{"database":"biostudies-literature","file_versions":[],"scores":null,"additional":{"submitter":["Qian X"],"funding":["NIBIB NIH HHS","NCI NIH HHS","National Institutes of Health","NIH HHS"],"pagination":["e70098"],"full_dataset_link":["https://www.ebi.ac.uk/biostudies/studies/S-EPMC12640244"],"repository":["biostudies-literature"],"omics_type":["Unknown"],"volume":["52(11)"],"pubmed_abstract":["<h4>Background</h4>Limited-angle cone-beam CT (LA-CBCT) reduces imaging time and dose but suffers from severe under-sampling artifacts and distortions. 2D-3D deformable registration mitigates this issue by estimating LA-CBCTs through the deformation of a prior, fully-sampled CT/CBCT, using deformation-vector-fields (DVFs) optimized by limited-angle cone-beam projections. Population-trained 2D-3D registration networks enable fast inference but face accuracy challenges, particularly under varying limited-angle scan directions. On the other hand, patient-specific models are more adaptable but typically require considerable runtimes to optimize model parameters from scratch for each case.<h4>Purpose</h4>To improve the accuracy and efficiency of 2D-3D registration-driven LA-CBCT estimation, a hybrid 2D-3D deformable registration framework was proposed.<h4>Methods</h4>The hybrid population-based and patient-specific 2D-3D deformable registration framework (HB-2D3DReg) synergized the advantages of both population-based and patient-specific approaches while mitigating their limitations. It integrated the fast inference of population-trained models with the test-time adaptability of patient-specific models through a two-stage approach. First, a population-based 2D-3D registration network, 2D3D-RegNet, was trained on a cohort dataset in an unsupervised manner, with a similarity loss defined between digitally reconstructed radiographs (DRRs) of the estimated LA-CBCTs and limited-angle 2D projections. Then, a 2D-3D registration network based on implicit neural representation (INR), 2D3D-INR, refined the DVFs solved by the population-based model during test time for each independent testing case. The population-based 2D3D-RegNet accelerated the optimization of the patient-specific 2D3D-INR and reduced the latter's chance of being trapped at a local optimum, while the patient-specific network, in turn, enhanced the accuracy of the population-based model. HB-2D3DReg was evaluated using a dataset of 48 4D-CTs, 26 of which were used to train the population-based model and 22 for testing. Different limited-angle scan scenarios, featuring varying scan directions and angles, were assessed.<h4>Results</h4>HB-2D3DReg attained superior LA-CBCT estimation and registration accuracy. Under an orthogonal-view 90° scan (45° each) with varying scan directions, HB-2D3DReg achieved mean (± S.D.) image relative error of 7.99 ± 2.16% and target registration error of 3.70 ± 1.94 mm, compared to 15.40 ± 2.41% and 8.52 ± 3.31 mm (no registration), 9.82 ± 2.12% and 6.38 ± 2.46 mm (2D3D-RegNet only), and 9.71 ± 2.33% and 5.01 ± 2.77 mm (2D3D-INR only) on the DIR-lab dataset. HB-2D3DReg took ∼3 min to optimize at test time, compared to 13 min for the 2D3D-INR method.<h4>Conclusion</h4>HB-2D3DReg achieved accurate and robust 2D-3D deformation registration for LA-CBCT estimation, enabling efficient anatomy monitoring to guide radiotherapy. The code will be released at: https://github.com/sanny1226/HB-2D3DReg."],"journal":["Medical physics"],"pubmed_title":["A hybrid population-based and patient-specific framework for 2D-3D deformable registration-driven limited-angle cone-beam CT estimation."],"pmcid":["PMC12640244"],"funding_grant_id":["R01 CA280135","R01 CA240808","R01 EB034691","R01 CA258987"],"pubmed_authors":["Qian X","Zhang Y","Shao HC"],"additional_accession":[]},"is_claimable":false,"name":"A hybrid population-based and patient-specific framework for 2D-3D deformable registration-driven limited-angle cone-beam CT estimation.","description":"<h4>Background</h4>Limited-angle cone-beam CT (LA-CBCT) reduces imaging time and dose but suffers from severe under-sampling artifacts and distortions. 2D-3D deformable registration mitigates this issue by estimating LA-CBCTs through the deformation of a prior, fully-sampled CT/CBCT, using deformation-vector-fields (DVFs) optimized by limited-angle cone-beam projections. Population-trained 2D-3D registration networks enable fast inference but face accuracy challenges, particularly under varying limited-angle scan directions. On the other hand, patient-specific models are more adaptable but typically require considerable runtimes to optimize model parameters from scratch for each case.<h4>Purpose</h4>To improve the accuracy and efficiency of 2D-3D registration-driven LA-CBCT estimation, a hybrid 2D-3D deformable registration framework was proposed.<h4>Methods</h4>The hybrid population-based and patient-specific 2D-3D deformable registration framework (HB-2D3DReg) synergized the advantages of both population-based and patient-specific approaches while mitigating their limitations. It integrated the fast inference of population-trained models with the test-time adaptability of patient-specific models through a two-stage approach. First, a population-based 2D-3D registration network, 2D3D-RegNet, was trained on a cohort dataset in an unsupervised manner, with a similarity loss defined between digitally reconstructed radiographs (DRRs) of the estimated LA-CBCTs and limited-angle 2D projections. Then, a 2D-3D registration network based on implicit neural representation (INR), 2D3D-INR, refined the DVFs solved by the population-based model during test time for each independent testing case. The population-based 2D3D-RegNet accelerated the optimization of the patient-specific 2D3D-INR and reduced the latter's chance of being trapped at a local optimum, while the patient-specific network, in turn, enhanced the accuracy of the population-based model. HB-2D3DReg was evaluated using a dataset of 48 4D-CTs, 26 of which were used to train the population-based model and 22 for testing. Different limited-angle scan scenarios, featuring varying scan directions and angles, were assessed.<h4>Results</h4>HB-2D3DReg attained superior LA-CBCT estimation and registration accuracy. Under an orthogonal-view 90° scan (45° each) with varying scan directions, HB-2D3DReg achieved mean (± S.D.) image relative error of 7.99 ± 2.16% and target registration error of 3.70 ± 1.94 mm, compared to 15.40 ± 2.41% and 8.52 ± 3.31 mm (no registration), 9.82 ± 2.12% and 6.38 ± 2.46 mm (2D3D-RegNet only), and 9.71 ± 2.33% and 5.01 ± 2.77 mm (2D3D-INR only) on the DIR-lab dataset. HB-2D3DReg took ∼3 min to optimize at test time, compared to 13 min for the 2D3D-INR method.<h4>Conclusion</h4>HB-2D3DReg achieved accurate and robust 2D-3D deformation registration for LA-CBCT estimation, enabling efficient anatomy monitoring to guide radiotherapy. The code will be released at: https://github.com/sanny1226/HB-2D3DReg.","dates":{"release":"2025-01-01T00:00:00Z","publication":"2025 Nov","modification":"2026-06-05T17:15:52.21Z","creation":"2026-05-19T03:11:52.26Z"},"accession":"S-EPMC12640244","cross_references":{"pubmed":["41145398"],"doi":["10.1002/mp.70098"]}}