posted on 2017-02-16, 00:00authored byJiaul Hoque, Relekar G. Prakash, Krishnamoorthy Paramanandham, Bibek R. Shome, Jayanta Haldar
Two component injectable hydrogels
that cross-link in situ have
been used as noninvasive wound-filling devices, i.e., sealants. These
materials carry a variety of functions at the wound sites, such as
sealing leaks, ceasing unwanted bleeding, binding tissues together,
and assisting in wound healing processes. However, commonly used sealants
typically lack antibacterial properties. Since bacterial infection
at the wound site is very common, bioadhesive materials with intrinsic
antibacterial properties are urgently required. Herein, we report
a biocompatible injectable hydrogel with inherent bioadhesive, antibacterial,
and hemostatic capabilities suitable for wound sealing applications.
The hydrogels were developed in situ from an antibacterial polymer, N-(2-hydroxypropyl)-3-trimethylammonium chitosan chloride
(HTCC), and a bioadhesive polymer, polydextran aldehyde. The gels
were shown to be active against both Gram-positive and Gram-negative
bacteria, including drug-resistant ones such as methicillin-resistant Staphylococcus aureus (MRSA), vancomycin-resistant Enterococcus faecium (VRE), and β-lactam-resistant Klebsiela pneumoniae. Mechanistic studies revealed that
the gels killed bacteria upon contact by disrupting the membrane integrity
of the pathogen. Importantly, the gels were shown to be efficacious
in preventing sepsis in a cecum ligation and puncture (CLP) model
in mice. While only 12.5% of animals survived in the case of mice
with punctured cecam but with no gel on the punctured area (control),
62.5% mice survived when the adhesive gel was applied to the punctured
area. Furthermore, the gels were also shown to be effective in facilitating
wound healing in rats and ceasing bleeding from a damaged liver in
mice. Notably, the gel showed negligible toxicity toward human red
blood cells (only 2–3% hemolysis) and no inflammation to the
surrounding tissue upon subcutaneous implantation in mice, thus proving
it as a safe and effective antibacterial sealant.