Treatment Of Skin Wounds Research Articles

Near-Field Coupling Resonance Enhancement with AuNiO Heterostructure Nanosheets For High-performance Photodynamic/Photothermal Hybrid Antibacterial & Imaging Tracking

Bacterial infection has always been a serious public health problem worldwide. Real-time microbial monitoring in the trauma resuscitation unit is crucial for infection control and plays an essential role in all aspects of wound treatment clinical practice, such as identification and evaluation of wound infection, diagnosis of wound infection, and topical antimicrobial treatment. Herein, gold-loaded nickel oxide nanosheets (Au-NiO NSs) prepared by hydrothermal and laser-assisted synthesis methods are used as fluorescent nanoprobes to rapidly detect and target bacteria at an early stage, and then achieve combined PTT and PDT to inactivate bacteria under sunlight. Optical detection, electronic structure and plasma local field analysis show that there is charge transfer between Au10-O-NiO through the O-Au-O bond, and effectively improves the plasmon effect through resonant energy transfer, achieving higher photothermal conversion efficiency. The detection limits of Staphylococcus aureus and Pseudomonas aeruginosa are as low as 145.6 and 157.7 cfu/mL, respectively, and the sterilization rates are both above 99%. In addition, Au-NiO NSs have low cytotoxicity, and the nanocomposite dressing prepared by combining Au−NiO NSs with hydrogels demonstrates the ability to monitor and kill pathogens in situ in the treatment of skin wounds. The platform integrates the targeting, imaging and inactivation capabilities of bacteria, showing great application potential in the field of bacterial diagnosis and treatment.

Dermatological Nanotechnology: Gelatin films with O/W emulsions for skin lesion repair.

The development of films, scaffolds, hydrogels, and other innovations based on biopolymers for the treatment of skin injuries is on the rise. Therefore, it is important to focus on their functionality, influence on human use, and environmental impact. This work investigates the antimicrobial capacity of gelatin films that incorporate O/W emulsions encapsulating bactericidal and healing active ingredients (EA). Their biocompatibility was evaluated in vitro in human skin keratinocyte and murine fibroblast cell cultures, as well as in vivo using the zebrafish model. Finally, its potential to heal wounds was assessed through a keratinocyte cell migration assay. The EA films exhibited antimicrobial activity against Pseudomonas aeruginosa and Staphylococcus aureus. The films were biocompatible with monolayer cultures, without affecting cell viability, metabolic activity, or membrane integrity. The films did not exhibit general toxicological effects in zebrafish nor specific organ toxicity in the heart, liver, or brain. Further, the EA films promoted keratinocyte migration in the wound healing assay. In conclusion, the films could be used as a potential treatment for various types of skin injuries, being safe for both potential human application and the environment after use and disposal.

An antimicrobial blue light prototype device controls infected wounds in a preclinical porcine model.

We developed a translational prototype antimicrobial blue light (ABL) device for treating skin wounds with ABL. Partial-thickness surgical wounds were created in live swine, an animal whose skin is considered the most like human skin, then heavily contaminated and left untreated for 24 hours with methicillin-resistant Staphylococcus aureus (MRSA). ABL treatment stabilized and reduced MRSA infection by greater than four orders of magnitude (>99.99%; p<0.0001) compared with untreated wounds in the same animal, after only two daily treatments. These data support further development of such devices for controlling infection in skin wounds. ABL, with or without concomitant administration of negative pressure, antimicrobials, or photosensitizers, could play an important role in modern wound care by reducing the amount, duration, and cost of antibiotics needed, helping reduce AMR. No such device for treating human cutaneous wounds currently exists. This deserves further development and study.

Multifunctional Dual Nano-MOF-Modified Decellularized Small Intestinal Submucosa Membrane Accelerates Healing of Infected Wound.

