Cell Sequence and Mitosis Affect Fibroblast Directional Decision-Making During Chemotaxis in Microfluidic Mazes

Authors

Quang Long Pham, Newark College of Engineering
Lydia N. Rodrigues, Newark College of Engineering
Max A. Maximov, Newark College of Engineering
Vishnu Deep Chandran, Newark College of Engineering
Cheng Bi, Newark College of Engineering
David Chege, Newark College of Engineering
Timothy Dijamco, Department of Computer Science
Elisabeth Stein, Newark College of Engineering
Nhat Anh Nguyen Tong, Newark College of Engineering
Sagnik Basuray, Newark College of Engineering
Roman S. Voronov, Newark College of Engineering

Document Type

Article

Publication Date

12-15-2018

Abstract

Introduction: Directed fibroblast migration is central to highly proliferative processes in regenerative medicine and developmental biology. However, the mechanisms by which single fibroblasts affect each other’s directional decisions, while chemotaxing in microscopic pores, are not well understood. Methods: We explored effects of cell sequence and mitosis on fibroblast platelet-derived growth factor-BB (PDGF-BB)-induced migration in microfluidic mazes with two possible through paths: short and long. Additionally, image-based modeling of the chemoattractant’s diffusion, consumption and decay, was used to explain the experimental observations. Results: It both cases, the cells displayed behavior that is contradictory to expectation based on the global chemoattractant gradient pre-established in the maze. In case of the sequence, the cells tend to alternate when faced with a bifurcation: if a leading cell takes the shorter (steeper gradient) path, the cell following it chooses the longer (weaker gradient) path, and vice versa. Image-based modeling of the process showed that the local PDGF-BB consumption by the individual fibroblasts may be responsible for this phenomenon. Additionally, it was found that when a mother cell divides, its two daughters go in opposite directions (even if it means migrating against the chemoattractant gradient and overcoming on-going cell traffic). Conclusions: It is apparent that micro-confined fibroblasts modify each other’s directional decisions in a manner that is counter-intuitive to what is expected from classical chemotaxis theory. Consequently, accounting for these effects could lead to a better understanding of tissue generation in vivo, and result in more advanced engineered tissue products in vitro.

Identifier

85052661951 (Scopus)

Publication Title

Cellular and Molecular Bioengineering

External Full Text Location

https://doi.org/10.1007/s12195-018-0551-x

e-ISSN

18655033

ISSN

18655025

First Page

483

Last Page

494

Issue

6

Volume

11

Grant

1450182

Fund Ref

National Science Foundation

Recommended Citation

Pham, Quang Long; Rodrigues, Lydia N.; Maximov, Max A.; Chandran, Vishnu Deep; Bi, Cheng; Chege, David; Dijamco, Timothy; Stein, Elisabeth; Tong, Nhat Anh Nguyen; Basuray, Sagnik; and Voronov, Roman S., "Cell Sequence and Mitosis Affect Fibroblast Directional Decision-Making During Chemotaxis in Microfluidic Mazes" (2018). Faculty Publications. 8161.
https://digitalcommons.njit.edu/fac_pubs/8161