Rapid Wound Healing Research Articles

Heterojunction Nanozyme Hydrogels Containing Cu-O-Zn Bonds with Strong Charge Transfer for Accelerated Diabetic Wound Healing.

The complex microenvironment of persistent inflammation and bacterial infection is a major challenge in chronic diabetic wounds. The development of nanozymes capable of efficiently scavenging reactive oxygen species (ROS) is a promising method to promote diabetic wound healing. However, many nanozymes show rather limited antioxidant activity and ROS-dependent antibacterial effects under certain circumstances, further weakening their ability to scavenge ROS. To meet these challenges, electronically regulated bioheterojunction (E-bio-HJ) nanozyme hydrogels derived from metal-organic frameworks (MOFs) were designed and prepared via an interface engineering strategy. Owing to the electron transfer and redistribution effects of the abundant and highly dispersed Cu-O-Zn sites at the heterogeneous interface, the E-bio-HJ nanozymes exhibited catalase (CAT)-like activity with ultrahigh hydrogen peroxide affinity (Km = 25.76 mM) and sustained ROS consumption. In addition, owing to the enhanced interfacial effect of E-bio-HJ and the good biocompatibility and cell adhesion of the methacryloylated gelatin (Gel) hydrogel, the E-bio-HJ gelatin hydrogel (E-bio-HJ/Gel) further reduced inflammation by inducing macrophage transformation to the M2 phenotype, accompanied by excellent antimicrobial properties and enhanced cell migration, angiogenesis, and collagen deposition, which synergistically promoted diabetic wound healing. This highly effective and comprehensive strategy offers a new approach for the rapid healing of diabetic wounds.

Fast Autograft Generation Using Transferable 3D Keratinocyte Cell Sheet on PEDOT:PSS Composite PDMS Membrane for Enhancing Wound Healing.

The application of cell sheet technology for wound healing preserves dense cell tissue and the natural extracellular matrix (ECM), contributing to disease prevention. Despite the effectiveness of autologous and allograft cell sheets for wound healing, conventional cell sheets, although stable, may experience necrosis in their middle layers due to a lack of nutrients or oxygen. To address these issues, a novel approach is proposed to create cell sheets using mechanical and electrical stimulation. This method not only facilitates the transfer of cell sheets but also enhances cell bioactivity. The performance of the proposed membrane, with a mechanically controlled microstructure under electrical stimulation, is validated in both in vitro and in vivo models. The micro-structured membrane allows for diverse electrical stimulation compared to flat membranes, which accelerates the detachment of cell sheets and promotes angiogenesis and re-epithelialization. These findings indicate that the innovative cell sheet technology could significantly enhance rapid wound healing in regenerative medicine.

Black rice bioactive with multifunctional health promotional activities: A special reference to wound healing activity with polyhydroxybutyrate composite

Black rice (BR) extract contains several functional food bioactive components that are health-promoting. This study assessed the multifunctional bioactivities of various BR extracts (methanol, ethanol, acetone, and aqueous). These BR extracts revealed significant antioxidant and antibacterial activity against various bacterial strains. Acetone extract exhibited high cytotoxicity against gastric adenocarcinoma cells (AGS), while ethanol extract was cytotoxic against pancreatic cancer cells (PANC-1). Moreover, the acetone extract induced 33.6 % and 16.5 % apoptosis in PANC-1 and AGS cells, respectively. Acetone extract showed significant anti-inflammatory action, reducing 76 % production of nitric oxide in the RAW 264.7 (murine macrophage). Furthermore, all BR extracts inhibited PANC-1 and AGS migration and promoted RAW 264.7 migration. Field emission scanning electron microscope, Fourier-transform infrared spectroscopy, and X-ray diffraction analysis of the BR-polyhydroxybutyrate composite revealed successful deposition for BR extracts. This study highlights the potential of BR extracts to develop multifunctional activity-based strips for rapid wound healing.