The treatment of complex or chronic skin wounds caused by burns, trauma, surgery, and genetic disorders has been a worldwide challenge. Small intestinal submucosa (SIS) is a biological material that is widely used in wound healing. How to further expand the wound healing application of SIS, especially in repairing infected wounds, remains a hot research topic for many tissue engineering and biomaterial scholars focusing on skin regeneration. This study uses nanometal-organic frameworks (nano-MOFs), which have not been applied to modify the SIS membrane before, to construct multifunctional dual nano-MOFs @ SIS membrane (dnMOF@SISm). Nano-MOFs are functionalized onto the nanofiber of SIS via in situ self-assembly under mild reaction conditions without any toxic reagent or complex instruments. The dnMOF@SISm can release Co2+, Zn2+, and bioactive factors, participating in the whole stage of the repair of infected wounds. In vitro, it can regulate the biological activities of various functional cells such as fibroblasts, endothelial cells, and macrophages and shows good antibacterial ability. In the infected full-thickness skin defect rat model, dnMOF@SISm can release metal ions and ligands, killing pathogenic bacteria colonized on the wound surface at the first stage, and then trigger and accelerate the skin repair process via angiogenesis, immune regulation, and collagen deposition. Above all, an efficient, nontoxic, mild self-assembly strategy realizes the functionalization of dual nano-MOFs on the nanofiber of SIS to expand its clinical application scenarios, especially in infected wounds.

Cord Blood Platelet Lysate-Loaded Thermo-Sensitive Hydrogels for Potential Treatment of Chronic Skin Wounds.

Chronic skin wounds (CSWs) are a worldwide healthcare problem with relevant impacts on both patients and healthcare systems. In this context, innovative treatments are needed to improve tissue repair and patient recovery and quality of life. Cord blood platelet lysate (CB-PL) holds great promise in CSW treatment thanks to its high growth factors and signal molecule content. In this work, thermo-sensitive hydrogels based on an amphiphilic poly(ether urethane) (PEU) were developed as CB-PL carriers for CSW treatment. A Poloxamer 407®-based PEU was solubilized in aqueous medium (10 and 15% w/v) and added with CB-PL at a final concentration of 20% v/v. Hydrogels were characterized for their gelation potential, rheological properties, and swelling/dissolution behavior in a watery environment. CB-PL release was also tested, and the bioactivity of released CB-PL was evaluated through cell viability, proliferation, and migration assays. PEU aqueous solutions with concentrations in the range 10-15% w/v exhibited quick (within a few minutes) sol-to-gel transition at around 30-37 °C and rheological properties modulated by the PEU concentration. Moreover, CB-PL loading within the gels did not affect the overall gel properties. Stability in aqueous media was dependent on the PEU concentration, and payload release was completed between 7 and 14 days depending on the polymer content. The CB-PL-loaded hydrogels also showed biocompatibility and released CB-PL induced keratinocyte migration and proliferation, with scratch wound recovery similar to the positive control (i.e., CB-PL alone). The developed hydrogels represent promising tools for CSW treatment, with tunable gelation properties and residence time and the ability to encapsulate and deliver active biomolecules with sustained and controlled kinetics.

Thymoquinone-Incorporated CollaGee Biomatrix: A Promising Approach for Full-Thickness Wound Healing.

Wound infection is the leading cause of delayed wound healing. Despite ongoing research, the ideal treatment for full-thickness skin wounds is yet to be achieved. Skin tissue engineering provides an alternative treatment, with the potential for skin regeneration. Background/Objectives: Previously, we characterized a collagen-gelatin-elastin (CollaGee) acellular skin substitute and evaluated its cytocompatibility. The assessments revealed good physicochemical properties and cytocompatibility with human dermal fibroblasts (HDF). This study aimed to incorporate thymoquinone (TQ) as the antibacterial agent into CollaGee biomatrices and evaluate their cytocompatibility in vitro. Methods: Briefly, dose-response and antibacterial studies were conducted to confirm the antimicrobial activity and identify the suitable concentration for incorporation; 0.05 and 0.1 mg/mL concentrations were selected. Then, the cytocompatibility was evaluated quantitatively and qualitatively. Results: Cytocompatibility analysis revealed no toxicity towards HDFs, with 81.5 + 0.7% cell attachment and 99.27 + 1.6% cell viability. Specifically, the 0.05 mg/mL TQ concentration presented better viability, but the differences were not significant. Immunocytochemistry staining revealed the presence of collagen I, vinculin, and alpha smooth muscle actin within the three-dimensional biomatrices. Conclusions: These results suggest that TQ-incorporated CollaGee biomatrices are a promising candidate for enhancing the main key player, HDF, to efficiently regenerate the dermal layer in full-thickness skin wound healing. Further investigations are needed for future efficiency studies in animal models.

