Search Results (88)

Background: The treatment of burns is a socio-economic challenge for both patients and the National Health Service. Early debridement and skin graft reduces the risk of local and systemic complications. However, when skin autografting is unfeasible or contraindicated, alternative options are required. Recent research has introduced new potential tools: fish skin grafts (FSGs). This systematic review focuses on FSGs with the aim of improving the management of burn patients. Methods: A systematic search on articles concerning FSG for the treatment of burns was performed by searching PubMed, Web of Science and Embase according to the PRISMA statement. Clinical trials, retrospective studies, case series and case reports were included. Results: A total of 36 studies were identified through the search strategy and imported for screening. After duplicate removal, 26 studies were considered. Based on predetermined criteria, 20 full texts were assessed for eligibility, leaving 18 articles to be included in the systematic review. Conclusions: By virtue of the safety and effectiveness of FSGs, including low risk of zoonosis transmission and valuable outcomes even in austere environments, FSGs could represent a new alternative for the treatment of burns. Full article

Traditional wound and burn treatments often fall short in balancing antimicrobial efficacy, patient comfort, and ease of application. This study introduces a novel, transparent, thermoresponsive sol–gel formulation incorporating polyhexamethylene biguanide (PHMB) for advanced topical therapy. Utilizing Poloxamer 407 as a biocompatible carrier, the formulation remains a sprayable liquid at room temperature and instantly gels upon contact with body temperature, enabling painless, pressure-free application on sensitive, injured skin. Comprehensive in vitro and in vivo evaluations confirmed the formulation’s broad-spectrum antimicrobial efficacy (≥5 log₁₀ reduction in 30 s), high biocompatibility (viability > 70% in fibroblasts), non-irritancy (OECD 425-compliant), and physical stability across three months. Importantly, the formulation maintained fibroblast migration capacity—crucial for wound regeneration—while exhibiting rapid sol-to-gel transition at ~34 °C. These findings highlight the system’s potential as a next-generation wound dressing with enhanced user compliance, transparent monitoring capability, and rapid healing support, particularly in disaster or emergency scenarios. Full article

Background and Objectives: Traditionally, full-thickness skin defects (FTSDs) are covered with split-thickness skin grafts (STSGs). This usually provides an epidermal coverage but entails a high risk of hypertrophic scarring mainly due to the absence of the dermal layer. The Novosorb^® Biodegradable Temporising Matrix (BTM) is a novel synthetic dermal substitute that has been used for the reconstruction of various complex and/or large defects in our center. The aim of this article is to evaluate the clinical performance of the BTM as a synthetic dermal substitute for complex FTSD reconstruction in a European context. Materials and methods: This case series focused on the treatment of complex FTSDs with the BTM. After wound debridement, the BTM was applied according to a defined protocol. Once adequate vascularization was observed, the sealing membrane was removed and the neo-dermis was covered with STSGs. Patient demographics, comorbidities, wound defect localization and etiology, wound bed preparations, time of BTM application and removal, time to complete wound healing after STSG, complications, and HTS formation were recorded. Results: The BTM was used to treat FTSDs in six patients with complex wounds from degloving (3), burns (1), ulcerations (1), and necrotizing fasciitis (1). Successful integration occurred in five cases (83%), with one partial integration. The BTM remained in situ for an average of 20.7 days before delamination and STSG coverage. No major complications occurred, though one case had hypergranulation with secondary STSG infection. Two patients were lost to follow-up, while the remaining four had excellent aesthetic and functional outcomes with good-quality scars. Conclusions: Within the limits of this small and heterogeneous case series, the BTM appears to be a promising option for the reconstruction of complex FTSDs of varying etiologies. Its successful integration in most cases and limited complication rate support its clinical potential. However, given this study’s retrospective design and limited sample size, further prospective studies are required to validate these findings and assess long-term outcomes. Full article

