Assessment of Centella Asiatica Extract Containing Dual-crosslinked Gel-MA/Pec Hydrogels as Wound Dressing

In the present work, 3D-printed wound dressings containing different amounts of Centella Asiatica extract were synthesized via dual-crosslinking method. Methacrylic anhydride modified gelatin (Gel-MA) and pectin (Pec) were chosen as the base material for dressings. A dual crosslinked network was formed with Gel-MA photo-crosslinking using Irgacure 2959 and Pectin (Pec) psychical-crosslinking using Ca++ ions. Meanwhile, the developed dual-crosslinked hydrogel dressings were characterized by Fourier transform infrared spectroscopy, scanning electron microscopy, and mechanical, swelling, in vitro degradation as well as ex vivo bioadhesion tests. It has been observed that the preapred dressings provide good bioadhesion on the chicken skin. Moreover, MTT assay revealed cell viability of Gel-MA/Pec hydrogel dressings containing Centella Asiatica extract. The results presented the dressings as a promising biomaterial to be used for wound healing purposes, which should be further investigated in future

Photocurable silk fibroin-based tissue sealants with enhanced adhesive properties for the treatment of corneal perforations

Corneal defects are associated with corneal tissue engineering in terms of vision loss. The treatment of corneal defects is an important clinical challenge due to a uniform corneal thickness and the apparent lack of regenerative ability. In this work, we synthesized a biocompatible and photocrosslinkable ocular tissue adhesive composite hydrogel prepared by using methacrylated gelatin (GelMA), which is called the most favorable derivative of gelatin used as a tissue adhesive, silk fibroin (SF), and GelMA/SF (GS) with high adhesion behaviours for use in corneal injuries. The adhesion behaviours of the materials prepared in the presence of silk fibroin were improved. Importantly, the effect of different UV curing times on the adhesion properties of the prepared materials was also investigated. The prepared GS tissue adhesives showed high physiological adhesion. GS can be modulated to increase its adhesive strength up to 3 times compared to G. GS was also found to be biocompatible and have a high healing potential. In addition, the obtained transmission value of GS is also close to that of the human cornea. GS supported cellular adhesion and proliferation. The burst pressure strength for fresh cornea of the GS-60s sealants (144.5 ± 13 kPa) was determined to be higher than that of the G-60s sealants (52.6 ± 33.5 kPa)

Aloe vera-based antibacterial porous sponges for wound dressing applications

The antibacterial sponges with high macroporosity, high interconnectivity and high biocompatibility is a significant concern for wound healing applications. In this work, novel Aloe vera (AV) based sponges were developed via subsequent lyophilization with further chemical crosslinking throughout the double network sponges. Single network was composed of gelatin-sodium alginate (G-SA) while the double network using gelatin-sodium alginate- sodium hyaluronate (G-SA-HA) was produced with the addition of hyaluronic acid solution into the gelatin-sodium alginate matrix. Lastly, Aloe vera as the bioactive agent was fabricated throughout the gelatin-sodium alginate-sodium hyaluronate matrix. The AV-based sponges demonstrated large pores with high interconnectivity. The swelling degree of the AV-based sponges were higher than that of G-SA and G-SA-HA sponges. The release of AV from the sponges reached an equilibrium value after 24 h showing a more controlled release at pH 5.5 than at pH 7.4. AV-based sponges showed antibacterial activity against Staphylococcus aureus, Enterococcus faecalis, Streptococcus pneumoniae and Bacillus cereus and displayed any cytotoxicity against Mesenchymal stem cells.Hitit University ; Hitit University Scientific and Tecnical Application and Research Cente

The comparison of contribution of GO and rGO produced by green synthesis to the properties of CMC-based wound dressing material

Herein, GO (graphene oxide) or rGO (reduced graphene oxide) which is produced by the green synthesis method using plant extract (Laurus nobilis) was incorporated into a polymeric structure consisting of carboxymethyl cellulose (CMC) and polyethylene glycol (PEG) to produce a wound dressing material with enhanced mechanical and electrical properties. The effect of GO and rGO on the wound dressing features of the produced materials was investigated and compared to each other. Conductivity tests demonstrated that rGO contributed more significantly to the electrical conductivity than GO. While rGO-CMC/PEG/CA reached 3.01 × 10−6 S.cm−1 as the conductivity value, that of GO-CMC/PEG/CA was determined as 0.85 × 10−6 S.cm−1. As for the mechanical tests, it was seen that rGO achieved the best results in terms of elastic modulus (588.62 N/mm2), tensile strength (94.95 MPa) and elongation at break (17.64 %) compared to GO reinforced and pure hydrogel. Curcumin and ascorbic acid were used for antibiotic-free wound treatment and their release kinetics were also modeled. The results showed that rGO reinforced hydrogel provided a more controlled release. All results assured that both the produced GO reinforced and especially rGO reinforced hydrogels could be utilized as modern wound dressing materials with suitable properties to achieve remarkable results for wound healing