Search Results (85)

Effective hemostasis in deep and irregular wounds remains a critical clinical challenge. To address this, we developed a bioresorbable chitosan composite hydrogel reinforced with short eggshell membrane (ESM) nanofibers, which were obtained through cryogenic grinding. The resulting ESM/CCS hydrogel, crosslinked with citric acid, exhibited significantly enhanced properties compared to pure CCS hydrogel, including a 63% increase in mechanical strength, a two-fold improvement in shape memory, a 25.31% reduction in hemolysis, over 2% higher cytocompatibility, and more than 48% greater hemostatic efficiency. Structural characterization confirmed the successful integration of bioactive chitosan with collagen mimetic ESM nanofibers. This biomimetic approach synergistically combines mechanical reinforcement with biological functionality, highlighting its strong potential as an advanced hemostatic dressing for complex wound management. Full article

Background/Objectives: Achieving effective hemostasis is a vital step in wound healing, particularly in cases of severe bleeding caused by surgical procedures or trauma. This study focuses on the development of chitosan-based dressings enriched with Heparin (hep)-loaded poly(butylene succinate) (PBSu) nanoparticles to combine hemostatic and anticoagulant properties. Methods: Chitosan, a biocompatible and biodegradable carbohydrate with inherent antibacterial and hemostatic properties, was chemically modified with 2-(N-morpholino)ethanesulfonic acid (MES) and 2-acrylamido-2-methylpropane sulfonic acid (AMPS) to enhance its swelling ability and hemostatic activity. PBSu nanoparticles were synthesized using an oil-in-water emulsification method and loaded with Hep to achieve controlled anticoagulant release. The dressings of the modified chitosan derivatives with the nanoparticles which were systematically characterized for morphology, chemical structure, swelling ability, loading capacity, and Hep release kinetics. Results: This dual-function system is designed to decouple local surface hemostasis from thrombotic processes: the chitosan matrix provides rapid topical hemostasis, while controlled heparin release from the nanoparticles aims to modulate excessive fibrin deposition, support microvascular perfusion, and exploit the pro-healing benefits of low-dose heparin reported in advanced wound dressings, particularly in high-risk or thrombotic-prone patients. In vitro and in vivo studies demonstrated their potential for promoting rapid hemostasis. Conclusions: These findings suggest that the integration of modified chitosan and Hep-loaded nanoparticles is a promising strategy for advancing wound care and hemostatic technologies. Full article

Chitosan is a natural biopolymer for advanced wound healing due to its antimicrobial activity, biocompatibility, and hemostatic properties. However, its clinical utility is limited by its low solubility and poor mechanical properties. This review summarizes recent strategies that have successfully overcome these shortcomings, focusing on the development of multifunctional chitosan hybrid dressings. These dressings, which include hydrogels, hydrocolloids, films, sponges, and scaffolds, are now being fabricated using advanced systems like electrospinning, 3D printing, microneedle (MN), and nanocomposites technologies to maximize wound healing efficacy. Specifically, modification techniques used to overcome chitosan’s shortcomings include: (1) chemical derivatization to enhance solubility, (2) polymer hybridization with natural and synthetic materials to enhance mechanical properties, and (3) functionalization with active ingredients. These materials, including metal/inorganic nanoparticles, natural compounds, and amino acids, are added to maximize therapeutic efficacy. In conclusion, chitosan hybrid materials and dressings provide an excellent foundation for next-generation wound dressings. However, overcoming challenges associated with material diversity and establishing standardized manufacturing processes and clinical trials remain critical for successful commercialization. Full article

In this work, kaolin/chitin (K/Ch) composite aerogels with different mass ratios were successfully fabricated via a freeze–drying approach. The influence of kaolin content on the microstructure, properties and hemostatic performance of the composite aerogels was systematically investigated. The results demonstrated that the incorporation of kaolin endowed the chitin-based aerogels with tunable porous structures, excellent water absorption capacity (up to 4282% for K_0.25/Ch₂), and enhanced water retention (73.7% for K₂/Ch₂ at 60 min). Moreover, the K/Ch composite aerogels exhibited good biodegradability, no cytotoxicity (cell viability > 91.9%), and no hemolysis (hemolysis rate < 1.5% at all test concentrations). In vitro hemostatic evaluations revealed that the composite aerogels exhibited rapid blood coagulation (blood clotting time of 16 s for K₂/Ch₂) with a blood coagulation index (BCI) as low as 0.5%, which was attributed to the synergistic effect of the physical adsorption of chitin and the coagulation cascade activation by kaolin. These findings indicated that the K/Ch composite aerogels could be used as novel natural hemostatic materials for potential effective and rapid hemostasis. Full article

