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Hamid Emadi

Hamid Emadi

Academic rank: Assistant Professor
ORCID: 7264-۲۷۶۴-۰۰۰۲-0000
Education: PhD.
ScopusId: 36701357400
HIndex:
Faculty: Faculty of Chemistry
Address: University of Mazandaran
Phone: 011-35302344

Research

Title
Development of an antibacterial and antioxidative nanofbrous membrane using curcumin-loaded halloysite nanotubes for smart wound healing: In vitro and in vivo studies
Type
JournalPaper
Keywords
Polyamide 6, Hyaluronic acid, Halloysite nanotube, Curcumin, Electrospinning, Wound dressing
Year
2023
Journal International Journal of Pharmaceutics
DOI
Researchers Mohamadreza Shakiba ، Mehdi Sheikhi ، Zohreh Pahnavar ، Alireza Tajiki ، Ashkan Bigham ، Amin Foroozandeh ، Sepehr Darvishan ، Mehrab Pourmadadi ، Hamid Emadi ، Javad Rezatabar ، Hamidreza Abdouss ، Majid Abdouss

Abstract

Endowing wound dressings with drug delivery capability is a suitable strategy to transfer medicinal compounds locally to damaged skin layers. These dressings are especially useful for accelerating the healing rate in the cases of long-term treatment, and adding more functionalities to the platform. In this study, a wound dressing composed of polyamide 6, hyaluronic acid, and curcumin-loaded halloysite nanotubes (PA6/HA/HNT@Cur) was designed and fabricated for wound healing applications. The physicochemical properties of this platform were investigated through Fourier-transform infrared spectroscopy and feld-emission scanning electron microscopy. Moreover, wettability, tensile strength, swelling, and in vitro degradation were assessed. The HNT@Cur was incorporated in the fbers in three concentrations and 1 wt% was found as the optimum concentration yielding desirable structural and mechanical properties. The loading effciency of Cur on HNT was calculated to be 43 ± 1.8%, and the release profles and kinetics of nanocomposite were investigated at physiological and acidic pH. In vitro antibacterial and antioxidation studies showed that the PA6/HA/HNT@Cur mat had strong antibacterial and antioxidation activities against gram-positive and -negative pathogens and reactive oxygen species, respectively. Desirable cell compatibility of the mat was found through MTT assay against L292 cells up to 72 h. Finally, the effcacy of the designed wound dressing was evaluated in vivo; after 14 days, the results indicated that the wound size treated with the nanocomposite mat signifcantly decreased compared to the control sample. This study proposed a swift and straightforward method for developing materials that might be utilized as wound dressings in clinical settings.