Background: Scald burns pose significant morbidity, and effective topical treatments remain a clinical priority. Burn injuries pose a significant clinical challenge due to the prolonged inflammation and high infection risk. Traditional treatments focus on moisture retention and infection prevention, but biocompatible formulations such as hydrogels and oleogels offer advantages. Hydrogels hydrate, cool, and promote epidermal regeneration, while oleogels form a lipid barrier that enhances the absorption of lipophilic bioactive compounds. There is an increasing demand for novel topical alternatives that can effectively improve wound healing by modulating the inflammatory cascade, accelerating epithelial and dermal regeneration, and restoring barrier function. Objective: This study aimed to determine the most effective plant-based topical formulations for enhancing second-degree scald burn wound healing. Methods: Utilizing a standardized rat model, we compared 21 distinct topical formulations, consisting of oleogel and hydrogel bases enriched with extracts from Boswellia serrata (frankincense), Ocimum basilicum (basil), Sambucus nigra flower (elderflower), and Galium verum (lady’s bedstraw). Second-degree burns were uniformly induced in 24 Wistar rats using boiling water (100 °C for 8 s) using the RAPID-3D device, a validated 3D-printed tool that ensures reproducible burns through controlled exposure to boiling water. Post-burn, rats were divided into three equal subgroups, and topical formulations were applied daily. Wound healing efficacy was evaluated through wound surface area measurements, transepidermal water loss (TEWL), skin hydration, sebum production, pigmentation, inflammation (erythema), skin perfusion, and histological parameters at multiple timepoints (days 1, 4, 9, 14, and 21 post-burn induction). Results: Statistical analyses indicated significant advantages of oleogel-based formulations over hydrogel-based formulations. Specifically, formulations containing Boswellia serrata and Ocimum basilicum extracts significantly reduced wound size and inflammation, improved skin hydration, and decreased melanin production by days 9 and 21 (p < 0.05). Conclusions: These findings underscore the potential clinical value of oleogel-based topical preparations containing specific plant extracts for improving scald burn wound healing outcomes, warranting further clinical evaluation. Full article

Background/Objectives: Burn injuries present significant treatment challenges due to the intricate nature of the healing process. Bombyx mori L. (silkworm) derivatives, containing healing-promoting proteins such as sericin and fibroin, as well as the anti-inflammatory enzyme serrapeptase, have shown promise as potential healing agents. This study aimed to identify the optimal dosage of silkworm body and gland extracts for burn healing, compare the selected dose’s effectiveness with that of silkworm cocoons, and assess the combined healing effects of a cocoon dressing and a silkworm body extract gel. Methods: An experimental model was employed using hairless SKH-hr2 female mice subjected to standardized second-degree burns. The mice received treatments with various formulations of silkworm body and gland extracts, silkworm cocoons, and a combined application of a cocoon dressing and silkworm body extract gel. Results: The most effective treatments were the cocoon dressing and the combination of cocoon dressing with 60% body extract gel. By Day 20, complete healing (100%) was observed in the 20% and 60% body and gland extract groups, while the cocoon and 60% gland extract groups exhibited 60% healing, significantly higher than the control group (0% healing). Wound contraction analysis showed the greatest reduction in surface area from Day 3 to Day 17 in the cocoon and 60% body extract groups (p < 0.05). Histopathological assessments revealed that the combination group exhibited the least tissue damage (score: 7), compared to the control (score: 10–13). Conclusions: The study highlights the poorly examined therapeutic potential of silkworm body and gland extracts, demonstrating their efficacy in accelerating burn healing. The effects observed by the silkworm cocoon and body extract suggests a novel and promising approach for burn wound management, warranting further clinical exploration. Full article

Background: Scald burns are common thermal injuries in clinical settings, yet existing animal models lack standardization in burn size, exposure time, and severity control. Traditional burn induction methods, such as manual immersion or heated metal contact, suffer from high variability, limited reproducibility, and are operator-dependent, reducing their translational relevance. This study presents RAPID-3D (rat printed induction device—3D), a novel 3D-printed system designed to induce uniform and reproducible scald burns in a rat model, ensuring precise exposure control and minimal variability. Methods: RAPID-3D features four burn exposure windows (10 × 20 mm each, 10 mm spacing), allowing for controlled boiling water (100 °C, 8 s) exposure while immobilizing the anesthetized rat’s dorsum. N = 10 female Wistar rats were subjected to eight controlled burns per animal. Internal unburned control areas were used in each rat for intra-animal comparison. Burn evolution was assessed using digital planimetry, histological evaluation, and real-time microvascular perfusion analysis via laser Doppler line scanning (LDLS) at 1 h, which was repeated on day 4, 9 and 21 post-burn. Results: RAPID-3D generated highly consistent burn sizes (198 ± 3.54 mm²) across all rats, with low inter-animal variability. Histological analysis confirmed full-thickness epidermal necrosis and deep partial-thickness dermal damage (600–900 µm depth). Microvascular Trends: Perfusion dropped immediately post-burn, remained low at day 4, and gradually increased from day 9 onward, suggesting progressive neovascularization and vascular remodeling. RAPID-3D provides a standardized, reproducible, and clinically relevant scald burn model, eliminates operator-induced variability, enhances experimental consistency, and offers strong translational relevance for burn treatment development and wound healing research. Full article

