Multiscale modeling of vascular dynamics of micro- and nano-particles : application to drug delivery system /
Huilin Ye, Zhiqiang Shen and Ying Li.
- 1 online resource (various pagings) : illustrations (some color).
- [IOP release 6] IOP concise physics, 2053-2571 .
- IOP (Series). Release 6. IOP concise physics. .
"Version: 20191201"--Title page verso. "A Morgan & Claypool publication as part of IOP Concise Physics"--Title page verso.
Includes bibliographical references.
1. Background -- 1.1. Blood flow in human vasculature -- 1.2. Vascular targeting and margination of particles in blood flow -- 1.3. Adhesion of particles on endothelium wall part I. Numerical method -- 2. Numerical methods: fluid-structure interaction and adhesive dynamics -- 2.1. Fluid-structure interaction -- 2.2. Adhesive dynamics -- 2.3. Validation of numerical method part II. Applications -- 3. Anomalous vascular dynamics of nanoworms within blood flow -- 3.1. Motivation -- 3.2. Experimental and computational results 4. Adhesion behavior of a single cell on the endothelial wall -- 4.1. Introduction -- 4.2. Computational model -- 4.3. Results and discussion 5. Localization of soft particles: margination and adhesion -- 5.1. Introduction -- 5.2. Physical problem and computational method -- 5.3. Results and discussion 6. Shape-dependent transport of micro-particles in blood flow: from margination to adhesion -- 6.1. Introduction -- 6.2. Computational model setup -- 6.3. Results and discussion 7. Conclusion and perspective -- Appendix A. Coarse-grained potential for RBCs.
Recent advances in this exciting field see the potential to employ nanomedicine and game-changing methods to deliver drug molecules directly to diseased sites. To optimize and then enhance efficacy and specificity, the control and guidance of dr
Professional and scholarly.
Mode of access: World Wide Web. System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
Huilin Ye is a Ph.D. candidate in Mechanical Engineering at the University of Connecticut. His research interest is mainly on developing high-fidelity computational methods in biosystems, especially for the blood flow. The key tasks include two
9781643277929 9781643277905
10.1088/2053-2571/ab4124 doi
Drug targeting. Drug carriers (Pharmacy) Nanoparticles--Therapeutic use. Blood-vessels. Biomechanics. Biomedical materials--Mechanical properties. Multiscale modeling. Drug Delivery Systems. Drug Carriers. Nanoparticles--therapeutic use. Blood Vessels--physiology. Biocompatible Materials. Biomechanical Phenomena. Models, Anatomic. Models, Biological. Biophysics. SCIENCE / Life Sciences / Biophysics.