Multifunctional Casein-Based Wound Dressing Capable of Monitoring and Moderating the Proteolytic Activity of Chronic Wounds

Bacteria-triggered on-demand thymol release for salmon preservation: A self-destructive antibacterial strategy

To prevent foodborne pathogen invasion in fresh meat during storage, this study develops an enzyme/redox dual-responsive nanomaterial (Thy@MSN-S-S-Casein). Upon encountering bacteria, the casein shell is degraded by bacterial proteases, and glutathione (GSH) cleaves the disulfide bonds on the mesoporous silica nanoparticle (MSN) surface, releasing thymol to combat the bacteria. Trypsin and GSH triggered a cumulative release of 68.37 % thymol from Thy@MSN-S-S-Casein within 48 h, which was significantly higher than the release by trypsin alone (49.93 %) or without any activation (17.33 %). The antibacterial activities of Thy@MSN-S-S-Casein can be triggered by both artificially inoculated bacteria and naturally-infected bacteria on the salmon surfaces, leading to a reduction in the total viable count (TVC) in both experiments. Additionally, it inhibited the deterioration of the salmon fillets' quality indicators and extended their shelf life by about 3 days. This bacteria-triggered release strategy offers a promising self-destructive antibacterial approach for mitigating pathogen outbreaks in food preservation.

Protein-Based Multifunctional Hydrogel Adhesive for Wound Healing

Wound healing is a complex and highly orchestrated biological process that encompasses four distinct stages including: hemostasis, inflammation, proliferation, and remodeling. Each stage is characterized by specific physiological responses and tissue repair mechanisms that collectively facilitate the restoration of tissue integrity. To achieve comprehensive wound management, the development of targeted hydrogel bioadhesives is of paramount importance. Hydrogel-based bioadhesives, characterized by their excellent physical properties and biocompatibility, have demonstrated significant potential in the field of wound treatment. However, the current research on protein-based hydrogel bioadhesives for wound healing remains limited. This review systematically examines the design principles of ideal hydrogel bioadhesives and their essential functions in wound repair. It provides an overview of the latest advancements multifunctional hydrogel bioadhesives derived from various proteins, including collagen, silk fibroin (SF), sericin, fibrin, gelatin (Gel), keratin, and casein. It also evaluates their performance in practical applications. Finally, the review highlights the primary challenges facing protein-based hydrogel bioadhesives in the field of wound healing and outlines prospective research directions, with the goal of advancing the development and clinical application of these technologies.

Nanocellulose Wound Dressings with Integrated Protease Sensors for Detection of Wound Pathogens

Wound infections result in delayed healing, morbidity, and increased risks of sepsis. Early detection of wound infections can facilitate treatment and reduce the need for the excessive use of antibiotics. Proteases are normally active during the healing process but are overexpressed during infection as part of the inflammatory response. Proteases are also produced by the bacteria infecting the wounds, making proteases a highly relevant biomarker for infection monitoring. Here, we show a fluorescence turn-on sensor for real-time monitoring of protease activity in advanced nanocellulose wound dressings for rapid detection of wound pathogens. Colloidal gold nanoparticles (AuNPs) were adsorbed on bacterial cellulose (BC) nanofibrils by using a carefully optimized self-assembly process. The AuNPs could either be homogeneously incorporated in BC dressings or 3D printed in wood-derived cellulose nanofiber (CNF) dressings using a BC-AuNP ink. The BC-adsorbed AuNPs were subsequently functionalized with fluorophore-labeled protease substrates. Cleavage of the substrates by proteases produced by the wound pathogens Staphylococcus aureus and Pseudomonas aeruginosa resulted in a significant increase in fluorescence that correlated with the growth phase of the bacteria. Wound dressing with integrated sensors for the detection of proteolytic activity can enable the sensitive and rapid detection of infections, allowing for optimization of treatment and reducing the risks of complications.

