Quantitative effect of combined chemotherapy and fractionated radiotherapy on the incidence of radiation-induced lung damage: a prospective clinical study

Acute Proteomic Changes in Lung after Radiation: Toward Identifying Initiating Events of Delayed Effects of Acute Radiation Exposure in Non-human Primate after Partial Body Irradiation with Minimal Bone Marrow Sparing

ABSTRACT

Radiation-induced lung injury is a delayed effect of acute radiation exposure resulting in pulmonary pneumonitis and fibrosis. Molecular mechanisms that lead to radiation-induced lung injury remain incompletely understood. Using a non-human primate model of partial body irradiation with minimal bone marrow sparing, lung was analyzed from animals irradiated with 12 Gy at timepoints every 4 d up to 21 d after irradiation and compared to non-irradiated (sham) controls. Tryptic digests of lung tissues were analyzed by liquid chromatography-tandem mass spectrometry followed by pathway analysis. Out of the 3,101 unique proteins that were identified, we found that 252 proteins showed significant and consistent responses across at least three time points post-irradiation, of which 215 proteins showed strong up-regulation while 37 proteins showed down-regulation. Canonical pathways affected by irradiation, changes in proteins that serve as upstream regulators, and proteins involved in key processes including inflammation, fibrosis, and retinoic acid signaling were identified. The proteomic profiling of lung conducted here represents an untargeted systems biology approach to identify acute molecular events in the non-human primate lung that could potentially be initiating events for radiation-induced lung injury.

Correlation of normal lung density changes with dose after stereotactic body radiotherapy (SBRT) for early stage lung cancer

BACKGROUND AND PURPOSE

To investigate the correlation between normal lung CT density changes with dose accuracy and outcome after stereotactic body radiation therapy (SBRT) for patients with early stage non-small-cell lung cancer (NSCLC).

MATERIALS AND METHODS

Thirty-one patients (with a total of 33 lesions) with non-small cell lung cancer were selected out of 270 patients treated with SBRT at a single institution between 2003 and 2009. Out of these 31 patients, 10 patients had developed radiation pneumonitis (RP). Dose distributions originally planned using a 1-D pencil beam-based dose algorithm were retrospectively recomputed using different algorithms. Prescription dose was 48 Gy in 4 fractions in most patients. Planning CT images were rigidly registered to follow-up CT datasets at 3-9 months after treatment. Corresponding dose distributions were mapped from planning to follow-up CT images. Hounsfield Unit (HU) changes in lung density in individual, 5 Gy, dose bins from 5 to 45 Gy were assessed in the peri-tumoral region. Correlations between HU changes in various normal lung regions, dose indices (V20, MLD, generalized equivalent uniform dose (gEUD)), and RP grade were investigated.

RESULTS

Strong positive correlation was found between HU changes in the peri-tumoral region and RP grade (Spearman's r = 0.760; p < 0.001). Positive correlation was also observed between RP and HU changes in the region covered by V20 for all algorithms (Spearman's r ≥ 0.738; p < 0.001). Additionally, V20, MLD, and gEUD were significantly correlated with RP grade (p < 0.01). MLD in the peri-tumoral region computed with model-based algorithms was 5-7% lower than the PB-based methods.

CONCLUSION

Changes of lung density in the peri-tumoral lung and in the region covered by V20 were strongly associated with RP grade. Relative to model-based methods, PB algorithms over-estimated mean peri-tumoral dose and showed displacement of the high-dose region, which correlated with HU changes on follow-up CT scans.

Acute Proteomic Changes in the Lung After WTLI in a Mouse Model: Identification of Potential Initiating Events for Delayed Effects of Acute Radiation Exposure

Radiation-induced lung injury is a delayed effect of acute radiation exposure resulting in pulmonary pneumonitis and fibrosis. Molecular mechanisms that lead to radiation-induced lung injury remain incompletely understood. Using a murine model of whole-thorax lung irradiation, C57BL/6J mice were irradiated at 8, 10, 12, and 14 Gy and assayed at day 1, 3, and 6 postexposure and compared to nonirradiated (sham) controls. Tryptic digests of lung tissues were analyzed by liquid chromatography-tandem mass spectrometry on a Waters nanoLC instrument coupled to a Thermo Scientific Q Exactive hybrid quadrupole-orbitrap mass spectrometer. Pathway and gene ontology analysis were performed with Qiagen Ingenuity, Panther GO, and DAVID databases. A number of trends were identified in the proteomic data, including protein changes greater than 10 fold, protein changes that were consistently up regulated or down regulated at all time points and dose levels interrogated, time and dose dependency of protein changes, canonical pathways affected by irradiation, changes in proteins that serve as upstream regulators, and proteins involved in key processes including inflammation, radiation, and retinoic acid signaling. The proteomic profiling conducted here represents an untargeted systems biology approach to identify acute molecular events that could potentially be initiating events for radiation-induced lung injury.

Occurrence of pneumonitis following radiotherapy of breast cancer - A prospective study

AIM

of this study is to determine the temporal resolution of therapy-induced pneumonitis, and to assess promoting factors in adjuvant treated patients with unilateral mammacarcinoma.

PATIENTS AND METHODS

A total of 100 post-surgery patients were recruited. The cohort was treated by 2 field radiotherapy (2FRT; breast and chest wall, N = 75), 3 field radiotherapy (3FRT; + supraclavicular lymphatic region, N = 8), or with 4 field radiotherapy (4FRT; + parasternal lymphatic region, N = 17). Ninety-one patients received various systemic treatments prior to irradiation. Following an initial screening visit post-RT, two additional visits after 12 and 25 weeks were conducted including radiographic examination. In addition, general anamnesis and the co-medication were recorded. The endpoint was reached as soon as a pneumonitis was developed or at maximum of six months post-treatment.

RESULTS

A pneumonitis incidence of 13% was determined. Of 91 patients with prior systemic therapy, 11 patients developed pneumonitis. Smoking history and chronic obstructive pulmonary disease (COPD) appeared to be positive predictors, whereas past pneumonia clearly promoted pneumonitis. Further pneumonitis-promoting predictors are represented by the applied field extensions (2 field radiotherapy [2FRT] < 3 field radiotherapy [3FRT] < 4 field radiotherapy [4FRT]) and the type of combined initial systemic therapies. As a consequence, all of the three patients in the study cohort treated with 4FRT and initial chemotherapy combined with anti-hormone and antibody protocols developed pneumonitis. A combination of the hormone antagonists tamoxifen and goserelin might enhance the risk for pneumonitis. Remarkably, none of the 11 patients co-medicated with statins suffered from pneumonitis.

CONCLUSIONS

The rapidly increasing use of novel systemic therapy schedules combined with radiotherapy (RT) needs more prospective studies with larger cohorts. Our results indicate that contribution to pneumonitis occurrence of various (neo)adjuvant therapy approaches followed by RT is of minor relevance, whereas mean total lung doses of >10 Gy escalate the risk of lung tissue complications. The validity of potential inhibitors of therapy-induced pneumonitis as observed for statin co-medication should further be investigated in future trials.

