Your search keyword '"Hindley, James W."' showing total 2 results

1. Biomimetic behaviors in hydrogel artificial cells through embedded organelles.

Author

Allen, Matthew E., Hindley, James W., O'Toole, Nina, Cooke, Hannah S., Contini, Claudia, Law, Robert V., Ces, Oscar, and Elani, Yuval

Subjects

*ARTIFICIAL cells, *ORGANELLES, *HYDROGELS

Abstract

Artificial cells are biomimetic structures formed from molecular building blocks that replicate biological processes, behaviors, and architectures. Of these building blocks, hydrogels have emerged as ideal, yet underutilized candidates to provide a gel-like chassis in which to incorporate both biological and nonbiological componentry which enables the replication of cellular functionality. Here, we demonstrate a microfluidic strategy to assemble biocompatible cell-sized hydrogel-based artificial cells with a variety of different embedded functional subcompartments, which act as engineered synthetic organelles. The organelles enable the recreation of increasingly biomimetic behaviors, including stimulus-induced motility, content release through activation of membrane-associated proteins, and enzymatic communication with surrounding bioinspired compartments. In this way, we showcase a foundational strategy for the bottom--up construction of hydrogel-based artificial cell microsystems which replicate fundamental cellular behaviors, paving the way for the construction of next-generation biotechnological devices. [ABSTRACT FROM AUTHOR]

Published

2023

2. Stimuli-responsive vesicles as distributed artificial organelles for bacterial activation.

Author

Gispert, Ignacio, Hindley, James W., Pilkington, Colin P., Shree, Hansa, Barter, Laura M. C., Ces, Oscar, and Elani, Yuval

Subjects

*ARTIFICIAL cells, *ORGANELLES, *CELL communication, *SYNTHETIC biology, *METHODS engineering, *ELECTROSPINNING

Abstract

Intercellular communication is a hallmark of living systems. As such, engineering artificial cells that possess this behavior has been at the heart of activities in bottom-up synthetic biology. Communication between artificial and living cells has potential to confer novel capabilities to living organisms that could be exploited in biomedicine and biotechnology. However, most current approaches rely on the exchange of chemical signals that cannot be externally controlled. Here, we report two types of remote-controlled vesicle-based artificial organelles that translate physical inputs into chemical messages that lead to bacterial activation. Upon light or temperature stimulation, artificial cell membranes are activated, releasing signaling molecules that induce protein expression in Escherichia coli. This distributed approach differs from established methods for engineering stimuli-responsive bacteria. Here, artificial cells (as opposed to bacterial cells themselves) are the design unit. Having stimuli-responsive elements compartmentalized in artificial cells has potential applications in therapeutics, tissue engineering, and bioremediation. It will underpin the design of hybrid living/nonliving systems where temporal control over population interactions can be exerted. [ABSTRACT FROM AUTHOR]

Published

2022