Casein-based film enriched with lignin as a biodegradable substrate for enzyme immobilization

In the last decades, the negative impact of petroleum derived materials on the environment is more and more evident; beyond the unavoidable reduction in the use of classical plastic, another promising approach is the development of alternative materials prepared starting from natural, biodegradable, and more sustainable biomolecules, particularly undervalued or discarded ones. Caseins are the most abundant proteins in milk, with important nutritional value but also interesting film-forming properties. Lignin is a polyphenolic polymer found in wood and derived from a by-product of the cellulose extraction processes; it is well known for its antibacterial, antioxidant, and UV-protecting properties. In the present work, casein was isolated from UHT skimmed bovine milk through acidification and used alone or in combination with lignin to produce films that are biodegradable and environmentally friendly. Casein and casein-lignin films presented a thickness in the range of 180-260 μm and a compact, non-porous texture. The presence of lignin did not affect the morphology of the films but influenced their mechanical properties. For casein and casein-lignin films covalently crosslinked with transglutaminase (TGM), the solubility decreased to 40-50% and the samples retained their shape. The results show that TGM-containing films are suitable as substrates for the immobilization of enzymes; herein, the FAD-dependent glucose oxidase from Aspergillus niger was added to the film and the enzyme remained stable and active against glucose for weeks, as demonstrated by the colorimetric detection of the H2O2 produced in the catalysed reaction. This study opens up the possibility of combining two products of natural origin for the production of films through processes with low environmental impact, thus offering interesting scenarios in the immobilization of macromolecules for the detection of target molecules.

A Comparative Study on the Structural, Physicochemical, Release, and Antioxidant Properties of Sodium Casein and Gelatin Films Containing Sea Buckthorn Oil

The aim of this study was to compare the effect of increasing concentrations (0, 1, 2, 4%) of sea buckthorn oil (SBO) on the structural, physicochemical, release, and antioxidant properties of glycerol-plasticized sodium casein (NaCAS) and gelatin (GEL) films. Ultrasonic treatment ensured effective homogenization of SBO in both types of emulsions, resulting in yellow-tinted semi-opaque films with relatively low micro-roughness. Generally, GEL films demonstrated lower UV barrier properties and solubility but exhibited higher compactness, crystallinity, transparency, surface hydrophobicity, oxygen barrier performance, strength, and antiradical activity compared to their NaCAS-based counterparts. In a concentration-dependent manner, SBO decreased the solubility and water absorption of the gelatin-based film and enhanced its oxygen permeability. Conversely, SBO improved the water vapor barrier properties of both films in a concentration-independent manner. At the highest SBO concentration, the tensile strength of NaCAS- and GEL-based films decreased by 27% and 20%, respectively, while their antiradical activity increased by 9.3× and 4.3× (based on the time required for the half-neutralization of 2,2-diphenyl-1-picrylhydrazyl radicals). Migration studies showed that at the lowest concentration, SBO was released (into 95% ethanol) approximately 2× faster from the GEL-based film than from the NaCAS film, whereas at higher concentrations, the trend reversed.

Effect of low degree succinylation on properties of enzyme-induced casein hydrogel

This study examines the impact of succinic anhydride (SA) modification (0-9 %) on the gel properties of casein. Upon succinylation, the surface hydrophobicity (H0) of casein initially increased before decreasing, achieving its peak at a degree of succinylation of 5.22 ± 0.16 %. The α-helix content rose to 14.13 ± 2.60 %, and the -OH peak shifted towards lower wavenumbers, suggesting enhanced hydrogen bonding within intra/intermolecular structures. The storage modulus in the rheological test escalated from 2160.11 Pa to 5047.60 Pa, and SEM analysis revealed that the optimally succinylated casein gel formed a denser and more stable gel network structure. Moreover, succinylated casein hydrogels demonstrated superior texture properties, swelling ability, and thermal stability. Molecular dynamics simulation (MD) results suggest that SA preferentially binds to LYS27 and LYS28 of β-casein via hydrogen bonds and amide bonds, respectively. The interaction between modified proteins is primarily governed by hydrogen bonds, aligning with FT-IR findings. PCA analysis identified a positive correlation between the ordered structure and gel performance. This research offers theoretical insights and reference data for modulating casein hydrogel properties through succinylation.