Morphological characteristics of wound healing with aloe extract, hydrogel, and their combination: experimental research

BACKGROUND: Currently, there remains a high incidence of skin damage due to trauma, chronic diseases, burns, so it is important to study the issues of regeneration and treatment of skin wounds. AIM: To conduct a morphological analysis of wound healing using aloe extract, hydrogel, and their combination in the experiment. MATERIALS AND METHODS: The study involved 40 sexually mature guinea pigs, which were divided into a control group and 4 experimental groups (independent wound healing, application of aloe extract, hydrosorb gel, layer-by-layer application of drugs). Histological skin preparations were prepared on days 3, 7, 14, and 28 of the experiment. In each microslide, in 10 fields of view of the microscope at a magnification of ×50, morphometric parameters were measured in micrometers (µm): the thickness of the purulent-necrotic scab, inflammatory (leukocyte) infiltrate, granulation tissue, the length of the newly formed epithelium on days 3, 7, 14; the thickness of the epithelium, its length and the thickness of the connective tissue in the central part of the regenerate on the 28th day. All data were subjected to statistical processing. RESULTS: The medications led to a decrease in the inflammatory reaction, acceleration of the formation of granulation tissue, and partial wound epithelization by day 7 of the experiment; however, more pronounced signs of wound healing were observed with layer-by-layer application of aloe extract and hydrogel. By day 14, regardless of the application method, the use of medications demonstrated signs of enhanced wound healing. Thus, the length of the epithelium increased by 1.2–1.6 times, the depth of granulation tissue increased by 1.0–1.2 times compared to the control group. By the end of the experiment, all animals had complete closure of the wound with scar formation, while in the experimental groups showed signs of skin remodeling with appendages. CONCLUSION: Morphological analysis showed that aloe extract, hydrosorb gel, and their combination accelerated the wound healing processes of full-thickness skin wounds in the experiment.

Recent advances in the application of functional hydrogels in skin wound healing

AbstractThe effective treatment of skin wounds has long posed a significant challenge in the medical field, impacting patient comfort, quality of life, and the rate and outcome of wound healing. With continuous advancements in science and technology, novel materials have emerged, providing new possibilities for skin wound treatment. Among these, multifunctional hydrogels have shown considerable potential in promoting skin wound healing as a type of wound dressing material. This review systematically examines the progress in the application of multifunctional hydrogels in skin wound healing. Initially, the structure and composition of the skin are introduced. Subsequently, skin wounds are classified, and the wound‐healing process is discussed in detail. Traditional and modern dressings are then categorized, with a particular emphasis on the characteristics and applications of hydrogel dressings. The various functions of hydrogels in skin wound healing, including antibacterial, antioxidant, hemostatic, adhesive, stimulus‐responsive, and wound status monitoring, are reviewed. The paper concludes with a summary of the existing research gaps and provides insights into the future development directions of multifunctional hydrogels. This review aims to guide the preparation of hydrogel wound dressings and offer theoretical references for the exploration of next‐generation functional hydrogels.

Exosomes Derived from Antler Mesenchymal Stem Cells Promote Wound Healing by miR-21-5p/STAT3 Axis.

Deer antlers, unique among mammalian organs for their ability to regenerate annually without scar formation, provide an innovative model for regenerative medicine. This study explored the potential of exosomes derived from antler mesenchymal stem cells (AMSC-Exo) to enhance skin wound healing. We explored the proliferation, migration and angiogenesis effects of AMSC-Exo on HaCaT cells and HUVEC cells. To investigate the skin repairing effect of AMSC-Exo, we established a full-thickness skin injury mouse model. Then the skin thickness, the epidermis, collagen fibers, CD31 and collagen expressions were tested by H&E staining, Masson's trichrome staining and immunofluorescence experiments. MiRNA omics analysis was conducted to explore the mechanism of AMSC-Exo in skin repairing. AMSC-Exo stimulated the proliferation and migration of HaCaT cells, accelerated the migration and angiogenesis of HUVEC cells. In the mouse skin injury model, AMSC-Exo stimulated angiogenesis and regulated the extracellular matrix by facilitating the conversion of collagen type III to collagen type I, restoring epidermal thickness to normal state without aberrant hyperplasia. Notably, AMSC-Exo enhanced the quality of wound healing with increased vascularization and reduced scar formation. MiRNAs in AMSC-Exo, especially through the miR-21-5p/STAT3 signaling pathway, played a crucial role in these processes. This study underscores the efficacy of AMSC-Exo in treating skin wounds, suggesting a new approach for enhancing skin repair and regeneration.

