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Your search keyword '"van Vlimmeren, Marijke"' showing total 21 results
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21 results on '"van Vlimmeren, Marijke"'

1. Priorities for Advancements in Neuroimaging in the Diagnostic Workup of Acute Stroke

Author

Samaniego, Edgar A., Boltze, Johannes, Lyden, Patrick D., Hill, Michael D., Campbell, Bruce C.V., Silva, Gisele Sampaio, Sheth, Kevin N., Fisher, Marc, Hillis, Argye E., Nguyen, Thanh N., Carone, Davide, Favilla, Christopher G., Deljkich, Emir, Albers, Gregory W., Heit, Jeremy J., Lansberg, Maarten G., Aksoy, Didem, Broderick, Joe, Castonguay, Alicia C., Ghosh, Supurna, Grotta, James C., Harston, George, Houser, Gary R., Kuchenbecker, Kristopher, Latour, Lawrence L., Liebeskind, David S., Kylan Lynch, John, Maier, Carolina, Mistry, Eva, Mocco, J., Nogueira, Raul G., Saver, Jeffrey L., van Vlimmeren, Marijke, Wakhloo, Ajay K., and Wechsler, Lawrence

Published
2023
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2. Motion artifact correction for cone beam CT stroke imaging: a prospective series.

Author

Cancelliere, Nicole M., van Nijnatten, Fred, Hummel, Eric, Withagen, Paul, van de Haar, Peter, Nishi, Hidehisa, Agid, Ronit, Nicholson, Patrick, Hallacoglu, Bertan, van Vlimmeren, Marijke, and Pereira, Vitor M.

Subjects
ISCHEMIC stroke, DIAGNOSTIC imaging, QUALITY assurance, RESEARCH funding, COMPUTED tomography, MEDICAL artifacts, DECISION making in clinical medicine, ENDOVASCULAR surgery, SENSITIVITY & specificity (Statistics), ALGORITHMS, LONGITUDINAL method
Abstract

Background Imaging assessment for acute ischemic stroke (AIS) patients in the angiosuite using cone beam CT (CBCT) has created increased interest since endovascular treatment became the first line therapy for proximal vessel occlusions. One of the main challenges of CBCT imaging in AIS patients is degraded image quality due to motion artifacts. This study aims to evaluate the prevalence of motion artifacts in CBCT stroke imaging and the effectiveness of a novel motion artifact correction algorithm for image quality improvement. Methods Patients presenting with acute stroke symptoms and considered for endovascular treatment were included in the study. CBCT scans were performed using the angiosuite X-ray system. All CBCT scans were post-processed using a motion artifact correction algorithm. Motion artifacts were scored before and after processing using a 4-point scale. Results We prospectively included 310 CBCT scans from acute stroke patients. 51% (n=159/310) of scans had motion artifacts, with 24% being moderate to severe. The post-processing algorithm improved motion artifacts in 91% of scans with motion (n=144/159), restoring clinical diagnostic capability in 34%. Overall, 76% of the scans were sufficient for clinical decisionmaking before correction, which improved to 93% (n=289/310) after post-processing with our algorithm. Conclusions Our results demonstrate that CBCT motion artifacts are significantly reduced using a novel post-processing algorithm, which improved brain CBCT image quality and diagnostic assessment for stroke. This is an important step on the road towards a direct-to-angio approach for endovascular thrombectomy (EVT) treatment. [ABSTRACT FROM AUTHOR]

Published
2023
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4. The butterfly effect: improving brain cone-beam CT image artifacts for stroke assessment using a novel dual-axis trajectory.

Author

Cancelliere, Nicole Mariantonia, Hummel, Eric, van Nijnatten, Fred, van de Haar, Peter, Withagen, Paul, van Vlimmeren, Marijke, Hallacoglu, Bertan, Agid, Ronit, Nicholson, Patrick, and Pereira, Vitor Mendes

Subjects
STROKE diagnosis, ISCHEMIA diagnosis, HEMORRHAGE diagnosis, BRAIN, ISCHEMIC stroke, QUALITY assurance, RESEARCH funding, STROKE patients, COMPUTED tomography, MEDICAL artifacts, COMPUTER-assisted image analysis (Medicine)
Abstract

