Impact of chest wall motion caused by respiration in adjuvant radiotherapy for postoperative breast cancer patients

New England Journal of Medicine, 347(16), 1233-1241

Estimation of chest wall motion by surface measurements only allows one-dimensional measurements of the chest wall. We have assessed on optical reflectance system (OR), which tracks reflective markers in three dimensions (3-D) for respiratory use. We used 86 (6-mm-diameter) hemispherical reflective markers arranged circumferentially on the chest wall in seven rows between the sternal notch and the anterior superior iliac crest in two normal standing subjects. We calculated the volume of the entire chest wall and compared inspired and expired volumes with volumes obtained by spirometry. Marker positions were recorded by four TV cameras; two were 4 m in front of and two were 4 m behind the subject. The TV signals were sampled at 100 Hz and combined with grid calibration parameters on a personal computer to obtain the 3-D coordinates of the markers. Chest wall surfaces were reconstructed by triangulation through the point data, and chest wall volume was calculated. During tidal breathing and vital capacity maneuvers and during CO2-stimulated hyperpnea, there was a very close correlation of the lung volumes (VL) estimated by spirometry [VL(SP)] and OR [VL(OR)]. Regression equations of VL(OR) (y) vs. VL(SP) (x, BTPS in liters) for the two subjects were given by y = 1.01x-0.01 (r = 0.996) and y = 0.96x + 0.03 (r = 0.997), and by y = 1.04x + 0.25 (r = 0.97) and y = 0.98x + 0.14 (r = 0.95) for the two maneuvers, respectively. We conclude spirometric volumes can be estimated very accurately and directly from chest wall surface markers, and we speculate that OR may be usefully applied to calculations of chest wall shape, regional volumes, and motion analysis.

Adjuvant radiotherapy after breast-conserving surgery for breast cancer implies a risk of late cardiac and pulmonary toxicity. This is the first study to evaluate cardiopulmonary dose sparing of breathing adapted radiotherapy (BART) using free breathing gating, and to compare this respiratory technique with voluntary breath-hold. 17 patients were CT-scanned during non-coached breathing manoeuvre including free breathing (FB), end-inspiration gating (IG), end-expiration gating (EG), deep inspiration breath-hold (DIBH) and end-expiration breath-hold (EBH). The Varian Real-time Position Management system (RPM) was used to monitor respiratory movement and to gate the scanner. For each breathing phase, a population based internal margin (IM) was estimated based on average chest wall excursion, and incorporated into an individually optimised three-field mono-isocentric wide tangential photon field treatment plan for each scan. The target included the remaining breast, internal mammary nodes and periclavicular nodes. The mean anteroposterior chest wall excursion during FB was 2.5mm. For IG and EG, the mean excursions within gating windows were 1.1 and 0.7 mm, respectively, whereas for DIBH and EBH the excursions were 4.1 and 2.6mm, respectively. For patients with left-sided cancer, the median heart volume receiving more than 50% of the prescription dose was reduced from 19.2% for FB to 2.8% for IG and 1.9% for DIBH, and the median left anterior descending (LAD) coronary artery volume was reduced from 88.9% to 22.4% for IG and 3.6% for DIBH. Simultaneously, the median ipsilateral relative lung volume irradiated to >50% of the prescribed target dose for both right- and left-sided cancers was reduced from 45.6% for FB to 29.5% for IG and 27.7% for DIBH. For EBH and EG, both the irradiated heart, LAD and lung volumes increased compared to FB. This is the first study to demonstrate the dosimetric benefits of free breathing gated breast cancer radiotherapy. IG compared favourably with DIBH, substantially reducing cardiac doses simultaneous with significant pulmonary tissue sparing.