Wireless power supply near-infrared light drug-loaded microneedle system for the treatment of linear skin wounds

The healing of linear skin wounds is a complex biological process, and traditional treatment methods have certain limitations. This study proposes a wireless power supply near-infrared light drug-loaded microneedle system (NIR-LED-NG-R1-MN), which utilizes microneedles (MNs) to achieve targeted delivery of the active component of traditional Chinese medicine, Notoginsenoside R1 (NG-R1), and combines the biological regulatory effect of near-infrared light (NIR) to achieve efficient synergistic treatment for linear skin wounds. Experimental results show that the device can significantly promote the wound closure rate and reduce the levels of inflammatory factors and the risk of scar formation. By comparing the wound repair conditions of different treatment groups, it was found that the group treated with the NIR-LED-NG-R1-MN patch for NG-R1 and NIR synergistic treatment (MN@NG-R1@LED group) showed superior wound repair effects compared to other groups, thus confirming the synergistic therapeutic advantages of NG-R1 and NIR in skin wound healing. In addition, the application of wireless power supply technology used in this system eliminates the dependence on external power sources, enhancing the convenience of treatment. This study clearly demonstrates that the NIR-LED-NG-R1-MN has the potential to become a new clinical method for the treatment of linear skin wound healing.

Mesenchymal stem cells-laden self-healing hydrogel microfiber fragments from microfluidic bubbles interrupted spinning for wound healing

Mesenchymal stem cells (MSCs) loaded hydrogels have shown positive therapeutic effects in skin wound treatment, while their application is still impractical on the wound bed. Here, we propose novel MSCs-loaded self-healing hydrogel microfiber fragments from microfluidic bubbles interrupted spinning for wound healing. The hydrogel microfibers are composed of sodium alginate, gelatin, polyvinyl alcohol, and borax, vesting them with good biocompatibility and self-healing ability. Their fragments with adjustable length are generated by introducing bubbles into microfluidic channels. We have demonstrated that the self-healing microfibers can promote the proliferation of MSCs, which are seeded alongside fragments’ surfaces to further facilitate the wound healing process. In addition, these MSCs laden self-healing hydrogel microfibers (MSG-fibers) showed obvious healing effect in rat wound model, which significantly promoted granulation tissue formation, collagen deposition and vascular construction at the wound site. Thus, we believe that our proposed MSC-laden microfiber fragments are valuable in promoting wound healing and have promising prospect in becoming new options for wound management.

MOF-Enhanced Phototherapeutic Wound Dressings Against Drug-Resistant Bacteria.

Phototherapy is a low-risk alternative to traditional antibiotics against drug-resistant bacterial infections. However, optimizing phototherapy agents, refining treatment conditions, and addressing misuse of agents, remain a formidable challenge. This study introduces a novel concept leveraging the unique customizability of metal-organic frameworks (MOFs) to house size-matched dye molecules in "single rooms". The mesoporous iron(III) carboxylate nanoMOF, MIL-100(Fe), and the hydrophobic heptamethine cyanine photothermal dye (Cy7), IR775, are selected as model systems. Their combination is predicted to minimize dye-dye interactions, leading to exceptional photostability and efficient light-to-heat conversion. Furthermore, MIL-100(Fe) preserves the antimicrobial nature of hydrophobic IR775, enabling it to disrupt bacterial cell envelopes. Through electrospinning, MIL-100(Fe)@IR775 nanoparticles are shaped into a gelatin-based film dressing for the treatment of skin wounds infected by Methicillin-resistant Staphylococcus aureus (MRSA). Activation of the dressing requires only a portable near-infrared light-emitting diode (NIR LED) and induces both low-dose photodynamic therapy (LPDT) and mild-temperature photothermal therapy (MPTT). Combined with the antimicrobial properties of IR775 and ferroptosis-like lipid peroxidation induced by MIL-100(Fe), the photoactive dressing eradicates MRSA and the healing is as quick as the uninfected wounds. This safe, cost-effective, and multifunctional therapeutic wound dressing offers a promising solution to overcome the current bottleneck in phototherapy.

