Evaluation of the radiation dose in micro-CT with optimization of the scan protocol.

INTRODUCTION Micro-CT provides non-invasive anatomic evaluation of small animals. Serial micro-CT measurements are, however, hampered by the severity of ionizing radiation doses cumulating over the total period of follow-up. The dose levels may be sufficient to influence experimental outcomes such as animal survival or tumor growth. AIM This study was designed to evaluate the radiation dose of micro-CT and to optimize the scanning protocol for longitudinal micro-CT scans. METHODS AND MATERIALS Normal C57Bl/6 mice were euthanized. Radiation exposure was measured using individually calibrated lithium fluoride thermoluminescent dosimeters (TLDs). Thirteen TLDs were placed in the mice at the thyroid, lungs, liver, stomach, colon, bladder and near the spleen. Micro-CT (SkyScan 1178) was performed using two digital X-ray cameras which scanned over 180 degrees at a resolution of 83 microm, a rotation step of 1.08 degrees , 50 kV, 615 microA and 121 s image acquisition time. The TLDs were removed after each scan. CTDI(100) was measured with a 100 mm ionization chamber, centrally positioned in a 2.7 cm diameter water phantom, and rotation steps were increased to reduce both scan time and radiation dose. RESULTS Internal TLD analysis demonstrated median organ dose of 5.5 +/- 0.6 mGy per mA s, confirmed by CTDI(100) with result of 6.6 mGy per mA s. A rotation step of 2.16 resulted in qualitatively accurate images. At a resolution of 83 microm the scan time is reduced to 63 s with an estimated dose of 2.9 mGy per mA s. At 166 microm resolution, the scan time is limited to 27 s, with a concordant dose of 1.2 mGy per mA s. CONCLUSIONS The radiation dose of a standard micro-CT scan is relatively high and could influence the experimental outcome. We believe that the presented adaptation of the scan protocol allows for accurate imaging without the risk of interfering with the experimental outcome of the study.

[1]  F Sato,et al.  Late effects of whole or partial body x-irradiation on mice: life shortening. , 1981, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[2]  Patrick L Chow,et al.  Monte carlo simulations of dose from microCT imaging procedures in a realistic mouse phantom. , 2005, Medical physics.

[3]  Simon R Cherry,et al.  In vivo molecular and genomic imaging: new challenges for imaging physics. , 2004, Physics in medicine and biology.

[4]  Ralph Müller,et al.  Monitoring individual morphological changes over time in ovariectomized rats by in vivo micro-computed tomography. , 2006, Bone.

[5]  H Weinans,et al.  Detecting and tracking local changes in the tibiae of individual rats: a novel method to analyse longitudinal in vivo micro-CT data. , 2004, Bone.

[6]  V. Lowe,et al.  In Vivo Quantitation of Intratumoral Radioisotope Uptake Using Micro-Single Photon Emission Computed Tomography/Computed Tomography , 2006, Molecular Imaging and Biology.

[7]  W. Miller,et al.  TLD assessment of mouse dosimetry during microCT imaging. , 2008, Medical physics.

[8]  M J Paulus,et al.  High resolution X-ray computed tomography: an emerging tool for small animal cancer research. , 2000, Neoplasia.

[9]  D W Holdsworth,et al.  Fundamental image quality limits for microcomputed tomography in small animals. , 2003, Medical physics.

[10]  B. Hasegawa,et al.  Radiation dose estimate in small animal SPECT and PET. , 2004, Medical physics.

[11]  S. Russell,et al.  Small Animal Absorbed Radiation Dose from Serial Micro-Computed Tomography Imaging , 2007, Molecular Imaging and Biology.

[12]  J. Boone,et al.  Small-animal X-ray dose from micro-CT. , 2004, Molecular imaging.

[13]  Robertson Js,et al.  Vertebrate Radiobiology (Lethal Actions and Associated Effects) , 1957 .

[14]  Robert E Guldberg,et al.  Microcomputed tomography imaging of skeletal development and growth. , 2004, Birth defects research. Part C, Embryo today : reviews.

[15]  Steven K Boyd,et al.  Radiation effects on bone architecture in mice and rats resulting from in vivo micro-computed tomography scanning. , 2008, Medical engineering & physics.

[16]  Paul D Acton,et al.  Small animal imaging with high resolution single photon emission tomography. , 2003, Nuclear medicine and biology.

[17]  Rik Huiskes,et al.  No effects of in vivo micro‐CT radiation on structural parameters and bone marrow cells in proximal tibia of wistar rats detected after eight weekly scans , 2007, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[18]  S. Gambhir,et al.  Multimodality imaging of tumor xenografts and metastases in mice with combined small-animal PET, small-animal CT, and bioluminescence imaging. , 2007, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[19]  Christoph Groden,et al.  Current issues and perspectives in small rodent magnetic resonance imaging using clinical MRI scanners. , 2007, Methods.

[20]  Rudi Deklerck,et al.  Time-Course of Contrast Enhancement in Spleen and Liver with Exia 160, Fenestra LC, and VC , 2009, Molecular Imaging and Biology.

[21]  H Weinans,et al.  Longitudinal micro-CT scans to evaluate bone architecture. , 2005, Journal of musculoskeletal & neuronal interactions.

[22]  Michel Defrise,et al.  Improved quantification in single-pinhole and multiple-pinhole SPECT using micro-CT information , 2009, European Journal of Nuclear Medicine and Molecular Imaging.

[23]  M Drangova,et al.  In vivo characterization of lung morphology and function in anesthetized free-breathing mice using micro-computed tomography. , 2007, Journal of applied physiology.

[24]  R. Kallman,et al.  The influence of strain on acute x-ray lethality in the mouse. II. Recovery rate studies. , 1957, Radiation Research.

[25]  Marvin D Nelson,et al.  Multimodal Imaging Analysis of Tumor Progression and Bone Resorption in a Murine Cancer Model , 2006, Journal of computer assisted tomography.