The development of functionality in wound dressings has progressed since the discovery by Winter that moist wounds heal more rapidly. Approaches to incorporate functionality on several fronts of wound healing have been targeted. Here, we consider three functional features that have received increased attention for their role in promoting healing in hard-to-heal wounds: control of protease levels, hydrogen peroxide generation, and antibacterial efficacy against multidrug resistance bacteria, the ESKAPE (Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter species) pathogens. We review some clinically employed dressings used to treat chronic and burn wounds that have been characterized by their functional protease-modulating activity and contrast one well-studied analog with a cotton-based technology. Similarly, hydrogen peroxide generation profiles were obtained for dressings in different moist wound healing categories and contrasted with a modified form of a known hemostatic cotton-based technology. We examined ascorbic acid-modified forms of a cotton-based technology used for bleeding control in an ESKAPE antibacterial assessment using the AATCC 100 TM. The results for the cotton-based technology were significant protease uptake, hydrogen peroxide generation capacities at proliferative and antimicrobial levels, and >99.99% efficacy against ESKAPE pathogens. These results reflect the importance of considering new forms of cotton fiber technology for incorporation in advanced wound dressing approaches. Full article

Injectable hydrogels (IHs) have gained considerable interest in biomedical and aesthetic applications due to their minimally invasive delivery, selective localization, and sustained release of bioactive agents. They exhibit flowability during administration and undergo in situ gelation under physiological conditions. These behaviors are influenced by their tunable structural, physical, mechanical, and viscoelastic properties, modulating performance. Rheological parameters, including viscosity (η), storage modulus (G′), loss modulus (G″), and yield stress (τ_y) of IHs with time (t), shear rate ($\stackrel{·}{\gamma }$), and frequency (f), explaining their shear thinning, thixotropy, viscoelasticity, and gelatin kinetics, serve as key quantitative indicators of their injectability, self-healing capability, and structural and mechanical stability. The rheological characteristics reflect molecular interactions and crosslinking mechanisms within IH networks, thereby linking formulation to provide overall performance, including injectability, biodegradability, and controlled release. This review summarizes recent advances in IHs for diverse applications, with a primary focus on their rheological properties. It also briefly addresses their composition, intermolecular interactions, and correlated function and performance. The applications discussed include hemostatic and wound dressings, tissue engineering and regenerative medicine scaffolds, drug delivery systems, reconstructive and aesthetic materials, and functional bioinks for 3D printing. Overall, this review demonstrates that rheological characterization provides an essential framework for the rational engineering of next-generation IH systems. Full article

Background: Postoperative abdominal adhesions are a common and serious complication following abdominal surgery, often leading to chronic pain, bowel obstruction, or infertility. This study aimed to evaluate the efficacy of the new starch-based absorbable hemostatic agent and dressing, BioSight, in comparison with a predicate device (4DryField^® PH) for the prevention of abdominal adhesions in a rat model. Methods: A total of 90 Sprague–Dawley rats were used to establish an intra-abdominal adhesion model and assigned to the BioSight, 4DryField^® PH, or control group. Standardized injuries were created on the cecum and parietal peritoneum, followed by application of the designated materials. Animals were sacrificed at 2, 4, and 12 weeks for macroscopic adhesion scoring and histopathological evaluation. Adhesion area, adhesion strength, and tissue thickness were assessed using established scoring systems, and local healing was examined by H&E staining. All quantitative data were analyzed using one-way ANOVA. Conclusions: In a rat peritoneal adhesion model, BioSight exhibited pronounced anti-adhesion efficacy comparable to 4DryField^® PH. Macroscopic evaluation showed consistently low adhesion scores (≤0.4) across all time points up to 12 weeks, while histological analysis confirmed reduced adhesion thickness, with BioSight displaying numerically lower values, particularly at early stages (251.3 ± 137.4 µm vs. 323.2 ± 174.6 µm at Week 2). This performance is attributed to rapid in situ hydrogel formation that provides effective temporary tissue separation, limits early fibrin deposition and inflammatory cell infiltration, and supports hemostasis. Importantly, the starch-based hydrogel exhibits a balanced biodegradation profile—persisting long enough to protect injured tissues during the critical inflammatory and fibroproliferative phases, yet undergoing complete enzymatic resorption thereafter without adverse tissue reactions. Collectively, these results highlight the anti-adhesion functionality of BioSight and support the clinical potential of plant-derived starch-based bioresorbable surgical adjuncts. Full article

