Search Results (2,926)

Conventional dental materials with organised crystal structures exhibit limitations in corrosion resistance, bioactivity, and drug delivery capability. In contrast, amorphous nanomaterials offer potential advantages in overcoming these limitations due to their unique structural properties. They are characterised by a non-crystalline, disordered atomic structure and are similar to a solidified liquid at the nanoscale. Among the amorphous nanomaterials used in dentistry, there are five major categories: calcium-, silicon-, magnesium-, zirconia-, and polymer-based systems. This study reviewed these amorphous nanomaterials by investigating their synthesis, properties, applications, limitations, and future directions in dentistry. These amorphous nanomaterials are synthesised primarily through low-temperature methods, including sol–gel processes, rapid precipitation, and electrochemical etching, which prevent atomic arrangements into crystalline structures. The resulting disordered atomic configuration confers exceptional properties, including enhanced solubility, superior drug-loading capacity, high surface reactivity, and controlled biodegradability. These characteristics enable diverse dental applications. Calcium-based amorphous nanomaterials, particularly amorphous calcium phosphate, demonstrate the ability to remineralise tooth enamel. Silicon-based amorphous nanomaterials function as carriers that can release antibacterial agents in response to stimuli. Magnesium-based amorphous nanomaterials are antibacterial and support natural bone regeneration. Zirconia-based amorphous nanomaterials strengthen the mechanical properties of restorative materials. Polymer-based amorphous nanomaterials enable controlled release of medications over extended periods. Despite the advances in these amorphous nanomaterials, there are limitations regarding material stability over time, precise control of degradation rates in the oral environment, and the development of reliable large-scale manufacturing processes. Researchers are creating smart materials that respond to specific oral conditions and developing hybrid systems that combine the strengths of different nanomaterials. In summary, amorphous nanomaterials hold great promise for advancing dental treatments through their unique properties and versatile applications. Clinically, these materials could improve the durability, bioactivity, and targeted drug delivery in dental restorations and therapies, leading to better patient outcomes. Full article

Water contamination by antibiotics has become a critical environmental and public health issue. Among emerging technologies for their removal, heterogeneous photocatalysis has shown remarkable potential. This review provides a systematic analysis of 40 recent studies (2019–2025) that employed green synthesis routes—including sol–gel, hydrothermal, combustion, pyrolysis and co-precipitation methods—for the photocatalytic degradation of antibiotics. The comparison of these techniques revealed that biogenic metal oxides and ferrites synthesized with plant extracts achieved outstanding photocatalytic performance, with degradation efficiencies often exceeding 90–100% for antibiotics such as ciprofloxacin and tetracycline. These results are attributed to the phytochemical composition of the extracts, which are rich in flavonoids, phenols, saponins, tannins, and alkaloids, which act as natural reducing, capping, and stabilizing agents, promoting uniform nucleation, smaller particle sizes, and enhanced crystallinity. The review also highlights the synergistic relationship between biomolecule-mediated reduction and controlled synthesis conditions, which enables the design of sustainable, reusable, and high-efficiency photocatalysts for wastewater treatment and environmental remediation. Full article