Microtubule-actin cross-linking factor 1 (MACF1), also known as actin cross-linking family protein 7 (ACF7), is a giant cytolinker protein with multiple conserved domains that can orchestrate cytoskeletal networks of actin and microtubules. MACF1 is involved in various biological processes, including cell polarity, cell–cell connection, cell proliferation, migration, vesicle transport, signal transduction, and neuronal development. In this review, we updated the physiological and pathological roles of MACF1, highlighting the components and signaling pathways involved. Novel evidence showed that MACF1 is involved in diverse human diseases, including multiple neuronal diseases, congenital myasthenic syndrome, premature ovarian insufficiency, spectraplakinopathy, osteoporosis, proliferative diabetic retinopathy, and various types of cancer. We also reviewed the physiological roles of MACF1, including its involvement in adhesome formation, bone formation, neuronal aging, and tooth development. In addition, MACF1 plays other roles, functioning as a biomarker for the prediction of infections in patients with burns and as a marker for genome selection breeding. These studies reinforce the idea that MACF1 is a bona fide versatile, multifaceted giant protein. Identifying additional MACF1 functions would finally help with the treatment of diseases caused by MACF1 defects. Full article

Cancer significantly impacts human quality of life and life expectancy, with an estimated 20 million new cases and 10 million cancer-related deaths worldwide every year. Standard treatments including chemotherapy, radiotherapy, and surgical removal, for aggressive cancers, such as glioblastoma, are often ineffective in late stages. Glioblastoma, for example, is known for its poor prognosis post-diagnosis, with a median survival time of approximately 15 months. Novel therapies using local electric fields have shown anti-tumour effects in glioblastoma by disrupting mitotic spindle assembly and inhibiting cell growth. However, constant application poses risks like patient burns. Wireless stimulation via piezoelectric nanomaterials offers a safer alternative, requiring ultrasound activation to induce therapeutic effects, such as altering voltage-gated ion channel conductance by depolarising membrane potentials. This review highlights the piezoelectric mechanism, drug delivery, ion channel activation, and current technologies in cancer therapy, emphasising the need for further research to address limitations like biocompatibility in whole systems. The goal is to underscore these areas to inspire new avenues of research and overcome barriers to developing piezoelectric nanoparticle-based cancer therapies. Full article

Cefiderocol is a novel cephalosporin antibiotic approved for urinary tract infections and hospital-acquired or ventilator-associated pneumonias caused by difficult-to-treat Gram-negative pathogens. To date, its use in treating difficult-to-treat Gram-negative infections in burn patients has been minimally described in the literature. Our aim was to evaluate cefiderocol use in a population of burn patients initiated on cefiderocol for resistant Gram-negative infections. A retrospective chart review of nine patients was conducted. Two patients were treated for pneumonia; five for bacteremia, three of which had coexisting burn wound infections or pneumonia; one was treated for a burn wound infection alone; and one patient was treated for a simultaneous burn wound infection, pneumonia, and bacteremia. The pathogens treated included the following: multidrug-resistant Pseudomonas aeruginosa, carbapenem-resistant Acinetobacter baumannii, and carbapenem-resistant Enterobacterales. Three isolates were confirmed as New Delhi metallo-beta-lactamase (NDM) producers, though this was likely an underestimate as genetic testing is not routinely performed at our institution and not all the isolates were tested. One of the nine patients in this study succumbed to their infection. Of note, the multidrug-resistant Pseudomonas aeruginosa in this patient tested intermediate to cefiderocol. The patients were treated with cefiderocol for a median of 14 days, most commonly in combination with other antimicrobial therapies. Treatment with cefiderocol appeared to be efficacious in this population of burn patients when other antibiotics routinely used for complicated infections caused by multidrug-resistant (MDR) Gram-negative pathogens showed treatment failure or resistance. Full article

