Cataracts after total body irradiation and bone marrow transplantation in patients with acute leukemia in complete remission: a study of the european group for blood and marrow transplantation

Purpose: Advances in bone marrow transplantation (BMT) have consistently improved long-term survival. Therefore, evaluation of late complications such as cataracts is of paramount importance.Methods and Materials: We analyzed data of 2149 patients from the EBMT registry. A cohort of 1063 patients were evaluable for survival and ophthalmologic status after transplant for acute leukemia (AL) in first or second complete remission. Conditioning therapy included either single-dose total body irradiation (STBI) or fractionated TBI (FTBI) grouped in different dose rates (low: LDR ≤ 0.04 Gy/min; high: HDR > 0.04 Gy/min).Results: The overall 10-year estimated cataract incidence (ECI) was 50%. It was 60% in the STBI group, 43% in the FTBI group ≤ 6 fractions, and 7% in the FTBI group > 6 fractions (p < 10⁻⁴). It was significantly lower (30%) in the LDR than in the HDR groups (59%; p < 10⁻⁴). Patients receiving heparin for veno-occlusive disease prophylaxis had fewer cataracts than those who did not (10-year ECI: 33% vs. 53%, respectively; p = 0.04). The 10-year ECI was 65% in the allogeneic vs. 46% in the autologous BMT patients (p = 0.0018).Factors independently associated with an increased risk of cataract were an older age (> 23 years), higher dose rate (> 0.04 Gy/min), allogeneic BMT, and steroid administration (> 100 days). The use of FTBI was associated with a decreased risk of cataract. Heparin administration was a protective factor in patients receiving STBI. In terms of cataract surgery, the unfavorable factors for requiring surgery were: age > 23 yr, STBI, dose rate > 0.04 Gy/min, chronic graft-vs.-host disease (cGvHD), and absence of heparin administration. Among the patients who required cataract surgery (111 out of 257), secondary posterior capsular opacification was observed in 15.7%.Conclusion: High dose rate and STBI are the main risk factors for cataract development and the need for surgery, and the administration of heparin has a protective role in cataractogenesis.     

Radiation-induced cataract: physiopathologic, radiobiologic and clinical aspects]

Cataractogenesis is a widely reported late effect of irradiated crystalline lens. In this review the authors discussed the different aspects of radiation cataract pathogenesis, and the different mechanisms involved in the lens opacification, particularly the epithelium modifications such as epithelial cell death. The authors also reported the influence of radiation exposure on cataract formation following total body irradiation (TBI) and autologous or allogeneic bone marrow transplantation for hematologic malignancies. Moreover, the radiobiological parameters are not studied for the crystalline lens of human. We applied for the first time the linear-quadratic (LQ) and biological effective dose (BED) concept to TBI data. The calculated value of alpha/beta of 1 Gy is in the range of the values reported for the other late responding tissues. The other risk factors for cataract development after TBI such as age, gender, central nervous system boost, long-term steroid therapy and heparin administration are discussed. In terms of cataract or sicca syndrome prevention, numerous compounds have been successfully tested in experimental models or used for the prevention of radiation-induced xerostomia in patients treated for head and neck cancer. However, none of them has been clinically evaluated for ocular radiation late effects prevention. In this report the authors discussed some of the radioprotectors potentially interesting for radiation-induced cataract or sicca syndrome prevention.     

Comparison of dosimetric and biologic effective dose parameters for prostate and urethra using 131 Cs and 125 I for prostate permanent implant brachytherapy

PURPOSE: To compare the urethral and prostate absolute and biologic effective doses (BEDs) for 131 Cs and 125 I prostate permanent implant brachytherapy (PPI). METHODS AND MATERIALS: Eight previously implanted manually planned 125 I PPI patients were replanned manually with 131 Cs, and re-planned using Inverse Planning Simulated Annealing. 131 Cs activity and the prescribed dose (115 Gy) were determined from that recommended by IsoRay. The BED was calculated for the prostate and urethra using an alpha/beta ratio of 2 and was also calculated for the prostate using an alpha/beta ratio of 6 and a urethral alpha/beta ratio of 2. The primary endpoints of this study were the prostate D90 BED (pD90BED) and urethral D30 BED normalized to the maximal potential prostate D90 BED (nuD30BED). RESULTS: The manual plan comparison (alpha/beta = 2) yielded no significant difference in the prostate D90 BED (median, 192 Gy2 for both isotopes). No significant difference was observed for the nuD30BED (median, 199 Gy2 and 202 Gy2 for 125 I and 131 Cs, respectively). For the inverse planning simulated annealing plan comparisons (alpha/beta = 2), the prostate D90 BED was significantly lower with 131 Cs than with 125 I (median, 177 Gy2 vs. 187 Gy2, respectively; p = 0.01). However, the nuD30BED was significantly greater with 131 Cs than with 125 I (median, 192 Gy2 vs. 189 Gy2, respectively; p = 0.01). Both the manual and the inverse planning simulated annealing plans resulted in a significantly lower prostate D90 BED (p = 0.01) and significantly greater nuD30BED for 131 Cs (p = 0.01), compared with 125 I, when the prostate alpha/beta ratio was 6 and the urethral alpha/beta ratio was 2. CONCLUSION: This report highlights the controversy in comparing the dose to both the prostate and the organs at risk with different radionuclides.     

