There is currently no consensus regarding the management of acute cutaneous reactions emerging from a concurrent treatment of radio-and chemotherapy, the goal of this case study series is to provide scientific evidenc...There is currently no consensus regarding the management of acute cutaneous reactions emerging from a concurrent treatment of radio-and chemotherapy, the goal of this case study series is to provide scientific evidence based on clinical practice regarding the efficacy of a film-forming wound dressing for patients receiving combined cancer therapy, in particular examples where the reactions are expected to be intense. In all the described cases, management of acute skin reactions allowed the cancer therapy to be finalized, instead of being interrupted due to an increase in the severity of the reactions. It has been shown in the current literature that the lack of compliance with treatment plans correlates with poorer clinical outcome. Evidence from the cases presented suggest that the studied dressing is safe and efficacious in the treatment and the prevention of acute cutaneous reactions arising from combined cancer therapy.展开更多
The healing of diabetic wounds poses a significant healthcare burden due to persistent inflammation,M1 macrophage aggregation,and high glucose levels in the microenvironment.Previous studies have demonstrated that imm...The healing of diabetic wounds poses a significant healthcare burden due to persistent inflammation,M1 macrophage aggregation,and high glucose levels in the microenvironment.Previous studies have demonstrated that immunomodulatory hydrogel dressings can facilitate diabetic wound healing.However,current immunomodulatory hydrogels require costly and complex treatments such as cell therapy and cytokines.Herein,a hierarchical hydrogel dressing with continuous biochemical gradient based on glycyrrhizic acid(GA) was constructed to modulate immunomodulatory processes in diabetic wounds.The hydrogels present many desirable features,such as tunable mechanical properties,broad antibacterial ability,outstanding conductive,transparent,and self-adhesive properties.The resultant hydrogel can promote diabetic wound healing by preventing bacterial infection,promoting macrophage polarization,improving the inflammatory microenvironment,and inducing angiogenesis and neurogenesis.Furthermore,electrical stimulation(ES) can further promote the healing of chronic diabetic wounds,providing valuable guidance for relevant clinical practice.展开更多
The treatment of chronic wounds presents significant challenges due to the necessity of accelerating healing within complex microenvironments characterized by persistent inflammation and biochemical imbalances.Factors...The treatment of chronic wounds presents significant challenges due to the necessity of accelerating healing within complex microenvironments characterized by persistent inflammation and biochemical imbalances.Factors such as bacterial infections,hyperglycemia,and oxidative stress disrupt cellular functions and impair angiogenesis,substantially delaying wound repair.Nanozymes,which are engineered nanoscale materials with enzyme-like activities,offer distinct advantages over conventional enzymes and traditional nanomaterials,making them promising candidates for chronic wound treatment.To enhance their clinical potential,nanozyme-based catalytic systems are currently being optimized through formulation advancements and preclinical studies assessing their biocompatibility,anti-oxidant activity,antibacterial efficacy,and tissue repair capabilities,ensuring their safety and clinical applicability.When integrated into multifunctional wound dressings,nanozymes modulate reactive oxygen species levels,promote tissue regeneration,and simultaneously combat infections and oxidative damage,extending beyond conventional enzyme-like catalysis in chronic wound treatment.The customizable architectures of nanozymes enable precise therapeutic applications,enhancing their effectiveness in managing complex wound conditions.This review provides a comprehensive analysis of the incorporation of nanozymes into wound dressings,detailing fabrication methods and emphasizing their transformative potential in chronic wound management.By identifying and addressing key limitations,we introduce strategic advancements to drive the development of nanozyme-driven dressings,paving the way for next-generation chronic wound treatments.展开更多
Diabetic wounds represent a significant challenge in the medical field,significantly impacting patient quality of life and imposing a heavy burden on healthcare systems.Intelligent hydrogel dressings have attracted si...Diabetic wounds represent a significant challenge in the medical field,significantly impacting patient quality of life and imposing a heavy burden on healthcare systems.Intelligent hydrogel dressings have attracted significant attention in diabetic wound treatment due to their unique properties.This review systematically explores the three main categories of intelligent hydrogels(natural,synthetic,and composite),dissecting their composition,structure,and the mechanisms that enable their intelligent responses.The crucial roles of these dressings in maintaining a moist wound environment,efficiently absorbing exudate,and precisely delivering drugs are expounded.Moreover,their application advantages in combating bacteria and infections,regulating inflammation and immunity,promoting angiogenesis and tissue regeneration,as well as enabling real-time monitoring and personalized treatment,are explored in depth.Additionally,we discuss future research directions and the prospects for personalized precision medicine in diabetic wound care,aiming to inspire innovation and provide a comprehensive theoretical basis for the development of nextgeneration intelligent dressings.展开更多
Chronic wounds resulting from diabetes are among the most common complications in diabetic patients.Attributable to poor local blood circulation and an increased risk of infection,these wounds heal slowly and are diff...Chronic wounds resulting from diabetes are among the most common complications in diabetic patients.Attributable to poor local blood circulation and an increased risk of infection,these wounds heal slowly and are difficult to treat,posing a significant global health challenge.Herein,we achieved the green valorization of waste liquid from the natural clay-derived zeolite synthesis process and utilized it to fabricate metal-loaded aluminosilicate dressings with pronounced wrinkled structures(wrinkled Cu–AS,Ga–AS,and Ce–AS)through simple procedures.展开更多
Diabetic wounds(DWs)are a major complication of diabetes mellitus,characterized by a complex patho-physiological microenvironment that is associated with elevated morbidity and mortality.Conventional management strate...Diabetic wounds(DWs)are a major complication of diabetes mellitus,characterized by a complex patho-physiological microenvironment that is associated with elevated morbidity and mortality.Conventional management strategies often fail to address the multifaceted nature of these wounds effectively.Recent advancements in understanding the mechanisms of DW healing have spurred the development of a plethora of bioactive dressings designed to interact with and modulate the DW microenvironment.These innovations have culminated in the introduction of the“microenvironment-sensitive with on-demand management”paradigm aimed at delivering precision therapy responsive to dynamic changes within DW.Despite these advancements,the current literature lacks a comprehensive review that cate-gorizes and evaluates active,passive,and on-demand approaches that address the DW microenviron-ment.Herein,we describe the unique pathogenic mechanisms and microenvironmental characteristics that distinguish DW from normal acute wounds.This review provides an extensive overview of contem-porary active and passive management strategies incorporating on-demand management principles designed for DW microenvironments.Furthermore,it addresses the principal challenges faced in this therapeutic domain and outlines the potential innovations that can enhance the efficacy and specificity of bioactive dressings.The insights presented here aim to guide further research and development in the on-demand management of DW to improve patient outcomes by aligning personalized therapy modali-ties with the pathophysiological realities of DW.展开更多
