The book "Computational Blood Cell Mechanics" presents a comprehensive study on the modeling of blood cells, their mechanics and their behavior under the flow. I like the way the mathematical model of cell mechanics is presented with illustrative examples that accompany mathematical formulations. That will help the students, that are new to this area, in understanding the presented concepts. One of the most exciting parts of this book is the usable code that allows the reader to see the model in action by following the examples. Numerous illustrations allow easily to check whether the simulations run by the reader will return the expected results. The authors also provide several practical hints for mathematical modeling and for running the simulations effectively. In particular, the chapter on checking the model against "bioreality" is very valuable for students new to mathematical modeling. It contains step-by-step instructions of how to deal with building the model and make all the necessary checks to gain confidence in model validity and accuracy. This will help not only when the problems related to blood cell mechanics are considered, but for modeling of biological problems at large. I think that this is a great textbook for somebody starting in blood flow modeling and a very good reference book for experienced modelers.
-Katarzyna (Kasia) A. Rejniak, Associate Member, Integrated Mathematical Oncology H. Lee Moffitt Cancer Center & Research Institute
The book "Computational Blood Cell Mechanics" presents a comprehensive study on the modeling of blood cells, their mechanics and their behavior under the flow. I like the way the mathematical model of cell mechanics is presented with illustrative examples that accompany mathematical formulations. That will help the students, that are new to this area, in understanding the presented concepts. One of the most exciting parts of this book is the usable code that allows the reader to see the model in action by following the examples. Numerous illustrations allow easily to check whether the simulations run by the reader will return the expected results. The authors also provide several practical hints for mathematical modeling and for running the simulations effectively. In particular, the chapter on checking the model against "bioreality" is very valuable for students new to mathematical modeling. It contains step-by-step instructions of how to deal with building the model and make all the necessary checks to gain confidence in model validity and accuracy. This will help not only when the problems related to blood cell mechanics are considered, but for modeling of biological problems at large. I think that this is a great textbook for somebody starting in blood flow modeling and a very good reference book for experienced modelers.
-Katarzyna (Kasia) A. Rejniak, Associate Member, Integrated Mathematical Oncology H. Lee Moffitt Cancer Center & Research Institute