Background Cone-beam computed tomography (CBCT) imaging of the brain can be performed in the angiography suite to support various neurovascular procedures. Relying on CBCT brain imaging solely, however, still lacks full diagnostic confidence due to the inferior image quality compared with CT and various imaging artifacts that persist even with modern CBCT. Objective To perform a detailed evaluation of image artifact improvement using a new CBCT protocol which implements a novel dual-axis 'butterfly' trajectory. Methods Our study included 94 scans from 47 patients who received CBCT imaging for assessment of either ischemia or hemorrhage during a neurovascular procedure. Both a traditional uni-axis 'circular' and novel dual-axis 'butterfly' protocol were performed on each patient (same-patient control). Each brain scan was divided into six regions and scored out of 3 based on six artifacts originating from various physics-based and patient-based sources. Results The dual-axis trajectory produces CBCT images with significantly fewer image artifacts than the traditional circular scan (whole brain average artifact score, AS: 0.20 vs 0.33), with the greatest improvement in bone beam hardening (AS: 0.13 vs 0.78) and cone- beam artifacts (AS: 0.04 vs 0.55). Conclusions Recent developments in CBCT imaging protocols have significantly improved image artifacts, which has improved diagnostic confidence for stroke and supports a direct-to-angiography suite transfer approach for patients with acute ischemic stroke. [ABSTRACT FROM AUTHOR]

Published
2023
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5. The butterfly effect: improving brain cone-beam CT image artifacts for stroke assessment using a novel dual-axis trajectory

Author

Cancelliere, Nicole Mariantonia, primary, Hummel, Eric, additional, van Nijnatten, Fred, additional, van de Haar, Peter, additional, Withagen, Paul, additional, van Vlimmeren, Marijke, additional, Hallacoglu, Bertan, additional, Agid, Ronit, additional, Nicholson, Patrick, additional, and Mendes Pereira, Vitor, additional

Published
2022
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8. Novel flat-panel cone-beam CT compared to multi-detector CT for assessment of acute ischemic stroke: A prospective study

Author

Nicholson, Patrick, primary, Cancelliere, Nicole M., additional, Bracken, John, additional, Hummel, Erik, additional, van Nijnatten, Fred, additional, Withagen, Paul, additional, van de Haar, Peter, additional, Hallacoglu, Bertan, additional, van Vlimmeren, Marijke, additional, Agid, Ronit, additional, Krings, Timo, additional, and Mendes Pereira, Vitor, additional

Published
2021
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20. An In VitroModel System to Quantify Stress Generation, Compaction, and Retraction in Engineered Heart Valve Tissue

Author

van Vlimmeren, Marijke A.A., Driessen-Mol, Anita, Oomens, Cees W.J., and Baaijens, Frank P.T.

Abstract

Autologous heart valve tissue engineering relies on extracellular matrix production by cells seeded into a degrading scaffold material. The cells naturally exert traction forces to their surroundings, and due to an imbalance between scaffold, tissue, and these traction forces, stress is generated within the tissue. This stress results in compaction during culture and retraction of the leaflets at release of constraints, causing shape loss of the heart valve leaflets. In the present study, an in vitromodel system has been developed to quantify stress generation, compaction, and retraction during culture and after release of constraints. Tissue-engineered (TE) constructs based on polyglycolic acid/poly-4-hydroxybutyrate scaffolds seeded with human vascular-derived cells were cultured for 4 weeks. Compaction in width was measured during culture, stress generation was measured during culture and after release of constraints at week 4, and contraction was measured after release of constraints at week 4. Both compaction and stress generation started after 2 weeks of culture and continued up to week 4. TE constructs compacted up to half of their original width and reached an internal stress of 6–8 kPa at week 4, which resulted in a retraction of 36%. The model system has provided a useful tool to unravel and optimize the balance between the different aspects of TE constructs to develop functional TE leaflets.

Published
2011
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21. An in vitro model system to quantify stress generation, compaction, and retraction in engineered heart valve tissue.

Author

van Vlimmeren MA, Driessen-Mol A, Oomens CW, and Baaijens FP

Subjects
Animals, Biomechanical Phenomena, Calibration, Humans, Sheep, Tissue Culture Techniques, Tissue Scaffolds chemistry, Heart Valve Prosthesis, Heart Valves physiology, Models, Biological, Stress, Mechanical, Tissue Engineering methods
Abstract

Autologous heart valve tissue engineering relies on extracellular matrix production by cells seeded into a degrading scaffold material. The cells naturally exert traction forces to their surroundings, and due to an imbalance between scaffold, tissue, and these traction forces, stress is generated within the tissue. This stress results in compaction during culture and retraction of the leaflets at release of constraints, causing shape loss of the heart valve leaflets. In the present study, an in vitro model system has been developed to quantify stress generation, compaction, and retraction during culture and after release of constraints. Tissue-engineered (TE) constructs based on polyglycolic acid/poly-4-hydroxybutyrate scaffolds seeded with human vascular-derived cells were cultured for 4 weeks. Compaction in width was measured during culture, stress generation was measured during culture and after release of constraints at week 4, and contraction was measured after release of constraints at week 4. Both compaction and stress generation started after 2 weeks of culture and continued up to week 4. TE constructs compacted up to half of their original width and reached an internal stress of 6-8 kPa at week 4, which resulted in a retraction of 36%. The model system has provided a useful tool to unravel and optimize the balance between the different aspects of TE constructs to develop functional TE leaflets., (© Mary Ann Liebert, Inc.)

Published
2011
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