Comparison of electron and x-ray beams for tumor bed boost irradiation in breast-conserving treatment

Purpose

This study aimed to compare the dosimetric profiles of electron beams (EB) and X-ray beams (XB) for boosting irradiation in breast cancer patients who underwent breast-conserving surgery and postoperative radiotherapy.

Methods

For 131 breast cancer patients who underwent breast-conserving surgery, we compared plans for EB and XB boost irradiation after whole-breast irradiation. The organs at risk (OAR) included the cardiac chambers, coronary arteries, ipsilateral lung, and skin. The conformity index (CI), inhomogeneity index (IHI), and dose-volume parameters for the planning target volume (PTV), and OAR were calculated. Postradiotherapy chest computed tomography scans were performed to detect radiation pneumonitis.

Results

XB plans showed a significantly better CI and IHI for the PTVs, compared to the EB plans. Regarding OAR sparing, the XB reduced the high-dose volume at the expense of an increased low-dose volume. In 33 patients whose radiation fields included nipples, IHI was higher in the EB plans, whereas the presence of a nipple in the radiation field did not interfere with the XB. EB-treated patients developed more subclinical radiation pneumonitis.

Conclusion

XB plans were superior to EB plans in terms of PTV coverage (homogeneity and conformity) and high-dose volume sparing in OAR when used as boost irradiation after breast-conserving surgery. A disadvantage of the XB plan was an increased low-dose volume in the OAR, but this was offset by the increased electron energy. Consequently, tailored plans with either XB or EB are necessary to adapt to patient anatomic variance and tumor bed geometric properties.

Pulmonary outcomes in survivors of childhood cancer: a systematic review

BACKGROUND

The purpose of this article is to summarize the literature that documents the long-term impact of cancer treatment modalities on pulmonary function among survivors of cancer and to identify potential areas for further research.

METHODS

Systematic reviews of clinical trials, observational studies, case series, and review articles were conducted. Articles were limited to the studies that discussed pulmonary toxicity or late effects among pediatric cancer survivors and to follow-up investigations that were conducted a minimum of 2 years after completion of cancer-related treatment or 1 year after hematopoietic stem cell transplant.

RESULTS

Sixty publications (51 clinical studies/reports and nine reviews) published from January 1970 to June 2010 in PubMed met the inclusion criteria. Data showed an association between radiotherapy, alkylating agents, bleomycin, hematopoietic stem cell transplant, and thoracic surgery and pulmonary toxicity, as well as possible interactions among these modalities.

CONCLUSIONS

Pulmonary toxicity is a common long-term complication of exposure to certain anticancer therapies in childhood and can vary from subclinical to life threatening. Pulmonary function and associated loss of optimal exercise capacity may have adverse effects on long-term quality of life in survivors. Lung function diminishes as a function of normal aging, and the effects of early lung injury from cancer therapy may compound these changes. The information presented in this review is designed to provide a stimulus to promote both observational and interventional research that expands our knowledge and aids in the design of interventions to prevent or ameliorate pulmonary late effects among survivors of childhood cancer.

A new approach to quantifying lung damage after stereotactic body radiation therapy

Radiological pneumonitis and fibrosis are common after stereotactic body radiotherapy (SBRT) but current scoring systems are qualitative and subjective. We evaluated the use of CT density measurements and a deformable registration tool to quantitatively measure lung changes post-SBRT. Material and methods. Four-dimensional CT datasets from 25 patients were imported into an image analysis program. Deformable registration was done using a B-spline algorithm (VelocityAI) and evaluated by landmark matching. The effects of respiration, contrast, and CT scanner on density measurements were evaluated. The relationship between density and clinician-scored radiological pneumonitis was assessed. Results. Deformable registration resulted in more accurate image matching than rigid registration. CT lung density was maximal at end-expiration, and most deformation with breathing occurred in the lower thorax. Use of contrast increased mean lung density by 18 HU (range 16-20 HU; p = 0.004). Diagnostic scans had a lower mean lung density than planning scans (mean difference 57 HU in lung contralateral to tumor; p = 0.048). Post-treatment CT density measurements correlated strongly with clinician-scored radiological pneumonitis (r = 0.75; p < 0.001). Conclusions. Quantitative analysis of changes in lung density correlated strongly with physician-assigned radiologic pneumonitis scores. Deformable registration and CT density measurements permit objective assessment of treatment toxicity.

Association between RT-induced changes in lung tissue density and global lung function

PURPOSE

To assess the association between radiotherapy (RT)-induced changes in computed tomography (CT)-defined lung tissue density and pulmonary function tests (PFTs).

METHODS AND MATERIALS

Patients undergoing incidental partial lung RT were prospectively assessed for global (PFTs) and regional (CT and single photon emission CT [SPECT]) lung function before and, serially, after RT. The percent reductions in the PFT and the average changes in lung density were compared (Pearson correlations) in the overall group and subgroups stratified according to various clinical factors. Comparisons were also made between the CT- and SPECT-based computations using the Mann-Whitney U test.

RESULTS

Between 1991 and 2004, 343 patients were enrolled in this study. Of these, 111 patients had a total of 203 concurrent post-RT evaluations of changes in lung density and PFTs available for the analyses, and 81 patients had a total of 141 concurrent post-RT SPECT images. The average increases in lung density were related to the percent reductions in the PFTs, albeit with modest correlation coefficients (range, 0.20-0.43). The analyses also indicated that the association between lung density and PFT changes is essentially equivalent to the corresponding association with SPECT-defined lung perfusion.

CONCLUSION

We found a weak quantitative association between the degree of increase in lung density as defined by CT and the percent reduction in the PFTs.

Relationship between radiation pneumonitis and prognosis in patients with primary lung cancer treated by radiotherapy

Relationship between the grade of radiation pneumonitis (RP) and treatment outcome in lung cancer patients has not been clarified yet. The purpose of this study was to retrospectively evaluate the relationship in patients with primary lung cancer treated by radiotherapy. One hundred thirty-five patients who underwent definitive radiotherapy with known grade of RP were analyzed. RP was scored by using the Radiation Therapy Oncology Group (RTOG) acute radiation morbidity scoring criteria. Survival and local control data were analyzed in relation to the grade of RP. RP was grade 0 in 5 patients, grade 1 in 71, grade 2 in 39, grade 3 in 15 (11%), grade 4 in 0 and grade 5 in 5 (3.7%). There were no significant correlations between patient or tumor characteristics and grade of RP. Excluding 5 patients with grade 5 pneumonitis, survival rates were similar between those with grade 0 or 1 pneumonitis and those with grade 2 or 3. Also, there was no difference in survival between patients with grade 0-2 pneumonitis and those with grade 3. Local control rates were similar between the two groups. Grade of RP did not appear to be associated with prognosis when patients with grade 5 pneumonitis were excluded from analysis.

Association between systemic chemotherapy before chemoradiation and increased risk of treatment-related pneumonitis in esophageal cancer patients treated with definitive chemoradiotherapy

BACKGROUND

There is limited information on risk factors for treatment-related pneumonitis in esophageal cancer patients.

