Transcutaneous electrotherapy of facial nerve injuries based on dissolvable conductive microneedles.

Local electrical stimulation (LES) is a widely used clinical method to treat peripheral nerve injury. However, existing plate electrodes (PE) usually suffer from low electronic transport efficiency, whereas acupuncture electrical stimulation may cause damage to normal tissues. There is an urgent need to develop an innovative LES technique with efficient electronic transport, minimal tissue injury and enhanced biosafety.

Oncostatin-M functionalized cryogel microspheres for promoting diabetic bone defects regeneration.

Background/objective: Bone defects, especially those associated with diabetes, pose a significant challenge due to impaired healing capabilities. bone tissue engineering harnesses the body's innate self-repair capabilities instead of introducing exogenous cells, and the development of biomaterials with well-designed biophysical and biochemical properties is pivotal for this strategy. Oncostatin M (OSM), a pleiotropic cytokine belonging to the IL-6 family, is responsible for recruiting endogenous cells and bone regeneration.

Harnessing RGDS peptides to regulate bacterial-host interfaces for targeted antimicrobial therapy.

Refractory infections caused by pathogenic bacteria, particularly multidrug-resistant bacteria, pose a significant threat to global human health. Emerging host-directed antimicrobial strategies have the potential to prolong the effectiveness of existing treatments or eliminate the development of antibiotic resistance, representing a promising avenue for addressing infections caused by resistant bacteria. Here, we propose a mechanobiology-based host-directed antimicrobial strategy that utilizes an inhibitory fibronectin (Fn) peptide, Arg-Gly-Asp-Ser (RGDS), to regulate bacterial-host interfacial adhesion forces and thereby effectively combat multidrug-resistant bacterial infections.

Macrophage membrane functionalized composite microspheres promote bone regeneration in periodontitis via manipulating inflammation reversing-osteogenesis coupling.

Periodontitis is characterized by inflammation and alveolar bone loss, primarily caused by immune cells activated by oral bacteria, leading to an imbalance between osteogenesis and bone resorption. Traditional treatments have limited efficacy, which has led to the exploration of regulating the immune microenvironment and utilizing tissue engineering methods as new research directions. Our study demonstrates that macrophage membranes, activated by LPS and IFN-γ, can effectively neutralize inflammatory factors.

Affinity Modifications of Porous Microscaffolds Impact Bone Regeneration by Modulating the Delivery Kinetics of Small Extracellular Vesicles.

Biomaterials functionalized with small extracellular vesicles (sEVs) hold great regenerative potential, and their therapeutic efficacy hinges on the delivery kinetics of the sEVs. Achieving rapid and stable loading, along with precisely controlled release of sEVs, necessitates affinity modifications of biomaterials. Here, we provide a quantitative description of the interaction between sEVs and various affinity molecules (i.

Engineered 3D mesenchymal stem cell aggregates with multifunctional prowess for bone regeneration: Current status and future prospects.

Background: Impaired efficacy of in vitro expanded mesenchymal stem cells (MSCs) is a universal and thorny situation, which cast a shadow on further clinical translation of exogenous MSCs. Moreover, the relatively lengthy healing process, host metabolic heterogeneity and the sophisticated cell recognition and crosstalk pose rigorous challenges towards MSC-based bone regeneration strategies. Three-dimensional (3D) cell aggregates facilitate more robust intercellular communications and cell-extracellular matrix (ECM) interactions, providing a better mimicry of microarchitectures and biochemical milieus in vivo, which is conducive for stemness maintenance and downstream bone formation.

Boosting the angiogenesis potential of self-assembled mesenchymal stem cell spheroids by size mediated physiological hypoxia for vascularized pulp regeneration.

Hypoxia is a pivotal factor in enhancing the vascularization potential of both two-dimensional (2D) cultured cells and three-dimensional (3D) cellular spheroids. Nevertheless, spheroids that closely mimic the in vivo microenvironment often experience excessive hypoxia, leading to the necrotic core and the release of toxic byproducts, ultimately impeding the regenerative process. To balance cell vitality and pro-angiogenic properties of cellular spheroids, this study investigates size-dependent hypoxia in stem cell spheroids utilizing an oxygen transfer finite element model.

Hydrogen bonding-mediated phase-transition gelatin-based bioadhesives to regulate immune microenvironment for diabetic wound healing.

Gelatin-based biomaterials have emerged as promising candidates for bioadhesives due to their biodegradability and biocompatibility. However, they often face limitations due to the uncontrollable phase transition of gelatin, which is dominated by hydrogen bonds between peptide chains. Here, we developed controllable phase transition gelatin-based (CPTG) bioadhesives by regulating the dynamic balance of hydrogen bonds between the peptide chains using 2-hydroxyethylurea (HU) and punicalagin (PA).