Cataract-free interval and severity of cataract after total body irradiation and bone marrow transplantation: influence of treatment parameters

PURPOSE: To determine prospectively the cataract-free interval (latency time) after total body irradiation (TBI) and bone marrow transplantation (BMT) and to assess accurately the final severity of the cataract. METHODS AND MATERIALS: Ninety-three of the patients who received TBI as a part of their conditioning regimen for BMT between 1982 and 1995 were followed with respect to cataract formation. Included were only patients who had a follow-up period of at least 23 months. TBI was applied in one fraction of 8 Gy or two fractions of 5 or 6 Gy. Cataract-free period was assessed and in 56 patients, who could be followed until stabilization of the cataract had occurred, final severity of the cataract was determined using a classification system. With respect to final severity, two groups were analyzed: subclinical low-grade cataract and high-grade cataract. Cataract-free period and final severity were determined with respect to type of transplantation, TBI dose, and posttransplant variables such as graft versus host disease (GVHD) and steroid treatment. RESULTS: Cataract incidence of the analyzed patients was 89%. Median time to develop a cataract was 58 months for autologous transplanted patients. For allogeneic transplanted patients treated or not treated with steroids, median times were 33 and 46 months, respectively. Final severity was not significantly different for autologous or allogeneic patients. In allogeneic patients, however, final severity was significantly different for patients who had or had not been treated with steroids for GVHD: 93% versus 35% high-grade cataract, respectively. Final severity was also different for patients receiving 1 x 8 or 2 x 5 Gy TBI, from patients receiving 2 x 6 Gy as conditioning therapy: 33% versus 79% high-grade cataract, respectively. The group of patients receiving 2 x 6 Gy comprised, however, more patients with steroid treatment for GVHD. So the high percentage of high-grade cataract in the 2 x 6 Gy group might also have been caused to a significant extent by steroid treatment. The percentage of patients with high-grade cataract was lower in allogeneic transplanted patients without steroid treatment for GVHD than in autologous transplanted patients: 35% versus 48%. An explanation for this could be pretransplant therapy containing high-dose steroids. CONCLUSIONS: After high-dose-rate TBI in one or two fractions, steroids for GVHD influence latency time of a cataract and are of great importance for the severity the cataract finally attains. Although a cataract will develop in all patients, a clinically important high-grade cataract is relatively infrequent in patients not treated with steroids. Pretransplant therapy might also influence final severity of cataract.     

Single dose versus hyperfractionated total body irradiation before allogeneic bone marrow transplantation: a non-randomized comparative study of 54 patients at the Institut Gustave-Roussy

At the Institut Gustave-Roussy (IGR), from January 1982 to December 1986, 54 patients received total body irradiation (TBI) as a part of the conditioning regimen before allogeneic bone marrow transplantation. The patients were non-randomly assigned to either single dose TBI (STBI) (31 patients receiving 10 Gy at a 4.5 cGy/min dose rate, 8 Gy to the lungs) or to a hyperfractionated scheme (HTBI) (23 patients receiving 13.2 Gy in 11 fractions, 3 fractions per day, 9 Gy to the lungs). Relapse rate and overall survival were not significantly different in the two STBI and HTBI groups, in spite of a larger number of 2nd and 3rd remission patients in the HTBI subset. The incidence of interstitial pneumonitis (IP) was significantly reduced in the HTBI group (13%, versus 45% after STBI, p = 0.02). Lethality by IP was also lower after HTBI (4%, versus 26% after STBI, p = 0.08). There was no case of veno-occlusive disease of the liver in the HTBI group, whereas three cases were observed after STBI. Based on these results, the IGR activated, in January 1987, a randomized trial comparing the single dose 10 Gy TBI (8 Gy to the lung) to a new hyperfractionated schedule (11 fractions of 1.35 Gy, 3 fractions per day, 9 Gy to the lungs).     