PROSPECTIVE DIRECTIONS OF THE DEVELOPMENT OF BIOACTIVE GLASS FIBERS FOR MEDICAL APPLICATION

The urgency of the development and use of glass fibers for the creation of microfiber dressings for the treatment of chronic wounds in combat conditions has been determined. The availability of such materials is especially important in the conditions of hostilities, which are characterized by the need for quick resuscitation of the wounded and the provision of emergency aid on the battlefield. The use of such materials will save life, shorten the rehabilitation period, and speed up the recovery of the military and civilian population. An analysis of the scientific and technical literature on the composition and properties of bioactive glass fibers for medical use was carried out. The compositions and properties of glass fibers for various purposes were analyzed and their possibility of use in the development of bioactive glass fibers for medical use was established. The selection of the compositions of bioactive glass fibers with a prolonged biocidal effect for the rapid healing of wounds and the restoration of bone tissue is substantiated. The mechanism of action of biocidal components and boron ions in the composition of bioglasses on the ability to inhibit the negative effects of pathogenic microorganisms was analyzed. The use of boroaluminophosphate glass fibers for the manufacture of effective dressings for the treatment of wounds in crisis situations in combat conditions will increase the percentage of survival and reduce the duration of treatment due to the direct action of cations and anions of the materials in vivo. The main theoretical principles of the creation of bioactive boroaluminophosphate glass fibers, modified with group II metal cations, which will be characterized by the presence of a strengthened surface layer, and characterized at the same time by high biocompatibility, biocide with prolonged action and non-toxicity, have been determined. The introduction of domestically developed bioactive glass fibers into medical practice will significantly increase the competitiveness of domestic medical materials, as well as ensure defense capability and safety, and contribute to the stabilization of the market in the conditions of sustainable development of the state.

Silk fibroin aerogels with AIE-featured berberine and MXene for rapid hemostasis and efficient wound healing

Rapid hemostasis and wound healing are crucial in emergency trauma situations for saving patients' lives. Traditional hemostatic materials often have drawbacks such as slow hemostasis and susceptibility to post-hemostasis bacterial infections. Therefore, there is an urgent need for advanced wound dressing materials that can provide both rapid hemostasis and antimicrobial properties. In this study, we designed and fabricated a biocompatible hemostatic silk fibroin (SF) aerogel loaded with aggregation-induced emission (AIE)-featured berberine (BBr) and Ti3C2Tx MXene. The resulting SFMB aerogel demonstrates robust mechanical properties and a porous structure that enables quick hemostasis. This aerogel exhibits photodynamic and photothermal responses for antimicrobial activity, releases BBr upon light exposure to enhance bacterial-killing efficiency (99.33 % in vitro and 99.09 % in vivo), and effectively promotes the healing of infected wounds in vivo through combined photothermal/photodynamic antibacterial and anti-inflammatory mechanisms. Furthermore, the aerogel shows high hemocompatibility and cytocompatibility, supporting its potential biomedical applications. Overall, the synthesized SFMB aerogel holds promise for treating bacteria-infected wounds and for use in first aid applications in clinical settings.

Zinc Oxide-Enhanced Copper Sulfide Nanozymes Promote the Healing of Infected Wounds by Activating Immune and Inflammatory Responses.

Bacterial infection and an excessive inflammatory response are two major factors that affect the healing of infected wounds. The zinc oxide/copper sulfide (ZnO-CuS) microspheres (MSs) developed in this work can kill bacteria and resist inflammation. ZnO-CuS exhibits different enzyme-like activities depending on pH. In acidic environments, ZnO-CuS exhibits peroxidase-like (POD-like) activity and can convert hydrogen peroxide (H2O2) into hydroxyl radicals (•OH) for sterilization. Under neutral conditions, ZnO-CuS removes reactive oxygen species (ROS) and can convert excess ROS into water and oxygen. The in vitro results of the antibacterial test demonstrate the pronounced disruption effect of ZnO-CuS on the bacterial biofilm and cell membrane. The transcriptome sequencing results of wounded animal tissue reveal that ZnO-CuS MSs increase the expression of proteins produced by immune cells, and reduce the expression levels of inflammatory factors at the wound site. Therefore, antimicrobial activity and rapid wound healing can be achieved by regulating the immune response and reducing the inflammatory response. The results from hemolysis, routine blood and blood biochemistry analyses demonstrate the excellent biosecurity of the ZnO-CuS MSs.

Nanoclay Mediated Two-Pronged Strategy for Infected-Wound Healing.