AIM OF THE STUDY

To determine factors associated with treatment-related pneumonitis in esophageal cancer patients treated with definitive chemoradiotherapy.

MATERIALS AND METHODS

We retrospectively reviewed clinical data from esophageal cancer patients treated with definitive chemoradiotherapy from 2000 to 2003. Demographic, clinical, and treatment-related data were collected for all patients. The time to occurrence of grade > or =2 pneumonitis was calculated from the end of radiotherapy. Univariate analyses were performed to determine the existence of any association between patient demographic, clinical, or treatment characteristics and pneumonitis.

RESULTS

In total, 96 patients were included in the study with a median follow-up of 8 months (range, <1-48 months). Among them, 23 patients also received an average of two cycles of systemic chemotherapy before the initiation of concurrent chemoradiation. The incidence of grade > or =2 pneumonitis was 22% at 1 year. Systemic chemotherapy before concurrent chemoradiation was significantly associated with an increased risk of grade > or =2 pneumonitis (p = 0.003), with the 1-year incidence of grade > or =2 pneumonitis for patients with and without systemic chemotherapy being 49 and 14%, respectively. No other clinical or dosimetric factors investigated were associated with the risk of grade > or =2 pneumonitis.

CONCLUSIONS

Systemic chemotherapy before concurrent chemoradiation was significantly associated with an increased risk of grade > or =2 pneumonitis, suggesting that induction chemotherapy may have sensitized the lung tissue to radiation damage in esophageal cancer patients.

Strain dependent differences in a histological study of CD44 and collagen fibers with an expression analysis of inflammatory response-related genes in irradiated murine lung

Using a mouse model, we investigated the mechanisms of heterogeneity in response to ionizing radiation in this research. C57BL/6J and C3H/HeMs mice were irradiated with gamma rays at 10 and 20 Gy. The animals were sacrificed at times corresponding to the latent period, the pneumonic phase, and the start of the fibrotic phase for histological investigation. Small areas of fibrosis initially appeared in C57BL/6J mice at 4 weeks postirradiation with 20 Gy, whereas small inflammatory lesions appeared at 4 and 8 weeks after 20 and 10 Gy, respectively. The alveoli septa were thickened by an infiltration of inflammatory cells, and alveoli were obliterated in lungs from C57BL/6J mice after 20 Gy irradiation. At 24 hours and from 2 to 4 weeks postirradiation, fourfold more CD44 positive cells had accumulated in the lungs of C3H/HeMs than in C57BL/6J mice. Hyaluronan accumulated 12 hours after irradiation, and the rapid resolution was achieved within 2 weeks in the lungs in both strains of mice. C57BL/6J mice lungs accumulated dense collagen at 8 weeks. Quantitative RT-PCR assay was performed for several genes selected by cDNA microarray analysis. The expression of several genes, such as Cap1, Il18, Mmp12, Per3, Ltf, Ifi202a, and Rad51ap1 showed strain-dependent variances. In conclusion, a histological investigation suggested that C3H/HeMs mice were able to induce a more rapid clearance of matrix after irradiation than C57BL/6J mice. The expression analysis showed that the several genes are potentially involved in interstrain differences in inflammatory response causing radiation-induced lung fibrosis.

Significance of plasma transforming growth factor-beta levels in radiotherapy for non-small-cell lung cancer

PURPOSE

In dose-escalation studies of radiotherapy (RT) for non-small-cell lung cancer (NSCLC), radiation pneumonitis (RP) is the most important dose-limiting complication. Transforming growth factor-beta1 (TGF-beta1) has been reported to be associated with the incidence of RP. It has been proposed that serial measurements of plasma TGF-beta1 can be valuable to estimate the risk of RP and to decide whether additional dose-escalation can be safely applied. The aim of this study was to evaluate prospectively the time course of TGF-beta1 levels in patients irradiated for NSCLC in relation to the development of RP and dose-volume parameters.

METHODS AND MATERIALS

Plasma samples were obtained in 68 patients irradiated for medically inoperable or locally advanced NSCLC (dose range, 60.8-94.5 Gy) before and 4, 6, and 18 weeks after the start of RT. Plasma TGF-beta1 levels were determined using a bioassay on the basis of TGF-beta1-induced plasminogen activator inhibitor-1 expression in mink lung cells. All patients underwent chest computed tomography scans before RT that were repeated at 18 weeks after RT. The computed tomography data were used to calculate the mean lung dose (MLD) and to score the radiation-induced radiologic changes. RP was defined on the basis of the presence of either radiographic changes or clinical symptoms. Symptomatic RP was scored according to the Common Toxicity Criteria (Grade 1 or worse) and the Southwestern Oncology Group criteria (Grade 2 or worse). Multivariate analyses were performed to investigate which factors (pre- or posttreatment TGF-beta1 level, MLD) were associated with the incidence of RP. To improve our understanding of the time course of TGF-beta1 levels, we performed a multivariate analysis to investigate which factors (pre-RT TGF-beta1 level, MLD, RP) were independently associated with the posttreatment TGF-beta1 levels.

RESULTS

The pre-RT TGF-beta1 levels were increased in patients with NSCLC (median 21 ng/mL, range, 5-103 ng/mL) compared with healthy individuals (range, 4-12 ng/mL). On average, the TGF-beta1 levels normalized toward the end of treatment and remained stable until 18 weeks after RT. In 29 patients, however, TGF-beta1 was increased at the end of RT with respect to the pre-RT value. The multivariate analyses revealed that the MLD was the only variable that correlated significantly with the risk of both radiographic RP (p = 0.05) and symptomatic RP, independent of the scoring system used (p = 0.05 and 0.03 for Southwestern Oncology Group and Common Toxicity Criteria systems, respectively). The TGF-beta1 level at the end of RT was significantly associated with the MLD (p <0.001) and pre-RT TGF-beta1 level (p = 0.001).

CONCLUSION

The MLD correlated significantly with the incidence of both radiographic and symptomatic RP. The results of our study did not confirm the reports that increased levels of TGF-beta1 at the end of RT are an independent additional risk factor for developing symptomatic RP. However, the TGF-beta1 level at the end of a RT was significantly associated with the MLD and the pre-RT level.

Early response of lung in breast cancer irradiation: radiologic density changes measured by CT and symptomatic radiation pneumonitis

PURPOSE

To quantify radiologic changes in the lung with CT after radiotherapy (RT) for breast cancer (BC) and to study their association with treatment techniques and symptomatic radiation pneumonitis (RP).

METHODS AND MATERIALS

CT scans of the lungs were performed before and 4 months after RT in 121 BC patients treated with four different RT techniques. The changes in mean density (MDCs) were analyzed at two lung levels (i.e., the central and apical CT slice). The central CT slice was also analyzed with respect to the MDCs in the anterior third and anterior half of the ipsilateral lung area. In mastectomized patients who received chest wall RT with an en-face electron beam, the maximal depths for a range of isodose curves were measured. The occurrence of mild/moderate symptomatic RP was assessed prospectively 1, 4, and 7 months after RT. Data on covariates with potential confounding effect on RT-induced lung toxicity were also collected prospectively.

