posted on 2021-02-23, 18:35authored byBonda
Rama Rao, Rajnish Kumar, Shagufta Haque, Jerald Mahesh Kumar, T. Nageswara Rao, Raju V. S. N. Kothapalli, Chitta Ranjan Patra
There
have been reports of different types of wound dressings for
various functions and purposes. Cotton being one of the most widely
used wound dressing material due to its non-toxic, biodegradable,
and other properties is used for fabrication as well as in the form
of scaffolds for faster and effective wound closure. Our research
team has already demonstrated the role of silver nitroprusside nanoparticles
(SNPNPs) for wound healing and antibacterial activity. In the current
study, we have developed cotton fabric impregnated with SNPNPs (SNPCFs)
which remain photo inert and displayed long-term antimicrobial activity
due to the surface modification with the silver nitroprusside complex.
These SNPCFs were characterized by various analytical techniques (XRD,
FTIR, UV spectroscopy, TGA, TEM, FESEM, EDAX, ICP−OES). The
fabricated cotton dressings with nanoparticles showed an improved
water contact angle (113–130°) than that of bare cotton
gauze (60°) and exhibited more antibacterial property in case
of both Gram-negative bacteria (Klebsiella aerogenes and Escherichia coli) and Gram-positive
bacteria (Pseudomonas aeruginosa and Bacillus subtilis) even after several washings. The
biocompatible nature of SNPCFs was assessed by in vivo chorioallantoic membrane assay that showed no obstruction in the
formation of blood vessels. The SNPCFs exhibited better wound healing
activity compared to the bare cotton and AgCFs as observed in the
C57BL6/J mouse. The histopathological investigation reveals increase
in re-epithelialization and deposition of connective tissue. The macrophage
(M2) counts in SNPCF-treated skin tissues were supportive of more
wound healing activity than mice treated with cotton fabric impregnated
with chemically synthesized silver nanoparticles. Based on biodistribution
analysis using ICP–OES, the data illustrated that a significant
amount of silver is absorbed in the skin tissues of mice as compared
to the blood and kidney. Furthermore, the absence of silver from the
vital organs (heart, liver, and kidney) corroborates our hypothesis
that the SNPCFs can act excellently in treating wounds when topically
applied over skin. Thereafter, all these results highlight a strong
possibility that SNPCFs exemplify the potential as a new antimicrobial
and wound healing agent in future times.