Photothermal therapy (PTT) is an efficient way to combat bacterial infections and circumvent multidrug resistance. However, balancing efficacious bacterial killing and minimizing damage to the surrounding normal tissues remain a great challenge. Herein, a highly cooperative Prussian blue/kaolinite (PB/Kaol) hybrid nanosystem is constructed for antibacterial therapy to accelerate the healing of infected wounds. After hybridization with Kaol, the prepared PB/Kaol forms interfacial Al-O-Fe bonds, a fast charge transfer channel from Kaol to PB, which contributes to the enhanced photothermal effect of PB/Kaol. Additionally, the hydroxyl and Lewis acid-base sites of the Kaol surface could promote the adhesion of PB/Kaol to bacteria, thereby ensuring that as much hyperthermia as possible is focused on the bacteria and minimizing damage to the surrounding healthy tissues. Furthermore, PB/Kaol inherits the anti-inflammatory and hemostasis functions of PB and Kaol, resulting in the rapid healing of infected wounds.

A sequential treatment strategy by copper ion-doped nanofiber dressing for highly efficient biofilm combating and rapid wound healing

Copper ions are considered as a promising alternative to combat infected wound and accelerate wound healing. However, exhibiting good antibiofilm activity meanwhile minimizing cell toxicity remains a great challenge. To address this issue, we provide a sequential treatment strategy to combat biofilm infected wound with low copper ion (Cu2+) release (as low as 1.2 μg·mL−1). Polydopamine (PDA) adherent copper ion complex is constructed on thermoplastic polyurethane (TPU) to develop the Cu2+@PTPU nanofibers. With the application of Cu2+@PTPU wound dressing, nitric oxide (NO) gas is released by catalyzing endogenous donor, thereby rapidly eliminating more than 90 % biofilm biomass. Subsequent moderate photothermal treatment (∼47℃) significantly enhanced bactericidal effect by deconstructing bacteria membrane. As a result, the biofilm infection was eradicated in only ∼ 6h, significantly more effective than existing methods (∼24 h). Additionally, Cu2+@PTPU dressing not only exhibits excellent cell compatibility, but also promotes wound healing. In vivo study demonstrates that it reduces the level of inflammatory responses by 104 % and increases angiogenesis capacity by 115 %, compared with untreated group, thereby narrowing the wound site area by 72 % at day 14 after treatment. Overall, the Cu2+@PTPU dressing and sequential treatment strategy provide quick, safe, yet efficacious biofilm combating outcomes and facilitates rapid wound healing.

Multi-functional Gleditsia sinensis galactomannan-based hydrogel with highly stretchable, adhesive, and antibacterial properties as wound dressing for accelerating wound healing

Design and development of a multifunctional wound dressing with self-healing, adhesive, and antibacterial properties to attain optimal wound closure efficiency are highly desirable in clinical applications. Nevertheless, conventional hydrogels face significant barriers in their mechanical strength, adhesive performance, and antibacterial properties. Herein, a tough hydrogel based on aldehyde-grafted galactomannan was synthesized through radical copolymerization and Schiff base reaction, incorporating hyaluronic acid, acrylamide, and the zwitterionic monomer to create a multi-crosslinked structure. The multiple crosslink structure pattern consisting of multiple hydrogen bonding, ionic interactions, reversible Schiff bases bonds, and molecular chain entanglement endowed this hydrogel with multiple functionalities, including high tensile strength (25 kPa), tensile strain (2200 %), toughness (391.59 kJ/m3), and Young's modulus (9.77 kPa). The presence of catechol groups and zwitterionic groups endow hydrogels with outstanding adhesion strength (42.21 kPa), which satisfied the adhesive demand for the ample motion of specific areas. The zwitterionic monomer provided long-lasting antibacterial properties and promoted migration and growth of negatively charged cells, capable of establishing efficient antibacterial barriers and serving as wound dressing. The in vivo and vitro experiments manifested that the optimized hydrogel demonstrated an inconspicuous inflammatory response, facilitating rapid healing of full-thickness skin wound in rat models. Therefore, this work provides a promising strategy and an ideal candidate for wound healing dressings in treating infected skin wounds.