Mimicking the hierarchical structure of the skin is one of the most important strategies in skin tissue engineering.Monolayer wound dressings are usually not able to provide several functions at the same time and cann...Mimicking the hierarchical structure of the skin is one of the most important strategies in skin tissue engineering.Monolayer wound dressings are usually not able to provide several functions at the same time and cannot meet all clinical needs.In order to maximize therapeutic efficiency,herein,we fabricated a Tri-layer wound dressing,where the middle layer was fabricated via 3D-printing and composed of alginate,tragacanth and zinc oxide nanoparticles(ZnO NPs).Both upper and bottom layers were constructed using electrospinning technique;the upper layer was made of hydrophobic polycaprolactone to mimic epidermis,while the bottom layer consisted of Soluplus■ and insulin-like growth factor-1(IGF-1)to promote cell behavior.Swelling,water vapor permeability and tensile properties of the dressings were evaluated and the Tri-layer dressing exhibited impressive antibacterial activity and cell stimulation following by the release of ZnO NPs and IGF-1.Additionally,the Tri-layer dressing led to faster healing of full-thicknesswound in ratmodel compared to monolayer and Bilayer dressings.Overall,the evidence confirmed that the Trilayer wound dressing is extremely effective for full-thickness wound healing.展开更多
BACKGROUND Aloe vera has been used as a traditional herbal therapy for wound management and dermatological conditions worldwide for thousands of years.Scientific evidence has confirmed that acemannan,the bioactive com...BACKGROUND Aloe vera has been used as a traditional herbal therapy for wound management and dermatological conditions worldwide for thousands of years.Scientific evidence has confirmed that acemannan,the bioactive compound in aloe vera gel,exhibits significant anti-inflammatory and immunomodulatory properties that enhance tissue regeneration.This case report describes the successful application of an innovative acemannan-enriched glycolipid sphere dressing derived from aloe vera gel in diabetic foot ulcer(DFU)treatment,which achieved a clinically remarkable outcome.CASE SUMMARY An 80-year-old female patient with a 20-year history of type 2 diabetes mellitus experienced recurrent diabetic foot pain for 15 years.She had multiple hospitalizations due to acute infections and poorly controlled hyperglycemia.Long-term treatments included metformin and gliclazide.Upon presentation,she had a nonhealing wound on her left dorsal foot,diagnosed as a severe DFU(Texas classification:Grade II,stage D).She declined amputation and opted for conservative treatment.The medical team applied an acemannan-enriched glycolipid sphere dressing five times daily to the left calf and foot,avoiding the wound area.Frequency was reduced to three times daily after scab formation.Weight-bearing on the injured foot was avoided.Through in-person and online consultations,the team managed her lifestyle and diet,emphasizing natural foods.After 5 months,the DFU healed without significant scarring or functional loss.No recurrence was observed during the 2-year follow-up.Acemannan-enriched glycolipid sphere dressings promote DFU healing.This suggests the potential of these dressings for treating other refractory wounds.展开更多
Bacterial infection is a very troublesome issue in wound treatment, which stimulates exudate formation and severely delays the healing process. Herein, a thermogelling dressing system composed of two triblock copolyme...Bacterial infection is a very troublesome issue in wound treatment, which stimulates exudate formation and severely delays the healing process. Herein, a thermogelling dressing system composed of two triblock copolymers of poly(D,L-lactic acid-co-glycolic acid)-b-poly(ethylene glycol)-b-poly(D,L-lactic acid-co-glycolic acid)(PLGA-PEG-PLGA) with different block lengths was developed to deliver teicoplanin(TPN), a glycopeptide antibiotic, for cutaneous wound repair. The TPN-loaded thermogel was a free-flowing sol at room temperature and formed a semi-solid gel at physiological temperature. In vitro studies demonstrated that the TPN-loaded thermogel system exhibited desired tissue adhesiveness and realized the sustained release of TPN in a fast-followed-slow manner for over three weeks. Furthermore, a full-thickness excision wound model in Sprague-Dawley(SD) rats was constructed to assess the efficacy of TPNloaded thermogel formulation. Gross and histopathologic observations implied that treatment with the thermogel formulation reduced inflammation response, promoted disposition of collagen, enhanced angiogenesis, and accelerated wound closure and maturity of SD rats.The combination of the bioactivity of TPN and the acidic nature of the thermogel matrix was responsible for such an enhanced wound healing process. Consequently, the TPN-loaded PLGA-PEG-PLGA thermogel is a good candidate of wound dressing for full-thickness excision wound healing.展开更多
Polyurethane foam dressings for dermal wounds were formulated with natural polyols in order to improve the foam characteristics and the release of 2 active agents,silver and asiaticoside(AS)as an antimicrobial agent a...Polyurethane foam dressings for dermal wounds were formulated with natural polyols in order to improve the foam characteristics and the release of 2 active agents,silver and asiaticoside(AS)as an antimicrobial agent and an herbal wound healing agent,respectively.The foam was instantly formed by interaction of polyols and diisocyanate.Hydroxypropyl methylcellulose,chitosan and sodium alginate were individually mixed with themain polyols,polypropylene glycol,in the formulation while the active componentswere impregnated into the obtained foam dressing sheets.Although the type and amount of the natural polyols slightly affected the pore size,water sorption-desorption profile and compression strength of the obtained foam sheets,a prominent effect was found in the release of both active components.Among natural polyols formulations,foam sheets with alginate showed the highest silver and AS release.Non-cytotoxicity of these foam sheets to human fibroblast cells was confirmed.Antimicrobial testing on four bacteria strains showed that 1mg/cm^2 silver in formulations with 6%of natural polyols and without natural polyols had sufficient content of the silver release with comparable inhibition zone and significantly larger zone than other formulations.In pig study,the foam dressing with 6%alginate,1mg/cm^2 silver and 5%AS could improve wound healing in both the percentage of the wound closure and histological parameters of the dermal wound without any dermatologic reactions.In conclusion,this innovative foam dressing had potential to be a good candidate for wound treatment.展开更多
Bacterial infection and the ever-increasing bacterial resistance have imposed severe threat to human health.And bacterial contamination could significantly menace the wound healing process.Considering the sophisticate...Bacterial infection and the ever-increasing bacterial resistance have imposed severe threat to human health.And bacterial contamination could significantly menace the wound healing process.Considering the sophisticated wound healing process,novel strategies for skin tissue engineering are focused on the integration of bioactive ingredients,antibacterial agents included,into biomaterials with different morphologies to improve cell behaviors and promote wound healing.However,a comprehensive review on antibacterial wound dressing to enhance wound healing has not been reported.In this review,various antibacterial biomaterials as wound dressings will be discussed.Different kinds of antibacterial agents,including antibiotics,nanoparticles(metal and metallic oxides,lightinduced antibacterial agents),cationic organic agents,and others,and their recent advances are summarized.Biomaterial selection and fabrication of biomaterials with different structures and forms,including films,hydrogel,electrospun nanofibers,sponge,foam and three-dimension(3D)printed scaffold for skin regeneration,are elaborated discussed.Current challenges and the future perspectives are presented in thismultidisciplinary field.We envision that this review will provide a general insight to the elegant design and further refinement of wound dressing.展开更多