RESULTS

In the entire study population, an association between the MDCs in the anterior third of the central CT slice and treatment technique (p <0.001) and symptomatic RP (p <0.001) was found. Among patients with chest wall treatment consisting of an en-face electron beam, the MDCs of the anterior third of the central CT slice correlated with the 35% isodose curve (16-30 Gy) (p = 0.046) and age (p <0.001). No association between post-RT lung density changes and pre-RT chemotherapy, concurrent tamoxifen intake, or smoking habits was found. Among patients treated with locoregional RT, an association was found between the MDCs in the anterior third of the central CT slice and the incidence of RP. MDCs in the apical CT slice, however, were not associated with RP.

CONCLUSION

The results imply that short-term post-RT lung density changes and symptomatic RP were associated with RT techniques, total doses as low as 16-30 Gy, and increasing age. Structural changes in the central part of lung appeared to be more important for the development of RP than changes in the apex.

Radiotherapy or chemotherapy followed by radiotherapy with or without amifostine in locally advanced lung cancer

Radiotherapy (RT) or radiochemotherapy is the treatment of choice for patients with medically or technically inoperable non-small cell lung cancer (NSCLC) localized to the primary site and regional lymph nodes. Radiation-induced damage has been recognized as a major complication in thoracic RT. The use of concurrent chemoradiation has been associated with an increase in acute and late toxicity. Amifostine (Ethyol) is an effective cytoprotective agent and also may have a role in protecting healthy lung tissue during radiation treatment. The purpose of these 2 clinical trials was to investigate whether daily pretreatment with amifostine could reduce the incidence of esophagitis, and acute and late lung toxicity without affecting the antitumor efficacy of the treatment. The first was a phase III randomized trial of 146 patients with locally advanced lung cancer. All patients received conventional RT to a total of 55 to 60 Gy, and they were assigned randomly to pretreatment with 340 mg/m(2) of amifostine (A). Acute and late toxicities were graded according to the Radiation Therapy Oncology Group (RTOG) grading system from grades 0 to 4. Ninety-seven patients were evaluated 2 months post-RT for the incidence of pneumonitis; 43% (23 of 53) of patients in the RT arm and 9% (9 of 44) in the A plus RT arm experienced grade > or = 2 pneumonitis (P <.001). Forty-nine percent (26 of 53) of patients in the RT arm and 16% (7/44) in the A plus RT arm showed changes that were representative of grade > or = 2 lung damage in the computed tomography (CT) scan. Fibrosis was present in 53% (19 of 36) of patients receiving RT versus 28% (9 of 32) in the A plus RT arm at 6 months (P < 0.05). The incidence of esophagitis grade > or = 2 during week 4 was 42% (31 of 73) in the RT arm versus 4% (3 of 73) in the A plus RT arm (P <.001). Among 97 patients evaluable for response 2 months after RT, complete or partial responses were present in 76% (40 of 53) of patients in the RT arm and 75% (33 of 44) in the A plus RT arm (P = 1.0). The second trial was a phase II randomized study of 45 patients with NSCLC. All patients had received platinum-based induction chemotherapy before being referred for conventional radiation treatment with or without A; a total dose of 55 to 60 Gy was administered at the primary site. Acute and late toxicities were evaluated and graded according the RTOG criteria from grades 0 to 4. Forty-five patients were evaluable for response 2 months after RT. Complete or partial responses were achieved in 78% (18 of 23) of patients in the RT arm and 82% (18 of 22) in the A plus RT arm (P =.278). By week 5, 74% (17 of 23) of patients in the RT group versus 36% (8 of 22) in the A plus RT group experienced grade > or = 2 esophagitis. (During the follow-up period, pulmonary toxicity was evaluated by CT scan.) Three months after RT, 65% (15/23) of patients in the RT group and 32% (7 of 22) in the A plus RT group presented with grade > or = 2 pneumonitis (P =.038). Amifostine reduces the incidence of acute and late radiation-induced toxicities.

The time course of radiation therapy-induced reductions in regional perfusion: a prospective study with >5 years of follow-up

PURPOSE

To assess the time-dependence of radiation therapy (RT)-induced reductions in regional lung perfusion, as measured by single photon emission computed tomography (SPECT) lung perfusion scans.

METHODS AND MATERIALS

Between 1991 and 1999, 79 patients had SPECT lung perfusion scans before and serially after RT. Changes in regional perfusion were correlated with regional dose using 3D planning tools and image fusion (PLUNC-Plan UNC). Multiple post-RT follow-up scans were evaluated to determine the temporal nature of RT-induced regional perfusion changes. To facilitate the comparison of dose-response curves (DRCs) at different post-RT intervals, each DRC was fit to a linear model and thus described by its slope.

RESULTS

There was a dose-dependent reduction in regional perfusion at nearly all time points post-RT (p = 0.0001). The slope of the DRCs for RT-induced reductions in regional perfusion became steeper at essentially each successive follow-up interval (p = 0.0001). However, the increases in slope became progressively smaller at later follow-up intervals. Overall, about 80% of the long-term RT-induced regional perfusion injury was manifest within 12 months post-RT.

CONCLUSION

There is a progression of RT-induced reductions in regional perfusion, with most of this injury manifest within 12 months post-RT. Additional regional injury appears to evolve for years.

Relating radiation-induced regional lung injury to changes in pulmonary function tests

PURPOSE

To determine whether the sum of radiotherapy (RT)-induced reductions in regional lung perfusion is quantitatively related to changes in global lung function as assessed by reductions in pulmonary function tests (PFTs).

METHODS AND MATERIALS

Two hundred seven patients (70% with lung cancer) who received incidental partial lung irradiation underwent PFTs (forced expiratory volume in 1 s and diffusion capacity for carbon monoxide) before and repeatedly after RT as part of a prospective clinical study. Regional lung function was serially assessed before and after RT by single photon emission computed tomography perfusion scans. Of these, 53 patients had 105 post-RT evaluations of changes in both regional perfusion and PFTs, were without evidence of intrathoracic disease recurrence that might influence regional perfusion and PFT findings, and were not taking steroids. The summation of the regional functional perfusion changes were compared with changes in PFTs using linear regression analysis.

RESULTS

Follow-up ranged from 3 to 86 months (median 19). Overall, a significant correlation was found between the sum of changes in regional perfusion and the changes in the PFTs (p = 0.002-0.24, depending on the particular PFT index). However, the correlation coefficients were small (r = 0.16-0.41).

CONCLUSIONS

A statistically significant correlation was found between RT-induced changes in regional function (i.e., perfusion) and global function (i.e., PFTs). However, the correlation coefficients are low, making it difficult to relate changes in perfusion to changes in the PFT results. Thus, with our current techniques, the prediction of changes in perfusion alone does not appear to be sufficient to predict the changes in PFTs accurately. Additional studies to clarify the relationship between regional and global lung injury are needed.