High Antimicrobial Electrotherapy and Wound Monitoring Hydrogel with Bimetal Phenolic Networks for Smart Healthcare

AbstractThe design and fabrication of novel soft bioelectronic materials for rapid wound healing and real‐time monitoring are critical for smart healthcare. However, developing such integrated multifunctional materials devices remains challenging due to fabrication dynamics and sensing interface issues. Herein, a novel strategy is presented for accelerating the kinetics of hydrogels integrating antimicrobial, electrotherapeutic, and wound monitoring functions via bimetallic phenolic networks. The Al3+ catalyzes the radical copolymerization reaction of acrylic acid, resulting in the gelation of the system within 10 s, and also catalyzes the redox reaction between silver and lignin, inducing the sustained release of catechol, which significantly enhances the hydrogel's antimicrobial activity and shortened the wound healing process. Meanwhile, the abundant non‐covalent interactions enhance the hydrogel's tissue adhesion, and mechanical properties (tensile strength 1.558 MPa and elongation 1563%). In addition, the bimetallic ions endow the hydrogels with excellent sensing properties. Under the synergy of electrical stimulation, the wound healing rate is accelerated. Notably, wound assessment can be performed by monitoring changes in electrical signals over the wound, which can assist physicians and patients in achieving intelligent wound management. This work provides new insights into the design and application of multifunctional smart bioelectronic materials.

Guar gum and gelatin-based hydrogel wound dressing loaded calcium-containing nanoparticles: Simpler preparation, faster hemostasis and faster pro-wound healing properties

In this work, we prepared a novel calcium-containing nanoparticles (CaNPs) and added it to a hydrogel composed of guar gum (GG) and gelatin (Gel) as a backbone to prepare a novel hydrogel (GG@Gel-Ca) with rapid hemostasis, antibacterial effect and wound healing promotion. We conducted a series of test to characterize the structure and properties of CaNPs and GG@Gel-Ca hydrogel. The results showed that CaNPs had been successfully prepared and had regular morphology, and the GG@Gel-Ca hydrogel had good swelling ability, good antibacterial ability and excellent hemocompatibility/hemostasis and perfect cytocompatibility. Animal experiments also showed that GG@Gel-Ca hydrogel was able to achieve rapid hemostasis in the rat liver hemostasis model and it could also accelerate wound healing in S. aureus infections. In summary, we developed an innovative and practical method to prepare a gentle hydrogel, employing two natural polysaccharides that remained unmodified and untreated with chemicals. By incorporating the prepared calcium nanoparticles into this hydrogel, we successfully achieved effective hemostasis. Therefore, the GG@Gel-Ca hydrogel has the potential for application as hemostatic wound dressings with antibacterial properties and good wound healing.

Nanocomposite conductive r(GO/BSA) hydrogel as an effective dressing for rapid chronic diabetic wound healing

Conductive hydrogels, with their soft, hydrated interface and superior electrical conductivity, represent a groundbreaking solution for diabetic wound healing. However, developing a conductive hydrogel with excellent biocompatibility has proven to be challenging. This study presents the synthesis of a novel conductive hydrogel composed of bovine serum albumin (BSA) protein and graphene oxide (GO) for the treatment of diabetic wounds. The prepared hydrogel is mildly reduced by ascorbic acid to facilitate charge-transfer and enhance its conductivity. Hydrogel is optimized for enhanced mechanical and electrical properties by changing the concentration of GO within the BSA matrix. The nanocomposite hydrogel demonstrates superior antibacterial properties and enhanced biocompatibility compared to the BSA hydrogel. The prepared hydrogel is investigated for wound healing capacity in a rat model, where it demonstrates rapid healing of chronic diabetic wound. The improved therapeutic outcomes are attributed to the hydrogel's ability to facilitate cellular activities through enhanced electrical conductivity by maintaining continuous electrical signal at the wound site. The presented findings suggest that nanocomposite protein-based conductive hydrogel not only hold great potential for advanced diabetic wound care and have potential for future innovation in tissue engineering, regenerative medicine and beyond.

Rapid wound healing with silver nanoparticle-decorated miswak-derived carbon quantum dots

