Tracking lung tissue motion and expansion/compression with inverse consistent image registration and spirometry.

Breathing motion is one of the major limiting factors for reducing dose and irradiation of normal tissue for conventional conformal radiotherapy. This paper describes a relationship between tracking lung motion using spirometry data and image registration of consecutive CT image volumes collected from a multislice CT scanner over multiple breathing periods. Temporal CT sequences from 5 individuals were analyzed in this study. The couch was moved from 11 to 14 different positions to image the entire lung. At each couch position, 15 image volumes were collected over approximately 3 breathing periods. It is assumed that the expansion and contraction of lung tissue can be modeled as an elastic material. Furthermore, it is assumed that the deformation of the lung is small over one-fifth of a breathing period and therefore the motion of the lung can be adequately modeled using a small deformation linear elastic model. The small deformation inverse consistent linear elastic image registration algorithm is therefore well suited for this problem and was used to register consecutive image scans. The pointwise expansion and compression of lung tissue was measured by computing the Jacobian of the transformations used to register the images. The logarithm of the Jacobian was computed so that expansion and compression of the lung were scaled equally. The log-Jacobian was computed at each voxel in the volume to produce a map of the local expansion and compression of the lung during the breathing period. These log-Jacobian images demonstrate that the lung does not expand uniformly during the breathing period, but rather expands and contracts locally at different rates during inhalation and exhalation. The log-Jacobian numbers were averaged over a cross section of the lung to produce an estimate of the average expansion or compression from one time point to the next and compared to the air flow rate measured by spirometry. In four out of five individuals, the average log-Jacobian value and the air flow rate correlated well (R2 = 0.858 on average for the entire lung). The correlation for the fifth individual was not as good (R2 = 0.377 on average for the entire lung) and can be explained by the small variation in tidal volume for this individual. The correlation of the average log-Jacobian value and the air flow rate for images near the diaphragm correlated well in all five individuals (R2 = 0.943 on average). These preliminary results indicate a strong correlation between the expansion/compression of the lung measured by image registration and the air flow rate measured by spirometry. Predicting the location, motion, and compression/expansion of the tumor and normal tissue using image registration and spirometry could have many important benefits for radiotherapy treatment. These benefits include reducing radiation dose to normal tissue, maximizing dose to the tumor, improving patient care, reducing treatment cost, and increasing patient throughput.

[1]  Gary E. Christensen,et al.  Consistent landmark and intensity-based image registration , 2002, IEEE Transactions on Medical Imaging.

[2]  C. Ramsey,et al.  A comparison of beam characteristics for gated and nongated clinical x-ray beams. , 1999, Medical physics.

[3]  S. K. Hilal,et al.  The tuning fork artifact in computerized tomography , 1979 .

[4]  Gary E. Christensen,et al.  Consistent image registration , 2001, IEEE Transactions on Medical Imaging.

[5]  P. Keall 4-dimensional computed tomography imaging and treatment planning. , 2004, Seminars in radiation oncology.

[6]  C. Ramsey,et al.  Clinical efficacy of respiratory gated conformal radiation therapy. , 1999, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[7]  George Starkschall,et al.  Quality assurance evaluation of delivery of respiratory‐gated treatments , 2004, Journal of applied clinical medical physics.

[8]  H Shirato,et al.  Impact of respiratory movement on the computed tomographic images of small lung tumors in three-dimensional (3D) radiotherapy. , 2000, International journal of radiation oncology, biology, physics.

[9]  K. Ohara,et al.  Irradiation synchronized with respiration gate. , 1989, International journal of radiation oncology, biology, physics.

[10]  Radhe Mohan,et al.  Patient training in respiratory-gated radiotherapy. , 2003, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[11]  Radhe Mohan,et al.  Four-dimensional radiotherapy planning for DMLC-based respiratory motion tracking. , 2005, Medical physics.

[12]  G. Christensen,et al.  A method for the reconstruction of four-dimensional synchronized CT scans acquired during free breathing. , 2003, Medical physics.

[13]  T. Solberg,et al.  Dosimetric characteristics of a new linear accelerator under gated operation , 2006, Journal of applied clinical medical physics.

[14]  E. Yorke,et al.  Deep inspiration breath hold and respiratory gating strategies for reducing organ motion in radiation treatment. , 2004, Seminars in radiation oncology.

[15]  D J Conces,et al.  Motion artifacts on CT simulate bronchiectasis. , 1988, AJR. American journal of roentgenology.

[16]  K Cleary,et al.  Feasibility of four-dimensional conformal planning for robotic radiosurgery. , 2005, Medical physics.

[17]  Lili Wang,et al.  Introduction of audio gating to further reduce organ motion in breathing synchronized radiotherapy. , 2002, Medical physics.

[18]  Jun Duan,et al.  Dosimetric effect of respiration-gated beam on IMRT delivery. , 2003, Medical physics.

[19]  George Starkschall,et al.  Dosimetric benefits of respiratory gating: a preliminary study , 2004, Journal of applied clinical medical physics.

[20]  H. Kubo,et al.  Respiration gated radiotherapy treatment: a technical study. , 1996, Physics in medicine and biology.

[21]  S. Denissova,et al.  A gated deep inspiration breath‐hold radiation therapy technique using a linear position transducer , 2005, Journal of applied clinical medical physics.

[22]  C. J. Ritchie,et al.  Predictive respiratory gating: a new method to reduce motion artifacts on CT scans. , 1994, Radiology.

[23]  C. Ling,et al.  Evaluation of respiratory movement during gated radiotherapy using film and electronic portal imaging. , 2002, International journal of radiation oncology, biology, physics.

[24]  Gary E. Christensen,et al.  Invertibility and transitivity analysis for nonrigid image registration , 2003, J. Electronic Imaging.

[25]  Geoffrey McLennan,et al.  Establishing a normative atlas of the human lung: intersubject warping and registration of volumetric CT images. , 2003, Academic radiology.

[26]  K. Brock,et al.  Feasibility of a novel deformable image registration technique to facilitate classification, targeting, and monitoring of tumor and normal tissue. , 2006, International journal of radiation oncology, biology, physics.

[27]  H. Mostafavi,et al.  Breathing-synchronized radiotherapy program at the University of California Davis Cancer Center. , 2000, Medical physics.

[28]  Uwe Oelfke,et al.  Compensation for respiratory motion by gated radiotherapy: an experimental study , 2005, Physics in medicine and biology.

[29]  X Allen Li,et al.  Technical and dosimetric aspects of respiratory gating using a pressure-sensor motion monitoring system. , 2005, Medical physics.

[30]  K. Brock,et al.  Accuracy of finite element model-based multi-organ deformable image registration. , 2005, Medical physics.

[31]  Sasa Mutic,et al.  Quantitation of the reconstruction quality of a four-dimensional computed tomography process for lung cancer patients. , 2005, Medical physics.

[32]  R M Henkelman,et al.  The double-fissure sign: a motion artifact on thin-section CT scans. , 1987, Radiology.

[33]  Gary E. Christensen,et al.  Consistent Linear-Elastic Transformations for Image Matching , 1999, IPMI.