Electrospun membranes chelated by metal magnesium ions enhance pro-angiogenic activity and promote diabetic wound healing

Bioelectrically Reprogramming Hydrogels Rejuvenate Vascularized Bone Regeneration in Senescence

Senescent bone tissue displays a pathological imbalance characterized by decreased angiogenesis, disrupted bioelectric signaling, ion dysregulation, and reduced stem cell differentiation. Once bone defects occur, this pathological imbalance makes them difficult to repair. An innovative synergistic therapeutic strategy is utilized to reverse these pathological imbalances via a conductive hydrogel doped with magnesium ion (Mg2+)-modified black phosphorus (BP). The hydrogel reprograms electrical signals, restores Mg2+ homeostasis, reconstructs physiological signals, and promotes blood vessel regeneration in senile bone defects. The conductive hydrogel synergistically restores both the chemical and bioelectric signals within the bone microenvironment. This hydrogel increases the expression of vascular endothelial growth factor (VEGF) and VEGF receptor-2 (VEGFR2), activates the PI3K-AKT-eNOS pathway, and significantly increases the angiogenic ability of vascular endothelial cells in the aged state. In addition, the conductive hydrogel normalizes calcium ion (Ca2+) influx, increases the accumulation of osteogenic transcription factors in the nucleus, and promotes the osteogenic differentiation of senescent stem cells. This innovative treatment strategy restores bone-vascular coupling in areas of senile bone defects, achieves effective vascularized bone regeneration, and has good potential for the treatment of senile bone defects.

A tranexamic acid-functionalized acellular dermal matrix sponge co-loaded with magnesium ions: Enhancing hemostasis, vascular regeneration, and re-epithelialization for comprehensive diabetic wound healing

Excessive inflammation, accumulation of wound exudate, and blood seepage are common in diabetic wounds, hindering cell proliferation and disrupting tissue remodeling, leading to delayed healing. This study presents a multifunctional sponge scaffold (P5T3@Mg) created by combining an acellular dermal matrix with tranexamic acid and MgO nanoparticles, designed for hemostatic and anti-inflammatory effects. The P5T3@Mg scaffold effectively absorbs wound fluid while promoting healing. In vivo and in vitro hemostasis experiments demonstrate that the P5T3@Mg sponge exhibits excellent hydrophilicity, enhancing blood absorption at the wound site, inhibiting fibrinolysis, and expediting hemostasis. Additionally, the sustained release of Mg2+ from the P5T3@Mg sponge promotes collagen deposition and angiogenesis in diabetic rat wounds, suppressing chronic inflammation and accelerating tissue remodeling and repair.

Recent advances in bioactive wound dressings

Traditional wound dressings, despite their widespread use, face limitations, such as poor infection control and insufficient healing promotion. To address these challenges, bioactive materials have emerged as a promising solution in wound care. This comprehensive review explores the latest developments in wound healing technologies, starting with an overview of the importance of effective wound management, emphasising the need for advanced bioactive wound dressings. The review further explores various bioactive materials, defining their characteristics. It covers a wide range of natural and synthetic biopolymers used to develop bioactive wound dressings. Next, the paper discusses the incorporation of bioactive agents into wound dressings, including antimicrobial and anti-inflammatory agents, alongside regenerative components like growth factors, platelet-rich plasma, platelet-rich fibrin and stem cells. The review also covers fabrication techniques for bioactive wound dressings, highlighting techniques like electrospinning, which facilitated the production of nanofibre-based dressings with controlled porosity, the sol-gel method for developing bioactive glass-based dressings, and 3D bioprinting for customised, patient-specific dressings. The review concludes by addressing the challenges and future perspectives in bioactive wound dressing development. It includes regulatory considerations, clinical efficacy, patient care protocol integration and wound healing progress monitoring. Furthermore, the review considers emerging trends such as smart materials, sensors and personalised medicine approaches, offering insights into the future direction of bioactive wound dressing research.