The hydrogel wound dressing based on polyvinyl alcohol (PVA) was prepared by the freezing-thawing cyclic method. The dehydration kinetics of prepared hydrogels was determined using the experimental method and mathem...The hydrogel wound dressing based on polyvinyl alcohol (PVA) was prepared by the freezing-thawing cyclic method. The dehydration kinetics of prepared hydrogels was determined using the experimental method and mathematical modeling based on diffusion mechanism. The results show that the dehydration rate of PVA hydrogel wound dressing inversely depends on the hydrogel thickness as well as water content of the wound. On the other hand, the initial water content of hydrogel and the atmospheric humidity have little direct effect on the dehydration rate. The good agreement between experimental and mathematical modeling results in early stages of dehydration process shows that the predominate factor determining the dehydration of these wound dressings is diffusion.展开更多
With the changes in the modern disease spectrum,pressure ulcers,diabetic feet,and vascular-derived diseases caused refractory wounds is increasing rapidly.The development of wound dressings has partly improved the eff...With the changes in the modern disease spectrum,pressure ulcers,diabetic feet,and vascular-derived diseases caused refractory wounds is increasing rapidly.The development of wound dressings has partly improved the effect of wound management.However,traditional wound dressings can only cover the wound and block bacteria,but are generally powerless to recurrent wound infection and tissue healing.There is an urgent need to develop a new type of wound dressing with comprehensive performance to achieve multiple effects such as protecting the wound site from the external environment,absorbing wound exudate,anti-inflammatory,antibacterial,and accelerating wound healing process.Hydrogel wound dressings have the aforementioned characteristics,and can keep the wound in a moist environment because of the high water content,which is an ideal choice for wound treatment.This review introduces the wound healing process and the development and performance advantages of hydrogel wound dressings.The choice of different preparation materials gives the particularities of different hydrogel wound dressings.It also systematically explains the main physical and chemical crosslinking methods for hydrogel synthesis.Besides,in-depth discussion of four typical hydrogel wound dressings including double network hydrogels,nanocomposite hydrogels,drug-loaded hydrogels and smart hydrogels fully demonstrates the feasibility of developing hydrogels as wound dressing products and their future development trends.展开更多
Background: Wounded personnel who work at sea often encounter a plethora of difficulties. The most important of these difficulties is seawater immersion. Common medical dressings have little effect when the affected a...Background: Wounded personnel who work at sea often encounter a plethora of difficulties. The most important of these difficulties is seawater immersion. Common medical dressings have little effect when the affected area is immersed in seawater, and only rarely dressings have been reported for the treatment of seawater-immersed wounds. The objective of this study is to develop a new dressing which should be suitable to prevent the wound from seawater immersion and to promote the wound healing.Methods: Shark skin collagen(SSC) was purified via ethanol de-sugaring and de-pigmentation and adjusted for p H. A shark skin collagen sponge(SSCS) was prepared by freeze-drying. SSCS was attached to an anti-seawater immersion polyurethane(PU) film(SSCS+PU) to compose a new dressing. The biochemical properties of SSC and physicochemical properties of SSCS were assessed by standard methods. The effects of SSCS and SSCS+PU on the healing of seawaterimmersed wounds were studied using a seawater immersion rat model. For the detection of SSCS effects on seawaterimmersed wounds, 12 SD rats, with four wounds created in each rat, were divided into four groups: the 3 rd day group, 5 th day group, 7 th day group and 12 th day group. In each group, six wounds were treated with SSCS, three wounds treated with chitosan served as the positive control, and three wounds treated with gauze served as the negative control. For the detection of the SSCS+PU effects on seawater-immersed wounds, 36 SD rats were divided into three groups: the gauze(GZ)+PU group, chitosan(CS)+PU group and SSCS+PU group, with 12 rats in each group, and two wounds in each rat. The wound sizes were measured to calculate the healing rate, and histomorphology and the immunohistochemistry of the CD31 and TGF-β expression levels in the wounded tissues were measured by standard methods.Results: The results of Ultraviolet-visible(UV-vis) spectrum, Fourier-transform infrared(FTIR) spectrum, circular dichroism(CD) spectra, sodium dodecyl sulfate polyacrylamide gel electrophoresis(SDS-PAGE), and amino acid composition analyses of SSC demonstrated that SSC is type I collagen. SSCS had a homogeneous porous structure of approximately 200μm, porosity rate of 83.57%±2.64%, water vapor transmission ratio(WVTR) of 4500 g/m2, tensile strength of 1.79±0.41 N/mm, and elongation at break of 4.52%±0.01%. SSCS had significant beneficial effects on seawater-immersed wound healing. On the 3 rd day, the healing rates in the GZ negative control, CS positive control and SSCS rats were 13.94%±5.50%, 29.40%±1.10% and 47.24%±8.40%, respectively. SSCS also enhanced TGF-in the initial stage of the healing period. The SSCS+PU dressing effectively protected woundsβ and CD31 expression from seawater immersion for at least 4 h, and accelerated re-epithelialization, vascularization and granulation formation of seawater-immersed wounds in the earlier stages of wound healing, and as well as significantly promoted wound healing. The SSCS+PU dressing also enhanced expression of TGF-n and gauze dressings.β and CD31. The effects of SSCS and SSCS+PU were superior to those of both the chitosaConclusion: SSCS has significant positive effects on the promotion of seawater-immersed wound healing, and a SSCS+PU dressing effectively prevents seawater immersion, and significantly promotes seawater-immersed wound healing.展开更多
For most traditional wound dressings,it is challenging to simultaneously eliminate bacteria and promote angiogenesis to accelerate the healing process of bacteria-infected wounds.In this work,we develop a multifunctio...For most traditional wound dressings,it is challenging to simultaneously eliminate bacteria and promote angiogenesis to accelerate the healing process of bacteria-infected wounds.In this work,we develop a multifunctional dressing based on bacterial cellulose(BC)deposited with a tannic acid/Cu^(2+)ion/Mg^(2+)ion(TCM)complex film.Overall,the TCM complex exhibits robust interfacial adhesion to modify BC and good photothermal properties to effectively eradicate bacteria in the wound area under near-infrared(NIR)irradiation.The individual components of the TCM complex have several advantageous features for wound healing,such as antibacterial ability and negligible cytotoxicity;in particular,the released Cu^(2+)and Mg^(2+)ions are favorable for the proliferation,migration,and tube formation of endothelial cells in vitro.The results of in vivo experiments demonstrated that with the assistance of NIR irradiation,this composite dressing is more effective than traditional gauze or pristine BC dressing in promotion of angiogenesis and collagen deposition without causing remarkable inflammation,thereby accelerating the healing process of bacteria-infected full-thickness skin wounds.This work thus provides a simple and facile way to fabricate multifunctional BC-based dressings that could be potentially used for treating infected wounds.展开更多