High-purity butoxydibutylborane catalysts enable the low-exothermic polymerization of PMMA bone cement with enhanced biocompatibility and osseointegration.

Polymethyl methacrylate (PMMA) based biomaterials have been widely utilized in clinics. However, currently, PMMA catalyzed by benzoyl peroxide (BPO) exhibits disquieting disadvantages including an exothermic polymerization reaction and a lack of bioactivity. Here, we first designed three industrial-scale synthesis methods for high-purity butoxydibutylborane (BODBB), achieving purity levels greater than 95% (maximum: 97.

Geometric constraint-triggered collagen expression mediates bacterial-host adhesion.

Cells living in geometrically confined microenvironments are ubiquitous in various physiological processes, e.g., wound closure.

Injectable, High Specific Surface Area Cryogel Microscaffolds Integrated with Osteoinductive Bioceramic Fibers for Enhanced Bone Regeneration.

Organic-inorganic composites with high specific surface area and osteoinductivity provide a suitable microenvironment for cell ingrowth and effective ossification, which could greatly promote bone regeneration. Here, we report gelatin methacryloyl (GelMA) cryogel microspheres that are reinforced with hydroxyapatite (HA) nanowires and calcium silicate (CS) nanofibers to achieve the goal. The prepared composite cryogel microspheres with open porous structure and rough surface greatly facilitate cell anchoring, simultaneously exhibiting excellent injectability.

Extracellular Matrix Rigidities Regulate the Tricarboxylic Acid Cycle and Antibiotic Resistance of Three-Dimensionally Confined Bacterial Microcolonies.

As a major cause of clinical chronic infection, microbial biofilms/microcolonies in host tissues essentially live in 3D-constrained microenvironments, which potentially modulate their spatial self-organization and morphodynamics. However, it still remains unclear whether and how mechanical cues of 3D confined microenvironments, for example, extracellular matrix (ECM) stiffness, exert an impact on antibiotic resistance of bacterial biofilms/microcolonies. With a high-throughput antibiotic sensitivity testing (AST) platform, it is revealed that 3D ECM rigidities greatly modulate their resistance to diverse antibiotics.

Self-reinforcement hydrogel with sustainable oxygen-supply for enhanced cell ingrowth and potential tissue regeneration.

Hydrogels composed of natural biopolymers are attractive for tissue regeneration applications owing to their advantages such as biocompatibility and ease of administration, etc.. Yet, the low oxygen level and the crosslinked network inside bulk hydrogels, as well as the hypoxic status in defect areas, hamper cell viability, function, and eventual tissue repair.

Controlled magnesium ion delivery system for in situ bone tissue engineering.

Magnesium cation (Mg) has been an emerging therapeutic agent for inducing vascularized bone regeneration. However, the therapeutic effects of current magnesium (Mg) -containing biomaterials are controversial due to the concentration- and stage-dependent behavior of Mg. Here, we first provide an overview of biochemical mechanism of Mg in various concentrations and suggest that 2-10 mM Mgin vitro may be optimized.

Bioinspired porous microspheres for sustained hypoxic exosomes release and vascularized bone regeneration.

Exosomes derived from mesenchymal stem cells (MSCs) have demonstrated regenerative potential for cell-free bone tissue engineering, nevertheless, certain challenges, including the confined therapeutic potency of exosomes and ineffective delivery method, are still persisted. Here, we confirmed that hypoxic precondition could induce enhanced secretion of exosomes from stem cells from human exfoliated deciduous teeth (SHEDs) comprehensive proteomics analysis, and the corresponding hypoxic exosomes (H-Exo) exhibited superior potential in promoting cellular angiogenesis and osteogenesis the significant up-regulation in focal adhesion, VEGF signaling pathway, and thyroid hormone synthesis. Then, we developed a platform technology enabling the effective delivery of hypoxic exosomes with sustained release kinetics to irregular-shaped bone defects via injection.

Construction of multifunctional cell aggregates in angiogenesis and osteogenesis through incorporating hVE-cad-Fc-modified PLGA/β-TCP microparticles for enhancing bone regeneration.

Multicellular aggregates have been widely utilized for regenerative medicine; however, the heterogeneous structure and undesired bioactivity of cell-only aggregates hinder their clinical translation. In this study, we fabricated an innovative kind of microparticle-integrated cellular aggregate with multifunctional activities in angiogenesis and osteogenesis, by combining stem cells from human exfoliated deciduous teeth (SHEDs) and bioactive composite microparticles. The poly(lactide--glycolide) (PLGA)-based bioactive microparticles (PTV microparticles) were ∼15 μm in diameter, with dispersed β-tricalcium phosphate (β-TCP) nanoparticles and surface-modified vascular endothelialcadherin fusion protein (hVE-cad-Fc).

