Low-dose megavoltage cone-beam CT imaging using thick, segmented scintillators

Megavoltage, cone-beam computed tomography (MV CBCT) employing an electronic portal imaging device (EPID) is a highly promising technique for providing soft-tissue visualization in image-guided radiotherapy. However, current EPIDs based on active matrix flat-panel imagers (AMFPIs), which are regarded as the gold standard for portal imaging and referred to as conventional MV AMFPIs, require high radiation doses to achieve this goal due to poor x-ray detection efficiency (∼2% at 6 MV). To overcome this limitation, the incorporation of thick, segmented, crystalline scintillators, as a replacement for the phosphor screens used in these AMFPIs, has been shown to significantly improve the detective quantum efficiency (DQE) performance, leading to improved image quality for projection imaging at low dose. Toward the realization of practical AMFPIs capable of low dose, soft-tissue visualization using MV CBCT imaging, two prototype AMFPIs incorporating segmented scintillators with ∼11 mm thick CsI:Tl and Bi4Ge3O12 (BGO) crystals were evaluated. Each scintillator consists of 120 × 60 crystalline elements separated by reflective septal walls, with an element-to-element pitch of 1.016 mm. The prototypes were evaluated using a bench-top CBCT system, allowing the acquisition of 180 projection, 360° tomographic scans with a 6 MV radiotherapy photon beam. Reconstructed images of a spatial resolution phantom, as well as of a water-equivalent phantom, embedded with tissue equivalent objects having electron densities (relative to water) varying from ∼0.28 to ∼1.70, were obtained down to one beam pulse per projection image, corresponding to a scan dose of ∼4 cGy–-a dose similar to that required for a single portal image obtained from a conventional MV AMFPI. By virtue of their significantly improved DQE, the prototypes provided low contrast visualization, allowing clear delineation of an object with an electron density difference of ∼2.76%. Results of contrast, noise and contrast-to-noise ratio are presented as a function of dose and compared to those from a conventional MV AMFPI.

[1]  L. Antonuk,et al.  Monte Carlo investigations of the effect of beam divergence on thick, segmented crystalline scintillators for radiotherapy imaging , 2010, Physics in medicine and biology.

[2]  Qihua Zhao,et al.  High-DQE EPIDs based on thick, segmented BGO and CsI:Tl scintillators: performance evaluation at extremely low dose. , 2009, Medical physics.

[3]  A Monte Carlo investigation of Swank noise for thick, segmented, crystalline scintillators for radiotherapy imaging. , 2009, Medical physics.

[4]  Qihua Zhao,et al.  An investigation of signal performance enhancements achieved through innovative pixel design across several generations of indirect detection, active matrix, flat-panel arrays. , 2009, Medical physics.

[5]  Qihua Zhao,et al.  Monte Carlo investigations of megavoltage cone-beam CT using thick, segmented scintillating detectors for soft tissue visualization. , 2007, Medical physics.

[6]  T. Marchant,et al.  Imaging doses from the Elekta Synergy X-ray cone beam CT system. , 2007, The British journal of radiology.

[7]  D. Jaffray,et al.  Advances in image-guided radiation therapy. , 2007, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[8]  B. Fallone,et al.  Thick, segmented CdWO4-photodiode detector for cone beam megavoltage CT: a Monte Carlo study of system design parameters. , 2006, Medical physics.

[9]  S. Samant,et al.  Study of a prototype high quantum efficiency thick scintillation crystal video-electronic portal imaging device. , 2006, Medical physics.

[10]  David A Jaffray,et al.  Patient dose from kilovoltage cone beam computed tomography imaging in radiation therapy. , 2006, Medical physics.

[11]  Qihua Zhao,et al.  Segmented crystalline scintillators: empirical and theoretical investigation of a high quantum efficiency EPID based on an initial engineering prototype CsI(TI) detector. , 2006, Medical physics.

[12]  B. Fallone,et al.  A bench-top megavoltage fan-beam CT using CdWO4-photodiode detectors. II. Image performance evaluation. , 2006, Medical physics.

[13]  B. Fallone,et al.  A bench-top megavoltage fan-beam CT using CdWO4-photodiode detectors. I. System description and detector characterization. , 2006, Medical physics.

[14]  D. Heron,et al.  Target delineation and localization (IGRT)--part 1. , 2006, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[15]  J. Pouliot,et al.  Megavoltage cone-beam CT: system description and clinical applications. , 2006, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[16]  P. Munro,et al.  Low-dose megavoltage cone-beam computed tomography for lung tumors using a high-efficiency image receptor. , 2006, Medical physics.

[17]  J. Pouliot,et al.  Dose Calculation Using Megavoltage Cone Beam CT Imaging , 2005 .