Chitosan, a naturally derived polysaccharide obtained by chitin deacetylation, has attracted considerable attention in dentistry as a multifunctional biomaterial owing to its excellent biocompatibility, biodegradability, and tunable physicochemical properties. This narrative review provides an up-to-date overview of the use of chitosan-based sponges in dental tissue engineering, bone regeneration, post-extraction wound management, and periodontal therapy. Chitosan sponges, characterized by high porosity, flexibility, and superior absorbency, serve as effective wound dressings, drug delivery carriers, and scaffolds that promote cell proliferation and tissue regeneration. Their intrinsic antibacterial, antifungal, hemostatic, and immunomodulatory properties further enhance their therapeutic value in managing complex oral conditions. In periodontal treatment, they enable localized drug delivery and support soft and hard tissue healing, while in post-extraction care, they aid hemostasis and reduce complications such as alveolar osteitis. Moreover, their osteoconductive and osteoinductive potential positions them as promising materials for alveolar bone repair and implantology. Chemical modification of chitosan and the incorporation of bioactive compounds allow customization of sponge formulations to meet specific clinical needs. Despite encouraging preclinical findings, challenges remain due to variability in chitosan sources, differences in the degree of deacetylation, and limited clinical validation. This review highlights the potential of chitosan sponges as innovative tools in regenerative dentistry and underscores the need for further standardization, mechanistic studies, and long-term clinical trials to ensure their safe and effective translation into dental practice. Moreover, the broad clinical applications of chitosan sponges beyond dentistry confirm their potential as a universal biomaterial platform in regenerative medicine. Full article

Diabetic wounds remain a major clinical challenge due to impaired angiogenesis, chronic inflammation, oxidative stress, and persistent infection, all of which delay tissue repair. Conventional dressings provide only passive protection and fail to modulate the wound microenvironment effectively. Chitosan (CS) is a naturally derived polysaccharide inspired by biological structures in crustaceans and fungi. It has emerged as a multifunctional biomimetic polymer with excellent biocompatibility, antimicrobial activity, and hemostatic properties. Recent advances in biomimetic materials science have enabled the development of stimuli-responsive CS hydrogels. These systems can sense physiological cues such as pH, temperature, glucose level, light, and reactive oxygen species (ROS). These smart systems emulate natural wound healing mechanisms and adapt to environmental changes. They release bioactive agents on demand and promote tissue homeostasis through controlled angiogenesis and collagen remodeling. This review discusses the biomimetic design rationale, crosslinking mechanism, and emerging strategies underlying single and dual-responsive hydrogel systems. It further emphasizes how nature-inspired structural and functional designs accelerate diabetic wound repair and outlines the current challenges and future prospects for translating these bioinspired intelligent hydrogels into clinical wound care applications. Full article

Designing and developing multifunctional wound dressings with sustained drug-release capability is a promising strategy for minimizing the risks of wound infection and promoting wound healing. Collagen composite aerogels have been widely employed as a medical device building block, although they still fail to display competitive mechanical properties and sustained drug-release capability. Thus, we solve this challenge by pursuing a multi-scale design method, which utilizes glutamic acid (Glu) to regulate the collagen self-assembly behavior to obtain a network-structured collagen/glutamate composite aerogel with sustained drug release, biocompatibility, and hemostatic ability. Through structural and performance analysis, the Glu endows collagen composite aerogels with excellent structural stability and superior mechanical properties by regulating the intermolecular interaction between collagen molecules, which made the aerogels achieve a supramolecular network structure through the entanglement of high-density collagen fibrils and showed excellent sustained drug-release characteristics. Moreover, collagen/Glu composite aerogels also exhibited outstanding biocompatibility and hemostatic capability. This self-assembly strategy provides new insight aimed at collagen composite aerogels with supramolecular network structures and sustained drug-release capability, making them a promising candidate for wound dressings in future clinical applications. Full article

Background/Objectives: Radial artery occlusion (RAO) following hemostasis after coronary procedures is the most common complication, with a highly variable incidence (1–33%). While it is well established that the patent hemostasis technique reduces RAO rates, it remains unclear which device should be preferred. The wide variety of available radial hemostasis devices makes it necessary to identify those associated with a lower incidence of complications. Methods: Literature from 2016 to 2021 was reviewed through a systematic search in PubMed, CINAHL, Cochrane, and Embase databases. Only randomized controlled trials (RCTs) involving adult patients undergoing percutaneous transradial coronary procedures were included. Devices considered included pneumatic compression devices, manual compression, elastic bandages, and hemostatic dressings. The review process followed PRISMA guidelines. Two random-effects frequentist network meta-analyses were conducted to compare the effects of 16 and 9 radial hemostasis devices on RAO incidence at 24 h and 30 days after the procedure. Results: A total of 17 RCTs were included. The network meta-analysis (NMA) showed a protective effect at the 24 h endpoint for both double-balloon devices and pneumatic compression devices adjusted to mean arterial pressure. At the 30-day endpoint, significant differences were observed among pneumatic compression, chitosan-based PADs, mechanical compression devices, and adjustable elastic bandages. Conclusions: Although some treatments with specific devices significantly differ from the reference treatment, the limited availability of data to assess RAO at 30 days and a certain heterogeneity between devices indicate the need for further investigation. Full article