Background: Facial atrophic acne scars have a significant impact on patients’ psychosocial well-being and remain a therapeutic challenge. Existing treatments options are frequently limited by modest efficacy and adverse effects. The combination of Polynucleotide High-Purification Technology (PN HPT™) and hyaluronic acid (HA) represents a novel bioregenerative strategy aimed at improving dermal remodelling and overall skin quality. Methods: This six-month, prospective, real-world study evaluated the efficacy and safety of Newest^® (Mastelli S.r.l., Sanremo, Italy), a sterile intradermal gel containing highly purified polynucleotides (10 mg/mL) and HA (10 mg/mL). Eligible participants, aged 20–60 years with moderate-to-severe atrophic facial post-acne scars, underwent four treatment sessions in two-week intervals. Efficacy was assessed using the Acne Scar Assessment Scale (ASAS) and Global Aesthetic Improvement Scale (GAIS) at three and six months, while safety was monitored throughout the study. Results: A total of 62 patients (32 Caucasian, 30 Asian; 19 males, 43 females; mean age: 36.6 years) completed the study. At three and six months, 46.8% showed at least a one-grade reduction in ASAS score with respect to the baseline. Patient-reported GAIS indicated that 54.8% perceived an improvement in scar appearance, aligning with investigator assessments. Only one mild, transient adverse event (wheal formation) occurred, which resolved spontaneously without intervention. Conclusions: In this real-world study, treatment with Polynucleotide High-Purification Technology (10 mg/mL) combined with HA (10 mg/mL) was associated with observable improvementin atrophic facial acne scars, with an excellent safety and tolerability profile. These findings support the potential of polynucleotide-based therapies for use as well-tolerated options for managing moderate-to-severe atrophic acne scarring, while the need for further controlled studies to confirm efficacy is also acknowledged. Full article

Objective: This study aims to engineer a novel nanoparticle formulation for combined tumor therapy, designated as PDA@Mn-siSur-c-NPs, which comprises a polydopamine/manganese dioxide (PDA@MnO₂) core alongside survivin-targeting siRNA and cyclo(RGD-DPhe-K)-targeting moiety. Methods: The PDA@Mn-siSur-c-NPs were constructed and subjected to detailed characterization. Inductively coupled plasma optical emission spectroscopy (ICP-OES) was employed to quantify manganese content. To assess siRNA stability within the system, samples were incubated with 50% fetal bovine serum (FBS) before agarose gel electrophoresis analysis. Additionally, cellular internalization by 4T1 cells and in vitro photothermal conversion efficiency of the formulation were evaluated. ICP-OES was further utilized to investigate the in vivo pharmacokinetics and tissue distribution of manganese. Animal model studies were conducted to assess the anti-breast cancer efficacy of PDA@Mn-siSur-c-NPs in combination with infrared irradiation. Results: The newly developed PDA@Mn-siSur-c-NPs demonstrated superior siRNA protection, reduced toxicity, and high photothermal conversion capacity. When combined with photothermal therapy (PTT), these nanoparticles exerted enhanced synergistic anti-tumor effects. Delivery of survivin siRNA resulted in a significant downregulation of survivin protein expression in tumor tissues. Moreover, magnetic resonance imaging (MRI) confirmed that the nanoparticles possess favorable imaging properties. Conclusions: This research demonstrates that the integration of PDA@Mn-siSur-c-NPs with PTT holds considerable therapeutic promise for improved breast cancer treatment. Full article

Outdoor glass is subject to degradation due to environmental factors, which alter its physical and chemical properties depending on the exposure conditions. Studying glass weathering and the effectiveness and durability of conservation treatments is necessary for developing optimal conservation strategies for glass heritage objects. Here, an accelerated aging protocol based on actual environmental data is successfully employed to replicate weathering caused by rain runoff, temperature, humidity and UVA radiation in unsheltered conditions. Two types of silicate glass with traditional compositions were artificially aged to investigate the corrosion processes and produce representative weathered substrates for applying and aging protective treatments. The performance of two recently marketed Siox-5 sol–gel systems was compared with that of Paraloid B72. Glass specimens, as well as leaching rain solutions, were analyzed with different techniques, including SEM/EDS, FTIR-ATR, color measurements and MP-AES. The composition of the glass influences weathering patterns, which in turn affect coating adhesion and overall performance. Sol–gel coatings demonstrate good chemical stability and tend to adhere more effectively to degraded surfaces than to well-preserved ones. The coatings exhibit varying degrees of sensitivity to environmental factors, with one of the sol–gel systems generally performing better than the others under the considered exposure conditions. Full article