Collagen-Based Nanoparticles as Drug Delivery System in Wound Healing Applications

Background

Conventional wound dressings often adhere to wounds and can cause secondary injury due to their lack of anti-inflammatory and antibacterial properties. In contrast, collagen-based nanoparticles (NPs) as drug delivery systems exhibit both biocompatibility and biodegradability, presenting a promising avenue for accelerating wound healing processes.

Aims of Study

This review aims to provide a comprehensive overview of the mechanisms involved in wound healing, description of the attributes of ideal wound dressings, understanding of wound healing efficacy of collagen, exploring NPs-mediated drug delivery mechanisms in wound therapy, detailing the synthesis and fabrication techniques of collagen-based NPs, and delineating the applications of various collagen-based NPs infused wound dressings on wound healing.

Methodology

This review synthesizes relevant literature from reputable databases such as Scopus, Science Direct, Google Scholar, and PubMed.

Results

A diverse array of collagen-based NPs, including nanopolymers, metal NPs, nanoemulsions, nanoliposomes, and nanofibers, demonstrate pronounced efficacy in promoting wound closure and tissue regeneration. The incorporation of collagen-based NPs has not only become an agent for the delivery of therapeutics but also actively contributes to the wound healing cascade.

Conclusion

In conclusion, In brief, the use of collagen-based NPs presents a compelling strategy for expediting wound healing processes.

Milk exosome-infused fibrous matrix for treatment of acute wound

To provide an advanced therapy for wound recovery, in this study, pasteurized bovine milk-derived exosomes (mEXO) are immobilized onto a polydopamine (PDA)-coated hyaluronic acid (HA)-based electrospun nanofibrous matrix (mEXO@PMAT) via a simple dip-coating method to formulate an mEXO-immobilized mesh as a wound-healing biomaterial. Purified mEXOs (∼82 nm) contain various anti-inflammatory, cell proliferation, and collagen synthesis-related microRNAs (miRNAs), including let-7b, miR-184, and miR-181a, which elicit elevated mRNA expression of keratin5, keratin14, and collagen1 in human keratinocytes (HaCaT) and fibroblasts (HDF). The mEXOs immobilized onto the PDA-coated meshes are gradually released from the meshes over 14 days without burst-out effect. After treatment with HaCaT and HDF, the degree of in vitro cell migration increases significantly in the mEXO@PMAT-treated HaCaT and HDF cells compared to the unmodified or PDA-coated meshes-treated cells. Additionally, the mEXO@PMAT provides significantly faster wound closure in vivo without notable toxicity. Thus, the sustained liberation of bioactive mEXO from the meshes can effectively enhance cell proliferation in vitro and accelerate wound closure in vivo, which could be harnessed mEXO@PMAT as a promising wound-healing biomaterial.

Incorporating silver nanoparticles into electrospun nanofibers of casein/polyvinyl alcohol to develop scaffolds for tissue engineering

Developing novel antimicrobial wound dressings that have the potential to address the challenges associated with chronic wounds is highly imperative in providing effective infection control and wound healing support. Biocompatible electrospun nanofibers with their high porosity and surface area enabling efficient drug loading and delivery have been investigated in this regard as viable candidates for chronic wound care. Here, we design Casein/Polyvinyl alcohol (CAN/PVA) nanofibers reinforced with silver nanoparticles (Ag NPs) by the electrospinning technique to develop diabetic wound healing scaffolds. The prepared samples were characterized using spectroscopic and electron microscopic techniques. The biocompatibility of the polymer samples were assessed using 3 T3 fibroblast cell lines and the maximum cell viability was found to 95 % at a concentration of 50 μg/mL for the prepared nanofibers. Scratch assay tests were also performed to analyze the wound healing activity of the nanofibers wherein they demonstrated increased migration and proliferation of fibroblast 3 T3 cells. Moreover, these nanofibers also exhibit antibacterial efficiency against Gram-negative bacteria, Escherichia coli (E.coli). Therefore, the antimicrobial nature of the electrospun nanofibers coupled with their moisture absorption properties and wound healing ability render them as effective materials for wound dressing applications.