Photodegradable Hydrogel Matrices for Spatiotemporal Control of Bacteria Transport and Delivery

Photodegradable Hydrogel Matrices for Spatiotemporal Control of Bacteria Transport and Delivery

Stimuli-responsive hydrogels that provide controlled degradation can be used as bacteria delivery systems for advanced therapeutic applications. Here, we report the first use of photodegradable hydrogels as materials that can direct bacterial movement, tune mean bacteria speed, and control bacteria...

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Bibliographic Details
Main Author: Jeffrey A. Reed (22168271) (author)
Other Authors: Scott T. Retterer (1800268) (author), Ryan R. Hansen (276370) (author)
Published: 2025
Subjects:
Biochemistry
Medicine
Microbiology
Genetics
Molecular Biology
Biotechnology
Cancer
Inorganic Chemistry
Infectious Diseases
Space Science
Chemical Sciences not elsewhere classified
without significant adhesion
using fluorescence visualization
monitored using time
mean directional change
living material applications
lapse fluorescence microscopy
formed using base
bacterial therapeutic applications
advanced therapeutic applications
bacteria mean speed
alter bacteria speed
direct bacterial movement
bacteria delivery systems
photodegradable hydrogel matrices
provide controlled degradation
control bacteria delivery
based hydrogel materials
spatiotemporal control
controlled doses
bacteria transport
bacteria chemotaxis
delivery vehicles
delivery stimuli
delivery sites
photodegradable poly
hydrogel photodegradation
hydrogel degradation
photodegradable hydrogels
varied levels
tunable degradation
tunable according
thiol cross
systematic study
scale regions
partially degraded
nutrient gradients
nutrient gradient
generated across
following characterization
fold difference
findings advance
ethylene glycol
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Summary:Stimuli-responsive hydrogels that provide controlled degradation can be used as bacteria delivery systems for advanced therapeutic applications. Here, we report the first use of photodegradable hydrogels as materials that can direct bacterial movement, tune mean bacteria speed, and control bacteria delivery through spatiotemporal control of degradation. Hydrogels were formed using base-catalyzed Michael addition reactions between photodegradable poly(ethylene glycol) (PEG) <i>o</i>-nitrobenzyl diacrylate macromers and PEG tetra-thiol cross-linkers within microfluidic channels. Nutrient gradients were generated across the channel, and micron-scale regions of the hydrogel were partially degraded by exposure to controlled doses (2.1–168 mJ/mm<sup>2</sup>) of patterned 365 nm light. Hydrogel degradation was then characterized <i>in situ</i> using fluorescence visualization of fluorescein-labeled hydrogels. Following characterization, Bacillus subtilis expressing green fluorescent protein was introduced into the device, and its movement up the nutrient gradient was monitored using time-lapse fluorescence microscopy to enable a systematic study of bacteria chemotaxis through the hydrogels at varied levels of degradation. B. subtilis showed minimal adhesion to partially degraded PEG hydrogels, and bacteria mean speed and mean directional change were tunable according to the level of hydrogel photodegradation, with a 2.6-fold difference in mean cell speed measured across the partially degraded hydrogel regions. Finally, the ability to alter bacteria speed and directionality through tunable degradation and without significant adhesion was used to achieve controlled release profiles of bacteria to delivery sites. These findings advance the use of PEG-based hydrogel materials as delivery vehicles for bacterial therapeutic applications and other living material applications that require controlled bacteria transport.

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