Serum levels of KL-6 are useful biomarkers for severe radiation pneumonitis

The antigen KL-6, a mucin-like high-molecular-weight glycoprotein, is expressed on type-2 pneumocytes and bronchiolar epithelial cells. Serum levels of KL-6 have been shown to correlate well with the activities of several different kinds of interstitial pneumonia. The purpose of this study was to assess the usefulness of monitoring serum KL-6 levels in patients who had received thoracic radiotherapy (TRT). In particular, the usefulness of such a protocol for the early diagnosis of severe radiation pneumonitis (RP) and the evaluation of its progress and severity was examined. Serum KL-6 levels were retrospectively monitored in 16 patients with lung cancer who had received TRT with or without chemotherapy. Eight of these patients had developed severe RP and eight had developed localized (within the irradiated field) RP. Serum KL-6 levels were measured using a modified sandwich-type enzyme-linked immunosorbent assay. In patients who developed severe RP, serum KL-6 levels showed a consistent tendency to increase after the clinical diagnosis of RP. In four patients, serum KL-6 levels even began to rise before a clinical diagnosis of severe RP had been made. In the patients with localized RP, on the other hand, the serum levels did not show any tendency to increase during or after TRT. Moreover, patients whose serum KL-6 levels rose more than 1.5 times higher than their pre-treatment serum KL-6 level, had a large chance of developing severe RP that was unresponsive to steroid hormones and resulted in death. Serum KL-6 levels, therefore, should be useful indicators for the early diagnosis of severe RP and for estimating its progress and severity in patients treated with TRT.

Partial irradiation of the lung

Many factors like fractionation, overall treatment time, and patient specific aspects are important when studying and quantifying the effects of partial lung irradiation. The local reactions of lung tissue to irradiation are described with regard to the dose-volume effect. Different models that are used to predict the incidence of radiation pneumonitis and the influence of irradiation on the overall lung function are discussed. The easy-to-calculate mean lung dose (MLD) and the volume irradiated to 20 Gy (V20) can both be used to predict the incidence of radiation pneumonitis. These parameters represent 2 extremes in underlying local dose-effect relations for radiation pneumonitis. However, clinically applied treatment plans show a high correlation between the V20 and the MLD, so that the decision for the "best" underlying local dose-effect relation should be based on the analysis of additional patient data. Dose-escalation studies and multi-center co-operation will create more possibilities to investigate all confounding factors concerning lung irradiation.

Radiation pneumonitis in lung cancer patients: a retrospective study of risk factors and the long-term prognosis

PURPOSE

To retrospectively evaluate the risk factors for acute radiation pneumonitis (RP) and long-term prognosis of patients with lung cancer treated by thoracic radiotherapy.

METHODS AND MATERIALS

Of the 256 lung cancer patients who underwent definitive thoracic radiotherapy between June 1988 and May 1998, the 191 patients who were capable of being evaluated were divided into three groups according to the grade of RP. RP was defined as "severe," when it caused severe clinical symptoms, such as intractable cough, dyspnea at rest, and the need for oxygen or steroid therapy. The definition was made by using a modification of the Radiation Therapy Oncology Group and the European Organization for Research and Treatment of Cancer acute radiation morbidity scoring criteria. Factors that influenced the incidence of severe RP were assessed by using the Mantel-Haenszel chi(2) test in the univariate analysis and the logistic regression test in the multivariate analysis. Survival rates was calculated by using the Kaplan-Meier method, and the p values indicating the significance of differences between the RP groups were calculated by the log-rank test.

RESULTS

Of the 94 patients (49%) who experienced clinical RP in this study, the RP was mild in 69 (36%) and severe in 25 (13%) patients. The 3-year survival rates of the patients who experienced no, mild, and severe RP were 33.4%, 38.2%, and and 0%, respectively, and the survival rate of the patients who experienced severe RP was significantly poorer than the other two groups combined (p = 0.0028). The incidence of severe RP did not correlate with any of the baseline patient characteristics, radiotherapeutic factors, or chemotherapeutic variables. Two clinical risk factors were identified from medical records before radiotherapy: low PaO2 (< 80 torr) and high C-reactive protein (CRP) (> 1.0 ng/mL). Both of them were significantly related to the development of severe RP in the univariate analysis (p = 0.004 and 0.013, respectively), and low PaO2 remained a significant risk factor in the multivariate analysis (p = 0.034). Multivariate analysis also revealed the occurrence of severe RP to be the most important factor determining poor survival (p = 0.0065). There was no significant difference in survival rate according to whether the patients had been treated with corticosteroids.

CONCLUSION

Mild and severe RP occurred in 69 (36%) and 25 (13%), respectively, of 191 lung cancer patients who had undergone irradiation of the chest. Only severe RP was an adverse prognostic factor. Low PaO2 (< 80 torr) before radiotherapy was a significant risk factor predictive of severe RP. The role of corticosteroids in RP could not be accurately determined.

Can we predict radiation-induced changes in pulmonary function based on the sum of predicted regional dysfunction?

PURPOSE

To determine whether changes in whole-lung pulmonary function test (PFT) values are related to the sum of predicted radiation therapy (RT)-induced changes in regional lung perfusion.

PATIENTS AND METHODS

Between 1991 and 1998, 96 patients (61% with lung cancer) who were receiving incidental partial lung irradiation were studied prospectively. The patients were assessed with pre- and post-RT PFTs (forced expiratory volume in one second [FEV1] and diffusion capacity for carbon monoxide [DLCO]) for at least a 6-month follow-up period, and patients were excluded if it was determined that intrathoracic recurrence had an impact on lung function. The maximal declines in PFT values were noted. A dose-response model based on RT-induced reduction in regional perfusion (function) was used to predict regional dysfunction. The predicted decline in pulmonary function was calculated as the weighted sum of the predicted regional injuries: equation [see text] where Vd is the volume of lung irradiated to dose d, and Rd is the reduction in regional perfusion anticipated at dose d.

RESULTS

The relationship between the predicted and measured reduction in PFT values was significant for uncorrected DLCO (P = .005) and borderline significant for DLCO (P = .06) and FEV1 (P = .08). However, the correlation coefficients were small (range,.18 to.30). In patients with lung cancer, the correlation coefficients improved as the number of follow-up evaluations increased (range,.43 to.60), especially when patients with hypoperfusion in the lung adjacent to a central mediastinal/hilar thoracic mass were excluded (range,.59 to.91).

CONCLUSION

The sum of predicted RT-induced changes in regional perfusion is related to RT-induced changes in pulmonary function. In many patients, however, the percentage of variation explained is small, which renders accurate predictions difficult.

Computed tomographic evaluation of radiation pneumonitis in a canine model

The objective of this study was to document the utility of computed tomography (CT) and a three-dimensional (3-D) radiotherapy treatment planning system for assessing the development of acute radiation pneumonitis in a canine model. Fourteen dogs were randomly assigned to a nonirradiated control group or one of three radiation dose groups receiving a single fraction of either 12, 15, or 18 Gy delivered to two-thirds of the right hemithorax. CT and survey radiographs were performed in all dogs prior to and at defined intervals for up to 13 weeks following irradiation. All images were subjectively evaluated for development of radiation pneumonitis and CT images were quantitatively analyzed. Radiation pneumonitis was detected earlier with CT images than with radiographs. Quantitatively, functional lung volume and radiation pneumonitis lesion volume on CT images changed over time in all irradiated dogs. However, there was no statistically significant difference between the three radiation dose groups, but a marked difference between irradiated dogs and nonirradiated controls. These data suggest that CT is superior to survey radiography for the evaluation and quantification of acute radiation pneumonitis in this canine model. Quantification of acute radiation pneumonitis suggests future promise for evaluating the efficacy of modifiers to lessen the effects of irradiating normal lung tissue in this canine model.