Interstitial pneumonitis following autologous bone-marrow transplantation conditioned with cyclophosphamide and total-body irradiation

PURPOSE: To assess the influence of different total-body irradiation (TBI) regimens on interstitial pneumonitis (IP), we retrospectively analyzed our clinical data concerning an homogeneous group of patients conditioned with cyclophosphamide (CY) alone and single-dose or fractionated TBI before autologous bone-marrow transplantation (ABMT). METHODS AND MATERIALS: One hundred eighty-six patients with acute nonlymphoblastic leukemia (n = 101), acute lymphoblastic leukemia (n = 62), chronic myeloid leukemia (n = 11), non-Hodgkin's lymphoma (n = 10), and multiple myeloma (n = 2) referred to our department between May 13, 1981 and September 16, 1992, underwent TBI before ABMT. The male-to-female ratio was 123:63 (1.95), and mean and median age was 33 +/- 12 (6-63 years) and 35 years, respectively. Cyclophosphamide alone (60 mg/kg/day on each of 2 successive days) was used as conditioning chemotherapy in all patients. Patients were irradiated according to two techniques: either with single-dose (STBI) (n = 124; 10 Gy administered to the midplane at the level of L4, and 8 Gy to the lungs) or with fractionated (FTBI) (n = 62; 12 Gy in 6 fractions over 3 consecutive days to the midplane at the level of L4, and 9 Gy to the lungs) TBI. The mean instantaneous dose rate was 0.057 +/- 0.0246 Gy/min (0.0264-0.1692 Gy/min). It was < or = 0.048 Gy/min in 48 patients (LOW group), > 0.048 and < or = 0.09 Gy/min in 129 patients (MEDIUM group), and > 0.09 Gy/min in 9 patients (HIGH group). The median follow-up period was 5 years (24-120 months). RESULTS: In January 1994, the 5-year overall (including all causes of death) and disease-free survival (DFS) rates were 50 and 48%, respectively. The 5-year DFS was 47.9% in the STBI group, and 47.8% in the FTBI group (p = 0.77). It was 44% in the HIGH group, 53% in the MEDIUM group, and 34% in the LOW group (LOW vs. MEDIUM, p = 0.009). The 5-year IP incidence was 17% in all patients, 16% in the STBI group and 18% in the FTBI group (p = 0.37), but it was significantly higher in patients receiving high instantaneous dose rate TBI (56% in the HIGH, 13% in the MEDIUM, 20% in the LOW groups; HIGH vs. MEDIUM, p = 0.002). However, sex (p = 0.37), age (18% for > 20 vs. 10% for < or = 20 years, p = 0.37), and body weight (> 60 kg vs. < or = 60 kg, p = 0.09) did not influence the IP incidence in univariate analyses. Multivariate analysis (Cox model) revealed that the instantaneous dose rate (p = 0.05), and the age (p = 0.04) were the two independent factors influencing the incidence of IP. CONCLUSION: This retrospective study including only the patients transplanted with ABMT conditioned with CY alone and STBI or FTBI concluded that instantaneous dose rate and age significantly influenced the incidence of IP, whereas sex, body weight, and fractionation did not.     

Late normal tissue injury from permanent interstitial implants

PURPOSE: To develop a simple method of calculating biologically effective doses in high-dose regions of permanent interstitial implants. METHODS AND MATERIALS: The incomplete repair model is used to clarify the relationship between dose, D, and biologically effective dose (BED), for permanent interstitial implants. The relationship is used to ascertain the BED at high-dose regions that may occur in (125)I, (103)Pd, and (198)Au prostate implants. RESULTS: The relationship between D and BED is nonlinear and is given by BED(D) = D + D(2)/D(lambda), where D(lambda) = [(t(lambda)/t(mu)) + 1](alpha/beta), t(lambda) and t(mu) are the half-lives of the isotope and of sublethal damage repair respectively, and alpha/beta is the alpha:beta ratio. Idealized geometrically identical (125)I, (103)Pd, and (198)Au prostate implants with minimum target dose (MTD) of 160 Gy, 120 Gy, and 64 Gy, respectively, are considered. The BED for (103)Pd and (198)Au will be less than the BED for (125)I, for doses up to about 2.5 times the MTD. For higher doses, the BED for (103)Pd may be significantly higher than for (125)I. CONCLUSION: Permanent interstitial implants using short-lived isotopes may have regions with very high biologically effective doses.     

