Extraction of the respiratory signal from small-animal CT projections for a retrospective gating method

Chavarrías, Cristina; Vaquero, J.J.; Sisniega, Alejandro; Rodriguez-Ruano, Alexia; Soto-Montenegro, María Luisa; García‐Barreno, Pedro

doi:10.1088/0031-9155/53/17/015

Cited by 12 publications

(18 citation statements)

References 46 publications

(130 reference statements)

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“…Typical imaging doses to small animals are around 0.3 Gy or even higher for micro-CT [47]; and need to be considered in longitudinal studies especially for non-tumor tissue. Technical solutions for respiratory motion management have been reported [48], and next generation systems are expected to offer dual energy options [49]. Table 2 Requirements for specification and reporting of small animal irradiation with particle beams.…”

Section: Computed Tomography (Ct)mentioning

confidence: 99%

A method to combine target volume data from 3D and 4D planned thoracic radiotherapy patient cohorts for machine learning applications

Johnson

Price

Khalifa

et al. 2018

Radiotherapy and Oncology

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Section: Computed Tomography (Ct)mentioning

confidence: 99%

A method to combine target volume data from 3D and 4D planned thoracic radiotherapy patient cohorts for machine learning applications

Johnson

Price

Khalifa

et al. 2018

Radiotherapy and Oncology

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“…In this work we present an evaluation of three CS algorithms were arranged into four gates using a software-based retrospective gating [9].…”

Section: The Prior Image Constrained Compressed Sensing (Piccs)mentioning

confidence: 99%

Investigation of different Compressed Sensing approaches for respiratory gating in small animal CT

Abascal

Sisniega

Chavarrías

et al. 2012

2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record (NSS/MIC)

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“…Prospective 6,7 and retrospective techniques, with intrinsic or extrinsic gating, 8 were implemented and investigated to improve spatial resolution. In prospective gating, data acquisition is restricted to a specific cardiac or respiratory phase given by a transitortransitor logic (TTL) signal produced by an external system (a pneumatic cushion, for example).…”

Section: Introductionmentioning

confidence: 99%

Development of a dynamic phantom and investigation of mobile target imaging and irradiation in preclinical small animal research

Frelin-Labalme

Beaudouin

2017

BJR

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Objective: Progress made in preclinical radiotherapy makes respiratory gating reachable. Nevertheless, technical means are still needed, as well as accurate investigations of the effect of motion on small animal treatment plans. Methods: An animal-scaled dynamic phantom (0.3-11.1-mm motion peak-to-peak amplitude, 30-120 cycles per minute) was developed and characterized. It was used to evaluate respiratory monitoring and high resolution imaging (mPET/CT scans). The width and position variations of a fluorine-18 solution were measured for various motions and gating configurations. The phantom was finally used to measure the impact of motion on dose distribution for vertical irradiation using 2.5-and 5-mm collimations. Results: Phantom motions accurately reproduced original waveforms with good rate and amplitude linearity (R 2 5 1 and R 2 5 0.9995, respectively). mPET/CT acquisitions showed an increase of 92% of the target size caused by a 4.9-mm sine motion and reduced to ,12% by gating. Target motion measurements showed consistency better than 18% between modalities. Irradiations showed that motions .0.8 and 1.1 mm (for the 2.5-and 5-mm collimations, respectively) significantly impact dose homogeneity in the target. Conclusion:The phantom allowed studying motion in small animal imaging and irradiation. It showed the important impact of motions .2 mm and provided accurate data to improve the management of mobile tumour irradiation. The implementation of gated irradiation, associated with motion-compensated imaging, is currently under progress. Advances in knowledge: Small animal irradiation gatingis not yet used in preclinical studies. As few solutions are under development, tools and accurate studies are highly needed.

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Extraction of the respiratory signal from small-animal CT projections for a retrospective gating method

Cited by 12 publications

References 46 publications

A method to combine target volume data from 3D and 4D planned thoracic radiotherapy patient cohorts for machine learning applications

A method to combine target volume data from 3D and 4D planned thoracic radiotherapy patient cohorts for machine learning applications

Investigation of different Compressed Sensing approaches for respiratory gating in small animal CT

Development of a dynamic phantom and investigation of mobile target imaging and irradiation in preclinical small animal research

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