The effect of patient-specific factors on radiation-induced regional lung injury

PURPOSE

To assess the impact of patient-specific factors on radiation (RT)-induced reductions in regional lung perfusion.

METHODS

Fifty patients (32 lung carcinoma, 7 Hodgkin's disease, 9 breast carcinoma and 2 other thoracic tumors) had pre-RT and > or = 24-week post-RT single photon emission computed tomography (SPECT) perfusion images to assess the dose dependence of RT-induced reductions in regional lung perfusion. The SPECT data were analyzed using a normalized and non-normalized approach. Furthermore, two different mathematical methods were used to assess the impact of patient-specific factors on the dose-response curve (DRC). First, DRCs for different patient subgroups were generated and compared. Second, in a more formal statistical approach, individual DRCs for regional lung injury for each patient were fit to a linear-quadratic model (reduction = coefficient 1 x dose + coefficient 2 x dose2). Multiple patient-specific factors including tobacco history, pre-RT diffusion capacity to carbon monoxide (DLCO), transforming growth factor-beta (TGF-beta), chemotherapy exposure, disease type, and mean lung dose were explored in a multivariate analysis to assess their impact on the coefficients.

RESULTS

None of the variables tested had a consistent impact on the radiation sensitivity of regional lung (i.e., the slope of the DRC). In the formal statistical analysis, there was a suggestion of a slight increase in radiation sensitivity in the dose range >40 Gy for nonsmokers (vs. smokers) and in those receiving chemotherapy (vs. no chemotherapy). However, this finding was very dependent on the specific statistical and normalization method used.

CONCLUSION

Patient-specific factors do not have a dramatic effect on RT-induced reduction in regional lung perfusion. Additional studies are underway to better clarify this issue. We continue to postulate that patient-specific factors will impact on how the summation of regional injury translates into whole organ injury. Refinements in our methods to generate and compare SPECT scans are needed.

Effects of ongoing smoking on the development of radiation-induced pneumonitis in breast cancer and oesophagus cancer patients

PURPOSE

To investigate the influence of smoking on the development of radiation-induced pneumonitis in patients treated for breast and oesophagus cancer.

MATERIALS AND METHODS

This is a retrospective study on 405 females diagnosed with primary unilateral breast cancer stages 1 and 2 and 201 oesophagus carcinoma patients. The possibilities in Sweden to obtain detailed information from different medical records were used to collect data on smoking habits, radiation treatment and spontaneously reported pneumonitis. Radiation-induced pneumonitis was defined as a combination of roentgenographic infiltrate in the lung field involving an irradiated area on the chest X-ray and clinical symptoms such as non-productive cough and dyspnoea.

RESULTS

Six breast cancer patients had spontaneously reported pneumonitis. Five of them were non-smokers (P = 0.182) and the other was a former smoker. Eight of the oesophagus cancer patients had spontaneously reported radiation-induced clinical pneumonitis and they were all non-smokers (P = 0.022), except one, who was a pipe smoker. None of the patients who were cigarette smokers were recorded as developing clinical pneumonitis after irradiation.

CONCLUSION

These data could support the previous clinical observations and experimental studies that smoking depresses the frequency of radiation-induced pneumonitis. The present study as well as earlier observations could justify further studies concerning the possibility of an interaction of smoking with cancer treatment, both from the view of therapeutic failures and reduced adverse effects.

Regional dose response to pulmonary irradiation using a manual method

PURPOSE

To better understand the dose dependence of radiation therapy (RT)-induced changes in regional lung perfusion and tissue density, using a manual method to reduce inaccuracies that might be present in previously described automated methods.

MATERIALS AND METHODS

Patients who were to receive RT for tumors in and around the thorax, wherein portions of healthy lung would be incidentally irradiated, were prospectively studied. Changes in regional perfusion and tissue density were assessed by comparison of pre- and post-RT single photon emission computed tomography (SPECT), lung perfusion scans and computed tomography (CT) scans, respectively. The three-dimensional dose distribution was calculated on the pre-RT CT scan and correlated to the other scans via image registration. Study volumes were defined by hand and individually visualized on pre- and post-RT scans. The manually generated dose response data were compared to data generated using automated methods. The relationship between CT density and SPECT perfusion was also determined.

RESULTS

Thirteen patients with lung cancer were evaluated for changes in tissue density and 11 patients were evaluated for changes in regional perfusion at 12 months post-RT. In general, density increases with increasing regional dose, with marked changes at >60 Gy. Regional perfusion decreases with increasing regional dose. In the low dose regions, relative perfusion increases by 35% on average. Manually measured dose responses correlated well with those determined automatically. The relationship between regional perfusion and CT density indicates a wide range of perfusion over a narrow range of CT density, with markedly reduced perfusion at CT densities of > -600 and < -900 H.

CONCLUSIONS

The manually generated CT density dose response data broadly agree with data previously generated using automated methods. The manually generated perfusion dose response data are in fairly good agreement with automated data, lending credibility to the accuracy of the automated methods. Regional perfusion is markedly diminished where CT density is outside the range of normal lung tissue.

Evaluation of two dose-volume histogram reduction models for the prediction of radiation pneumonitis

PURPOSE

To evaluate the similarities between the mean lung dose and two dose-volume histogram (DVH) reduction techniques of 3D dose distributions of the lung.

PATIENTS AND METHODS

DVHs of the lungs were calculated from 3D dose distributions of patients treated for malignant lymphoma (44), breast cancer (42) and lung cancer (20). With a DVH reduction technique, a DVH is summarized by the equivalent uniform dose (EUD), a quantity which is directly related to the normal tissue complication probability (NTCP). Two DVH reduction techniques were used. The first was based on an empirical model proposed by Kutcher et al. (Kutcher, G.J., Burman, C., Brewster, M.S., Goitein, M. and Mohan, R. Histogram reduction method for calculating complication probabilities for three-dimensional treatment planning evaluations. Int. J. Radiat. Oncol. Biol. Phys. 21: 137-146, 1991), which needs a volume exponent n. Several values for n were tested. The second technique was based on a radiobiological model, the parallel functional subunit model developed by Niemierko et al. (Niemierko, A. and Goitein, M. Modeling of normal tissue response to radiation: the critical volume model. Int. J. Radiat. Oncol. Biol. Phys. 25: 135-145, 1993) and Jackson et al. (Jackson, A., Kutcher, G.J. and Yorke, E.D. Probability of radiation-induced complications for normal tissues with parallel architecture subject to non-uniform irradiation. Med. Phys. 20: 613-625, 1993), for which a local dose-effect relation needed to be specified. This relation was obtained from an analysis of perfusion and ventilation SPECT data.