Comparison between single-dose and hyperfractionated total-body irradiation for the conditioning of allogenic grafts of the bone marrow. A retrospective study of 54 patients with malignant hematologic diseases

The present study is a retrospective analysis of 54 patients with hematological malignancies who were treated by total body irradiation (TBI) and allogenic bone-marrow transplantation from 1982-1986. Patients were not randomly assigned to receive either single dose total body irradiation (STBI) (10 Gy x 1-4 cGy/min-lung dose 8 Gy) or hyperfractionated total body irradiation (HTBI) (1,20 Gy x 11-3 fractions/day-lung dose 9 Gy). Thirty one patients received STBI and 23 a HTBI regimen. Despite the presence of a large proportion of patients with a high risk of leukemic relapse in the HTBI group, the incidence of relapse did not differ significantly in the two groups: STBI (16%), HTBI (21%). Lung and liver toxicity were predominant in the STBI group. Interstitial pneumonitis occurred in 45% of the STBI patients versus 13% in the HTBI group. This difference remains significant when adjusted to the incidence of graft versus host disease (GVHD) in the two groups. Three cases of veino-occlusive disease were observed (10%), but only in the STBI group. Even when differences in age and the frequency of GVHD are considered in the two groups, these findings suggest that HTBI is at least as effective as STBI and that toxicity is reduced with this schedule.     

Relevance of biologically equivalent dose values in outcome evaluation of stereotactic radiotherapy for lung nodules

PURPOSE: Different biologically equivalent dose (BED) values associated with stereotactic radiotherapy (SRT) of patients with primary and metastatic pulmonary nodules were studied. The BED values were calculated for tumoral tissue and low alpha/beta ratio, assuming that better local response could be obtained by using stereotactic high-BED treatment. METHODS AND MATERIALS: Fifty-eight patients with T1-T3 N0 non-small-cell lung cancer and 46 patients with metastatic lung nodules were treated with SRT. The BED was calculated for alpha/beta ratios of 3 and 10. Overall survival (OS) was assessed according to Kaplan-Meier and appraised as a function of three BED levels: low (30-50 Gy), medium (50-70 Gy), and high (70-98 Gy; alpha/beta = 10). RESULTS: The OS rates for all 104 patients at 12, 24, and 36 months were 73%, 48.3%, and 35.8%, respectively. Local response greater than 50% for low, medium, and high BED values was observed in 54%, 47%, and 73%, respectively. In the high-BED treated group, OS rates at 12, 24, and 36 months (80.9%, 70%, and 53.6%, respectively) were significantly improved compared with low- (69%, 46.1%, and 30.7%, respectively) and medium-BED (67%, 28%, and 21%, respectively) treated patients. Results are also discussed in terms of BED calculated on alpha/beta 3 Gy characteristic of the microcapillary bed. No acute toxicity higher than Grade 1 was observed. CONCLUSIONS: Radioablation of pulmonary neoplastic nodules may be achieved with SRT delivered by using a high-dose fraction with high BED value.     

Total biological effect on late reactive tissues following reirradiation for recurrent nasopharyngeal carcinoma

PURPOSE: To assess the additional damage of normal tissues attributable to reirradiation and the magnitude of partial recovery following the initial course. METHODS AND MATERIALS: Symptomatic late complication rates (excluding xerostomia) in 3635 patients receiving one course (Group 1) and 487 patients receiving two courses of external radiotherapy (Group 2) for nasopharyngeal carcinoma were retrospectively analyzed and compared. RESULTS: Group 2 had significantly lower actuarial complication-free survival rates than Group 1: 48% versus 81% at 5 years. The post-retreatment incidence was significantly affected by biologically effective dose (BED) (assuming an alpha/beta ratio of 3 Gy) of the first course: hazard ratio (HR) = 1.04 per Gy(3) (p = 0.01), but only marginally by that of the second course: HR = 1.01 per Gy(3) (p = 0.06). If the summated BED was taken as the dose unit, it was estimated that a total BED of 143 Gy(3) would induce a 20% incidence at 5 years, while the corresponding dose projected from Group 1 was 111 Gy(3). The gap effect was insignificant in the overall analyses, but a trend of decreasing risk with increasing interval was observed in patients with gap > or = 2 years: HR = 0.86 per year (p = 0.07). CONCLUSION: The major determinant of post-retreatment complication is the severity of damage during the initial course. The sum of total doses tolerated is higher than that expected with a single-course treatment, suggesting occurrence of partial recovery (particularly in those reirradiated after an interval of 2 years or more).     