The variety of wound types has resulted in a wide range of wound dressings, with new products frequently being introduced to target different aspects of the wound healing process. The ideal wound dressing should achie...The variety of wound types has resulted in a wide range of wound dressings, with new products frequently being introduced to target different aspects of the wound healing process. The ideal wound dressing should achieve rapid healing at a reasonable cost, with minimal inconvenience to the patient. Microcurrent dressing, a novel wound dressing with inherent electric activity, can generate low-level microcurrents at the device-wound contact surface in the presence of moisture and can provide an advanced wound healing solution for managing wounds. This article offers a review of the effects and mechanisms of the microcurrent dressing on the healing of skin wounds.展开更多
Objective This study tests the efficacy of Bletilla striata polysaccharide(BSP),carboxymethyl chitosan(CMC),baicalin(BA)and silver titanate(ST)in a wound dressings to fight infection,promote healing and provide superi...Objective This study tests the efficacy of Bletilla striata polysaccharide(BSP),carboxymethyl chitosan(CMC),baicalin(BA)and silver titanate(ST)in a wound dressings to fight infection,promote healing and provide superior biocompatibility.Methods The antibacterial activity of BA and ST was evaluated in vitro using the inhibition zone method.BA/ST/BSP/CMC porous sponge dressings were prepared and characterized.The biocompatibility of BA/ST/BSP/CMC was assessed using the cell counting kit-8 assay.The therapeutic effect of BA/ST/BSP/CMC was further investigated using the dorsal skin burn model in Sprague-Dawley rats.Results The wound dressing had good antibacterial activity against Escherichia coli and Staphylococcus aureus through BA and ST,while the combination of BSP and CMC played an important role in promoting wound healing.The BA/ST/BSP/CMC porous sponge dressings were prepared using a freeze-drying method with the concentrations of BA and ST at 20 and 0.83 mg/mL,respectively,and the optimal ratio of 5%BSP to 4%CMC was 1:3.The average porosity,water absorption and air permeability of BA/ST/BSP/CMC porous sponge dressings were measured to be 90.43%,746.1%and 66.60%,respectively.After treatment for 3 and 7 days,the healing rates of the BA/ST/BSP/CMC group and BA/BSP/CMC group were significantly higher than those of the normal saline(NS)group and silver sulfadiazine(SSD)group(P<0.05).Interleukin-1βexpression in the BA/ST/BSP/CMC group at 1 and 3 days was significantly lower than that in the other three groups(P<0.05).After being treated for 3 days,vascular endothelial growth factor expression in the BA/BSP/CMC group and BA/ST/BSP/CMC group was significantly higher than that in the NS group and SSD group(P<0.05).Inspection of histological sections showed that the BA/ST/BSP/CMC group and BA/BSP/CMC group began to develop scabbing and peeling of damaged skin after 3 days of treatment,indicating accelerated healing relative to the NS group and SSD group.Conclusion The optimized concentration of BA/ST/BSP/CMC dressing was as follows:6 mg BSP,14.4 mg CMC,0.5 mg ST and 12 mg BA.The BA/ST/BSP/CMC dressing,containing antibacterial constituents,was non-cytotoxic and effective in accelerating the healing of burn wounds,making it a promising candidate for wound healing.展开更多
Bacterial infections are a major cause of chronic infections.Thus,antibacterial material is an urgent need in clinics.Antibacterial nanofibers,with expansive surface area,enable efficient incorporation of antibacteria...Bacterial infections are a major cause of chronic infections.Thus,antibacterial material is an urgent need in clinics.Antibacterial nanofibers,with expansive surface area,enable efficient incorporation of antibacterial agents.Meanwhile,structure similar to the extracellular matrix can accelerate cell growth.Electrospinning,the most widely used technique to fabricate nanofiber,is often used in many biomedical applications including drug delivery,regenerative medicine,wound healing and so on.Thus,this review provides an overview of all recently published studies on the development of electrospun antibacterial nanofibers in wound dressings and tissue me-dicinal fields.This reviewer begins with a brief introduction of electrospinning process and then discusses electrospun fibers by incorporating various types of antimicrobial agents used as in wound dressings and tissue.Finally,we finish with conclusions and further perspectives on electrospun antibacterial nanofibers as 2D biomedicine materials.展开更多
A series of hydrogels with different ratios of chitosan and licorice polysaccharide(LP)were prepared by crosslinking to different concentrations of genipin(gp).They were characterized by FTIR(Fourier transform infrare...A series of hydrogels with different ratios of chitosan and licorice polysaccharide(LP)were prepared by crosslinking to different concentrations of genipin(gp).They were characterized by FTIR(Fourier transform infrared spectroscopy),SEM(Scanning electron microscope),swelling ratio,rheological measurements,degradation with time,cytotoxicity,and antibacterial efficacy.Results show that the hydrogels have porous structures.With an increase in LP content,the swelling rate grows in the early stage of immersion in buffer and drops later.The swelling ratio ranged from 986%to 1677%,and stiffness varied from 777 Pa to 1792 Pa.The addition of LP reduced the mechanical strength and delayed gelation and degradation of the hydrogels.However,the most important discovery was that gp increases the viability of NIH 3T3 cells from 94%to 137%,and LP raises the bacteriostatic efficacy from 51%to 78%.Hydrogels synthesized from 1%genipin,3%chitosan,and 4%licorice polysaccharide showed the best antibacterial and fibroblast proliferation promoting activities.They exhibited moderate swelling and degradation rates over time,while being more suitable to affect healing of chronic wound infections.These results provide a new strategy to improve the antibacterial effectiveness and cyto-compatibility of chitosan hydrogels with water soluble active LPs from Glycyrrhiza that derive from traditional Chinese medicine.展开更多
Inspired by the skin structure,an asymmetric wettability tri-layer nanofiber membrane(TNM)consisting of hydrophilic inner layer loaded with lidocaine hydrochloride(LID),hydrophobic middle layer with ciprofloxacin(CIP)...Inspired by the skin structure,an asymmetric wettability tri-layer nanofiber membrane(TNM)consisting of hydrophilic inner layer loaded with lidocaine hydrochloride(LID),hydrophobic middle layer with ciprofloxacin(CIP)and hydrophobic outer layer has been created.The hydrophobic outer layer endows the TNM with waterproof function and anti-adhesion from contaminants.The hydrophobic middle layer with CIP preserves long-term inhibition of bacteria growth and the hydrophilic inner layer with LID possesses optimal waterabsorbing capacity and air permeability.The TNM dramatically elevates the water contact angles from 10°(inner layer)to 120(outer layer),indicating an asymmetric wettability,which could directionally transport wound exudate within the materials and meanwhile maintain a comfortable and moist environment to promote wound healing.Furthermore,the sequential release of LID and CIP could relieve pain rapidly and achieve antibacterial effect in the long run,respectively.In addition,the TNM shows superior biocompatibility towards L929 cells.The in vivo results show the TNM could prevent infection,accelerate epithelial regeneration and significantly accelerate wound healing.This study indicates the developed TNM with asymmetrical wettability and synergetic drug release shows great potential as a wound dressing in clinical application.展开更多
文摘There is currently no consensus regarding the management of acute cutaneous reactions emerging from a concurrent treatment of radio-and chemotherapy, the goal of this case study series is to provide scientific evidence based on clinical practice regarding the efficacy of a film-forming wound dressing for patients receiving combined cancer therapy, in particular examples where the reactions are expected to be intense. In all the described cases, management of acute skin reactions allowed the cancer therapy to be finalized, instead of being interrupted due to an increase in the severity of the reactions. It has been shown in the current literature that the lack of compliance with treatment plans correlates with poorer clinical outcome. Evidence from the cases presented suggest that the studied dressing is safe and efficacious in the treatment and the prevention of acute cutaneous reactions arising from combined cancer therapy.