RESULTS

It can be shown analytically that the two DVH reduction techniques are identical, if the local dose-effect relation obeys a power-law relationship in the clinical dose range. Local dose-effect relations based on perfusion and ventilation SPECT data can indeed be fitted with a power-law relationship in the range 0-80 Gy, from which values of n = 0.8-0.9 were deduced. These correspond to the commonly used value of n = 0.87 for lung tissue and yielded EUDn=0.87 values which were almost identical to the mean lung doses. For other n values, for which no experimental data are present, differences exist between EUD and mean dose values. Six patients with malignant lymphoma (6/44) and none of the breast cancer patients (0/42) developed radiation pneumonitis. These cases occurred only at high values for the mean lung dose.

CONCLUSION

The two DVH reduction techniques are identical for lung and are very similar to mean dose calculations. The two techniques are also relatively similar for other model parameter values.

Factors influencing the development of lung fibrosis after chemoradiation for small cell carcinoma of the lung: evidence for inherent interindividual variation

PURPOSE

Clinical observations often reveal individual differences in the severity of lung fibrosis after definitive radiation therapy for lung cancer. Recent experimental studies suggest that the risk of developing lung fibrosis may be genetically controlled. The present study was undertaken to examine the magnitude of individual variation in the incidence and severity of lung fibrosis in a well-defined patient population treated by concurrent chemoradiation for limited small-cell lung carcinomas (LSCLC).

MATERIALS AND METHODS

Between 1989 and 1994, 56 patients with LSCLC were enrolled in one of two controlled prospective studies of concurrent chemotherapy and concomitant conventional (45 Gy in 25 fractions q.d. over 5 weeks) or accelerated (45 Gy in 30 fractions b.i.d. over 3 weeks) radiotherapy. Chemotherapy consisted of cisplatin and etoposide (PE) or PE plus ifosfamide and mesna (PIE). Of the 56, a group of 25 patients who had serial computerized tomography (CT) examinations of the chest and were deemed to have unequivocal radiographic complete responses were selected for this study. The severity of lung fibrosis was recorded for each patient from the CT images using an arbitrary scale (0 to 3) at 1 year after treatment. Radiographic fibrosis scores were recorded on 1-3 CT slices in 3 different dose-areas (20-30 Gy; 30-40 Gy; and >40 Gy) that were defined using the corresponding CT slices from the patient's CT treatment plan. Of these patients, 23 (92%) had at least 2 slices scored; 11 patients had all 3 slices scored.

RESULTS

Among the clinical and treatment parameters investigated (including type of chemotherapy), only total dose and fractionation schedule were identified as significant and independent determinants of lung fibrosis. Radiographic fibrosis scores were higher in high-dose areas and among patients treated with the accelerated schedule. Using a fit of the proportional odds (PO) model based on the total dose and fractionation schedule, fibrosis score residuals were calculated for each patient. The residual for each score is defined as the difference between the observed and expected score based on the dose and treatment schedule received. Average residuals varied significantly among patients (p = 0.005, Kruskal-Willis test). Using a modified version of the PO model, the coefficient of variation in patient heterogeneity was estimated to be 10.1% (95% confidence interval: 6.2-14.9%). Inclusion of the heterogeneity factor, in addition to total dose and fractionation schedule, improved the fit of the PO model to an extremely high level of significance (p < 10(-7)).

CONCLUSIONS

Our data indicate that the risk and severity of lung fibrosis analyzed radiographically on CT images increases with total dose and with the use of an accelerated radiation schedule, for patients treated with chemoradiation for small-cell lung cancer. There was also demonstrable patient-to-patient heterogeneity, suggesting that the risk of lung fibrosis is strongly affected by inherent factors that vary among individuals.

Considerations in optimizing radiation therapy for non-small cell lung cancer

Irradiation therapy for lung cancer is mostly restricted to conventional methods. To improve therapeutic ratio, we have combined a treatment planning and a gene therapy approach. Three-dimensional conformal radiotherapy is described as carried out by methods of gene therapy for radiation protection using the manganese-superoxide-dismutase transgene delivered by inhalation gene transfer. These methods may improve therapeutic outcomes in lung cancer.

Combined modality therapy for early Hodgkin's disease: heterogeneity in Australasian clinical practice

Two case studies of locally extensive clinical stage IIA Hodgkin's disease (HD) were presented to radiation oncologists at a meeting of the Australasian Radiation Oncology Lymphoma Group, and subsequently to non-attending members who were asked to indicate their recommended treatment. This paper discusses the 25 responses which were notable by considerable heterogeneity in philosophy and detail. There is clearly no consensus among Australasian radiation oncologists at present, although combined modality therapy (CMT) with Adriamycin, bleomycin, vinblastine, and dacarbazine (ABVD) followed by low-medium-dose involved field radiotherapy (25-36 Gy) was the most popular response. The literature on radiation dose and chemotherapy in CMT for HD is then reviewed. It seems very likely that low doses in the range of 25-30 Gy (at 1.5-2.0 Gy per fraction) are sufficient. The ABVD should be considered as the 'standard' regimen at present, although the optimal sequencing with radiation and number of cycles remain unknown. The heterogeneity of responses to management of the case studies raises questions about ongoing education processes in radiation and medical oncology. Hypothetical case management review may complement currently proposed methods of assessing continuing medical education.

Quantification of radiation-induced regional lung injury with perfusion imaging

PURPOSE

To better understand the dose and time dependence of radiation therapy (RT)-induced regional lung dysfunction as assessed by changes in regional lung perfusion.

METHODS AND MATERIALS

Patients who were to receive RT for tumors in and around the thorax, wherein portions of healthy lung would be incidentally irradiated, were prospectively studied. Regional function was assessed pre- and post-RT with single photon emission computed tomography (SPECT) lung perfusion scans, obtained following the intravenous administration of approximately 4 mCi of technetium-99m macroaggregated albumin. Pre-RT computed tomography (CT) scans were used to calculate the three-dimensional (3D) dose distribution, reflecting tissue density inhomogeneity corrections. Each SPECT scan was correlated with the pre-RT CT scan, and the 3D dose distribution. Changes in regional lung perfusion were correlated with regional RT dose, at various time intervals following radiation.

RESULTS

The data from 20 patients (7 breast cancer, 5 lymphoma, 1 esophagus, 1 sarcoma, and 6 lung cancer) have been analyzed. Patients with gross intrathoracic lung cancers causing obstruction of regional pulmonary arteries were not included. For most patients, there is a statistically significant dose-dependent reduction in regional blood flow at all time points following radiation. While a time dependence is suggested in the high dose range, the limited amount of data prevents meaningful statistical evaluation.

