Search Results (858)

Fiber-reinforced composites (FRCs) have emerged as transformative alternatives to traditional marine construction materials, owing to their superior corrosion resistance, design flexibility, and strength-to-weight ratio. This review comprehensively examines the current state of FRC technologies in marine deck and underwater applications, with a focus on manufacturing methods, durability challenges, and future innovations. Thermoset polymer composites, particularly those with epoxy and vinyl ester matrices, continue to dominate marine applications due to their mechanical robustness and processing maturity. In contrast, thermoplastic composites such as Polyether Ether Ketone (PEEK) and Polyether Ketone Ketone (PEKK) offer advantages in recyclability and hydrothermal performance but are hindered by higher processing costs. The review evaluates the performance of various fiber types, including glass, carbon, basalt, and aramid, highlighting the trade-offs between cost, mechanical properties, and environmental resistance. Manufacturing processes such as vacuum-assisted resin transfer molding (VARTM) and automated fiber placement (AFP) enable efficient production but face limitations in scalability and in-field repair. Key durability concerns include seawater-induced degradation, moisture absorption, interfacial debonding, galvanic corrosion in FRP–metal hybrids, and biofouling. The paper also explores emerging strategies such as self-healing polymers, nano-enhanced coatings, and hybrid fiber architectures that aim to improve long-term reliability. Finally, it outlines future research directions, including the development of smart composites with embedded structural health monitoring (SHM), bio-based resin systems, and standardized certification protocols to support broader industry adoption. This review aims to guide ongoing research and development efforts toward more sustainable, high-performance marine composite systems. Full article

Based on ethnographic research among the Misings of Assam and the ethnic communities of the Darjeeling Himalayas, the paper seeks to highlight the intricate relationship between Indigenous communities and their natural surroundings maintained through sacred connections of revering the spirits that govern it. It brings forth the notions of healing and care amongst these communities by engaging with practices of spirit worship, which govern the daily lives of these communities. Encounters with hegemonic forms of religious traditions, colonialism, and extractive forms of development regimes have rendered these communities vulnerable and marginalised. Literature also suggests that some of the most affected populations by “climate change” belong to Indigenous communities. In the process, their relationship with immediate natural surroundings has evolved and transformed, but with certain continuities in practices and beliefs. This has also challenged their existing forms of practice and their relationship with nature. Spirit worship has remained an integral part of their lives, playing a critical role in healing and care within a fast-changing world under “development”. Taking these aspects into consideration, throughout the article, we lay out several anecdotes from the Indigenous communities that will tell us about their beliefs and practices that continue to shape their lives. Full article

Mozambican traditional healing is a longstanding, community-embedded practice grounded in local knowledge systems and biodiversity. Despite its resilience, it has been persistently marginalized—from colonial impositions to enduring legal ambiguities—while Western medicine, rooted in Hippocratic, Galenic, and Cartesian paradigms, has become the normative model. This article explores the ethical, legal, and consequentialist dimensions of emancipating traditional healing, analyzing four policy options: prohibition, indifference, protection, and encouragement. Emancipation is presented not as subordination to biomedical standards but as a process of epistemic justice, affirming cultural sovereignty and community agency. Core values such as justice, equity, and respect for plural worldviews underpin the discussion. Traditional healers are often spiritually mandated and serve over 80% of the population, particularly in underserved areas, yet remain institutionally undervalued. Promoting respectful dialogue among stakeholders is crucial to avoid reductive adaptations and foster inclusive, sustainable health systems. Recognizing traditional healing as a legitimate and complementary system not only strengthens Mozambique’s National Health System (SNS) but also contributes to achieving the Sustainable Development Goals (SDGs) related to health, inclusion, and cultural rights. This article argues that empowering traditional healing is both a moral imperative and a strategic investment in planetary health and human flourishing. Full article

Hydrogels are water-rich polymeric networks mimicking the body’s extracellular matrix, making them highly biocompatible and ideal for precision medicine. Their “tunable” and “smart” properties enable the precise adjustment of mechanical, chemical, and physical characteristics, allowing responses to specific stimuli such as pH or temperature. These versatile materials offer significant advantages over traditional drug delivery by facilitating targeted, localized, and on-demand therapies. Applications range from diagnostics and wound healing to tissue engineering and, notably, cancer therapy, where they deliver anti-cancer agents directly to tumors, minimizing systemic toxicity. Hydrogels’ design involves careful material selection and crosslinking techniques, which dictate properties like swelling, degradation, and porosity—all crucial for their effectiveness. The development of self-healing, tough, and bio-functional hydrogels represents a significant step forward, promising advanced biomaterials that can actively sense, react to, and engage in complex biological processes for a tailored therapeutic approach. Beyond their mechanical resilience and adaptability, these hydrogels open avenues for next-generation therapies, such as dynamic wound dressings that adapt to healing stages, injectable scaffolds that remodel with growing tissue, or smart drug delivery systems that respond to real-time biochemical cues. Full article