基金supported by Natural Science Foundation of Jilin Province(No.SKL202302002)。
文摘The healing of diabetic wounds poses a significant healthcare burden due to persistent inflammation,M1 macrophage aggregation,and high glucose levels in the microenvironment.Previous studies have demonstrated that immunomodulatory hydrogel dressings can facilitate diabetic wound healing.However,current immunomodulatory hydrogels require costly and complex treatments such as cell therapy and cytokines.Herein,a hierarchical hydrogel dressing with continuous biochemical gradient based on glycyrrhizic acid(GA) was constructed to modulate immunomodulatory processes in diabetic wounds.The hydrogels present many desirable features,such as tunable mechanical properties,broad antibacterial ability,outstanding conductive,transparent,and self-adhesive properties.The resultant hydrogel can promote diabetic wound healing by preventing bacterial infection,promoting macrophage polarization,improving the inflammatory microenvironment,and inducing angiogenesis and neurogenesis.Furthermore,electrical stimulation(ES) can further promote the healing of chronic diabetic wounds,providing valuable guidance for relevant clinical practice.
基金supported by the Key Project of the Joint Fund for Regional Innovation and Development of the National Natural Science Foundation of China(U23A20686)the National Natural Science Foundation of China(81901979)+2 种基金the Peking University People’s Hospital Scientific Research Development Funds(RDJP2022-07)the Joint Funds for the Innovation of Science and Technology,Fujian Province(2023Y9226)the Introduced High-Level Talent Team Project of Quanzhou City(2023CT008).
文摘The treatment of chronic wounds presents significant challenges due to the necessity of accelerating healing within complex microenvironments characterized by persistent inflammation and biochemical imbalances.Factors such as bacterial infections,hyperglycemia,and oxidative stress disrupt cellular functions and impair angiogenesis,substantially delaying wound repair.Nanozymes,which are engineered nanoscale materials with enzyme-like activities,offer distinct advantages over conventional enzymes and traditional nanomaterials,making them promising candidates for chronic wound treatment.To enhance their clinical potential,nanozyme-based catalytic systems are currently being optimized through formulation advancements and preclinical studies assessing their biocompatibility,anti-oxidant activity,antibacterial efficacy,and tissue repair capabilities,ensuring their safety and clinical applicability.When integrated into multifunctional wound dressings,nanozymes modulate reactive oxygen species levels,promote tissue regeneration,and simultaneously combat infections and oxidative damage,extending beyond conventional enzyme-like catalysis in chronic wound treatment.The customizable architectures of nanozymes enable precise therapeutic applications,enhancing their effectiveness in managing complex wound conditions.This review provides a comprehensive analysis of the incorporation of nanozymes into wound dressings,detailing fabrication methods and emphasizing their transformative potential in chronic wound management.By identifying and addressing key limitations,we introduce strategic advancements to drive the development of nanozyme-driven dressings,paving the way for next-generation chronic wound treatments.
文摘Diabetic wounds represent a significant challenge in the medical field,significantly impacting patient quality of life and imposing a heavy burden on healthcare systems.Intelligent hydrogel dressings have attracted significant attention in diabetic wound treatment due to their unique properties.This review systematically explores the three main categories of intelligent hydrogels(natural,synthetic,and composite),dissecting their composition,structure,and the mechanisms that enable their intelligent responses.The crucial roles of these dressings in maintaining a moist wound environment,efficiently absorbing exudate,and precisely delivering drugs are expounded.Moreover,their application advantages in combating bacteria and infections,regulating inflammation and immunity,promoting angiogenesis and tissue regeneration,as well as enabling real-time monitoring and personalized treatment,are explored in depth.Additionally,we discuss future research directions and the prospects for personalized precision medicine in diabetic wound care,aiming to inspire innovation and provide a comprehensive theoretical basis for the development of nextgeneration intelligent dressings.
基金financially supported by the start-up research grant from Wuhan University(China)。
文摘Chronic wounds resulting from diabetes are among the most common complications in diabetic patients.Attributable to poor local blood circulation and an increased risk of infection,these wounds heal slowly and are difficult to treat,posing a significant global health challenge.Herein,we achieved the green valorization of waste liquid from the natural clay-derived zeolite synthesis process and utilized it to fabricate metal-loaded aluminosilicate dressings with pronounced wrinkled structures(wrinkled Cu–AS,Ga–AS,and Ce–AS)through simple procedures.
基金supported by the National Natural Science Foundation of China(22408078,82401057,32101170)the Zhejiang Province Postdoctoral Excellence Funding Program-Special Support(ZJ2024004).
文摘Diabetic wounds(DWs)are a major complication of diabetes mellitus,characterized by a complex patho-physiological microenvironment that is associated with elevated morbidity and mortality.Conventional management strategies often fail to address the multifaceted nature of these wounds effectively.Recent advancements in understanding the mechanisms of DW healing have spurred the development of a plethora of bioactive dressings designed to interact with and modulate the DW microenvironment.These innovations have culminated in the introduction of the“microenvironment-sensitive with on-demand management”paradigm aimed at delivering precision therapy responsive to dynamic changes within DW.Despite these advancements,the current literature lacks a comprehensive review that cate-gorizes and evaluates active,passive,and on-demand approaches that address the DW microenviron-ment.Herein,we describe the unique pathogenic mechanisms and microenvironmental characteristics that distinguish DW from normal acute wounds.This review provides an extensive overview of contem-porary active and passive management strategies incorporating on-demand management principles designed for DW microenvironments.Furthermore,it addresses the principal challenges faced in this therapeutic domain and outlines the potential innovations that can enhance the efficacy and specificity of bioactive dressings.The insights presented here aim to guide further research and development in the on-demand management of DW to improve patient outcomes by aligning personalized therapy modali-ties with the pathophysiological realities of DW.
基金support of Isfahan University of Medical Sciences(Project code No.#1401262).
