Electrospun nanofibers synthesized from polymers incorporated with bioactive compounds for wound healing

The development of innovative wound dressing materials is crucial for effective wound care. It's an active area of research driven by a better understanding of chronic wound pathogenesis. Addressing wound care properly is a clinical challenge, but there is a growing demand for advancements in this field. The synergy of medicinal plants and nanotechnology offers a promising approach to expedite the healing process for both acute and chronic wounds by facilitating the appropriate progression through various healing phases. Metal nanoparticles play an increasingly pivotal role in promoting efficient wound healing and preventing secondary bacterial infections. Their small size and high surface area facilitate enhanced biological interaction and penetration at the wound site. Specifically designed for topical drug delivery, these nanoparticles enable the sustained release of therapeutic molecules, such as growth factors and antibiotics. This targeted approach ensures optimal cell-to-cell interactions, proliferation, and vascularization, fostering effective and controlled wound healing. Nanoscale scaffolds have significant attention due to their attractive properties, including delivery capacity, high porosity and high surface area. They mimic the Extracellular matrix (ECM) and hence biocompatible. In response to the alarming rise of antibiotic-resistant, biohybrid nanofibrous wound dressings are gradually replacing conventional antibiotic delivery systems. This emerging class of wound dressings comprises biopolymeric nanofibers with inherent antibacterial properties, nature-derived compounds, and biofunctional agents. Nanotechnology, diminutive nanomaterials, nanoscaffolds, nanofibers, and biomaterials are harnessed for targeted drug delivery aimed at wound healing. This review article discusses the effects of nanofibrous scaffolds loaded with nanoparticles on wound healing, including biological (in vivo and in vitro) and mechanical outcomes.

Immunobiology of foreign body response to composite PLACL/gelatin electrospun nanofiber meshes with mesenchymal stem/stromal cells in a mouse model: Implications in pelvic floor tissue engineering and regeneration

Pelvic Organ Prolapse (POP) is a common gynaecological disorder where pelvic organs protrude into the vagina. While transvaginal mesh surgery using non-degradable polymers was a commonly accepted treatment for POP, it has been associated with high rates of adverse events such as mesh erosion, exposure and inflammation due to serious foreign body response and therefore banned from clinical use after regulatory mandates. This study proposes a tissue engineering strategy using uterine endometrium-derived mesenchymal stem/stromal cells (eMSC) delivered with degradable poly L-lactic acid-co-poly ε-caprolactone (PLACL) and gelatin (G) in form of a composite electrospun nanofibrous mesh (P + G nanomesh) and evaluates the immunomodulatory mechanism at the material interfaces. The study highlights the critical acute and chronic inflammatory markers along with remodelling factors that determine the mesh surgery outcome. We hypothesise that such a bioengineered construct enhances mesh integration and mitigates the Foreign Body Response (FBR) at the host interface associated with mesh complications. Our results show that eMSC-based nanomesh significantly increased 7 genes associated with ECM synthesis and cell adhesion including, Itgb1, Itgb2, Vcam1, Cd44, Cdh2, Tgfb1, Tgfbr1, 6 genes related to angiogenesis including Ang1, Ang2, Vegfa, Pdgfa, Serpin1, Cxcl12, and 5 genes associated with collagen remodelling Col1a1, Col3a1, Col6a1, Col6a2, Col4a5 at six weeks post-implantation. Our findings suggest that cell-based tissue-engineered constructs potentially mitigate the FBR response elicited by biomaterial implants. From a clinical perspective, this construct provides an alternative to current inadequacies in surgical outcomes by modulating the immune response, inducing angiogenesis and ECM synthesis during the acute and chronic phases of the FBR.

Micro/nanofibrous nonwovens with high filtration performance and radiative heat dissipation property for personal protective face mask

The COVID-19 pandemic and airborne particulate matter (PM) pollution have posed a great threat to human health. Personal protective face masks have become an indispensable protective equipment in our daily lives. However, wearing conventional face masks for a long time cause swelter and discomfort on the face. Introducing thermal comfort into personal protective face masks becomes desirable. Herein, face masks that show excellent filtration performance and radiative heat dissipation effect are successfully designed and prepared by electrospining Nylon-6 (PA) nanofibers onto polyethylene (PE) meltblown nonwovens. The resultant PE/PA nonwovens have high PM filtration efficiency (>99%) with a low pressure drop (<100 Pa). Moreover, taking the advantage of the property of PE, the designed face mask posses high mid-infrared (mid-IR) transmittance and brings about high radiative cooling power, resulting in effective heat dissipation performance. This face mask design may provides new insights into the development of thermal comfort materials for personal protection.

Application of reusable flat-membrane in electro-membrane extraction for tamsulosin hydrochloride determination in cleaning validation samples of sterile production line equipment by RP-HPLC

In order to ensure compliance with the current Good Manufacturing Practice (cGMP), cleaning process of pharmaceutical manufacturers should be validated. This study was aimed to utilize a reusable flat-membrane in the electromembrane extraction (EME) for isolation of tamsulosin hydrochloride (TMS) from rinse samples of sterile production of pharmaceutical line. Moreover, validation of mentioned method was done. The residual concentration of TMS was determined by RP-HPLC. Effective parameters such as pH, applying voltage and extraction time were optimized individually. Optimum conditions were found 12, 100 V and 10 min for pH, applying voltage and extraction time, respectively. Figures of merit were calculated under optimum conditions, therefore, linear range and limit of detection (LOD) were obtained 0.5-1000 ng mL^-1 with a good coefficient of determination (R²=0.9901) and 0.05 ng mL^-1, respectively. Last but not least, RSD of determination was found 0.67% which shows a satisfactory repeatability. According to the obtained results, proposed method is a precise, accurate, relatively fast and applicable route to determine TMS concentrations in rinse samples.

Nanofibrous Mineralized Electrospun Scaffold as a Substrate for Bone Tissue Regeneration

Fibrous scaffolds that reconstruct the extracellular matrix (ECM) have been utilized for tissue regeneration demonstrated potential for guiding stem cell differentiation. Nanofibrous scaffolds fabricated by a unique electrospinning method enabled us to create tailored, functional scaffolds on-demand. Several patterned electrospun poly(ε-caprolactone) (PCL) scaffolds were prepared, and then utilized for creating a hybrid composite in which bone-like hydroxyapatite (b-HA) was deposited onto the unique electrospun scaffolds. The mineral deposits onto the patterned PCL scaffolds was confirmed by scanning electron microscope (SEM). When culturing human adipose-derived stem cells (hASC) onto the different SBF-treated electrospun PCL scaffolds, it was found that the hybrid composite can support hASC differentiated into osteoblasts under osteogenic differentiation conditions. Image analysis and alamar blue assay indicated a significant increase of hASC adhesion and proliferation on the SBF-treated PCL scaffolds. Subsequent analysis of osteogenic potential by via gene expression analysis and alkaline phosphatase (ALP) activity also demonstrated that the SBF-treated electrospun PCL made by the modified electrospinning process is more favorable for the osteogenic differentiation hASCs. Additionally, results of alizarin red S staining and ALP staining at days 7 and 14 showed improved deposition of mineralized matrix on the SBF-treated PCL. Therefore, this study indicates that the facile scaffold fabrication method described in this study is promising approach to prepare osteoconductive scaffold for bone tissue engineering.