Traditional polyurethanes have gained widespread application due to their excellent mechanical properties, wear resistance, and processability. However, these materials are susceptible to cracking or fracture under environmental stresses. In recent years, self-healing polyurethanes have garnered significant attention as a critical research field owing to their key capabilities, such as repairing physical damage, restoring mechanical strength, structural adaptability, and cost-effective manufacturing. This review systematically examines the healing mechanisms, structural characteristics, and performance metrics of self-healing polyurethanes, with in-depth analysis of their repair efficacy across various applications—particularly in flexible electronic devices. It demonstrates that self-healing polyurethanes overcome traditional failure modes in flexible electronics through self-repair-function integration mechanisms. Their stimuli-responsive healing behavior is driving the evolution of this field toward an intelligent regenerative electronics paradigm. Full article

Drawing on in-depth interviews and thematic analysis, this study explores the therapeutic benefits of outdoor experiences through the lived experiences of 24 outdoor practitioners, including educators, environmentalists, therapists, and program leaders. Three core themes emerged: (a) nature as an emotional regulator and reflective space; (b) therapeutic benefits of human–nature relationships; and (c) decolonial, bioregional, and cultural healing. Although practitioners facilitated physical challenges and skill-building for their participants, they primarily described outdoor experiences as relational, somatic, and culturally rooted practices that foster emotional regulation, grief processing, identity integration, and social inclusion. Healing emerged through solitude, silence, ancestral connections, sacred landscapes, inclusive dynamics, and the restoration of cultural knowledge. This study’s results challenge Western-centric outdoor education models by foregrounding Indigenous and postcolonial perspectives embedded in Indian ecological traditions. The results contribute to global discussions on decolonizing outdoor fields and offer implications for culturally responsive, emotionally safe, and ecologically grounded practices. Full article

Intestinal regeneration is essential for maintaining epithelial integrity and repairing mucosal damage caused by inflammation, infections, or injuries. Traditional Chinese Medicine (TCM) has long utilized herbal remedies for gastrointestinal disorders, and accumulating evidence highlights that natural compounds derived from TCM possess significant regenerative potential. This review summarizes the multifaceted mechanisms by which these bioactive compounds promote intestinal healing. Key actions include the stimulation of intestinal stem cell (ISC) proliferation and differentiation, the modulation of inflammatory responses, the reinforcement of epithelial barrier integrity, the attenuation of oxidative stress, and the reshaping of the gut microbiota. Representative compounds such as Astragalus polysaccharides, berberine, curcumin, puerarin, and flavonoids like quercetin exhibit these effects through signaling pathways, including HIF-1, Wnt/β-catenin, NF-κB, Nrf2, and IL-22. Evidence from in vitro organoid models and in vivo studies in colitis, radiation injury, antibiotic-associated diarrhea, and intestinal dysmotility and diarrhea models demonstrates that these compounds enhance crypt villus regeneration, preserve tight junctions, and improve clinical outcomes. The holistic, multi-target actions of Chinese medicine-derived natural products make them promising candidates for therapeutic strategies aimed at intestinal repair. Further clinical validation and mechanistic studies are warranted to facilitate their integration into modern gastrointestinal medicine. Full article

Background and Objectives: Medication-related osteonecrosis of the jaw (MRONJ) is a challenging condition linked to antiresorptive and antiangiogenic medications. Their complex pathophysiology and resistance to standard treatments have led researchers to explore adjunctive therapies. This systematic review evaluated the effectiveness of autologous platelet concentrates—namely platelet-rich plasma (PRP) and platelet-rich fibrin (PRF)—in promoting healing, bone regeneration, and symptom relief in MRONJ patients. Materials and Methods: A systematic literature search was conducted using PubMed, Scopus, and Web of Science for studies that assessed the use of PRP or PRF in MRONJ management. The risk of bias and study quality were evaluated using ROB-2 and ROBINS-I tools. Results: A total of 24 studies were included: seven on PRP and 17 on PRF. Reported complete mucosal healing rates ranged from 33% to 100% for PRP and from 36% to 100% for PRF. Although two randomized controlled trials and one prospective observational study found no statistically significant advantage of PRF over conventional surgical treatments, most studies indicated positive outcomes. Overall, the methodological quality varied, with several studies showing moderate-to-high risk of bias. Conclusions: Platelet concentrates can add benefits to traditional MRONJ treatments. The current evidence suggests that integrating these autologous therapies with conventional approaches clinically enhances healing outcomes, supports bone regeneration, and alleviates symptoms, ultimately leading to improved patient care. Full article

