Toward in vivo lung's tissue incompressibility characterization for tumor motion modeling in radiation therapy.

PURPOSE A novel technique is proposed to characterize lung tissue incompressibility variation during respiration. Estimating lung tissue incompressibility parameter variations resulting from air content variation throughout respiration is critical for computer assisted tumor motion tracking. Continuous tumor motion is a major challenge in lung cancer radiotherapy, especially with external beam radiotherapy. If not accounted for, this motion may lead to areas of radiation overdosage for normal tissue. Given the unavailability of imaging modality that can be used effectively for real-time lung tumor tracking, computer assisted approach based on tissue deformation estimation can be a good alternative. This approach involves lung biomechanical model where its fidelity depends on input tissue properties. This investigation shows that considering variable tissue incompressibility parameter is very important for predicting tumor motion accurately, hence improving the lung radiotherapy outcome. METHODS First, an in silico lung phantom study was conducted to demonstrate the importance of employing variable Poisson's ratio for tumor motion predication. After it was established that modeling this variability is critical for accurate tumor motion prediction, an optimization based technique was developed to estimate lung tissue Poisson's ratio as a function of respiration cycle time. In this technique, the Poisson's ratio and lung pressure value were varied systematically until optimal values were obtained, leading to maximum similarity between acquired and simulated 4D CT lung images. This technique was applied in an ex vivo porcine lung study where simulated images were constructed using the end exhale CT image and deformation fields obtained from the lung's FE modeling of each respiration time increment. To model the tissue, linear elastic and Marlow hyperelastic material models in conjunction with variable Poisson's ratio were used. RESULTS The phantom study showed that the tumor motion trajectory and its final locations obtained from simulations with and without considering tissue incompressibility variation were very different. For example, tumor displacements in the z direction were -11.23 and -38.10 mm obtained with the Marlow hyperelastic material model in conjunction with constant and variable Poisson's ratio, respectively. By comparing the acquired 4D-CT image sequence of the porcine lung with their image sequence counterparts obtained from the hyperelastic model with constant and variable Poisson's ratio, it was shown that using variable tissue incompressibility reduced errors significantly in tumor motion prediction. CONCLUSIONS This investigation demonstrates the importance of incompressibility variation estimation and utilization for accurate tumor tracking in computer assisted lung external beam radiation therapy. An optimization framework was developed to estimate a Poisson's ratio function in terms of respiration cycle time using experimental image data of the lung. Utilizing this function along with respiratory system FE modeling may lead to more effective tumor targeting, hence potentially improving the outcome of lung external beam radiation therapy techniques. This is particularly true for stereotactic body radiation therapy where only one or a few fraction treatments are applied, precluding the possibility of averaging out dosimetric deviations introduced by the respiratory motion.

[1]  B. Sapoval,et al.  A 3 D DISCRETE MODEL OF THE DIAPHRAGM AND HUMAN TRUNK ∗ , 2008 .

[2]  J Moseley,et al.  Contact surface and material nonlinearity modeling of human lungs , 2008, Physics in medicine and biology.

[3]  Rajni V. Patel,et al.  CT image construction of a totally deflated lung using deformable model extrapolation. , 2011, Medical physics.

[4]  Jeffrey C. Lagarias,et al.  Convergence Properties of the Nelder-Mead Simplex Method in Low Dimensions , 1998, SIAM J. Optim..

[5]  Heinz Handels,et al.  Patient-specific finite element modeling of respiratory lung motion using 4D CT image data. , 2009, Medical physics.

[6]  Bhudatt R Paliwal,et al.  Technical note: A novel boundary condition using contact elements for finite element based deformable image registration. , 2004, Medical physics.

[7]  Pierre Baconnier,et al.  A 3D discrete model of the diaphragm and human trunk , 2006, 0808.0339.

[8]  M. V. van Herk,et al.  Physical aspects of a real-time tumor-tracking system for gated radiotherapy. , 2000, International journal of radiation oncology, biology, physics.