文摘Mimicking the hierarchical structure of the skin is one of the most important strategies in skin tissue engineering.Monolayer wound dressings are usually not able to provide several functions at the same time and cannot meet all clinical needs.In order to maximize therapeutic efficiency,herein,we fabricated a Tri-layer wound dressing,where the middle layer was fabricated via 3D-printing and composed of alginate,tragacanth and zinc oxide nanoparticles(ZnO NPs).Both upper and bottom layers were constructed using electrospinning technique;the upper layer was made of hydrophobic polycaprolactone to mimic epidermis,while the bottom layer consisted of Soluplus■ and insulin-like growth factor-1(IGF-1)to promote cell behavior.Swelling,water vapor permeability and tensile properties of the dressings were evaluated and the Tri-layer dressing exhibited impressive antibacterial activity and cell stimulation following by the release of ZnO NPs and IGF-1.Additionally,the Tri-layer dressing led to faster healing of full-thicknesswound in ratmodel compared to monolayer and Bilayer dressings.Overall,the evidence confirmed that the Trilayer wound dressing is extremely effective for full-thickness wound healing.
文摘BACKGROUND Aloe vera has been used as a traditional herbal therapy for wound management and dermatological conditions worldwide for thousands of years.Scientific evidence has confirmed that acemannan,the bioactive compound in aloe vera gel,exhibits significant anti-inflammatory and immunomodulatory properties that enhance tissue regeneration.This case report describes the successful application of an innovative acemannan-enriched glycolipid sphere dressing derived from aloe vera gel in diabetic foot ulcer(DFU)treatment,which achieved a clinically remarkable outcome.CASE SUMMARY An 80-year-old female patient with a 20-year history of type 2 diabetes mellitus experienced recurrent diabetic foot pain for 15 years.She had multiple hospitalizations due to acute infections and poorly controlled hyperglycemia.Long-term treatments included metformin and gliclazide.Upon presentation,she had a nonhealing wound on her left dorsal foot,diagnosed as a severe DFU(Texas classification:Grade II,stage D).She declined amputation and opted for conservative treatment.The medical team applied an acemannan-enriched glycolipid sphere dressing five times daily to the left calf and foot,avoiding the wound area.Frequency was reduced to three times daily after scab formation.Weight-bearing on the injured foot was avoided.Through in-person and online consultations,the team managed her lifestyle and diet,emphasizing natural foods.After 5 months,the DFU healed without significant scarring or functional loss.No recurrence was observed during the 2-year follow-up.Acemannan-enriched glycolipid sphere dressings promote DFU healing.This suggests the potential of these dressings for treating other refractory wounds.
基金financially supported by the National Natural Science Foundation of China (Nos. 51773043, 81772363, and 21474019)National Key R&D Program of China (No. 2016YFC1100300)China Postdoctoral Science Foundation (No. 2018M632020)
文摘Bacterial infection is a very troublesome issue in wound treatment, which stimulates exudate formation and severely delays the healing process. Herein, a thermogelling dressing system composed of two triblock copolymers of poly(D,L-lactic acid-co-glycolic acid)-b-poly(ethylene glycol)-b-poly(D,L-lactic acid-co-glycolic acid)(PLGA-PEG-PLGA) with different block lengths was developed to deliver teicoplanin(TPN), a glycopeptide antibiotic, for cutaneous wound repair. The TPN-loaded thermogel was a free-flowing sol at room temperature and formed a semi-solid gel at physiological temperature. In vitro studies demonstrated that the TPN-loaded thermogel system exhibited desired tissue adhesiveness and realized the sustained release of TPN in a fast-followed-slow manner for over three weeks. Furthermore, a full-thickness excision wound model in Sprague-Dawley(SD) rats was constructed to assess the efficacy of TPNloaded thermogel formulation. Gross and histopathologic observations implied that treatment with the thermogel formulation reduced inflammation response, promoted disposition of collagen, enhanced angiogenesis, and accelerated wound closure and maturity of SD rats.The combination of the bioactivity of TPN and the acidic nature of the thermogel matrix was responsible for such an enhanced wound healing process. Consequently, the TPN-loaded PLGA-PEG-PLGA thermogel is a good candidate of wound dressing for full-thickness excision wound healing.
基金supported by the Yeungnam University research grant in 2017。
文摘Polyurethane foam dressings for dermal wounds were formulated with natural polyols in order to improve the foam characteristics and the release of 2 active agents,silver and asiaticoside(AS)as an antimicrobial agent and an herbal wound healing agent,respectively.The foam was instantly formed by interaction of polyols and diisocyanate.Hydroxypropyl methylcellulose,chitosan and sodium alginate were individually mixed with themain polyols,polypropylene glycol,in the formulation while the active componentswere impregnated into the obtained foam dressing sheets.Although the type and amount of the natural polyols slightly affected the pore size,water sorption-desorption profile and compression strength of the obtained foam sheets,a prominent effect was found in the release of both active components.Among natural polyols formulations,foam sheets with alginate showed the highest silver and AS release.Non-cytotoxicity of these foam sheets to human fibroblast cells was confirmed.Antimicrobial testing on four bacteria strains showed that 1mg/cm^2 silver in formulations with 6%of natural polyols and without natural polyols had sufficient content of the silver release with comparable inhibition zone and significantly larger zone than other formulations.In pig study,the foam dressing with 6%alginate,1mg/cm^2 silver and 5%AS could improve wound healing in both the percentage of the wound closure and histological parameters of the dermal wound without any dermatologic reactions.In conclusion,this innovative foam dressing had potential to be a good candidate for wound treatment.
基金supported by the National Natural Science Foundation of China (grant numbers: 51973172)Natural Science Foundation of Shaanxi Province (No. 2020JC03 and 2019TD-020)+2 种基金State Key Laboratory for Mechanical Behavior of Materials, and Opening Project of Key Laboratory of Shaanxi Province for Craniofacial Precision Medicine Research, College of Stomatology, Xi’an Jiaotong University (No. 2019LHM-KFKT008)the World-Class Universities (Disciplines)the Characteristic Development Guidance Funds for the Central Universities
文摘Bacterial infection and the ever-increasing bacterial resistance have imposed severe threat to human health.And bacterial contamination could significantly menace the wound healing process.Considering the sophisticated wound healing process,novel strategies for skin tissue engineering are focused on the integration of bioactive ingredients,antibacterial agents included,into biomaterials with different morphologies to improve cell behaviors and promote wound healing.However,a comprehensive review on antibacterial wound dressing to enhance wound healing has not been reported.In this review,various antibacterial biomaterials as wound dressings will be discussed.Different kinds of antibacterial agents,including antibiotics,nanoparticles(metal and metallic oxides,lightinduced antibacterial agents),cationic organic agents,and others,and their recent advances are summarized.Biomaterial selection and fabrication of biomaterials with different structures and forms,including films,hydrogel,electrospun nanofibers,sponge,foam and three-dimension(3D)printed scaffold for skin regeneration,are elaborated discussed.Current challenges and the future perspectives are presented in thismultidisciplinary field.We envision that this review will provide a general insight to the elegant design and further refinement of wound dressing.