For pediatric patients with full-thickness burns, achieving adequate dermal regeneration is essential to prevent inelastic scars that may hinder growth. Traditional autologous split-thickness skin grafts alone often fail to restore the dermal layer adequately. This study evaluates the long-term effect of using a NovoSorb^® Biodegradable Temporizing Matrix (BTM) as a dermal scaffold in four pediatric patients, promoting dermal formation before autografting. Pediatric burn patients treated at the University Children’s Hospital Zurich between 2020 and 2022 underwent a two-step treatment involving NovoSorb^® BTM application, followed by autografting. Histological analysis, conducted through 22 punch biopsies taken up to 2.6 years post-application, demonstrated robust dermal reorganization, with mature epidermal regeneration and stable dermo-epidermal connections. Immunofluorescence staining showed rapid capillary ingrowth, while extracellular matrix components, including collagen and elastic fibers, gradually aligned over time, mimicking normal skin structure. By 2.6 years, the dermal layer displayed characteristics close to uninjured skin, with remnants of NovoSorb^® BTM degrading within five months post-application. This study suggests that NovoSorb^® BTM facilitates elastic scar formation, offering significant benefits for pediatric patients by reducing functional limitations associated with inelastic scarring. Full article

Food processing is a fundamental requirement for extending the shelf life of food products, but it often involves heat treatment, which can compromise organoleptic quality while improving food safety. Infrared (IR) radiation has emerged as a transformative technology in food processing, offering a rapid, energy-efficient method for inactivating microbial cells and spores while preserving the nutritional and sensory attributes of food. Unlike traditional heating methods, IR technology enhances heating homogeneity, shortens processing time, and reduces energy consumption, making it an environmentally friendly alternative. Additionally, IR processing minimizes water usage, prevents undesirable solute migration, and maintains product quality, as evidenced by its effectiveness in applications ranging from drying fruits and vegetables to decontaminating meat and grains. The advantages of IR heating, including its precise and even heat diffusion, ability to retain color and nutrient content, and capacity to improve the microbial safety of food, position it as a promising tool in modern food preservation. Nevertheless, there are gaps in knowledge with respect to optimal application of IR in foods, especially in the maintenance product quality and the impact of factors such as IR power level, temperature, wavelength (λ), food depth, and target microorganisms on the applicability of this novel technology in food systems. Recent research has attempted to address challenges to the application of IR in food processing such as its limited penetration depth and the potential for surface burns due to high energy which has delayed the widespread utilization of this technology in food processing. Thus, this review critically evaluates the application of IR in food safety and quality, focusing on factors that affect its effectiveness and its use to moderate food quality and safety while comparing its advantages/disadvantages over traditional thermal processing methods. Full article

This study investigates the impact of chitosan-based nanofibers on burn wound healing in a rat model. Two formulations of chitosan nanofibers were prepared through electrospinning. The formulations were then incorporated with different amounts of norfloxacin and underwent surface modifications with 2-formylphenylboronic acid. The burn model was applied to Wistar male rats by the contact method, using a heated steel rod attached to a thermocouple. The effectiveness of the nanofibers was tested against a negative control group and a standard commercial dressing (Atrauman Ag) on the described model and evaluated by wound diameter, histological analysis and biochemical profiling of systemic inflammatory markers. The results showed that chitosan-based dressings significantly accelerated burn healing compared to the control treatments. The high-concentration norfloxacin-infused chitosan coated with 2-formylphenylboronic acid’ groups exhibited significant improvements in wound closure and reduced inflammation compared to the other groups; antioxidant enzymes SOD and GPx expression was significantly higher, p < 0.05, whereas pro-oxidative markers such as cortisol were lower (p < 0.05). Macroscopically, the wound area itself was significantly diminished in the chitosan-treated groups (p < 0.05). Furthermore, a histological evaluation indicated enhanced epithelialization and granulation tissue formation within the experiment time frame, while the biochemical panel revealed lower levels of inflammatory cytokines and lower leukocyte counts in the treated groups. These findings highlight the potential of the studied chitosan nanofibers as novel nanosystems for next-generation wound therapies, as well as the clinical utility of the novel chitosan fibers obtained by electrospinning technique. Full article