Renal toxicity after total body irradiation

PURPOSE: To evaluate the incidence of renal dysfunction after total body irradiation (TBI). METHODS AND MATERIALS: Between 1990 and 1997, 64 patients (median age 50 years) received TBI as part of the conditioning regimen before bone marrow transplantation (BMT). Five patients with abnormal renal function at the beginning of treatment or with incomplete data were excluded. All patients received a total of 12 Gy (6 fractions twice daily for 3 consecutive days) prescribed to the peak lung dose (corrected for lung transmission) at a dose rate of 7.5 cGy/min. Renal shielding was not used. Renal dysfunction was assessed on the basis of the serum creatinine levels measured at the start and end of TBI and at 6, 12, 18, and 24 months after completion of BMT. Cox proportional hazard analysis was used to evaluate the various factors known to affect renal function. RESULTS: Only 4 patients had elevated serum creatinine levels at 12 months and subsequently only 2 of the 33 surviving patients had persistent elevated renal serum creatinine levels 24 months after BMT. A fifth patient developed proteinuria and mildly elevated serum creatinine levels at 2.5 years. In 2 patients, the elevation coincided with disease relapse and normalized once remission was achieved. In the third patient, the elevation in serum creatinine levels coincided with relapse of multiple myeloma and the presence of Bence-Jones proteinuria. The fourth patient was the only patient who developed chronic renal failure secondary to radiation nephritis at 2 years. The etiology of the fifth patient's rise in creatinine was unknown, but may have been secondary to radiation nephritis. On univariate analysis, but not on multivariate analysis, a significant correlation was found between TBI-related renal dysfunction and hypertension before and after BMT. CONCLUSION: A dose of 12 Gy at 2 Gy/fraction resulted in only 1 case of radiation nephritis in the 59 patients studied 24 months after the completion of TBI and BMT.     

Total body irradiation before allogeneic bone marrow transplantation: is more dose better?

PURPOSE: This study was performed to retrospectively assess the potential influence of total-body irradiation (TBI) dose on overall survival in patients undergoing allogeneic bone-marrow transplants (BMT) for hematologic malignancies. METHODS AND MATERIALS: Between October 1984 and December 1996, 116 patients were conditioned with high-dose chemotherapy and fractionated TBI before allogeneic BMT. The median age was 34 years (range 3-60). The TBI dose was given in 6 fractions, twice-a-day, over 3 days before BMT. The total dose was 10 Gy in 24 patients, 12 Gy in 66 patients, and 13.5 Gy in 26 patients. RESULTS: TBI dose was inversely correlated with overall survival. Five-year survival was 62% for patients conditioned with 10 Gy, 55% for patients conditioned with 12 Gy, and 46% for patients conditioned with 13.5 Gy. Age at BMT was also independently correlated with survival, with the best outcome for patients < 40 years old. CONCLUSION: A TBI dose (fractionated) > 10 Gy may not necessarily be associated with a better outcome in patients undergoing allogeneic bone-marrow transplant for hematologic malignancies.     

Clinical implications of incomplete repair parameters for rat spinal cord: the feasibility of large doses per fraction in PDR and HDR brachytherapy

