21 results on '"van Vlimmeren, Marijke"'
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2. Motion artifact correction for cone beam CT stroke imaging: a prospective series.
3. Motion artifact correction for cone beam CT stroke imaging: a prospective series
4. The butterfly effect: improving brain cone-beam CT image artifacts for stroke assessment using a novel dual-axis trajectory.
5. The butterfly effect: improving brain cone-beam CT image artifacts for stroke assessment using a novel dual-axis trajectory
6. A SYSTEMATIC APPROACH TO UNRAVEL HOW LIGHT IMPACTS PRIMARY HUMAN DERMAL FIBROBLASTS: #149
7. LIGHT PARAMETERS IN LOW-LEVEL LIGHT THERAPY: A SYSTEMATIC LITERATURE REVIEW: #150
8. Novel flat-panel cone-beam CT compared to multi-detector CT for assessment of acute ischemic stroke: A prospective study
9. Dose‐response of human follicles during laser‐based hair removal:Ex vivophotoepilation model with classification system embracing morphological and histological features
10. Light‐based home‐use devices for hair removal: Why do they work and how effective they are?
11. Dose-response of human follicles during laser-based hair removal: Ex vivo photoepilation model with classification system embracing morphological and histological features.
12. The Potential of Prolonged Tissue Culture to Reduce Stress Generation and Retraction in Engineered Heart Valve Tissues
13. Low Oxygen Concentrations Impair Tissue Development in Tissue-Engineered Cardiovascular Constructs
14. Passive and active contributions to generated force and retraction in heart valve tissue engineering
15. AnIn VitroModel System to Quantify Stress Generation, Compaction, and Retraction in Engineered Heart Valve Tissue
16. The Role of Cells in Collagen Modeling in Tissue Engineered Constructs: A Theoretical Framework
17. The Potential of Prolonged Tissue Culture to Reduce Stress Generation and Retraction in Engineered Heart Valve Tissues
18. Controlling matrix formation and cross-linking by hypoxia in cardiovascular tissue engineering
19. Hypoxia Induces Near-Native Mechanical Properties in Engineered Heart Valve Tissue
20. An In VitroModel System to Quantify Stress Generation, Compaction, and Retraction in Engineered Heart Valve Tissue
21. An in vitro model system to quantify stress generation, compaction, and retraction in engineered heart valve tissue.
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