文摘The hydrogel wound dressing based on polyvinyl alcohol (PVA) was prepared by the freezing-thawing cyclic method. The dehydration kinetics of prepared hydrogels was determined using the experimental method and mathematical modeling based on diffusion mechanism. The results show that the dehydration rate of PVA hydrogel wound dressing inversely depends on the hydrogel thickness as well as water content of the wound. On the other hand, the initial water content of hydrogel and the atmospheric humidity have little direct effect on the dehydration rate. The good agreement between experimental and mathematical modeling results in early stages of dehydration process shows that the predominate factor determining the dehydration of these wound dressings is diffusion.
基金Authors acknowledged the funding supports from the National Key R&D Program of China(2019YFA0905200).
文摘With the changes in the modern disease spectrum,pressure ulcers,diabetic feet,and vascular-derived diseases caused refractory wounds is increasing rapidly.The development of wound dressings has partly improved the effect of wound management.However,traditional wound dressings can only cover the wound and block bacteria,but are generally powerless to recurrent wound infection and tissue healing.There is an urgent need to develop a new type of wound dressing with comprehensive performance to achieve multiple effects such as protecting the wound site from the external environment,absorbing wound exudate,anti-inflammatory,antibacterial,and accelerating wound healing process.Hydrogel wound dressings have the aforementioned characteristics,and can keep the wound in a moist environment because of the high water content,which is an ideal choice for wound treatment.This review introduces the wound healing process and the development and performance advantages of hydrogel wound dressings.The choice of different preparation materials gives the particularities of different hydrogel wound dressings.It also systematically explains the main physical and chemical crosslinking methods for hydrogel synthesis.Besides,in-depth discussion of four typical hydrogel wound dressings including double network hydrogels,nanocomposite hydrogels,drug-loaded hydrogels and smart hydrogels fully demonstrates the feasibility of developing hydrogels as wound dressing products and their future development trends.
基金supported by a Major Project of the Ministry of National Science and Technology of China(Grant No.2014ZX09J14103-09C).
文摘Background: Wounded personnel who work at sea often encounter a plethora of difficulties. The most important of these difficulties is seawater immersion. Common medical dressings have little effect when the affected area is immersed in seawater, and only rarely dressings have been reported for the treatment of seawater-immersed wounds. The objective of this study is to develop a new dressing which should be suitable to prevent the wound from seawater immersion and to promote the wound healing.Methods: Shark skin collagen(SSC) was purified via ethanol de-sugaring and de-pigmentation and adjusted for p H. A shark skin collagen sponge(SSCS) was prepared by freeze-drying. SSCS was attached to an anti-seawater immersion polyurethane(PU) film(SSCS+PU) to compose a new dressing. The biochemical properties of SSC and physicochemical properties of SSCS were assessed by standard methods. The effects of SSCS and SSCS+PU on the healing of seawaterimmersed wounds were studied using a seawater immersion rat model. For the detection of SSCS effects on seawaterimmersed wounds, 12 SD rats, with four wounds created in each rat, were divided into four groups: the 3 rd day group, 5 th day group, 7 th day group and 12 th day group. In each group, six wounds were treated with SSCS, three wounds treated with chitosan served as the positive control, and three wounds treated with gauze served as the negative control. For the detection of the SSCS+PU effects on seawater-immersed wounds, 36 SD rats were divided into three groups: the gauze(GZ)+PU group, chitosan(CS)+PU group and SSCS+PU group, with 12 rats in each group, and two wounds in each rat. The wound sizes were measured to calculate the healing rate, and histomorphology and the immunohistochemistry of the CD31 and TGF-β expression levels in the wounded tissues were measured by standard methods.Results: The results of Ultraviolet-visible(UV-vis) spectrum, Fourier-transform infrared(FTIR) spectrum, circular dichroism(CD) spectra, sodium dodecyl sulfate polyacrylamide gel electrophoresis(SDS-PAGE), and amino acid composition analyses of SSC demonstrated that SSC is type I collagen. SSCS had a homogeneous porous structure of approximately 200μm, porosity rate of 83.57%±2.64%, water vapor transmission ratio(WVTR) of 4500 g/m2, tensile strength of 1.79±0.41 N/mm, and elongation at break of 4.52%±0.01%. SSCS had significant beneficial effects on seawater-immersed wound healing. On the 3 rd day, the healing rates in the GZ negative control, CS positive control and SSCS rats were 13.94%±5.50%, 29.40%±1.10% and 47.24%±8.40%, respectively. SSCS also enhanced TGF-in the initial stage of the healing period. The SSCS+PU dressing effectively protected woundsβ and CD31 expression from seawater immersion for at least 4 h, and accelerated re-epithelialization, vascularization and granulation formation of seawater-immersed wounds in the earlier stages of wound healing, and as well as significantly promoted wound healing. The SSCS+PU dressing also enhanced expression of TGF-n and gauze dressings.β and CD31. The effects of SSCS and SSCS+PU were superior to those of both the chitosaConclusion: SSCS has significant positive effects on the promotion of seawater-immersed wound healing, and a SSCS+PU dressing effectively prevents seawater immersion, and significantly promotes seawater-immersed wound healing.
基金the National Natural Science Foundation of China(No.22175125)the Natural Science Foundation of the Jiangsu Higher Education Institutions of China(No.21KJA150008)the Key Laboratory of Polymeric Materials De-sign and Synthesis for Biomedical Function,Soochow University,and the Priority Academic Program Development of Jiangsu Higher Education Institutions(PAPD).
文摘For most traditional wound dressings,it is challenging to simultaneously eliminate bacteria and promote angiogenesis to accelerate the healing process of bacteria-infected wounds.In this work,we develop a multifunctional dressing based on bacterial cellulose(BC)deposited with a tannic acid/Cu^(2+)ion/Mg^(2+)ion(TCM)complex film.Overall,the TCM complex exhibits robust interfacial adhesion to modify BC and good photothermal properties to effectively eradicate bacteria in the wound area under near-infrared(NIR)irradiation.The individual components of the TCM complex have several advantageous features for wound healing,such as antibacterial ability and negligible cytotoxicity;in particular,the released Cu^(2+)and Mg^(2+)ions are favorable for the proliferation,migration,and tube formation of endothelial cells in vitro.The results of in vivo experiments demonstrated that with the assistance of NIR irradiation,this composite dressing is more effective than traditional gauze or pristine BC dressing in promotion of angiogenesis and collagen deposition without causing remarkable inflammation,thereby accelerating the healing process of bacteria-infected full-thickness skin wounds.This work thus provides a simple and facile way to fabricate multifunctional BC-based dressings that could be potentially used for treating infected wounds.