PURPOSE: To evaluate the clinical implications of the repair parameters determined experimentally in rat spinal cord and to test the feasibility of large doses per fraction or pulses in daytime high-dose-rate (HDR) or pulsed-dose-rate (PDR) brachytherapy treatment schedules as an alternative to continuous low-dose-rate (CLDR) brachytherapy. METHODS AND MATERIALS: BED calculations with the incomplete repair LQ-model were performed for a primary CLDR-brachytherapy treatment of 70 Gy in 140 h or a typical boost protocol of 25 Gy in 50 h after 46-Gy conventional external beam irradiation (ERT) at 2 Gy per fraction each day. Assuming biphasic repair kinetics and a variable dose rate for the iridium-192- (192Ir) stepping source, the LQ-model parameters for rat spinal cord as derived in three different experimental studies were used: (a) two repair processes with an alpha/beta ratio = 2.47 Gy and repair half-times of 0.2 h (12 min) and 2.2 h (Pop et. al.); (b) two repair processes with an alpha/beta ratio = 2.0 Gy and repair half-times of 0.7 h (42 min) and 3.8 h (Ang et al.); and (c) two repair processes with an alpha/beta ratio = 2.0 Gy and repair half-times of 0.25 h (15 min) and 6.4 h (Landuyt et al.). For tumor tissue, an alpha/beta ratio of 10 Gy and a monoexponential repair half time of 0.5 h was assumed. The calculated BED values were compared with the biologic effect of a clinical reference dose of conventional ERT with 2 Gy/day and complete repair between the fractions. Subsequently, assuming a two-catheter implant similar to that used in our experimental study and with the repair parameters derived in our rat model, BED calculations were performed for alternative PDR- and HDR-brachytherapy treatment schedules, in which the irradiation was delivered only during daytime. RESULTS: If the repair parameters of the study of Pop et al., Ang et al., or Landuyt et al. are used, for a CLDR-treatment of 70 Gy in 140 h, the calculated BED values were 117, 193, or 216 Gy(sc) (Gy(sc) was used to express the BED value for the spinal cord), respectively. These BED values correspond with total doses of conventional ERT of 65, 96, or 104 Gy. The latter two are unrealistic high values and illustrate the danger of a straightforward comparison of BED values if repair parameters are used in situations quite different from those in which they were derived. For a brachytherapy boost protocol, the impact of the different repair parameters is less, due to the fact that the percentage increase in total BED value by the brachytherapy boost is less than 50%.If a primary treatment with CLDR brachytherapy delivering 70 Gy in 140 h has to be replaced, high doses per fraction or pulses (> 1 Gy) during daytime can only be used if the overall treatment time is prolonged with 3-4 days. The dose rate during the fraction or pulse should not exceed 6 Gy/h. For a typical brachytherapy boost protocol after 46 Gy ERT, it seems to be safe to replace CLDR delivering a total dose of 25 Gy in 50 h by a total dose of 24 Gy in 4 days with HDR or PDR brachytherapy during daytime only. Total dose per day should be limited to 6 Gy, and the largest time interval as possible between each fraction or pulse should be used. CONCLUSION: Extrapolations based on longer repair half-times in a CLDR reference scheme may lead to the calculation of unrealistically high BED values and dangerously high doses for alternative HDR and PDR treatment schedules. Based on theoretical calculations with the IR model and using the repair parameters derived in our rat spinal cord model, it is estimated that with certain restrictions, large doses per fraction or pulses can be used during daytime schedules of HDR or PDR brachytherapy as an alternative to CLDR brachytherapy, especially for those treatment conditions in which brachytherapy is used after ERT for only less than 50% of the total dose.     

Application of the linear-quadratic model to combined modality radiotherapy

PURPOSE: Methods of performing dosimetry for a combined modality radiotherapy (CMRT) consisting of a targeted radionuclide therapy (TRT) and separately delivered external beam therapy (EBT) have been established using the biologically effective dose (BED). However, a concurrent delivery of the two therapies may influence the radiobiologic effect of the treatment resulting from interaction between the therapies, and this situation has been modeled to assess the likely consequences of this regime. METHODS AND MATERIALS: A general form of the linear-quadratic model with a dose protraction factor was applied to concurrent delivery of EBT and TRT. Contributions to total BED from intra- and intermodality effects were calculated, and parameter values varied to determine conditions under which the intermodality contributions were likely to be most significant. A Poisson model of tumor control probability (TCP) was used to assess the predicted effect of concurrent delivery on treatment outcome. RESULTS: In general, over a wide range of parameter values, the effect of intermodality interactions in CMRT is small, increasing total BED delivered to tumor by approximately 1%, and producing a negligible increase in TCP. Synergistic effects could be greater in normal tissues if high doses were received from both therapies, with intermodality terms increasing total BED delivered by approximately 6% in the general case, and by approximately 18% for the case of slow repair in the spinal cord. A significant synergistic effect was predicted between EBT and I-125 seed therapy of the prostate when values of alpha/beta = 1.2 Gy, alpha = 0.026 Gy, mu = 0.36 h(-1) and N(0) = 138 clonogens were used, with TCP increasing from approximately 0.5 to 0.6. CONCLUSIONS: Under most clinical conditions, the relative temporal delivery of these two therapies is unlikely to significantly influence the overall radiobiologic effect to tumor at the cellular level. Synergistic effects may, however, be more significant in normal tissues and for tumors with low values of alpha/beta and alpha.     

Lethal pulmonary complications significantly correlate with individually assessed mean lung dose in patients with hematologic malignancies treated with total body irradiation