BackgroundOxidants are pivotal in combating aging, cancer, and weakened immunity. Shielding the body from free radicals is crucial for an extended lifespan. The development of effective systems for this purpose is paramount. This study investigated the impact of miswak carbon quantum dots (M-CQD) on radical elimination and wound healing. MethodsM-CQD were synthesized via a hydrothermal method using miswak water extract at 220°C for 8 h. Chitosan-modified Ag@M-CS-CQD were produced. The characterization involved SEM, XRD, and FTIR analysis. M-CQD and Ag@M-CS-CQD emitted bluish-white light under UV excitation. ResultsAt 10, 30, and 50 μg/mL, DPPH• and phosphomolybdenum complex radicals inhibited 67%, 82%, and 98%, respectively, with Ag@M-CS-CQD demonstrating the highest activity. The IC50 values for M-CQD and Ag@M-CS-CQD were 0.91 ±0.010 and 1.183 ±0.033, respectively. Ag@M-CS-CQD NPs displayed remarkable wound healing efficacy at 20 μg/L, highlighting their potential as potent antioxidants. Immunohistochemical analyzes also showed that Ag@M-CS-CQD increased TGF-β expression levels, which was associated with wound healing. ConclusionThis eco-friendly synthesis method yielded Ag@M-CS-CQD, which exhibited robust antioxidant properties and efficacy in wound healing. This study emphasizes the potential of these nanoparticles as effective therapeutic agents.

Effect of Mirabilis jalapa Plant Fortified with Nano-Quercetine to Accelerate Wound Healing in Vivo

Given the problem of incomplete wounds affecting the skin, which leads to tearing and damage to its parts in accidents, investigation and discovery of effective medicines for wounds affecting the skin has become an important aim. Therefore, it is necessary to continue studying and experimenting with new and effective medicines, including effective substances and the discovery of effective nanomaterials. To reach efficient treatments to treat such injuries. In this study, Nano-Quercetine was prepared by grinding. This material was examined by (FTIR), (XRD) and then (FE-SEM) was used, and the results obtained were on the nanoscale with sizes ranging between (13.40-44.66 nanometers). The effectiveness and effect of the materials prepared from nanoparticles and Mirabilis Jalapa plant were studied in the living body and at different concentrations (10, 50, 100) mg on wounds in the skin of laboratory mice. The results of the study showed the effectiveness and speed of healing of wounds that affect the skin of laboratory mice using a Nano-Quercetine preparation supported by Mirabilis Jalapa plant extract. The result of wound healing was significant (p<0.05) on the eighth day of the experiment, as the average and standard deviation of healing were (1.66±0.577) for the concentration of 10 mg, (0.00±0.000) for the concentration of 50 mg, (0.00±0.000) for the concentration of 100 mg, compared to the second day of the experiment, which was (28.00± 0.005, 26.96± 0.398, 25.07±0.887) for concentrations 10 mg, 50 mg, and 100 mg, respectively. The results of the study showed effective activity and rapid healing of wounds affecting the skin of laboratory mice using the nano-complex of the alcoholic extract of the Mirabilis Jalapa plant fortified with quercetin. It is one of the medicinal plants that have great therapeutic value and are important vital sources. When the active substances are loaded onto the surfaces of Nano-Quercetine, it leads to their reaching the target, as plant materials are natural compounds that have enormous potential as antioxidants and are of great importance in providing health benefits against many diseases. Each part of the plant has its medicinal properties that possess different types of secondary metabolites that play an important role in treating different types of diseases, including wounds that affect humans and animals.

Exosomes and microRNAs: insights into their roles in thermal-induced skin injury, wound healing and scarring.

A burn is a type of injury to the skin or other tissues caused by heat, chemicals, electricity, sunlight, or radiation. Burn injuries have been proven to have the potential for long-term detrimental effects on the human body. The conventional therapeutic approaches are not able to effectively and easily heal these burn wounds completely. The main potential drawbacks of these treatments include hypertrophic scarring, contracture, infection, necrosis, allergic reactions, prolonged healing times, and unsatisfactory cosmetic results. The existence of these drawbacks and limitations in current treatment approaches necessitates the need to search for and develop better, more efficient therapies. The regenerative potential of microRNAs (miRNAs) and the exosomal miRNAs derived from various cell types, especially stem cells, offer advantages that outweigh traditional burn wound healing treatment procedures. The use of multiple types of stem cells is gaining interest due to their improved healing efficiency for various applications. Stem cells have several key distinguishing characteristics, including the ability to promote more effective and rapid healing of burn wounds, reduced inflammation levels at the wound site, and less scar tissue formation and fibrosis. In this review, we have discussed the stages of wound healing, the role of exosomes and miRNAs in improving thermal-induced wounds, and the impact of miRNAs in preventing the formation of hypertrophic scars. Research studies, pre-clinical and clinical, on the use of different cell-derived exosomal miRNAs and miRNAs for the treatment of thermal burns have been documented from the year 2000 up to the current time. Studies show that the use of different cell-derived exosomal miRNAs and miRNAs can improve the healing of burn wounds. The migration of exosomal miRNAs to the site of a wound leads to inhibition of apoptosis, induction of autophagy, re-epithelialization, granulation, regeneration of skin appendages, and angiogenesis. In conclusion, this study underscores the importance of integrating miRNA and exosome research into treatment strategies for burn injuries, paving the way for novel therapeutic approaches that could significantly improve patient outcomes and recovery times.

