, while increasing the degree of normal tissue tolerance. Traditionally, bone marrow stem cells, leukemic cells and immunocytes have been considered as having a limited ability to repair radiation damage while cells of lung tissue and intestinal epithelial cells have a greater capacity. During fractionated radiation therapy or continuous low-dose rate exposure, repair of sublethal damage between fractions allows greater recovery in the cells of lung tissue compared to those in the bone marrow. Clinically, the potential benefit of six fractions over one fraction or low dose-rate TBI has yet to be proved, although there is suggestive evidence for a reduced incidence of interstitial pneumonitis. However, other extraneous factors such as doses to the lung, differences in conditioning regimens, effect of increased delay in BMT for patients receiving fractionated TBI, and the immeasurable differences between institutions make definite conclusions impossible. Despite this, a consensus for dose fractionation has developed and most centers are moving away from the use of large single dose TBI.     

Single dose total lymphoid irradiation combined with cyclophosphamide as immunosuppression for human marrow transplantation in aplastic anemia.

Six patients with aplastic anemia underwent bone marrow transplantation following conditioning with high dose cyclophosphamide and single dose total lymphoid irradiation with 750 rad, 26 rad/min at the midplane of the patient. They all received bone marrow from human leukocyte antigens/mixed lymphocyte culture (HLA/MLC) matched siblings. Five of 6 patients were alive without complications at 12, 11, 7, 4 and 4 months respectively. The remaining patient died from sepsis which he had prior to transplantation. There were no graft rejection, graft-vs-Host Disease (GVHD) or interstitial pneumonitis among these patients. The procedure was well tolerated with minimal side effects. The results will be compared with those of groups whose bone marrow was previously transplanted with different immunosuppressive methods.     

Late onset of renal dysfunction in survivors of bone marrow transplantation

Between 1980 and 1986, 44 children with acute lymphoblastic leukemia (ALL) or Stage IV neuroblastoma (NB) underwent allogeneic or autologous bone marrow transplantation (BMT). Twenty-nine of these patients were alive and in remission 3 months post BMT and were evaluable for this analysis of whom eleven have developed renal dysfunction. Six of 17 (35%) evaluable ALL patients developed renal dysfunction (3.5 to 6 months post BMT). This group was transplanted for CALLA positive ALL and received an autologous transplant. Preparation included tenopiside (VM 26) cytosine arabinoside, and cyclophosphamide followed by total body irradiation (TBI). One patient received 850 cGy in a single fraction, while all other patients received fractionated TBI (1200-1400 cGy in 6-8 fractions over 3-4 days). Five of 7 (71%) evaluable patients who received a BMT for NB have developed late renal problems (4-7 months after BMT). The preparation for NB patients included VM 26, cis-platinum, melphalan, cyclophosphamide, and fractionated TBI (1200-1296 cGy). All seven NB patients had received cis-platinum as induction treatment prior to transplantation. All patients presented with anemia, hematuria, and elevations of BUN and creatinine. Two patients underwent renal biopsies which were consistent with radiation nephropathy or hemolytic uremic syndrome. In conclusion, a high incidence of renal dysfunction has occurred 3 to 7 months after BMT for children with NB and ALL. The clinical and laboratory features are consistent with either acute radiation nephropathy or hemolytic-uremic syndrome. These patients were prepared for BMT with multiple chemotherapeutic agents as well as TBI. The relatively young age of these patients and conditioning with intensive multi-agent chemotherapy may decrease the tolerance of the kidney to radiation injury.     

Indication and results of bone marrow transplantation in acute leukemia

The indication and results of bone marrow transplantation (BMT) for acute leukemia were discussed focusing on data obtained by the BMT study group of the Ministry of Health and Welfare, Japan. With regard to the indication of BMT, the following factors were selected as significantly favorable: young age, in remission, no infection, complete HLA-matched marrow donor, no previous radiation treatment of the brain or lung, fractionated TBI, low dose rate, platelet transfusion from anti-CMV antibody-negative donor. Recently, the incidence of such favorable patients has increased in BMT, reflecting the improvement of results with this procedure. The long-term survival rates were 75% for ALL and 50% for ANLL when BMT was performed during the patients' first remission. These data reveal the merit of BMT as a treatment with a high rate of complete cure.     

Eradication of leukaemic marrow and prevention of leukaemia relapse with total body irradiation and bone marrow transplantation.

A series of studies was carried out to determine the effect of allogeneic bone marrow transplantation (BMT) on leukaemia. The study aimed at two different, but strictly linked issues: (1) identification of the eradication capability of BMT, and (2) evaluation of the effect of BMT, both in preventing relapse and in producing long-term disease-free survival. Fifty-four patients allografted for leukaemia were evaluated at various intervals, after bone marrow transplantation, for the presence of host haemopoiesis using red-blood-cell and cytogenetic markers. Among 40 patients in remission, 10 showed functional host and donor haemopoiesis (mixed chimerism), while in 30, host haemopoiesis was never detected (complete chimerism). Seven of the 14 evaluable patients who relapsed showed the reappearance of host haemopoiesis at the time of relapse. The records of received doses of TBI indicate that patients who achieved mixed chimerism, either relapsing or not, received significantly lower doses than complete chimeras. However, some patients with complete chimerism received a TBI dose equivalent to the dose received by those with mixed chimerism, suggesting that the TBI dose is not the only factor determining the reappearance of host haemopoiesis. The data on chimerism and relapse suggest that there is heterogeneity in radiosensitivity between normal marrow cells and leukaemic cells, and further, within the different types of leukaemia. The incidence/severity of acute and chronic graft-vs-host disease (GvHD) was significantly higher in complete chimeras than in mixed chimeras suggesting that mixed chimerism may play a role in the development of tolerance; however, it could be the tolerance (i.e. absence of GvHD) which is responsible for the persistence of host haemopoietic cells. One-hundred-and-sixty-eight patients undergoing allogeneic bone marrow transplantation (BMT) for acute myeloid leukaemia (AML) and chronic myeloid leukaemia were analyzed for risk factor associated with relapse. All patients received marrow from an HLA identical sibling after preparation with cyclophosphamide 120 mg/kg and total body irradiation (TBI) of 330 cGy on days -3, -2, -1. There was a difference of +/- 18% between the nominal total dose of 990 cGy and the actual received dose as indicated by dosimetric recordings. While interstitial pneumonitis had minimal impact on survival there was a considerable difference in the incidence of relapses. The incidence of relapse was higher in patients receiving less, than in patients receiving more than 1000 cGy respectively and this had a major impact on survival. However, transplant-related mortality was slightly higher in the group of patients receiving higher doses of TBI.(ABSTRACT TRUNCATED AT 400 WORDS)     