Black-odorous water pollution presents a serious threat to aquatic ecosystems and severely hinders the sustainable development of the ecological environment, as conventional remediation technologies often fall short in achieving the simultaneous removal of multiple pollutants. In this study, a novel composite remediation agent was developed by integrating microbial active components with modified clay minerals—sodium-modified zeolite (Na-Z) and magnesium–aluminum–lanthanum layered ternary hydroxides loaded onto sulfuric acid-modified bentonite (Mg-Al-La-LTHs@SBt)—through gel-embedding immobilization. This integrated system enabled the synergistic remediation of both overlying water and sediment pollutants. The modified clay minerals exhibited strong adsorption capacity for nitrogen and phosphorus compounds in the overlying water. Under 25 °C conditions, the composite agent achieved removal efficiencies of 58.14% for ammonium nitrogen (NH₄⁺-N) and 88.89% for total phosphorus (TP) while significantly reducing sedimentary organic matter and acid volatile sulfide (AVS). Notably, the agent retained substantial remediation efficacy even under low-temperature conditions (5 °C). High-throughput microbial community analysis revealed that the treatment enriched beneficial phyla (e.g., Proteobacteria) and beneficial genera (e.g., Thiobacillus) and suppressed sulfate-reducing groups (e.g., Desulfobacterota), promoting favorable nitrogen and sulfur transformations. These results provide a robust material and methodological basis for efficient, synergistic restoration of black-odorous water and the sustainable development of water resources. Full article

Background/Objectives: Keratitis–ichthyosis–deafness (KID) syndrome is an exceptionally rare congenital multisystem disorder, with an estimated prevalence below 1:1,000,000 and fewer than 100 reported cases worldwide. It is characterized by hyperkeratosis, alopecia, nail dystrophy, hearing loss, and ocular involvement. While dermatological management is well described, surgical experience with wound treatment in KID syndrome remains extremely limited. The objective of this report is to describe the surgical management and outcomes of a patient with chronic lower-limb wounds associated with KID syndrome. Methods: A 35-year-old male with KID syndrome was referred to the surgical outpatient clinic for chronic traumatic wounds of both lower limbs resistant to conservative dermatological therapy. Initial outpatient treatment included serial sharp surgical debridement under local anesthesia, combined with topical keratolytics and silver sulfadiazine with hyaluronic acid. Due to minimal improvement after three months, an inpatient surgical approach was initiated, involving complete excision of hyperkeratotic tissue, creation of a wide ulcer bed, and adjunct systemic and topical therapies. Results: The inpatient management enabled thorough removal of pathological tissue and better control of local infection and inflammation. Combined systemic antibiotic and antipsoriatic therapy, together with topical sodium hyaluronate and iodine, was associated with gradual wound healing and improved skin condition. The patient tolerated the procedures well, without major complications. Conclusions: Surgical debridement and excision, when combined with targeted dermatological and antimicrobial therapy, can be an effective and safe strategy for managing chronic wounds in KID syndrome. This case highlights the importance of multidisciplinary collaboration and individualized surgical planning in this extremely rare disorder. Full article

Background: Oral mucositis (OM) is a significant complication after allogeneic stem cell transplantation. Objectives: This prospective, observational cohort study assessed the effectiveness of a polyvinylpyrrolidone-zinc gluconate and taurine (PVP-ZG-TAU) oral gel in managing OM. The primary objective was to determine whether the gel reduced the incidence and grade of OM and accelerated its resolution. Methods: The study enrolled 82 patients; 39 received the PVP-ZG-TAU gel, and 43 represented a historical control group. To prevent oral mucositis, both groups maintained good oral hygiene. In the experimental group, patients received three sprays of PVP-ZG-TAU gel, three times a day, from the start of conditioning chemotherapy until day +15 after allo-SCT. Results: In the PVP-ZG-TAU group, 79.1% patients experienced grade 1–2 OM and 20.9% experienced grade 3–4 OM. In the control group, 74.4% had grade 1–2 OM, and 25.6% had grade 3–4 OM (p = ns). Resolution occurred significantly faster in the PVP-ZG-TAU group, with an 84% resolution rate per 100 person-weeks, compared with 62% in the control group. Cox regression analysis revealed that treatment was associated with a 68% greater likelihood of earlier resolution (adjusted hazard ratio [HR], 1.68; 95% confidence interval [CI], 1.03–2.74; p = 0.036). Conclusions: These findings suggest that PVP-ZG-TAU can reduce OM duration and serve as a supportive intervention for allo-SCT patients. Full article