Liposomal nano-encapsulation of bFGF combined with injectable BSA hydrogel for efficient burn wound healing

Rapid and scar-free healing of burn wounds is an urgent clinical issue. Basic fibroblast growth factor (bFGF) has been proven to promote the healing of burn wounds by accelerating ECM remodeling and angiogenesis. However, exudates from burn wounds can accelerate bFGF degradation, thereby affecting its bioactivity. This study proposes an effective protection strategy for bFGF that involves encapsulating bFGF in nanoliposomes (bFGF-NLip) and then incorporating bFGF-NLip into a bovine serum albumin (BSA) hydrogel. This hybrid hydrogel system (bFGF-NLip@B) could maintain the activity of bFGF, achieve sustained release, and allow phospholipids and cholesterol to penetrate the skin, thereby enabling bFGF to function in the dermis. The experimental results showed that the hydrogel was injectable with good mechanical properties and biocompatibility. In a mouse scald wound model, owing to the sustained release of bFGF and skin permeation function of the nanoliposomes, the hydrogel promoted granulation formation, collagen deposition, vascular regeneration, and re-epithelialisation, ultimately accelerating wound healing. In addition, the hydrogel effectively inhibited scar formation. This system provides novel insights into the delivery of bFGF and scar-free healing of burn wounds.

Antibacterial and Healing Efficacy of Mangiferin-Loaded Silver Nanoparticle and Chitosan-Alginate Membrane Dressings

Mangiferin, a bioactive constituent of Mangifera indica (family Anacardiaceae), has an impressive therapeutic profile, having antioxidant, anti-inflammatory, analgesic, antibacterial, and immunomodulatory properties capable of possessing wound healing potential. Our investigation aims to isolate and characterize mangiferin, green synthesis of silver nanoparticles (Ag-NPs) and production of chitosan alginate (Cs/Alg) film dressing loaded with mangiferin Ag-NPs and assess antibacterial and wound-healing properties against infected excision and burn wounds. The isolated mangiferin was authenticated by estimating melting point, thin layer chromatography (TLC), fourier-transform infrared spectroscopy (FTIR), and high-performance liquid chromatography (HPLC). Ag-NPs were green synthesized and characterized by UV-visible, particle size, zeta potential (ZP), entrapment efficiency (%EE), scanning electron microscope (SEM), transmission electron microscope (TEM), and stability study. Chitosan alginate membrane dressing was prepared by incorporating mangiferin Ag-NPs, and film thickness, pH, film weight, water intake capacity, and in-vitro drug release parameters were estimated. Among the four mangiferin Ag-NP batches, MN3 formed stable polydispersity spherical Ag-NPs with smaller particle size and high %EE. Mangiferin-loaded Cs/Alg film MN-CM4 showed significantly higher (p < 0.001) drug content, wettability, release profile, and favorable pH changes. The mangiferin Ag-NPs embedded Cs/Alg film dressing showed a significantly high antimicrobial effect against the gram-positive bacterial strain of S. aureus, commonly found in wounds. MN3 and MN-CM4 treatment showed the shortest epithelialization period and enhanced wound closure. The hydroxyproline content has significantly (p < 0.001) increased, and myeloperoxidase content was reduced by MN3 and MN-CM4 treatment. MN-CM4 treatment showed complete re-epithelialization reduced inflammatory cells with thicker and denser collagen fiber deposition. The effectiveness of the Cs/Alg film of mangiferin Ag-NPs dressing has a synergistic effect on promoting speedy wound healing. The Cs/Alg film of mangiferin Ag-NPs showed rapid wound healing against infected and burned wounds, enhanced collagen synthesis, and anti-inflammatory and antibacterial efficacy.