基金supported by the National Science Foundation of China(81301345)
文摘The variety of wound types has resulted in a wide range of wound dressings, with new products frequently being introduced to target different aspects of the wound healing process. The ideal wound dressing should achieve rapid healing at a reasonable cost, with minimal inconvenience to the patient. Microcurrent dressing, a novel wound dressing with inherent electric activity, can generate low-level microcurrents at the device-wound contact surface in the presence of moisture and can provide an advanced wound healing solution for managing wounds. This article offers a review of the effects and mechanisms of the microcurrent dressing on the healing of skin wounds.
基金The work was supported by grants from the Dark Blue 123 Project of First Affliated Hospital of Naval Medical University(Foundation No.2019SLZ015)Youth Cultivation Project of Military Medical Science(Foundation No.14QNP083)the Clinical Research Plan of SHDC(Foundation No.SHDC2020CR3097B).
文摘Objective This study tests the efficacy of Bletilla striata polysaccharide(BSP),carboxymethyl chitosan(CMC),baicalin(BA)and silver titanate(ST)in a wound dressings to fight infection,promote healing and provide superior biocompatibility.Methods The antibacterial activity of BA and ST was evaluated in vitro using the inhibition zone method.BA/ST/BSP/CMC porous sponge dressings were prepared and characterized.The biocompatibility of BA/ST/BSP/CMC was assessed using the cell counting kit-8 assay.The therapeutic effect of BA/ST/BSP/CMC was further investigated using the dorsal skin burn model in Sprague-Dawley rats.Results The wound dressing had good antibacterial activity against Escherichia coli and Staphylococcus aureus through BA and ST,while the combination of BSP and CMC played an important role in promoting wound healing.The BA/ST/BSP/CMC porous sponge dressings were prepared using a freeze-drying method with the concentrations of BA and ST at 20 and 0.83 mg/mL,respectively,and the optimal ratio of 5%BSP to 4%CMC was 1:3.The average porosity,water absorption and air permeability of BA/ST/BSP/CMC porous sponge dressings were measured to be 90.43%,746.1%and 66.60%,respectively.After treatment for 3 and 7 days,the healing rates of the BA/ST/BSP/CMC group and BA/BSP/CMC group were significantly higher than those of the normal saline(NS)group and silver sulfadiazine(SSD)group(P<0.05).Interleukin-1βexpression in the BA/ST/BSP/CMC group at 1 and 3 days was significantly lower than that in the other three groups(P<0.05).After being treated for 3 days,vascular endothelial growth factor expression in the BA/BSP/CMC group and BA/ST/BSP/CMC group was significantly higher than that in the NS group and SSD group(P<0.05).Inspection of histological sections showed that the BA/ST/BSP/CMC group and BA/BSP/CMC group began to develop scabbing and peeling of damaged skin after 3 days of treatment,indicating accelerated healing relative to the NS group and SSD group.Conclusion The optimized concentration of BA/ST/BSP/CMC dressing was as follows:6 mg BSP,14.4 mg CMC,0.5 mg ST and 12 mg BA.The BA/ST/BSP/CMC dressing,containing antibacterial constituents,was non-cytotoxic and effective in accelerating the healing of burn wounds,making it a promising candidate for wound healing.
基金supported by the National Natural Science Foundation of China(Project No.51573103,No.21274094)2019 Foundation Research fostering project 21 and postdoctoral fund(2019SCU12007)from SiChuan University
文摘Bacterial infections are a major cause of chronic infections.Thus,antibacterial material is an urgent need in clinics.Antibacterial nanofibers,with expansive surface area,enable efficient incorporation of antibacterial agents.Meanwhile,structure similar to the extracellular matrix can accelerate cell growth.Electrospinning,the most widely used technique to fabricate nanofiber,is often used in many biomedical applications including drug delivery,regenerative medicine,wound healing and so on.Thus,this review provides an overview of all recently published studies on the development of electrospun antibacterial nanofibers in wound dressings and tissue me-dicinal fields.This reviewer begins with a brief introduction of electrospinning process and then discusses electrospun fibers by incorporating various types of antimicrobial agents used as in wound dressings and tissue.Finally,we finish with conclusions and further perspectives on electrospun antibacterial nanofibers as 2D biomedicine materials.
基金This work was financially supported by the National Natural Science Foundation of China for support for this research(Nos.81560737 and 31860250)We also thank the Natural Science Foundation of Gansu Province through Grant 18JR3RA148+1 种基金the Fundamental Research Funds for Key Laboratory of Drug Screening and Deep Processing for Traditional Chinese and Tibetan Medicine of Gansu Province Grant(No.20180801)Distinguished Young Cultivation Project(No.JQ2020)of Lanzhou University of Technology.
文摘A series of hydrogels with different ratios of chitosan and licorice polysaccharide(LP)were prepared by crosslinking to different concentrations of genipin(gp).They were characterized by FTIR(Fourier transform infrared spectroscopy),SEM(Scanning electron microscope),swelling ratio,rheological measurements,degradation with time,cytotoxicity,and antibacterial efficacy.Results show that the hydrogels have porous structures.With an increase in LP content,the swelling rate grows in the early stage of immersion in buffer and drops later.The swelling ratio ranged from 986%to 1677%,and stiffness varied from 777 Pa to 1792 Pa.The addition of LP reduced the mechanical strength and delayed gelation and degradation of the hydrogels.However,the most important discovery was that gp increases the viability of NIH 3T3 cells from 94%to 137%,and LP raises the bacteriostatic efficacy from 51%to 78%.Hydrogels synthesized from 1%genipin,3%chitosan,and 4%licorice polysaccharide showed the best antibacterial and fibroblast proliferation promoting activities.They exhibited moderate swelling and degradation rates over time,while being more suitable to affect healing of chronic wound infections.These results provide a new strategy to improve the antibacterial effectiveness and cyto-compatibility of chitosan hydrogels with water soluble active LPs from Glycyrrhiza that derive from traditional Chinese medicine.
文摘Inspired by the skin structure,an asymmetric wettability tri-layer nanofiber membrane(TNM)consisting of hydrophilic inner layer loaded with lidocaine hydrochloride(LID),hydrophobic middle layer with ciprofloxacin(CIP)and hydrophobic outer layer has been created.The hydrophobic outer layer endows the TNM with waterproof function and anti-adhesion from contaminants.The hydrophobic middle layer with CIP preserves long-term inhibition of bacteria growth and the hydrophilic inner layer with LID possesses optimal waterabsorbing capacity and air permeability.The TNM dramatically elevates the water contact angles from 10°(inner layer)to 120(outer layer),indicating an asymmetric wettability,which could directionally transport wound exudate within the materials and meanwhile maintain a comfortable and moist environment to promote wound healing.Furthermore,the sequential release of LID and CIP could relieve pain rapidly and achieve antibacterial effect in the long run,respectively.In addition,the TNM shows superior biocompatibility towards L929 cells.The in vivo results show the TNM could prevent infection,accelerate epithelial regeneration and significantly accelerate wound healing.This study indicates the developed TNM with asymmetrical wettability and synergetic drug release shows great potential as a wound dressing in clinical application.
