posted on 2019-04-12, 00:00authored byCaio G. Otoni, Juliana S. L. Figueiredo, Larissa B. Capeletti, Mateus B. Cardoso, Juliana S. Bernardes, Watson Loh
To
shed light on novel sustainable materials with antimicrobial
functionality, in this contribution, we describe the use of cationic
nanocellulose to produce foams featuring antibacterial activity against
the powerful human pathogen Escherichia coli. Dialdehyde
cellulose was cationized with Girard’s reagent T (GRT), mechanically
disintegrated into nanofibrillated cellulose (NFC), and shaped into
foams through different protocols. All steps were carried out in aqueous
media and in the absence of hazardous chemicals. While evaporative
drying led to compact films (density of 1.3 g cm–3), freeze-casting (i.e., freezing and freeze-drying) produced monolithic
cryogels with low densities (<50 mg cm–3) and
porosities of ca. 98%. Although highly porous, the cryogels obtained
through rapid freezing remarkably presented smaller pores than those
that were previously frozen in a slow fashion. The quaternary ammonium
groups of GRT-cationized NFC removed E. coli to different
extents depending upon sample morphology. We demonstrated in an innovative
manner that porosity, which is directly associated with surface area,
and pore size play an essential role on the antimicrobial performance.
This outcome arises from the inaccessibility of bacterial cells to
cationic surfaces inside monoliths composed of small pores. We herein
present an uncomplicated, environmentally friendly protocol for fine-tuning
the porosity and pore size of all-cellulose materials through cryo-templating.
Controlling these morphometric parameters allowed us to achieve a
ca. 85% higher anti-E. coli activity when comparing
samples made up of the very same material (i.e., the same NFC concentration
and degree of substitution) but presented as dense films. These findings
bear clear implications for the pursuit of sustainable materials presenting
multifunctionality.