Intrinsic respiratory gating in small-animal CT

Intrinsic respiratory gating in small-animal CT

Gating in small-animal CT imaging can compensate artefacts caused by physiological motion during scanning. However, all published gating approaches for small animals rely on additional hardware to derive the gating signals. In contrast, in this study a novel method of intrinsic respiratory gating of...

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Bibliographic Details
Published in:European radiology 2008-07, Vol.18 (7), p.1375-1384, Article 1375
Main Authors: Bartling, Soenke H., Dinkel, Julien, Stiller, Wolfram, Grasruck, Michael, Madisch, Ijad, Kauczor, Hans-Ulrich, Semmler, Wolfhard, Gupta, Rajiv, Kiessling, Fabian
Format: Article
Language:eng
Subjects:
Algorithms
Animals
Cancer research
Computed tomography
Contrast Media
Cushions
Diagnostic Radiology
Diaphragm
Experimental
Gating
Hardware
Health physics
Image quality
Imaging
Internal Medicine
Interventional Radiology
Lungs
Medical research
Medicine
Medicine & Public Health
Methods
Mice
Neuroradiology
Physiology
Rabbits
Radiographic Image Interpretation, Computer-Assisted
Radiology
Research centers
Respiration
Respiratory Mechanics
Rodents
Sensors
Tomography, X-Ray Computed - instrumentation
Tomography, X-Ray Computed - methods
Ultrasound
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Summary:Gating in small-animal CT imaging can compensate artefacts caused by physiological motion during scanning. However, all published gating approaches for small animals rely on additional hardware to derive the gating signals. In contrast, in this study a novel method of intrinsic respiratory gating of rodents was developed and tested for mice (n=5), rats (n=5) and rabbits (n=2) in a flat-panel cone-beam CT system. In a consensus read image quality was compared with that of non-gated and retrospective extrinsically gated scans performed using a pneumatic cushion. In comparison to non-gated images, image quality improved significantly using intrinsic and extrinsic gating. Delineation of diaphragm and lung structure improved in all animals. Image quality of intrinsically gated CT was judged to be equivalent to extrinsically gated ones. Additionally 4D datasets were calculated using both gating methods. Values for expiratory, inspiratory and tidal lung volumes determined with the two gating methods were comparable and correlated well with values known from the literature. We could show that intrinsic respiratory gating in rodents makes additional gating hardware and preparatory efforts superfluous. This method improves image quality and allows derivation of functional data. Therefore it bears the potential to find wide applications in small-animal CT imaging.
ISSN:0938-7994
1432-1084