Arginine-Biofunctionalized Ternary Hydrogel Scaffolds of Carboxymethyl Cellulose-Chitosan-Polyvinyl Alcohol to Deliver Cell Therapy for Wound Healing.

Wound healing is important for skin after deep injuries or burns, which can lead to hospitalization, long-term morbidity, and mortality. In this field, tissue-engineered skin substitutes have therapy potential to assist in the treatment of acute and chronic skin wounds, where many requirements are still unmet. Hence, in this study, a novel type of biocompatible ternary polymer hybrid hydrogel scaffold was designed and produced through an entirely eco-friendly aqueous process composed of carboxymethyl cellulose, chitosan, and polyvinyl alcohol and chemically cross-linked by citric acid, forming three-dimensional (3D) matrices, which were biofunctionalized with L-arginine (L-Arg) to enhance cellular adhesion. They were applied as bilayer skin biomimetic substitutes based on human-derived cell cultures of fibroblasts and keratinocytes were seeded and grown into their 3D porous structures, producing cell-based bio-responsive hybrid hydrogel scaffolds to assist the wound healing process. The results demonstrated that hydrophilic hybrid cross-linked networks were formed via esterification reactions with the 3D porous microarchitecture promoted by foam templating and freeze-drying. These hybrids presented chemical stability, physicochemical properties, high moisture adsorption capacity, surface properties, and a highly interconnected 3D porous structure well suited for use as a skin substitute in wound healing. Additionally, the surface biofunctionalization of these 3D hydrogel scaffolds with L-arginine through amide bonds had significantly enhanced cellular attachment and proliferation of fibroblast and keratinocyte cultures. Hence, the in vivo results using Hairless mouse models (an immunocompromised strain) confirmed that these responsive bio-hybrid hydrogel scaffolds possess hemocompatibility, bioadhesion, biocompatibility, adhesiveness, biodegradability, and non-inflammatory behavior and are capable of assisting the skin wound healing process.

A chitosan-modified tea tree oil self-nanoemulsion improves antibacterial effects in vivo and in vitro and promotes wound healing by influencing metabolic processes against multidrug-resistant bacterial infections

Infectious diseases, especially multidrug-resistant bacterial infections, have caused crises and majorly disrupted public health and economic stability worldwide. Many natural essential oils, especially tea tree oil, have potential to treat multidrug-resistant bacteria, such as H. pylori and P. aeruginosa. However, there are some problems need to be solved, such as poor stability upon light or oxygen exposure. Therefore, it is urgent to develop the ideal formation to tackle these difficulties. Herein, we reported the novel chitosan-modified self-nanoemulsion (TNE) encapsulating natural essential tea tree oil with strong antibacterial and stability characterize. In this study, we found that this self-nanoemulsion (size: 212 nm, PDI: 0.124, zeta potential: −20.5 mV, 6 % tea tree oil) not only had physical properties, good stability and tissue safety, but also had better antibacterial synergism (2–8 times) than that of water suspension against various multidrug-resistant bacterial (such as H. pylori, MRSA and P. aeruginosa). Additionally, TNE showed high antibacterial effectiveness in vivo, reduced inflammation, promoted ulcer healing after H. pylori infection and accelerated wound healing after P. aeruginosa infection. Importantly, this novel self-nanoemulsion can induce 274 protein down-regulated and 251 protein up-regulated, and disrupt H. pylori metabolic processes (glyoxylate, dicarboxylic acid, glutamate and tryptophan metabolism) and reduced its viability, leading to significant synergistic antibacterial effects. TNE is a potential treatment for skin wounds or ulcers caused by multidrug-resistant bacterial infections.

Advances in Smart-Response Hydrogels for Skin Wound Repair

Hydrogels have emerged as promising candidates for biomedical applications, especially in the treatment of skin wounds, as a result of their unique structural properties, highly tunable physicochemical properties, and excellent biocompatibility. The integration of smart-response features into hydrogels allows for dynamic responses to different external or internal stimuli. Therefore, this paper reviews the design of different smart-responsive hydrogels for different microenvironments in the field of skin wound therapy. First, the unique microenvironments of three typical chronic difficult-to-heal wounds and the key mechanisms affecting wound healing therapeutic measures are outlined. Strategies for the construction of internal stimulus-responsive hydrogels (e.g., pH, ROS, enzymes, and glucose) and external stimulus-responsive hydrogels (e.g., temperature, light, electricity, and magnetic fields) are highlighted from the perspective of the wound microenvironment and the in vitro environment, and the constitutive relationships between material design, intelligent response, and wound healing are revealed. Finally, this paper discusses the severe challenges faced by smart-responsive hydrogels during skin wound repair and provides an outlook on the combination of smart-responsive hydrogels and artificial intelligence to give scientific direction for creating and using hydrogel dressings that respond to stimuli in the clinic.