Mechanism and Application of Biomaterials Targeting Reactive Oxygen Species and Macrophages in Inflammation

Inflammation, an adaptive reaction to harmful stimuli, is a necessary immune system response and can be either acute or chronic. Since acute inflammation tends to eliminate harmful stimuli and restore equilibrium, it is generally advantageous to the organism. Chronic inflammation, however, is caused by either increased inflammatory signaling or decreased pro-anti-inflammatory signaling. According to current studies, inflammation is thought to be a major factor in a number of chronic diseases, including diabetes, cancer, arthritis, inflammatory bowel disease, and obesity. Consequently, reducing inflammation is essential for both preventing and delaying diseases. The application of biomaterials in the treatment of inflammatory illnesses has grown in recent years. A variety of biomaterials can be implanted either by themselves or in conjunction with other bioactive ingredients and therapeutic agents. The mechanisms of action and therapeutic applications of well-known anti-inflammatory biomaterials are the main topics of this article.

Metal ion formulations for diabetic wound healing: Mechanisms and therapeutic potential

Metals are vital in human physiology, which not only act as enzyme catalysts in the processes of superoxide dismutase and glucose phosphorylation, but also affect the redox process, osmotic adjustment, metabolism and neural signals. However, metal imbalances can lead to diseases such as diabetes, which is marked by chronic hyperglycemia and affects wound healing. The hyperglycemic milieu of diabetes impairs wound healing, posing significant challenges to patient quality of life. Wound healing encompasses a complex cascade of hemostasis, inflammation, proliferation, and remodeling phases, which are susceptible to disruption in hyperglycemic conditions. In recent decades, metals have emerged as critical facilitators of wound repair by enhancing antimicrobial properties (e.g., iron and silver), providing angiogenic stimulation (copper), promoting antioxidant activity and growth factor synthesis (zinc), and supporting wound closure (calcium and magnesium). Consequently, research has pivoted towards the development of metal ion-based therapeutics, including innovative formulations such as nano-hydrogels, nano-microneedle dressings, and microneedle patches. Prepared by combining macromolecular materials such as chitosan, hyaluronic acid and sodium alginate with metals, aiming at improving the management of diabetic wounds. This review delineates the roles of key metals in human physiology and evaluates the application of metal ions in diabetic wound management strategies.

Anti-inflammatory and anti-oxidative electrospun nanofiber membrane promotes diabetic wound healing via macrophage modulation

BACKGROUND

In the inflammatory milieu of diabetic chronic wounds, macrophages undergo substantial metabolic reprogramming and play a pivotal role in orchestrating immune responses. Itaconic acid, primarily synthesized by inflammatory macrophages as a byproduct in the tricarboxylic acid cycle, has recently gained increasing attention as an immunomodulator. This study aims to assess the immunomodulatory capacity of an itaconic acid derivative, 4-Octyl itaconate (OI), which was covalently conjugated to electrospun nanofibers and investigated through in vitro studies and a full-thickness wound model of diabetic mice.

RESULTS

OI was feasibly conjugated onto chitosan (CS), which was then grafted to electrospun polycaprolactone/gelatin (PG) nanofibers to obtain P/G-CS-OI membranes. The P/G-CS-OI membrane exhibited good mechanical strength, compliance, and biocompatibility. In addition, the sustained OI release endowed the nanofiber membrane with great antioxidative and anti-inflammatory activities as revealed in in vitro and in vivo studies. Specifically, the P/G-CS-OI membrane activated nuclear factor-erythroid-2-related factor 2 (NRF2) by alkylating Kelch-like ECH-associated protein 1 (KEAP1). This antioxidative response modulates macrophage polarization, leading to mitigated inflammatory responses, enhanced angiogenesis, and recovered re-epithelization, finally contributing to improved healing of mouse diabetic wounds.

CONCLUSIONS

The P/G-CS-OI nanofiber membrane shows good capacity in macrophage modulation and might be promising for diabetic chronic wound treatment.