[9]  Suvranu De,et al.  Modeling Respiratory Motion for Cancer Radiation Therapy Based on Patient-Specific 4DCT Data , 2009, MICCAI.

[10]  Rajnikant V. Patel,et al.  Measurement of Lung Hyperelastic Properties Using Inverse Finite Element Approach , 2011, IEEE Transactions on Biomedical Engineering.

[11]  Steve B. Jiang,et al.  The management of respiratory motion in radiation oncology report of AAPM Task Group 76. , 2006, Medical physics.

[12]  Steve B. Jiang,et al.  The management of respiratory motion in radiation oncology report of AAPM Task Group 76. , 2006, Medical physics.

[13]  D. Parkin,et al.  Global cancer statistics in the year 2000. , 2001, The Lancet. Oncology.

[14]  Manish Kakar,et al.  Respiratory motion prediction by using the adaptive neuro fuzzy inference system (ANFIS). , 2005, Physics in medicine and biology.

[15]  Max A. Viergever,et al.  A survey of medical image registration , 1998, Medical Image Anal..

[16]  Dimitris N. Metaxas,et al.  Integrating Anatomy and Physiology for Behavior Modeling , 1995 .

[17]  K. Camphausen,et al.  Advances in 4D Medical Imaging and 4D Radiation Therapy , 2008, Technology in cancer research & treatment.

[18]  Adil Al-Mayah,et al.  Effect of Friction and Material Compressibility on Deformable Modeling of Human Lung , 2008, ISBMS.

[19]  Rajnikant V. Patel,et al.  Estimation of Lung's Air Volume and Its Variations Throughout Respiratory CT Image Sequences , 2011, IEEE Transactions on Biomedical Engineering.

[20]  R. Mohan,et al.  Motion adaptive x-ray therapy: a feasibility study , 2001, Physics in medicine and biology.

[21]  D. Hill,et al.  Non-rigid image registration: theory and practice. , 2004, The British journal of radiology.

[22]  Horst Bischof,et al.  Assessing breathing motion by shape matching of lung and diaphragm surfaces , 2005, SPIE Medical Imaging.

[23]  Abbas Samani,et al.  Lung tumor motion prediction during lung brachytherapy using finite element model , 2012, Medical Imaging.

[24]  B. Shariat,et al.  Simulation of lung behaviour with finite elements: influence of bio-mechanical parameters , 2005, Third International Conference on Medical Information Visualisation--BioMedical Visualisation.

[25]  M. Kessler Image registration and data fusion in radiation therapy. , 2006, The British journal of radiology.

[26]  A. Jemal,et al.  Global Cancer Statistics , 2011 .

[27]  J Moseley,et al.  Sliding characteristic and material compressibility of human lung: parametric study and verification. , 2009, Medical physics.

[28]  V.R.S Mani,et al.  Survey of Medical Image Registration , 2013 .

[29]  H Shirato,et al.  Detection of lung tumor movement in real-time tumor-tracking radiotherapy. , 2001, International journal of radiation oncology, biology, physics.

[30]  Adil Al-Mayah,et al.  Deformable image registration of heterogeneous human lung incorporating the bronchial tree. , 2010, Medical physics.

[31]  K. Mardia,et al.  A review of image-warping methods , 1998 .

[32]  Kaamran Raahemifar,et al.  Statistical finite element method for real-time tissue mechanics analysis , 2012, Computer methods in biomechanics and biomedical engineering.

[33]  A. Naini Modeling Lung Tissue Motions and Deformations: Applications in Tumor Ablative Procedures , 2011 .

[34]  Ghassan Hamarneh,et al.  MATLAB-ITK interface for medical image filtering, segmentation, and registration , 2006, SPIE Medical Imaging.

[35]  Mack Roach,et al.  Advances in Radiation Therapy: Conventional to 3D, to IMRT, to 4D, and Beyond , 2005, CA: a cancer journal for clinicians.

[36]  Karol Miller,et al.  Real-Time Nonlinear Finite Element Computations on GPU - Application to Neurosurgical Simulation. , 2010, Computer methods in applied mechanics and engineering.