Acquiring a four-dimensional computed tomography dataset using an external respiratory signal.

Four-dimensional (4D) methods strive to achieve highly conformal radiotherapy, particularly for lung and breast tumours, in the presence of respiratory-induced motion of tumours and normal tissues. Four-dimensional radiotherapy accounts for respiratory motion during imaging, planning and radiation delivery, and requires a 4D CT image in which the internal anatomy motion as a function of the respiratory cycle can be quantified. The aims of our research were (a) to develop a method to acquire 4D CT images from a spiral CT scan using an external respiratory signal and (b) to examine the potential utility of 4D CT imaging. A commercially available respiratory motion monitoring system provided an 'external' tracking signal of the patient's breathing. Simultaneous recording of a TTL 'X-Ray ON' signal from the CT scanner indicated the start time of CT image acquisition, thus facilitating time stamping of all subsequent images. An over-sampled spiral CT scan was acquired using a pitch of 0.5 and scanner rotation time of 1.5 s. Each image from such a scan was sorted into an image bin that corresponded with the phase of the respiratory cycle in which the image was acquired. The complete set of such image bins accumulated over a respiratory cycle constitutes a 4D CT dataset. Four-dimensional CT datasets of a mechanical oscillator phantom and a patient undergoing lung radiotherapy were acquired. Motion artefacts were significantly reduced in the images in the 4D CT dataset compared to the three-dimensional (3D) images, for which respiratory motion was not accounted. Accounting for respiratory motion using 4D CT imaging is feasible and yields images with less distortion than 3D images. 4D images also contain respiratory motion information not available in a 3D CT image.

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

[2]  I. Suramo,et al.  Cranio-Caudal Movements of the Liver, Pancreas and Kidneys in Respiration , 1984, Acta radiologica: diagnosis.

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

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

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

[6]  R. Rabbitt,et al.  3D brain mapping using a deformable neuroanatomy. , 1994, Physics in medicine and biology.

[7]  Yongmin Kim,et al.  Correction of computed tomography motion artifacts using pixel-specific back-projection , 1996, IEEE Trans. Medical Imaging.

[8]  Cameron J. Ritchie,et al.  Respiratory compensation in projection imaging using a magnification and displacement model , 1996, IEEE Trans. Medical Imaging.

[9]  Michael I. Miller,et al.  Volumetric transformation of brain anatomy , 1997, IEEE Transactions on Medical Imaging.

[10]  B W Corn,et al.  Respiration-induced motion of the kidneys in whole abdominal radiotherapy: implications for treatment planning and late toxicity. , 1997, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[11]  G D Rubin,et al.  Thoracic spiral CT: influence of subsecond gantry rotation on image quality. , 1998, Radiology.

[12]  W A Kalender,et al.  Electrocardiogram-correlated image reconstruction from subsecond spiral computed tomography scans of the heart. , 1998, Medical physics.

[13]  J M Balter,et al.  A comparison of ventilatory prostate movement in four treatment positions. , 2000, International journal of radiation oncology, biology, physics.

[14]  Werner Moshage,et al.  Noninvasive coronary angiography by retrospectively ECG-gated multislice spiral CT. , 2000 .

[15]  James M. Balter,et al.  Ventilatory movement of the prostate during radiotherapy , 2000 .

[16]  Marc Kachelriess,et al.  ECG-correlated imaging of the heart with subsecond multislice spiral CT , 2000, IEEE Transactions on Medical Imaging.

[17]  J. Adler,et al.  Robotic motion compensation for respiratory movement during radiosurgery. , 2000, Computer aided surgery : official journal of the International Society for Computer Aided Surgery.

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

[19]  Gikas S. Mageras,et al.  Fluoroscopic evaluation of diaphragmatic motion reduction with a respiratory gated radiotherapy system , 2001, Journal of applied clinical medical physics.

[20]  D Baltas,et al.  Correcting organ motion artifacts in x-ray CT systems based on tracking of motion phase by the spatial overlap correlator. II. Experimental study. , 2001, Medical physics.

[21]  K. Langen,et al.  Organ motion and its management. , 2001, International journal of radiation oncology, biology, physics.

[22]  A C Dhanantwari,et al.  Correcting organ motion artifacts in x-ray CT medical imaging systems by adaptive processing. I. Theory. , 2001, Medical physics.

[23]  Weiguo Lu,et al.  Tomographic motion detection and correction directly in sinogram space. , 2002, Physics in medicine and biology.

[24]  Mark Ruschin,et al.  Integration of digital fluoroscopy with CT-based radiation therapy planning of lung tumors. , 2002, Medical physics.

[25]  Sasa Mutic,et al.  Performance evaluation of an 85-cm-bore X-ray computed tomography scanner designed for radiation oncology and comparison with current diagnostic CT scanners. , 2002, International journal of radiation oncology, biology, physics.

[26]  Martin J Murphy,et al.  Issues in respiratory motion compensation during external-beam radiotherapy. , 2002, International journal of radiation oncology, biology, physics.