Late toxicity of total body irradiation with bone marrow transplantation in a rat model

In defined-flora, barrier-maintained rats, radiation nephritis is the principle late toxicity seen after high dose-rate total body irradiation (TBI), when hematologic toxicity is prevented by bone marrow transplantation (BMT). Pneumonitis develops only if rats are placed in a conventional microbiological environment during and after BMT. Low dose-rate TBI gives qualitatively similar late toxicity, but at radiation doses twice as large. Fractionation of the TBI has little effect on the bone marrow ablation doses, but results in increased gastrointestinal and renal tolerance. The addition of immunosuppressive or cytotoxic drugs (cyclosporine-A, methotrexate, cis-platinum) after TBI and BMT greatly decreases the dose of TBI that can be tolerated. The use of a cyclophosphamide plus cytosine arabinoside conditioning regimen prior to TBI and BMT increases the bone marrow ablation dose, but has no effect on acute gastrointestinal toxicity or on renal toxicity. These results indicate that substantial late toxicity may be associated with the TBI conditioning regimens used for BMT even in the absence of cytotoxic and antibiotic drugs, immunosuppressive agents, infection and graft-versus-host disease; and that radiation may be a contributing factor in the nephritis sometimes observed after TBI and BMT.     

Systemic irradiation for selected stage IV and recurrent pediatric solid tumors: method, toxicity, and preliminary results

Eight patients with advanced pediatric solid tumors received either sequential upper and lower half-body irradiation (HBI) (7.5 rad/min to 500 rad total) or total body irradiation (TBI) (7.5 rad/min to 800 rad total) as part of two multimodality treatment regimens. All patients received combination chemotherapy; drugs were determined by the tumor type. The TBI regimen was selected for two patients who had progression of disease with conventional chemotherapy and for two patients with stage IV neuroblastoma. This intensive regimen consisted of bone marrow harvesting, followed by local radiation to gross disease, marrow-ablative chemotherapy, TBI, and re-infusion of the cryopreserved autologous marrow. Significant acute toxicity was followed by hematologic reconstitution in each patient within seven weeks. At this writing, two patients survive, one of whom is disease free two and one half years without maintenance chemotherapy. A less intensive, outpatient regimen was selected for four patients; three had a complete or good partial response to chemotherapy. The fourth patient had tumor-involved bone marrow not responsive to chemotherapy and was therefore ineligible for marrow cryopreservation and TBI. Each of these four patients received HBI after chemotherapy and local radiation to the primary and/or metastatic sites. Acute toxicity was limited to nausea and vomiting. Significant leukopenia and thrombocytopenia occured in three patients. All four patients were alive 10 to 26 months post HBI. This pilot study demonstrates that chemotherapy can be integrated with local fractionated radiation, and systemic radiation given as HBI or TBI with acceptable toxicity; sufficient bone marrow stem cells can be harvested after conventional chemotherapy and then cryopreserved to permit hematologic reconstitution of the patient who receives marrow ablative therapy.     

Cyclophosphamide 24 hours before or after total body irradiation: effects on lung and bone marrow

Preparative regimens for bone marrow transplantation (BMT) use a sequence of drugs, such as cyclophosphamide, in combination with radiation. However, the optimum sequencing of the two agents that will maximize tumor cell kill and minimize normal tissue damage is unknown and controversial. The studies presented here were done in order to determine the effect of cyclophosphamide on bone marrow and lung damage in mice when given 24 h before or after total body irradiation (TBI). A range of single doses of TBI was given before or after a single sublethal dose of 180 mg/kg of cyclophosphamide. The bone marrow of all mice intended for lung damage assessment was reconstituted with 5 x 10(6) syngeneic bone marrow cells. Lung damage was assessed by breathing rate and lethality; bone marrow damage by lethality at 30 days. LD50 values for pneumonitis were obtained between 30 and 84 days after cyclophosphamide and radiation and between 80 and 180 days after radiation alone. Dose modifying factors were obtained as the ratio of LD50s for mice given only TBI compared to those for mice given cyclophosphamide and TBI. Cyclophosphamide enhanced radiation pneumonitis when given before or after TBI, giving DMFs of 1.4 and 1.2 (1.1-1.4, 95% c.l.) respectively. The effect of cyclophosphamide on radiation pneumonitis was drug dose-dependent. The LD50 for death from bone marrow damage was reduced when cyclophosphamide was given either before or after TBI but the effect was greater, i.e. the LD50 was lower when cyclophosphamide was given after TBI. These data show that cyclophosphamide given 24 h after TBI causes less lung damage but more bone marrow damage in this mouse model.