Exploring the potential of chitosan polyherbal hydrogel loaded with AgNPs to enhance wound healing A triangular study

Hydrogel wound dressings provide a moist environment, which promotes the formation of granulation tissue and epithelium in the wound area, accelerating the wound healing process. There have been numerous approaches to skin wound management and treatment, but the limitations of current methods highlight the need for more effective alternatives. A Chitosan polyherbal hydrogel integrated with AgNPs was synthesized to assess its wound-healing potential both in vitro and in vivo. The AgNPs were synthesized using Calotropis procera leaf extract and characterized via X-ray diffraction analysis (XRD), Scanning electron microscopy (SEM), and Fourier Transform Infrared Spectroscopy (FT-IR). In swelling kinetic analysis, the hydrogel's weight reached its maximum at 8 h of incubation and began to decrease from 12 h up to 72 h (49 % ± 6.04). The hydrogel formulation demonstrated strong antimicrobial potential against E. coli and S. aureus with an inhibition zone of 18 mm and 25 mm, respectively. Furthermore, in mice studies, the formulation exhibited significant wound size reduction within 12 days, supported by histopathology analysis revealing higher angiogenic potential compared to commercial hydrogels. The concentrations of IL-6 and TNF-α in CS-polyherbal/AgNPs hydrogel were 500 pg/ml and 125 pg/ml, respectively. Additionally, a network pharmacology approach identified 11 chemical constituents in Aloe vera, Azadirachta indica, and Alternanthera brasiliana extracts, along with 326 potential targets, suggesting the superior wound healing properties of this formulation compared to commercially available hydrogels.

Antibacterial and antioxidant supramolecular nanocomposite hydrogel dressings with angiogenesis and photo-thermal effect for multidrug‐resistant bacterial infected wound healing

Antioxidant, antibacterial and removable supramolecular nanocomposite hydrogel dressings with self-healing and tissue adhesiveness is highly anticipated for bacterial infected skin wound healing. A series of supramolecular nanocomposite hydrogels via quadruple hydrogen bond and coordination bonds (catechol-Cu) was developed based on ureidopyrimidinone-modified poly(glycerol sebacate)–co-poly(ethylene glycol)-g-catechol (PEGSDU) and mesoporous copper sulfide nanoparticle (CuS NPs) as antioxidative, antibacterial, removable and tissue-adhesive dressing to treat the MRSA-infected wound. The hydrogels exhibited good self-healing, free radical scavenging, photothermal sterilization performance, adhesiveness, and temperature-sensitive removability. In addition, the Cu2+ was able to be slowly released from the hydrogel, which can promote the proliferation and migration of fibroblasts. Hydrogels containing CuS NPs showed better wound repair efficiency than commercial TegadermTM films and hydrogels without CuS NPs in MRSA-infected skin wound, which was attributed to the good antibacterial property, improved collagen deposition, reduced inflammatory response, and improved new vessels formation, thereby significantly promoting the repair of wounds. In summary, this antioxidative and antibacterial supramolecular nanocomposite hydrogel dressing provide a new type of multi-functional dressing for the treatment of infected skin wounds.

Multifunctional Microneedle Patch with Diphlorethohydroxycarmalol for Potential Wound Dressing.