CONCLUSIONS

Radiation therapy-induced regional lung dysfunction occurs in a dose-dependent manner and develops within 3-6 months following radiation. In contrast to classical "sigmoid" dose-response curves, described mainly for changes following whole lung irradiation, these data suggest a more gradual relationship between regional dysfunction and RT dose. Retraction of irradiated lung with secondary movement of unirradiated lung into the "3D-defined irradiated volume" may have introduced inaccuracies into this analysis. Additional studies are currently underway to assess this possibility and better refine this dose-response curve. Studies are underway to determine if changes in assessments of whole lung function, such as pulmonary function tests, can be predicted by summing the regional changes observed.

Impact of setup variability on incidental lung irradiation during tangential breast treatment

PURPOSE

This study aimed to determine the variability in treatment setup during a 5-week course of tangential breast treatment for patients immobilized in a customized hemibody cradle, to assess the relationship between the height of the lung shadow on the tangential port film and the percentage of lung volume irradiated, and to estimate the impact of setup variabilities on irradiated lung volume.

METHODS

One hundred seventy-two port films were reviewed from 20 patients who received tangential beam treatment for breast cancer. The height of the lung shadow at the central axis (CLD) on each port film was compared to the corresponding simulator film as an assessment of setup variability. A three-dimensional dose calculation was performed, and the percentage of total lung volume within the field was correlated with the CLD. The three-dimensional dose calculation was repeated for selected patients with the location of the treatment beams modified to reflect typical setup variations.

RESULTS

The CLD measured on the port films was within 3 mm of that prescribed on the simulator film in 43% (74 of 172) of the port films. The variation was 3-5 mm in 26%, 5-10 mm in 25%, and >10 mm in 6%. The height of the lung shadow correlated with the percentage of lung volume included in the radiation field (r2 = 0.6). Typical variations in treatment setup resulted in < or = 5% fluctuation in the absolute volume of ipsilateral lung irradiated.

CONCLUSION

The current immobilization system used in our clinic provides a clinically acceptable reproducibility of patient setup. The height of the lung shadow is reasonably well correlated with the percentage of irradiated lung volume. During a typical 5-week course of radiotherapy, the ipsilateral irradiated lung volume fluctuates <5%.

Hodgkin's disease. Treatment sequelae and quality of life

Hodgkin's disease is considered a curable disease. The use of appropriate staging techniques and treatment methods has resulted to long-term cause-specific survival rates as high as 90% in early stages, 75% or greater in advanced stages. Long-surviving Hodgkin's disease patients, however, face new problems which have become apparent as greater numbers of successfully treated patients are followed for longer periods of time. These problems mostly concern chronic medical as well as psychosocial complications which can interfere with survivors' quality of life. Specific therapy may result in severe infections, thyroid, cardiovascular, pulmonary, digestive or gonadal dysfunction. It may also result in secondary malignancy which is considered the most serious complication. Because the vast majority of patients who achieve remission will remain symptom-free and do enjoy a normal life, long-term follow-up should concentrate on prevention and early detection of treatment-related complications and of secondary malignancy.

Azathioprine as a steroid-sparing agent in radiation pneumonitis

Radiation therapy is commonly used for treatment of neoplastic disease involving the thorax. Treatment complications include radiation pneumonitis that may require therapy with corticosteroids which possess significant side effects. We report the use of azathioprine as a steroid-sparing agent in a patient with severe radiation pneumonitis and steroid-induced myopathy.

Late complications after Hodgkin's disease

Hodgkin's disease is considered a curable disease. The use of appropriate staging techniques and treatment methods has resulted in long-term survival rates as high as 90% in early stages, 75% or greater in advanced stages. Long-surviving Hodgkin's disease patients, however, face new problems which have become apparent as greater numbers of successfully treated patients are followed for longer periods of time. They concern mostly chronic medical as well as psychosocial complications which can interfere with survivors quality of life. Hodgkin's disease therapy may result in severe infections, thyroid, cardiovascular, pulmonary, digestive or gonadal dysfunction. It may also result in secondary malignancy which is considered the most serious complication. This review focuses on the variety of medical problems considering subsequent nonmalignant complications, secondary malignancies, long-term patient quality of life and causes of death. Because the vast majority of patients who achieve remission remain symptom-free and enjoy a normal life, an attempt is made to provide estimated risk for individuals based on available data.

Dose-effect relations for local functional and structural changes of the lung after irradiation for malignant lymphoma

PURPOSE

To estimate the dose-effect relations for local functional (ventilation and perfusion) and structural (density) changes of the lung, 3-4 months after irradiation.

METHODS

Twenty-five patients with malignant lymphoma were irradiated with a (modified) mantle field to an average dose of 38 Gy, given in 21 fractions. Single photon emission computed tomography (SPECT) ventilation (V) and perfusion (Q) scans, and CT scans were performed before and 3-4 months after radiation treatment. The three-dimensional dose distribution was calculated using the CT data. After correlation of SPECT and CT data sets, the average post-treatment value of V, Q and lung density per voxel was calculated relative to the pre-treatment value, per dose interval of 4 Gy. Subsequently, the dose-effect relations in each patient were normalized to the average value per voxel in the dose interval of 0-12 Gy. In addition, in each dose interval of 4 Gy the fraction of patients with changes larger than 20% was calculated for all three parameters. The dose-effect relations for perfusion and ventilation normalized to the low-dose regions, and the dose-incidence curves for the fraction of patients with changes larger than 20% were fitted for all three parameters, using a logistic model.

RESULTS

Marked changes in the distribution of V and Q were found after irradiation. Prior to normalization to the low-dose regions, a change in V and Q was found in most patients in the dose interval of 0-12 Gy, varying from an increase of 37% to a decrease of 10%, which was followed by a decreasing trend at higher doses. The increase in the low-dose regions indicated a redistribution phenomenon, the magnitude of which was dependent of the irradiated volume. The logistic fit of the dose-effect relations for Q and V, normalized to the low-dose regions, resulted in values for D50 of 51 Gy and 54 Gy (given in 21 fractions on average), respectively, and for the steepness parameter k of 4.2 and 4.0, respectively. The logistic fit for the dose-incidence curves for Q, V and lung density resulted in values for D50 and k of 38 Gy, 37 Gy, 44 Gy and 10.3, 7.8 and 9.4, respectively.

CONCLUSIONS

With the combined use of SPECT and CT scans, we have obtained dose-effect relations for local functional and structural damage in the lung, 3-4 months after irradiation.

A procedure for estimating the dose modifying effect of chemotherapy on radiation response

A procedure based on a logistic regression model was used to estimate the dose-modifying effect of chemotherapy on the response of normal tissues to radiation. The magnitude of this modifying effect is usually expressed as a dose-effect factor (DEF). Values > 1.0 indicate an enhancing effect of chemotherapy while values < 1.0 suggest a 'protective' effect. The DEF in the proposed procedure is expressed as a function of logistic regression coefficients, response levels and values of covariates in the model. The proposed procedure is advantageous as it allows consideration of both the response levels and the values of covariates in calculating the DEF. A plot of the DEF against the response or a covariate describes how the DEF varies with the response levels or a covariate describes how the DEF varies with the response levels or the covariate values. Confidence intervals of the DEF were obtained based on the normal approximation of the distribution of the estimated DEF and on a non-parametric Bootstrap method. An example is given to illustrate the proposed procedure.