Vascularized pulp regeneration via injecting simvastatin functionalized GelMA cryogel microspheres loaded with stem cells from human exfoliated deciduous teeth.

Dental pulp necrosis are serious pathologic entities that causes tooth nutrition deficiency and abnormal root development, while regeneration of functional pulp tissue is of paramount importance to regain tooth vitality. However, existing clinical treatments, which focus on replacing the necrotic pulp tissue with inactive filling materials, fail to restore pulp vitality and functions, thus resulting in a devitalized and weakened tooth. Currently, dental pulp regeneration via stem cell-based therapy for pulpless teeth has raised enormous attention to restore the functional pulp.

Hydrogel-based patient-friendly photodynamic therapy of oral potentially malignant disorders.

Oral potentially malignant disorders (OPMDs) are precursor lesions with an increased risk of malignant transformation. Topical photodynamic therapy (PDT) mediated by 5-aminolevulinic acid (ALA) (ALA-PDT) is a promising therapeutic method in the treatment of OPMDs. However, the clinical application of topical ALA-PDT is restricted by several limitations, including low delivery efficiency, poor comfort, and easy influence by saliva.

Strong underwater adhesion of injectable hydrogels triggered by diffusion of small molecules.

It is challenging for injectable hydrogels to achieve high underwater adhesiveness. Based on this concern, we report a fully physically crosslinked injectable hydrogel composed of gelatin, tea polyphenols and urea, capable of realising smart adhesion to various materials, like glass and porcine skin, in diverse aqueous environments. The urea molecules are designed as crosslinking disruptors for interfering with the formation of hydrogen bonds in the hydrogel, therefore modulating its crosslinking density and mechanical properties such as tensile strength, toughness and adhesive strength.

Controlled co-delivery system of magnesium and lanthanum ions for vascularized bone regeneration.

For craniofacial bone regeneration, how to promote vascularized bone regeneration is still a significant problem, and the controlled release of trace elements vital to osteogenesis has attracted attention. In this study, an ion co-delivery system was developed to promote angiogenesis and osteogenesis. Magnesium ions (Mg) and lanthanum ions (La) were selected as biosignal molecules because Mgcan promote angiogenesis and both of them can enhance bone formation.

Injectable GelMA Cryogel Microspheres for Modularized Cell Delivery and Potential Vascularized Bone Regeneration.

Cell therapeutics hold tremendous regenerative potential and the therapeutic effect depends on the effective delivery of cells. However, current cell delivery carriers with unsuitable cytocompatibility and topological structure demonstrate poor cell viability during injection. Therefore, porous shape-memory cryogel microspheres (CMS) are prepared from methacrylated gelatin (GelMA) by combining an emulsion technique with gradient-cooling cryogelation.

Osteoconductive and osteoinductive biodegradable microspheres serving as injectable micro-scaffolds for bone regeneration.

There are intensive needs for scaffolds with new designs to meet the diverse requirements of bone repairing. Biodegradable microspheres are highlighted as injectable micro-scaffolds thanks to their advantages in filling irregular defects a minimally invasive surgery. In this study, microspheres with surface micropores were made the W1/O/W2 double emulsion method using amphiphilic triblock copolymers (PLLA-PEG-PLLA) composed of poly(L-lactide) (PLLA) and poly(ethylene glycol) (PEG) segments.

Dual-Controlled Release of Icariin/Mg from Biodegradable Microspheres and Their Synergistic Upregulation Effect on Bone Regeneration.

Current scaffolds applied for bone tissue engineering are still lacking sufficient osteogenic capacity to induce efficient bone regeneration. Biodegradable microsphere-type scaffolds are designed to achieve the dual-controlled release of a Chinese medicine (i.e.

Anisotropic CoFeO@Graphene Hybrid Aerogels with High Flux and Excellent Stability as Building Blocks for Rapid Catalytic Degradation of Organic Contaminants in a Flow-Type Setup.

Macroscopic three-dimensional catalytic materials could overcome the poor operability and avoid secondary pollution of common powdery counterparts, especially in flow-type setups. However, conventional isotropic graphene-based aerogels and foams have randomly distributed graphene sheets, which may cause stream erosion and reduce the flux seriously. Herein, for the first time, we design and fabricate a novel anisotropic CoFeO@graphene hybrid aerogel (CFO@GA-A) with a hydrothermal synthesis followed by directional-freezing and freeze-drying for a tube-like flow-type setup analogous to a wastewater discharge pipeline.