Microfluidics in Cell Biology: Part A: Microfluidics for Multicellular Systems

<p>Section 1: Microfluidics for Cell Monolayers/Spheroids<br>1. Tubular microscaffolds for studying collective cell migration<br>Wang Xi, Surabhi Sonam, Chwee Teck Lim and Benoit Ladoux<br>2. Endothelial cell monolayer-based microfluidic systems mimicking complex in vivo microenvironments for the study of leukocyte dynamics in inflamed blood vessels<br>Jaehyun Lee, Hyung Kyu Huh, Sung Ho Park, Sang Joon Lee and Junsang Doh<br>3. Constrained spheroids/organoids in perfusion culture<br>Fan Lee, Ciprian Iliescu, Fang Yu and Hanry Yu</p> <p>Section 2: Organs on Chips<br>4. Generation of functional cardiac microtissues in a beating heart-on-a-chip<br>Giovanni Stefano Ugolini, Roberta Visone, Daniela Cruz-Moreira, Andrea Mainardi and Marco Rasponi<br>5. Kidney on chips<br>Jeonghwan Lee, Kipyo Kim and Sejoong Kim<br>6. Liver sinusoid on a chip<br>Yu Du, Ning Li and Mian Long<br>7. Pathomimetic modeling of human intestinal diseases and underlying host-gut microbiome interactions in a gut-on-a-chip<br>Woojung Shin and Hyun Jung Kim<br>8. 3D in vitro microvascular model-based lymphoma model<br>Robert G. Mannino, Pallab Pradhan, Krishnendu Roy and Wilbur A. Lam<br>9. Blood–brain barrier on a chip<br>Eyleen Goh<br>10. Pharmacokinetic-based multi-organ chip for recapitulating organ interactions<br>Jong Hwan Sung<br>11. Studying TCR T cell anti-tumor activity in a microfluidic intrahepatic tumor model<br>Giulia Adriani, Andrea Pavesi and Roger D. Kamm</p> <p>Section 3: Microfluidics for Model Organisms<br>12. Microfluidics for mechanobiology of model organisms<br>Anna A. Kim, Adam L. Nekimken, Sylvia Fechner, Lucy E. O'Brien and Beth L. Pruitt</p>