1 research outputs found
Self-Assembly with Orthogonal-Imposed Stimuli To Impart Structure and Confer Magnetic Function To Electrodeposited Hydrogels
A magnetic nanocomposite film with
the capability of reversibly collecting functionalized magnetic particles
was fabricated by simultaneously imposing two orthogonal stimuli (electrical
and magnetic). We demonstrate that cathodic codeposition of chitosan
and Fe<sub>3</sub>O<sub>4</sub> nanoparticles while simultaneously
applying a magnetic field during codeposition can (i) organize structure,
(ii) confer magnetic properties, and (iii) yield magnetic films that
can perform reversible collection/assembly functions. The magnetic
field triggered the self-assembly of Fe<sub>3</sub>O<sub>4</sub> nanoparticles
into hierarchical “chains” and “fibers”
in the chitosan film. For controlled magnetic properties, the Fe<sub>3</sub>O<sub>4</sub>-chitosan film was electrodeposited in the presence
of various strength magnetic fields and different deposition times.
The magnetic properties of the resulting films should enable broad
applications in complex devices. As a proof of concept, we demonstrate
the reversible capture and release of green fluorescent protein (EGFP)-conjugated
magnetic microparticles by the magnetic chitosan film. Moreover, antibody-functionalized
magnetic microparticles were applied to capture cells from a sample,
and these cells were collected, analyzed, and released by the magnetic
chitosan film, paving the way for applications such as reusable biosensor
interfaces (e.g., for pathogen detection). To our knowledge, this
is the first report to apply a magnetic field during the electrodeposition
of a hydrogel to generate magnetic soft matter. Importantly, the simple,
rapid, and reagentless fabrication methodologies demonstrated here
are valuable features for creating a magnetic device interface