[18]  Fang-Fang Yin,et al.  A technique for on-board CT reconstruction using both kilovoltage and megavoltage beam projections for 3D treatment verification. , 2005, Medical physics.

[19]  G H Olivera,et al.  The use of megavoltage CT (MVCT) images for dose recomputations , 2005, Physics in medicine and biology.

[20]  Patrick A Kupelian,et al.  Performance characterization of megavoltage computed tomography imaging on a helical tomotherapy unit. , 2005, Medical physics.

[21]  Jean Pouliot,et al.  Soft tissue visualization using a highly efficient megavoltage cone beam CT imaging system , 2005, SPIE Medical Imaging.

[22]  Qihua Zhao,et al.  Segmented phosphors: MEMS-based high quantum efficiency detectors for megavoltage x-ray imaging. , 2005, Medical physics.

[23]  Ping Xia,et al.  Low-dose megavoltage cone-beam CT for radiation therapy. , 2005, International journal of radiation oncology, biology, physics.

[24]  J. Rowlands,et al.  Development of high quantum efficiency, flat panel, thick detectors for megavoltage x-ray imaging: a novel direct-conversion design and its feasibility. , 2004, Medical physics.

[25]  Radhe Mohan,et al.  Quantification of volumetric and geometric changes occurring during fractionated radiotherapy for head-and-neck cancer using an integrated CT/linear accelerator system. , 2004, International journal of radiation oncology, biology, physics.

[26]  B. Fallone,et al.  Modeling scintillator-photodiodes as detectors for megavoltage CT. , 2004, Medical physics.

[27]  Radhe Mohan,et al.  Evaluation of mechanical precision and alignment uncertainties for an integrated CT/LINAC system. , 2003, Medical physics.

[28]  Carlo Tognina,et al.  Megavoltage cone-beam computed tomography using a high-efficiency image receptor. , 2003, International journal of radiation oncology, biology, physics.

[29]  C C Ling,et al.  Cone-beam CT with megavoltage beams and an amorphous silicon electronic portal imaging device: potential for verification of radiotherapy of lung cancer. , 2002, Medical physics.

[30]  Fang-Fang Yin,et al.  Accuracy of inhomogeneity correction in photon radiotherapy from CT scans with different settings. , 2002, Physics in medicine and biology.

[31]  J. Wong,et al.  Flat-panel cone-beam computed tomography for image-guided radiation therapy. , 2002, International journal of radiation oncology, biology, physics.

[32]  J H Siewerdsen,et al.  A performance comparison of flat-panel imager-based MV and kV cone-beam CT. , 2002, Medical physics.

[33]  R Jeraj,et al.  Monte Carlo study of a highly efficient gas ionization detector for megavoltage imaging and image-guided radiotherapy. , 2002, Medical physics.

[34]  L. Antonuk,et al.  Determination of the detective quantum efficiency of a prototype, megavoltage indirect detection, active matrix flat-panel imager. , 2001, Medical physics.

[35]  R. Lu,et al.  Low-dose radiation damage and recovery of undoped BGO crystals , 2000 .

[36]  J H Siewerdsen,et al.  Cone-beam computed tomography with a flat-panel imager: initial performance characterization. , 2000, Medical physics.

[37]  Larry E. Antonuk,et al.  An asynchronous, pipelined, electronic acquisition system for Active Matrix Flat-Panel Imagers (AMFPIs) , 1999 .

[38]  S. Webb,et al.  Rapid portal imaging with a high-efficiency, large field-of-view detector. , 1998, Medical physics.

[39]  P. Evans,et al.  Optimization of the scintillation detector in a combined 3D megavoltage CT scanner and portal imager. , 1998, Medical physics.

[40]  Giselher G. Lichti,et al.  Influence of radiation damage on BGO scintillation properties 1 1 Supported by the Deutsches Zentrum für Luft- und Raumfahrt e. V (DLR) under Contract 50.OG.9503.0 and partly by the Deutsche Forschungsgemeinschaft (DFG) under Contract Ri 242/12-1. , 1998 .

[41]  S. Sahu,et al.  Radiation hardness of undoped BGO crystals , 1997 .

[42]  H. Newman,et al.  Scintillating crystals in a radiation environment , 1995 .

[43]  D. G. Lewis,et al.  A megavoltage CT scanner for radiotherapy verification. , 1992, Physics in medicine and biology.

[44]  C. Woody Radiation damage in cesium iodide and other scintillating crystals , 1992 .

[45]  H. Stone,et al.  A study on radiation damage in doped BGO crystals , 1991 .

[46]  H. B. Newman,et al.  Radiation resistance and fluorescence of europium doped BGO crystals , 1990 .