The transition from three-dimensional (3D) to four-dimensional (4D)-bioprinting marks a significant advancement in tissue engineering and drug delivery. 4D-bioprinting offers the potential to more accurately mimic the adaptive qualities of living tissues due to its dynamic flexibility. Structures created with 4D-bioprinting can change shape in response to internal and external stimuli. This article reviews the background, key concepts, techniques, and applications of 4D-bioprinting, focusing on its role in tissue scaffolding and drug delivery. We discuss the limitations of traditional 3D-bioprinting in providing customized and sustained medication release. Shape memory polymers and hydrogels are examples of new responsive materials enabled by 4D-bioprinting that can enhance drug administration. Additionally, we provide a thorough analysis of various biopolymers used in drug delivery systems, including cellulose, collagen, alginate, and chitosan. The use of biopolymers in 4D-printing significantly increases material responsiveness, allowing them to react to stimuli such as temperature, light, and humidity. This capability enables complex designs with programmable shape and function changes. The expansion and contraction of hydrogels in response to temperature changes offer a practical method for controlled drug release. 4D-bioprinting has the potential to address significant challenges in tissue regeneration and medication administration, spurring ongoing research in this technology. By providing precise control over cell positioning and biomaterial integration, traditional 3D-bioprinting has evolved into 4D-bioprinting, enhancing the development of tissue constructs. 4D-bioprinting represents a paradigm shift in tissue engineering and biomaterials, offering enhanced possibilities for creating responsive, adaptive structures that address clinical needs. Researchers can leverage the unique properties of biopolymers within the 4D-printing framework to develop innovative approaches for tissue regeneration and drug delivery, leading to advanced treatments in regenerative medicine. One potential future application is in vivo tissue regeneration using bioprinted structures that can enhance the body’s natural healing capabilities. Full article

The treatment of chronic wounds and pressure sores is an important challenge in the context of public health and the effectiveness of patient treatment. Therefore, new methods are being developed to reduce or, in extreme cases, to initiate and conduct the wound healing process. This article presents an innovative smart bandage, programmable using a smartphone, which generates small amplitude impulse vibrations. The communication between the smart bandage and the smartphone is realized using BLE. The possibility of programming the smart bandage allows for personalized therapy. Owing to the built-in MEMS sensor, the smart bandage makes it possible to monitor work during rehabilitation and implement an auto-calibration procedure. The flexible, openwork mechanical structure of the dressing was made in 3D printing technology, thanks to which the solution is easy to implement and can be used together with traditional dressings to create hybrid ones. Miniature electronic circuits and actuators controlled by the PWM signal were designed as replaceable elements; thus, the openwork structure can be treated as single-use. The smart bandage containing six actuators presented in this article generates oscillations in the range from about 40 Hz to 190 Hz. The system generates low-amplitude vibrations, below 1 g. The actuators were operated at a voltage of 1.65 V to reduce energy consumption. For comparison, the actuators were also operated at the nominal voltage of 3.17 V, as specified by the manufacturer. Full article

Herbs from the Gentianaceae family are widely known for their medicinal and pharmacological properties. They were used centuries ago as a part of traditional medicine in China and Tibet. This review aims to draw attention to the potential uses of gentian herbs in treating various diseases, including skin conditions, gastrointestinal and liver disorders, wound healing, rheumatoid arthritis, and diabetes. The aim of our study was to systematically summarize current knowledge about key bioactive compounds present in both roots and aerial parts—such as xanthones, iridoids, and flavonoids—and highlight their pharmacological significance. We also focused on the Gentianaceae family’s usage in complementary and alternative medicine, as well as their anti-inflammatory, anti-melanogenic, anti-ischemic, anti-fibrotic, and antioxidant properties, which can be utilized in the treatment and prevention of dermatological diseases, such as skin cancers. Here, we involve ethnomedicinal knowledge with modern pharmacological data; we also highlight the scientific relevance of gentian-derived compounds in drug development. This review concludes that these species represent a promising source of natural agents, while also underlining the need for further research and conservation strategies to preserve threatened species. Full article

