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Main Authors: Dutto, Alessandro, Kan, Anton, Saraw, Zoubeir, Maillard, Aline, Zindel, Daniel, Studart, André R.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.00789
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author Dutto, Alessandro
Kan, Anton
Saraw, Zoubeir
Maillard, Aline
Zindel, Daniel
Studart, André R.
author_facet Dutto, Alessandro
Kan, Anton
Saraw, Zoubeir
Maillard, Aline
Zindel, Daniel
Studart, André R.
contents Microorganisms hosted in abiotic structures have led to engineered living materials that can grow, sense and adapt in ways that mimic biological systems. Although porous structures should favor colonization by microorganisms, they have not yet been exploited as abiotic scaffolds for the development of living materials. Here, we report porous ceramics that are colonized by bacteria to form an engineered living material with self-regulated and genetically programmable carbon capture and gas-sensing functionalities. The carbon capture capability is achieved using wild-type photosynthetic cyanobacteria, whereas the gas-sensing function is generated utilizing genetically engineered E. coli. Hierarchical porous clay is used as ceramic scaffold and evaluated in terms of bacterial growth, water uptake and mechanical properties. Using state-of-the-art chemical analysis techniques, we demonstrate the ability of the living porous ceramics to capture CO2 directly from the air and to metabolically turn minute amounts of a toxic gas into a benign scent detectable by humans.
format Preprint
id arxiv_https___arxiv_org_abs_2409_00789
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Living porous ceramics for bacteria-regulated gas sensing and carbon capture
Dutto, Alessandro
Kan, Anton
Saraw, Zoubeir
Maillard, Aline
Zindel, Daniel
Studart, André R.
Materials Science
Biological Physics
Quantitative Methods
Microorganisms hosted in abiotic structures have led to engineered living materials that can grow, sense and adapt in ways that mimic biological systems. Although porous structures should favor colonization by microorganisms, they have not yet been exploited as abiotic scaffolds for the development of living materials. Here, we report porous ceramics that are colonized by bacteria to form an engineered living material with self-regulated and genetically programmable carbon capture and gas-sensing functionalities. The carbon capture capability is achieved using wild-type photosynthetic cyanobacteria, whereas the gas-sensing function is generated utilizing genetically engineered E. coli. Hierarchical porous clay is used as ceramic scaffold and evaluated in terms of bacterial growth, water uptake and mechanical properties. Using state-of-the-art chemical analysis techniques, we demonstrate the ability of the living porous ceramics to capture CO2 directly from the air and to metabolically turn minute amounts of a toxic gas into a benign scent detectable by humans.
title Living porous ceramics for bacteria-regulated gas sensing and carbon capture
topic Materials Science
Biological Physics
Quantitative Methods
url https://arxiv.org/abs/2409.00789