TY - JOUR
T1 - Robotic motion compensation for respiratory movement during radiosurgery
AU - Schweikard, A.
AU - Glosser, G.
AU - Bodduluri, M.
AU - Murphy, M. J.
AU - Adler, J. R.
PY - 2000/1/1
Y1 - 2000/1/1
N2 - Tumors in the chest and abdomen move during respiration. The ability of conventional radiation therapy systems to compensate for respiratory motion by moving the radiation source is inherently limited. Since safety margins currently used in radiation therapy increase the radiation dose by a very large amount, an accurate tracking method for following the motion of the tumor is of the utmost clinical relevance. We investigate methods to compensate for respiratory motion using robotic radiosurgery. Thus, the therapeutic beam is moved by a robotic arm, and follows the moving target tumor. To determine the precise position of the moving target, we combine infrared tracking with synchronized X-ray imaging. Infrared emitters are used to record the motion of the patient's skin surface. A stereo X-ray imaging system provides information about the location of internal markers. During an initialization phase (prior to treatment), the correlation between the motions observed by the two sensors (X-ray imaging and infrared tracking) is computed. This model is also continuously updated during treatment to compensate for other, non-respiratory motion. Experiments and clinical trials suggest that robot-based methods can substantially reduce the safety margins currently needed in radiation therapy. (C) 2000 Wiley-Liss, Inc.
AB - Tumors in the chest and abdomen move during respiration. The ability of conventional radiation therapy systems to compensate for respiratory motion by moving the radiation source is inherently limited. Since safety margins currently used in radiation therapy increase the radiation dose by a very large amount, an accurate tracking method for following the motion of the tumor is of the utmost clinical relevance. We investigate methods to compensate for respiratory motion using robotic radiosurgery. Thus, the therapeutic beam is moved by a robotic arm, and follows the moving target tumor. To determine the precise position of the moving target, we combine infrared tracking with synchronized X-ray imaging. Infrared emitters are used to record the motion of the patient's skin surface. A stereo X-ray imaging system provides information about the location of internal markers. During an initialization phase (prior to treatment), the correlation between the motions observed by the two sensors (X-ray imaging and infrared tracking) is computed. This model is also continuously updated during treatment to compensate for other, non-respiratory motion. Experiments and clinical trials suggest that robot-based methods can substantially reduce the safety margins currently needed in radiation therapy. (C) 2000 Wiley-Liss, Inc.
UR - http://www.scopus.com/inward/record.url?scp=0033743945&partnerID=8YFLogxK
U2 - 10.3109/10929080009148894
DO - 10.3109/10929080009148894
M3 - Journal articles
C2 - 11029159
AN - SCOPUS:0033743945
SN - 1092-9088
VL - 5
SP - 263
EP - 277
JO - Computer Aided Surgery
JF - Computer Aided Surgery
IS - 4
ER -