Treatment of skin wounds with diverse pathological characteristics presents significant challenges due to the limited specific and efficacy of current wound healing approaches. Microneedle (MN) patches incorporating bioactive and stimulus materials have emerged as a promising strategy to overcome these limitations and integrating bioactive materials with anti-bacterial and anti-inflammatory properties for advanced wound dressing. We isolated diphlorethohydroxycarmalol (DPHC) from Ishige okamurae and assessed its anti-inflammatory and anti-bacterial effects on macrophages and its antibacterial activity against Cutibacterium acnes. Subsequently, we fabricated polylactic acid (PLA) MN patches containing DPHC at various concentrations (0-0.3%) (PDPHC MN patches) and evaluated their mechanical properties and biological effects using in vitro and in vivo models. Our findings demonstrated that DPHC effectively inhibited nitric oxide production in macrophages and exhibited rapid bactericidal activity against C. acnes. The PDPHC MN patches displayed potent antibacterial effects without cytotoxicity. Moreover, in 2,4-Dinitrochlorobenzene-stimulated mouse model, the PDPHC MN patches significantly suppressed inflammatory response and cutaneous lichenification. The results suggest that the PDPHC MN patches holds promise as a multifunctional wound dressing for skin tissue engineering, offering antibacterial properties and anti-inflammatory properties to promote wound healing process.

Machine Learning Accelerates the Discovery of Epitope-based Dual-bioactive Peptides Against Skin Infections

Skin injuries and infections are an inevitable part of daily human life, particularly with chronic wounds, becoming an increasing socioeconomic burden. In treating skin infections and promoting wound healing, bioactive peptides may hold significant potential, particularly those possessing antimicrobial and anti-inflammatory properties. However, obtaining these peptides solely through traditional wet laboratory experiments is costly and time-consuming, and peptides identified by current computer-assisted predictive models largely lack validation of their effects via wet laboratory experiments. Consequently, this study aimed to integrate computer-assisted methods and traditional wet laboratory experiments to identify anti-inflammatory and antimicrobial peptides. We developed a computer-assisted mining pipeline to screen potential peptides from the epitopes of the major histocompatibility complex class II (MHC-II). The peptide AIMP1 was identified, with the ability to physically damage Escherichia coli by increasing bacterial cell membrane permeability and with the ability to inhibit inflammation by binding to endotoxin-lipopolysaccharide. Additionally, in an LPS-induced inflammation animal model, AIMP1 slightly increased levels of proinflammatory cytokines (TNF-α, IL-1β, and IL-6), and in a skin wound infection animal model, AIMP1 effectively accelerated healing, reduced levels of these pro-inflammatory cytokines, and showed no acute hepatotoxicity or nephrotoxicity. In conclusion, this study not only developed a computer-assisted mining pipeline for identifying anti-inflammatory and antimicrobial peptides but also successfully pinpointed the peptide AIMP1, demonstrating its therapeutic potential for skin injury treatment.

Clinical and histological study of cold physical plasma jet in treatment of full thickness skin wounds of normal and diabetic dogs.

To study the effect of physical plasma jet in treating open wounds in diabetic and non-diabetic dogs. The experimental study was conducted at the College of Veterinary Medicine, University of Baghdad, Iraq, from 20 January, 2020 to 1st May 2020, according to (no. 1364/ P.G), and comprised adult male diabetic and nondiabetic dogs. They were divided into non-diabetic group N and diabetic group D. Each group was further divided into treatment subgroup T and control subgroup C. Each dog was subjected to 4 wounds 3×3cm in size. Homemade helium non-equilibrium atmospheric pressure plasma jet therapy was used for healing purposes. Clinical parameters were evaluated by observation, while histological images were scored based on the semi-quantitative evaluation of histological sections on days 3-, 7- and 21-days post-wound. Data was analysed using SPSS Version 26 with One-way ANOVA for statistical analysis between groups and sub-groups. Of the 24 dogs, 12(50%) were in each of the two groups, which were further divided into subgroups having 6(50%) dogs each. The therapy accelerated the process of wound healing in the NT and DT subgroups compared to NC and DC. Clinical observations revealed early and complete closure of plasma-treated wounds in NT and DT subgroups started at day 30 post-wounding, while in the NC subgroup it started at day 35, and in the DC subgroup, wounds failed to close even after 35 days post-wounding. Histological analysis suggested that a plasma jet supported epithelisation, angiogenesis, formation of new hair follicles and collagen fibres, while it also controlled inflammation. In addition, in NT and DT subgroups, it increased the proliferation of fibroblasts and deposition of collagen, and there is a very, highly significant difference between groups (P<0.001), and a significant difference between days (P<0.05). Home-made helium non-equilibrium atmospheric pressure plasma jet therapy improved the quality and pace of wound healing.