PURPOSE: To assess the impact of lung dose on lethal pulmonary complications (LPCs) in a single-center group of patients with hematologic malignancies treated with total body irradiation (TBI) in the conditioning regimen for bone marrow transplantation (BMT). METHODS: The mean lung dose of 101 TBI-conditioned patients was assessed by a thorough (1 SD around 2%) in vivo transit dosimetry technique. Fractionated TBI (10 Gy, 3.33 Gy/fraction, 1 fraction/d, 0.055 Gy/min) was delivered using a lateral-opposed beam technique with shielding of the lung by the arms. The median lung dose was 9.4 Gy (1 SD 0.8 Gy, range 7.8--11.4). The LPCs included idiopathic interstitial pneumonia (IIP) and non-idiopathic IP (non-IIP). RESULTS: Nine LPCs were observed. LPCs were observed in 2 (3.8%) of 52 patients in the group with a lung dose < or = 9.4 Gy and in 7 (14.3%) of 49 patients in the >9.4 Gy group. The 6-month LPC risk was 3.8% and 19.2% (p = 0.05), respectively. A multivariate analysis adjusted by the following variables: type of malignancy (acute leukemia, chronic leukemia, lymphoma, myeloma), type of BMT (allogeneic, autologous), cytomegalovirus infection, graft vs. host disease, and previously administered drugs (bleomycin, cytarabine, cyclophosphamide, nitrosoureas), revealed a significant and independent association between lung dose and LPC risk (p = 0.02; relative risk = 6.7). Of the variables analyzed, BMT type (p = 0.04; relative risk = 6.6) had a risk predictive role. CONCLUSION: The mean lung dose is an independent predictor of LPC risk in patients treated with the 3 x 3.33-Gy low-dose-rate TBI technique. Allogeneic BMT is associated with a higher risk of LPCs.     

Cerebral radiation necrosis: incidence, outcomes, and risk factors with emphasis on radiation parameters and chemotherapy

PURPOSE: To investigate radiation necrosis in patients treated for glioma in terms of incidence, outcomes, predictive and prognostic factors. METHODS AND MATERIALS: Records were reviewed for 426 patients followed up until death or for at least 3 years. Logistic regression analysis was performed to identify predictive and prognostic factors. Multivariate survival analysis was conducted using Cox proportional hazards regression. Separate analyses were performed for the subset of 352 patients who received a biologically effective dose (BED) > or =85.5 Gy2 (> or =45 Gy/25 fractions) who were at highest risk for radionecrosis. RESULTS: Twenty-one patients developed radionecrosis (4.9%). Actuarial incidence plateaued at 13.3% after 3 years. In the high-risk subset, radiation parameters confirmed as risk factors included total dose (p < 0.001), BED (p < 0.005), neuret (p < 0.001), fraction size (p = 0.028), and the product of total dose and fraction size (p = 0.001). No patient receiving a BED <96 Gy2 developed radionecrosis. Subsequent chemotherapy significantly increased the risk of cerebral necrosis (p = 0.001) even when adjusted for BED (odds ratio [OR], 5.8; 95% confidence interval [CI], 1.6-20.3) or length of follow-up (OR, 5.4; 95% CI, 1.5-19.3). Concurrent use of valproate appeared to delay the onset of necrosis (p = 0.013). The development of radionecrosis did not affect survival (p = 0.09). CONCLUSIONS: Cerebral necrosis is unlikely at doses below 50 Gy in 25 fractions. The risk increases significantly with increasing radiation dose, fraction size, and the subsequent administration of chemotherapy.     

Optimum fractionation for high-dose-rate endoesophageal brachytherapy following external irradiation of early stage esophageal cancer

PURPOSE: To establish the optimum fractionation for high-dose-rate (HDR) endoesophageal brachytherapy (EBT) for early stage esophageal cancer from retrospective data of patients treated with different HDR schedules following external beam irradiation (EBI). METHODS AND MATERIALS: The study population consisted of 35 consecutive early stage esophageal cancer patients who received EBI to the mediastinum, plus EBT, between May 1992 and November 1995 at the Hiroshima University Medical Center and Hiroshima City Hospital. All patients were treated with EBI, with doses ranging from 50 to 61 Gy. The spinal cord was spared after 44-45 Gy. HDR EBT was performed using a double-balloon applicator in conjunction with an Ir-192 remote afterloading system. One group of 10 patients was given a weekly endoesophageal boost of 4 or 5 Gy at a distance of 5 mm from the applicator surface over a period of 1-2 weeks. Another group of 25 patients was treated with 4 or 5 endoesophageal boosts with a fraction dose of either 2.5 or 2 Gy for 1 week. The linear quadratic (LQ) formula was used to calculate the biologically effective dose (BED) for tumor (Gy10) and esophageal mucosa (Gy3); Gy10 means alpha/beta equals 10 Gy, and Gy3 means alpha/beta equals 3 Gy.The Kaplan-Meier method was used to calculate the local control and late complication rates, while the Cox-Mantel test was used to evaluate statistical significance (p < 0.01). RESULTS: Nine (26%) of the 35 patients recurred locally and 7 (20%) had late complications (esophageal ulcer grade by RTOG/EORTC criteria > 1). The 5-year overall survival, local control, and late complication rates were 38%, 57%, and 26%, respectively. The probability of local recurrence was not affected by the treatment parameters. Results from the LQ formula significantly correlate with data on late complications. A BED > 134 Gy3 and a fraction number = < 3 were associated with late complications (grade > 1). BED analysis showed that the fractionation dose should be decreased to 2.5 or 2.0 Gy at a distance of 5 mm from the applicator surface, and the number of doses increased to 4 or 5, respectively, to yield a satisfactory BED (< 134 Gy3). CONCLUSION: A significant reduction in endoesophageal brachytherapy dose per fraction is necessary to reduce late complications. Our current treatment protocol for early-stage esophageal cancer consists of EBI of 60 Gy followed by 4 EBT doses at a fraction dose of 2.5 Gy applied over 1 week.     