Background/Objectives: Efficient wound treatment embraces the management of four overlapping phases, starting with hemostasis, an immediate physiological response aimed at stopping bleeding from damaged blood vessels caused by skin injury. This paper proposes an innovative, nature-based hemostatic biomaterial designed to assist natural self-healing regenerative mechanisms. Methods: Light, transparent, and skin-adhesive films based on κ-carrageenan, meadow polyfloral honey, and Calendula officinalis flower extract were fabricated via solution casting. Comprehensive characterization revealed the physicochemical, structural, swelling, and barrier properties and the influence of each bioactive compound utilized for film preparation. Results: The samples subcutaneously implanted in Wistar rats induced vascularization, deposition of collagen, and orientation of collagen fibers while being fully phagocytosed and gradually biodegraded. The rat tail-cut model demonstrated that the films significantly reduced blood loss (0.1875 ± 0.0732 g) compared to the control (0.7837 ± 0.3319 g), and hemostasis was achieved notably faster (355.75 ± 71.42 s) than in the control group (704.25 ± 85.29 s). The rat liver punch biopsy model confirmed reduced blood loss (2.8025 ± 1.5174 g) and shorter time to hemostasis (303.25 ± 77.90 s) compared to the control (3.1475 ± 1.5413 g, 383.00 ± 36.53 s). Conclusions: The results indicate the great potential of the fabricated films as hemostatic wound dressings. Full article

Rapid hemostasis and wound healing are crucial severe trauma treatment. Natural mechanisms often prove insufficient, spurring research for innovative biomaterials. This review focuses on cellulose-based materials, which are promising due to their absorbency, biocompatibility, and processability. The novelty lies in exploring how these materials promote clotting and tissue regeneration. They operate via extrinsic and intrinsic mechanisms. Extrinsically, they create a matrix at the wound to activate coagulation; intrinsically, they maintain clotting factors. Additionally, they aid healing through physical, chemical, and biological means, such as maintaining moisture, incorporating antimicrobial agents, and stimulating cell activity. The innovative fabrication strategies include material selection and chemical modification. Techniques like oxidation enhance performance. Structural engineering methods like freeze-drying and 3D printing optimize porosity and alignment. Cellulose-based dressings are versatile and effective in various forms. They address different wound needs and show benefits like rapid coagulation and tissue repair. This review also covers challenges and future trends, emphasizing the need to enhance mechanical properties and biodegradability. Further, new technologies offer potential improvements to the nanocomposites. Overall, continued research on cellulose-based dressing is vital, and unlocking their potential could revolutionize wound care, providing suitable solutions for trauma management. Full article

Thermosensitive biopolymer gelatin–alginate hydrogels are promising for use as dressings for wound healing and drug delivery. This work presents fluorescence arising from the internal fluorophores of alginate and gelatin biopolymers in thermosensitive hydrogels modified with calcium- and sodium-containing humic acids before and after their impregnation with the hemostatic drug aminocaproic acid. A new approach of using fluorescence emission spectra, along with the analysis of morphological features, optical properties, and the elemental composition of dried hydrogels, is used as a tool for monitoring the ability of these hydrogels for the thermosensitive delivery of a hemostatic drug. A comparative analysis made it possible to select the optimal composition of hydrogels suitable for the targeted delivery of aminocaproic acid through a gel–sol transition at physiological temperatures. Optimal concentrations of sodium-containing humic acids in gelatin–alginate hydrogels of 2.5 wt.% and 5 wt.% provided a gel–sol transition temperature of about 37 °C. The quantum yield of fluorescence of 8–10% upon introduction of 20 wt.% aminocaproic acid into these hydrogels indicates that this hemostatic drug does not destroy three-dimensional networks formed by molecules of gelatin, alginate, and humic acids, the gel–sol transition temperature for which is maintained at a physiological level without significant contracture of the wound dressing. Full article

Background/Objectives: The safe completion of a non-invasive procedure is crucial to the success of an endovascular approach. Chitosan, a natural polysaccharide derived from chitin, is an ideal material for the study and application of medical devices in post-operative wound management. Methods: The present work is based on a retrospective study conducted on a sample of patients treated with Axiostat (a sterile, single-use, non-absorbable dressing), composed of 100% chitosan and designed to instantly stop bleeding through a mucus adhesion mechanism for the treatment of conditions such as Leriche’s syndrome. The objective was to evaluate the efficacy and safety of the hemostatic Axiostat dressing in patients undergoing anticoagulant and/or antiplatelet therapy in whom endovascular procedures using the axillary artery as an access site are performed to treat Leriche syndrome. Results: The obtained results showed that Axiostat is safe and effective in promoting hemostasis at the axillary vascular access site even when prolonged hemostasis was required in patients on antiplatelet and anticoagulant therapy. The mean time to hemostasis was 5.75 min in all types of patients considered. Full article