Background: The silkworm (Bombyx mori L.) and its cocoon are rich in bioactive proteins like sericin and fibroin, as well as enzymes such as serrapeptase, which possess anti-inflammatory and skin-healing properties. This study aimed to evaluate the in vivo effects of various silkworm products, including cocoon patches and extracts from the silkworm body and glands, on the healing of second-degree burns. Methods: Hairless, female SKH-2 mice were used to model second-degree burns. The study tested formulations containing 1%, 10%, or 20% silkworm body or gland extracts, as well as cocoon-derived patches. In addition to histopathological and clinical assessments, the study measured parameters including burn size, hydration, transepidermal water loss and thickness. Results: The results of this study demonstrated that, in terms of primary outcomes (complete healing), both the silkworm cocoon and the 20% body extract significantly promoted wound healing, with similar efficacy. All body extracts showed statistical significance in wound area reduction, while the gland extracts had no significant effect. Histopathological evaluation confirmed the superior healing potential of the body extracts increasing by increased concentration and cocoon. This novel insight into the therapeutic properties of silkworm body extracts opens new opportunities for the development of cost-effective, renewable second-degree burn healing treatments. Full article

Two novel membranes based on collagen and two polyphenols, taxifolin pentaglutarate (TfG5) and a conjugate of taxifolin with glyoxylic acid (DfTf), were prepared. Fourier transform infrared spectroscopy examination confirmed the preservation of the triple helical structure of collagen. A scanning electron microscopy study showed that both materials had a porous structure. The incorporation of DfTf into the freeze-dried collagen matrix increased the aggregation of collagen fibers to a higher extent than the incorporation of TfG5, resulting in a more compact structure of the material containing DfTf. It was found that NIH/3T3 mouse fibroblasts were attached to, and relatively evenly spread out on, the surface of both newly obtained membranes. In addition, it was shown that the membranes enhanced skin wound healing in rats with a chemical burn induced by acetic acid. The treatment with the materials led to a faster reepithelization and granulation tissue formation compared with the use of other agents (collagen without polyphenols and buffer saline). It was also found that, in the wound tissue, the level of thiobarbituric acid reactive substances (TBARS) was significantly higher and the level of low-molecular-weight SH-containing compounds (RSH) was significantly lower than those in healthy skin, indicating a rise in oxidative stress at the site of injury. The treatment with collagen membranes containing polyphenols significantly decreased the TBARS level and increased the RSH level, suggesting the antioxidant/anti-inflammatory effect of the materials. The membrane containing TfG5 was more effective than other ones (the collagen membrane containing DfTf and collagen without polyphenols). On the whole, the data obtained indicate that collagen materials containing DfTf and TfG5 have potential as powerful therapeutic agents for the treatment of burn wounds. Full article

Wound healing is important for skin after deep injuries or burns, which can lead to hospitalization, long-term morbidity, and mortality. In this field, tissue-engineered skin substitutes have therapy potential to assist in the treatment of acute and chronic skin wounds, where many requirements are still unmet. Hence, in this study, a novel type of biocompatible ternary polymer hybrid hydrogel scaffold was designed and produced through an entirely eco-friendly aqueous process composed of carboxymethyl cellulose, chitosan, and polyvinyl alcohol and chemically cross-linked by citric acid, forming three-dimensional (3D) matrices, which were biofunctionalized with L-arginine (L-Arg) to enhance cellular adhesion. They were applied as bilayer skin biomimetic substitutes based on human-derived cell cultures of fibroblasts and keratinocytes were seeded and grown into their 3D porous structures, producing cell-based bio-responsive hybrid hydrogel scaffolds to assist the wound healing process. The results demonstrated that hydrophilic hybrid cross-linked networks were formed via esterification reactions with the 3D porous microarchitecture promoted by foam templating and freeze-drying. These hybrids presented chemical stability, physicochemical properties, high moisture adsorption capacity, surface properties, and a highly interconnected 3D porous structure well suited for use as a skin substitute in wound healing. Additionally, the surface biofunctionalization of these 3D hydrogel scaffolds with L-arginine through amide bonds had significantly enhanced cellular attachment and proliferation of fibroblast and keratinocyte cultures. Hence, the in vivo results using Hairless mouse models (an immunocompromised strain) confirmed that these responsive bio-hybrid hydrogel scaffolds possess hemocompatibility, bioadhesion, biocompatibility, adhesiveness, biodegradability, and non-inflammatory behavior and are capable of assisting the skin wound healing process. Full article