Background/Objectives: Vinegar–egg is a traditional health-promoting beverage prepared by soaking eggs in vinegar. While both eggs and vinegar are common dietary components with well-documented nutritional and pharmacological activities, eggs treated with vinegar have been rarely studied. This study aims to identify and characterize bioactive compounds in vinegar–egg and investigate their potential wound-healing activities. Methods: The vinegar–egg extract was analyzed using liquid chromatography–mass spectrometry (LC–MS) and column chromatography, including HPLC purification, which led to the isolation of four phenolic compounds. Results: These compounds were identified as 4-hydroxybenzoic acid (1), vanillic acid (2), methyl syringate (3), and leptosperin (4) using ESI-MS, UV, and NMR spectroscopic data. Among the isolates, 4-hydroxybenzoic acid (1) and vanillic acid (2) demonstrated wound-healing properties in mouse embryonic fibroblast (MEF) cells. None of the compounds, 4-hydroxybenzoic acid (1), vanillic acid (2), methyl syringate (3), or leptosperin (4), exhibited cytotoxicity in PC12, AGS, MEF, or MDA-MB-231 cells. Notably, 4-hydroxybenzoic acid (1) enhanced cell motility by 2.59-fold and cell invasion by 1.20-fold, while vanillic acid (2) increased cell motility by 2.69-fold and cell invasion by 1.23-fold. Western blot analysis revealed that treatment with 4-hydroxybenzoic acid (1) and vanillic acid (2) increased the phosphorylation of focal adhesion kinase (p-FAK) and matrix metalloproteinase 2 (MMP-2). Furthermore, both compounds elevated the phosphorylation of p38, a key regulator in wound-healing pathways. Conclusions: These findings demonstrate that 4-hydroxybenzoic acid (1) and vanillic acid (2) accelerate wound healing through the activation of focal adhesion and mitogen-activated protein kinase (MAPK) signaling pathways. These results highlight vinegar–egg as a promising therapeutic candidate for wound healing. Full article

Bassia scoparia (Syn. Kochia scoparia (L.) Schrad.) is a medicinal plant whose fruit, Kochiae Fructus, has been extensively studied for its dermatological applications. This study focused on extracts from the whole plant B. scoparia (WPBS), excluding fruits, to address the research gap regarding the medicinal properties of non-fruit parts. The diverse skin benefits of WPBS, including its anti-photoaging, moisturizing, wound healing, anti-inflammatory, and anti-angiogenic effects, were investigated. The WPBS extract enhanced the viability of keratinocytes (HaCaT) without inducing cytotoxic effects. WPBS significantly reduced matrix metalloproteinase-1 (MMP-1) levels and increased collagen type I alpha 1 (COL1A1) levels (p < 0.01) in fibroblasts exposed to ultraviolet B (UVB) radiation, indicating strong anti-photoaging effects. WPBS upregulated skin hydration markers such as aquaporin-3 (AQP3) and hyaluronan synthase-3 (HAS3) and effectively accelerated fibroblast wound closure compared to the positive control. Furthermore, WPBS substantially downregulated the expression of inflammatory (COX-2 and IL-1β) and angiogenic markers (VEGF). Transcriptome analysis (RNA-seq) confirmed that WPBS suppressed inflammation-related and UV-induced gene expression pathways. Overall, these findings expand the therapeutic scope of B. scoparia beyond its traditional fruit use and suggest that WPBS is a promising botanical ingredient for various skin applications. Full article

Biopolymer films doped with active substances may become a promising alternative to traditional dressings for skin wounds, as they can deliver drugs while maintaining wound moisture, thus contributing to the healing process. This article describes the preparation of amygdalin-doped biopolymer films for in vitro testing against the bacterial strains typical of chronic wounds: E. coli and S. aureus. Thus, FTIR characterization suggests minimal chemical interaction between amygdalin and the biopolymer matrix components, indicating potential compatibility, while thermogravimetric analysis highlights the thermal behavior of the films as well as the influence of the polymer matrix composition on the amount of bound water and the shift of T_peak value for the decomposition process of the base polymer. Moreover, the identity of the secondary biopolymer (gelatin or CMC) significantly influences film morphology and antibacterial performance. Full article

Wound care in military and combat environments poses distinct challenges that set it apart from conventional medical practice in civilian settings. The nature of injuries sustained on the battlefield—often complex, contaminated, and involving extensive tissue damage—combined with limited access to immediate medical intervention, significantly increases the risk of infection, delayed healing, and adverse outcomes. Traditional wound dressings frequently prove inadequate under such extreme conditions, as they have not been designed to address the specific physiological and logistical constraints present during armed conflicts. This review provides a comprehensive overview of recent progress in the development of advanced wound dressings tailored for use in military scenarios. Special attention has been given to multifunctional dressings that go beyond basic wound coverage by incorporating biologically active macromolecules such as collagen, chitosan, thrombin, alginate, therapeutic peptides, and growth factors. These compounds contribute to properties including moisture balance control, exudate absorption, microbial entrapment, and protection against secondary infection. This review highlights the critical role of advanced wound dressings in improving medical outcomes for injured military personnel. The potential of these technologies to reduce complications, enhance healing rates, and ultimately save lives underscores their growing importance in modern battlefield medicine. Full article