Semi-automatic construction of reference standards for evaluation of image registration

Murphy, Keelin; Ginneken, van B Bram; Klein, Stefan; Staring, Marius; Hoop, de Bj; Viergever, MA Max; Pluim, Jpw Josien

doi:10.1016/j.media.2010.07.005

Cited by 107 publications

(103 citation statements)

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“…First, we identified approximately 100 corresponding landmarks (vessel bifurcations) between the 2 image sets using the Ix software (20). Then we created a deformation field from these landmarks using a spline kernel transform.…”

Section: Pretreatment and Posttreatment Ct Registrationsmentioning

confidence: 99%

Analysis of Long-Term 4-Dimensional Computed Tomography Regional Ventilation After Radiation Therapy

King

Maxim

Diehn

et al. 2015

International Journal of Radiation Oncology*Biology*Physics

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Section: Pretreatment and Posttreatment Ct Registrationsmentioning

confidence: 99%

Analysis of Long-Term 4-Dimensional Computed Tomography Regional Ventilation After Radiation Therapy

King

Maxim

Diehn

et al. 2015

International Journal of Radiation Oncology*Biology*Physics

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“…Patients are within the range of 49 to 78 years old and for each patient a baseline image and a follow-up image (after 30 months) are available in which 100 well-distributed corresponding landmarks are selected semi-automatically on distinctive locations [11]. The residual Euclidean distance after registration between the corresponding points can be seen as the accuracy of the registration.…”

Section: Experiments and Resultsmentioning

confidence: 99%

Accuracy Estimation for Medical Image Registration Using Regression Forests

Sokooti

Saygılı

Glocker

et al. 2016

Lecture Notes in Computer Science

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Abstract. This paper reports a new automatic algorithm to estimate the misregistration in a quantitative manner. A random regression forest is constructed, predicting the local registration error. The forest is built using local and modality independent features related to the registration precision, the transformation model and intensity-based similarity after registration. The forest is trained and tested using manually annotated corresponding points between pairs of chest CT scans. The results show that the mean absolute error of regression is 0.72 ± 0.96 mm and the accuracy of classification in three classes (correct, poor and wrong registration) is 93.4%, comparing favorably to a competing method. In conclusion, a method was proposed that for the first time shows the feasibility of automatic registration assessment by means of regression, and promising results were obtained.

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“…Such work will benefit from semiautomatic target identification methods to further streamline error analysis and accuracy validation. 56 The additional trials will be enabled in part by integration of the model-driven and image-driven methods in an in-house image guidance system, 11 also facilitating workflow analysis and preclinical testing in CBCT guidance of thoracic surgery. Previous work in the context of spine and skull base surgery have demonstrated the utility of such application-specific modules for early translational research in seeing CBCT guidance from the laboratory to early clinical studies.…”

Section: Discussionmentioning

confidence: 99%

Deformable registration of the inflated and deflated lung in cone‐beam CT‐guided thoracic surgery: Initial investigation of a combined model‐ and image‐driven approach

et al. 2012

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Purpose: Surgical resection is the preferred modality for curative treatment of early stage lung cancer, but localization of small tumors (<10 mm diameter) during surgery presents a major challenge that is likely to increase as more early-stage disease is detected incidentally and in low-dose CT screening. To overcome the difficulty of manual localization (fingers inserted through intercostal ports) and the cost, logistics, and morbidity of preoperative tagging (coil or dye placement under CT-fluoroscopy), the authors propose the use of intraoperative cone-beam CT (CBCT) and deformable image registration to guide targeting of small tumors in video-assisted thoracic surgery (VATS). A novel algorithm is reported for registration of the lung from its inflated state (prior to pleural breach) to the deflated state (during resection) to localize surgical targets and adjacent critical anatomy. Methods: The registration approach geometrically resolves images of the inflated and deflated lung using a coarse model-driven stage followed by a finer image-driven stage. The model-driven stage uses image features derived from the lung surfaces and airways: triangular surface meshes are morphed to capture bulk motion; concurrently, the airways generate graph structures from which corresponding nodes are identified. Interpolation of the sparse motion fields computed from the bounding surface and interior airways provides a 3D motion field that coarsely registers the lung and initializes the subsequent image-driven stage. The image-driven stage employs an intensity-corrected, symmetric form of the Demons method. The algorithm was validated over 12 datasets, obtained from porcine specimen experiments emulating CBCT-guided VATS. Geometric accuracy was quantified in terms of target registration error (TRE) in anatomical targets throughout the lung, and normalized crosscorrelation. Variations of the algorithm were investigated to study the behavior of the model-and image-driven stages by modifying individual algorithmic steps and examining the effect in comparison to the nominal process. Results: The combined model-and image-driven registration process demonstrated accuracy consistent with the requirements of minimally invasive VATS in both target localization (∼3-5 mm within the target wedge) and critical structure avoidance (∼1-2 mm). The model-driven stage initialized the registration to within a median TRE of 1.9 mm (95% confidence interval (CI) maximum = 5.0 mm), while the subsequent image-driven stage yielded higher accuracy localization with 0.6 mm median TRE (95% CI maximum = 4.1 mm). The variations assessing the individual algorithmic steps elucidated the role of each step and in some cases identified opportunities for further simplification and improvement in computational speed. Conclusions:The initial studies show the proposed registration method to successfully register CBCT images of the inflated and deflated lung. Accuracy appears sufficient to localize the target and adjacent critical anatomy within ∼1-2 mm and guide ...

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Semi-automatic construction of reference standards for evaluation of image registration

Cited by 107 publications

References 50 publications

Analysis of Long-Term 4-Dimensional Computed Tomography Regional Ventilation After Radiation Therapy

Analysis of Long-Term 4-Dimensional Computed Tomography Regional Ventilation After Radiation Therapy

Accuracy Estimation for Medical Image Registration Using Regression Forests

Deformable registration of the inflated and deflated lung in cone‐beam CT‐guided thoracic surgery: Initial investigation of a combined model‐ and image‐driven approach

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