Update of human spinal cord reirradiation tolerance based on additional data from 38 patients

PURPOSE: To update a combined analysis of all published clinical data. METHODS AND MATERIALS: We collected data from 38 additional patients treated in our department or published in four different reports and calculated the biologically effective dose (BED) according to the linear-quadratic model using an alpha/beta value of 2 Gy for cervical and thoracic cord and 4 Gy for lumbar cord. In this model, a dose of 50 Gy given in single daily fractions of 2 Gy is equivalent to a BED of 100 Gy(2) or 75 Gy(4). RESULTS: The 2005 risk score based on three variables (cumulative BED, highest BED of all treatment series in a particular individual, and interval), which discriminate three different risk groups, does not require modification. The low-risk group now contains 1 case of radiation myelopathy (RM) after hypofractionated stereotactic reirradiation. Therefore, the rate increased from 0% to 3%. Intermediate-risk patients developed RM in 25%, and high-risk patients in 90%. When the interval between the two treatment courses is not shorter than 6 months and the dose of each course is < or =98 Gy(2), the cumulative BED where no case of RM has yet been reported is 120 Gy(2). CONCLUSIONS: Based on these updated results, the risk of RM appears small after < or =135.5 Gy(2) when the interval is not shorter than 6 months and the dose of each course is < or =98 Gy(2). We would recommend limiting the dose to the lowest feasible level. The influence of very steep dose gradients from stereotactic and intensity-modulated approaches (i.e., a more complex volume-effect) requires further evaluation.     

Acute radiation reactions in oral and pharyngeal mucosa: tolerable levels in altered fractionation schedules.

PURPOSE:To investigate whether a predictive estimate can be obtained for a 'tolerance level' of acute oral and pharyngeal mucosal reactions in patients receiving head and neck radiotherapy, using an objective set of dose and time data. MATERIALS AND METHODS:Several dozen radiotherapy schedules for treating head and neck cancer have been reviewed, together with published estimates of whether they were tolerated or (in a number of schedules) not. Those closest to the borderline were given detailed analysis. Total doses and biologically effective doses (BED or ERD) were calculated for a range of starting times of cellular repopulation and rates of daily proliferation. Starting times of proliferation from 5 to 10 days and daily cellular doubling rates of 1-3 days were considered. The standard published form of BED with its linear overall time factor was used: BED=nd(1 + d/(alpha/beta) - Ln2(T - T(k))/alpha T(p) (see text for parameters). RESULTS: A clear progression from acceptable to intolerable mucosal reactions was found, which correlated with total biologically effective dose (BED in our published modeling), for all the head and neck cancer radiotherapy schedules available for study, when ranked into categories of 'intolerable' or 'tolerable'. A review of published mechanisms for mucosal reactions suggested that practical schedules used for treatment caused stimulated compensatory proliferation to start at about 7 days. The starting time of compensatory proliferation had little predictive value in our listing, so we chose the starting time of 7 days. Very short and very long daily doubling rates also had little reliability, so we suggest choosing a doubling time of 2.5 days as a datum. With these parameters a 'tolerance zone of uncertainty' could be identified which predicted acute-reaction acceptability or not of a schedule within a range of about 2-10 Gy in total BED. If concurrent chemoradiotherapy is used, our provisional suggestion is that this zone should be reduced by up to roughly 3-5 Gy10 in BED, with a request for further evidence. CONCLUSIONS:It is suggested that total BED should be used, as specified above. Parameters of alpha=0.35 Gy-(1), alpha/beta=10 Gy, Tk=7 days and Tp=2.5 days are suggested. The 'acute/ tolerance zone' then turns out to be 59-61 Gy10 for radiation-only treatments. Further information about the decrement caused by concurrent head-and-neck cancer chemoradiotherapy, possibly 3-5 Gy10, is required.