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SINGAPORE – Asia Pacific Medical Technology Association (APACMed) Announces Partnership with Duke-NUS Medical School’s Centre of Regulatory Excellence (CoRE), Pledging Joint Commitment to Promote Regulatory Convergence and Capacity Building Across the Region.

SINGAPORE – Guardian Partners with MyDoc to Address Singapore’s Population Health Needs through Integrating Technology and Self-Care.

SINGAPORE & UNITED STATES – CellMax Life’s Precision, Non-Invasive Cancer Testing Now Available throughout Southeast Asia through Asia Genomics.

UNITED STATES – 3-D Printed Models Could Improve Patient Outcomes in Heart Valve Replacements.

UNITED STATES – Promising Target to Protect Bone in Patients with Diabetes.

UNITED STATES – New Antibody Appears to Re-Activate Immune System in Cancer Therapy.

UNITED STATES – Combo Immunotherapy May Herald New Standard of Care for Kidney Cancer.

JAPAN – Chugai’s Bispecific Antibody “Emicizumab” Global Phase III Data in Patients with Haemophilia A with Inhibitors Published in The New England Journal of Medicine Online.

RUSSIA & INDIA – BIOCAD’s Rituximab Biosimilar to Receive Market Authorization Soon in India.

The immersed boundary method is both a general mathematical framework and a particular numerical approach to problems of fluid-structure interaction. In the present work, we describe the application of the immersed boundary method to the simulation of the fluid dynamics of heart valves, including a model of a natural aortic valve and a model of a chorded prosthetic mitral valve. Each valve is mounted in a semi-rigid flow chamber. In the case of the mitral valve, the flow chamber is a circular pipe, and in the case of the aortic valve, the flow chamber is a model of the aortic root. The model valves and flow chambers are immersed in a viscous incompressible fluid, and realistic fluid boundary conditions are prescribed at the upstream and downstream ends of the chambers. To connect the immersed boundary models to the boundaries of the fluid domain, we introduce a novel modification of the standard immersed boundary scheme. In particular, near the outer boundaries of the fluid domain, we modify the construction of the regularized delta function which mediates fluid-structure coupling in the immersed boundary method, whereas in the interior of the fluid domain, we employ a standard four-point delta function which is frequently used with the immersed boundary method. The standard delta function is used wherever possible, and the modified delta function continuously transitions to the standard delta function away from the outer boundaries of the fluid domain. Three-dimensional computational results are presented to demonstrate the capabilities of our immersed boundary approach to simulating the fluid dynamics of heart valves.