Genome of Halimeda opuntia reveals differentiation of subgenomes and molecular bases of multinucleation and calcification in algae

Algae mostly occur either as unicellular (microalgae) or multicellular (macroalgae) species, both being uninucleate. There are important exceptions, however, as some unicellular algae are multinucleate and macroscopic, some of which inhabit tropical seas and contribute to biocalcification and coral reef robustness. The evolutionary mechanisms and ecological significance of multinucleation and associated traits (e.g., rapid wound healing) are poorly understood. Here, we report the genome of Halimeda opuntia, a giant multinucleate unicellular chlorophyte characterized by interutricular calcification. We achieve a high-quality genome assembly that shows segregation into four subgenomes, with evidence for polyploidization concomitant with historical sea level and climate changes. We further find myosin VIII missing in H. opuntia and three other unicellular multinucleate chlorophytes, suggesting a potential mechanism that may underpin multinucleation. Genome analysis provides clues about how the unicellular alga could survive fragmentation and regenerate, as well as potential signatures for extracellular calcification and the coupling of calcification with photosynthesis. In addition, proteomic alkalinity shifts were found to potentially confer plasticity of H. opuntia to ocean acidification (OA). Our study provides crucial genetic information necessary for understanding multinucleation, cell regeneration, plasticity to OA, and different modes of calcification in algae and other organisms, which has important implications in reef conservation and bioengineering.

An antimicrobial microneedle patch promotes functional healing of infected wounds through controlled release of adipose tissue-derived apoptotic vesicles

The high incidence and mortality rates associated with acute and chronic wound infections impose a significant burden on global healthcare systems. In terms of the management of wound infection, the reconstruction and regeneration of skin appendages are essential for the recovery of mechanical strength and physiological function in the regenerated skin tissue. Novel therapeutic approaches are a requisite for enhancing the healing of infected wounds and promoting the regeneration of skin appendages. Herein, a novel antimicrobial microneedle patch has been fabricated for the transdermal controlled delivery of adipose tissue-derived apoptotic vesicles (ApoEVs-AT@MNP) for the treatment of infected wounds, which is expected to achieve high-quality scarless healing of the wound skin while inhibiting the bacteria in the infected wound. The microneedle patch (MNP) system possesses adequate mechanical strength to penetrate the skin, allowing the tips to remain inside tissue for continuous active release of biomolecules, and subsequently degrades safely within the host body. In vivo transplantation demonstrates that ApoEVs-AT@MNP not only inhibits bacterial proliferation in infected wounds but also significantly promotes effective and rapid scarless wound healing. Particularly noteworthy is the ability of ApoEVs-AT@MNP to promote the rapid formation of mature, evenly arranged hair follicles in infected wounds, observed as early as 8 days following implantation, which is essential for the restoration of skin function. This rapid development of skin appendages has not been reported this early in previous studies. Therefore, ApoEVs-AT@MNP has emerged as an excellent, painless, non-invasive, and highly promising treatment for infected wounds.

Flexible and antibacterial conductive hydrogels based on silk fibroin/polyaniline/AgNPs for motion sensing and wound healing promotion under electrical stimulation.

Flexible conductive hydrogel-based electronic skin (E-skin) for simultaneous biotherapeutics and sensing applications is one of the current research directions. In this study, conductive and homogeneous silk fibroin/polyaniline/AgNP complexes (SPAg complexes) were prepared with the assistance of silk fibroin, which greatly optimized the compatibility of PANI with the hydrogel matrix. Then, SPAg was introduced into the covalently crosslinked polymer network to prepare poly(acrylamide-co-sulfobetaine methacrylate) - SPAg hydrogels (labeled as PSPAg hydrogels). The PSPAg hydrogels exhibit good biocompatibility, excellent mechanical properties, superb adhesive performance, and fantastic sensing capabilities. Being connected to a smartphone via a Bluetooth system, the SPAg hydrogel-based E-skin was employed to accurately monitor human movements including vigorous joint movements and subtle facial micro-expressions. Finally, benefiting from the synergistic effect of antimicrobial and exogenous electrical stimulation, through promoting angiogenesis and accelerating collagen production in diabetic wounds, PSPAg E-skin successfully facilitates rapid diabetic wound healing. Therefore, the multifunctional PSPAg hydrogel-based E-skin shows great promise for applications in wearable devices and bioelectronics.