Due to the limitations of SRP, new methods are being sought to support non-surgical periodontal therapy. One of them is the use of antiseptics such as low-concentration sodium hypochlorite gel buffered with amino acids (NaOCl/AA). The aim of the study was to evaluate periodontal parameters and the concentration of metalloproteinase 8 (MMP-8) and interleukin 8 (IL-8) in the gingival crevicular fluid (GCF) after SRP with or without NaOCL/AA gel. The study included 40 periodontal patients randomized to study and control groups. Before SRP, the study group had a gel introduced into pockets with PD ≥ 5 mm. After treatment in both groups, the pocket depth (PD) decreased, there was a CAL gain, and unnoticeable changes in the gingival recession (GR). In the study group, deep pockets accounted for 25% of the sites examined prior to therapy, whereas after therapy, they decreased to 12%. In the control group, the proportion of deep periodontal pockets (PD ≥ 5 mm) fell from 17.46% to 9.05%. No differences were noted between groups. In the study group, there was a significant reduction in the amount of MMP-8 in GCF from 8.32 ng/mL to 5.14 ng/mL after 3 months. No statistically significant difference was observed in the control group. The concentration of IL-8 decreased significantly over time in both groups without differences between them. A single application of the NaOCl/AA gel in deep periodontal pockets does not affect clinical results and IL-8 levels. However, it had a significant effect on the amount of MMP-8. Full article

Background: Chlorhexidine (CHX) is an effective antiseptic rinse for managing gingival inflammation; however, side effects such as staining and altered taste limit its long-term use. StellaLife^® (SL), an herbal-based mouth rinse and a gel, has shown promising in vitro effects, including enhanced biocompatibility and wound healing. This study aimed to compare the clinical efficacy of SL and 0.12% CHX in an experimental gingivitis model. Methods: In this randomized, controlled, cross-over clinical trial, 34 dental students received both treatment regimens in alternating two-week phases following prophylaxis. Group 1 used SL (mouth rinse and the gel) and then crossed over to CHX with placebo gel. Group 2 followed the reverse sequence. Participants refrained from oral hygiene during treatment phases. Clinical parameters and gingival crevicular fluid (GCF) were assessed at baseline and post-treatment. Paired t-tests and Bonferroni corrections were applied (p < 0.05). Bacterial count was determined by an external laboratory using a PCR test. Mean values for bacteria after SL and CHX use measured in genome copies/mL for Aggregatibacter actinomycetemcomitans, P. gingivalis, T. denticola, T. forsythia and F. nucleatum. Results: No statistically significant differences were observed between the SL and CHX groups for PI (p = 0.057), GI (p = 0.960), PD (p = 0.112), BOP (p = 0.895), GR (p = 0.768), CAL (p = 0.112), or GCF (p = 0.951). Both regimens improved periodontal parameters similarly. No significant differences were found between CHX and SL use in respect to periodontal pathogenic bacteria in the oral cavity. Conclusions: SL demonstrated clinical efficacy comparable to CHX in managing experimental gingivitis. Given its favorable safety profile, SL may serve as a promising alternative to CHX, though larger and longer-term studies are warranted. Full article

This study presents the synthesis and characterization of novel kaolinite niobium and kaolinite titanium niobium nanocomposites and their application as heterogeneous photocatalysts. Utilizing a hydrolytic sol–gel route, we combined kaolinite with isopropyl alcohol, acetic acid, titanium (IV) isopropoxide, and ammonium niobium oxalate, followed by heat treatment at 400, 700, and 1000 °C. X-ray diffraction confirmed the retention of kaolinite’s characteristic reflections, with basal spacings indicating the presence of semiconductors on the external surfaces and edges. Heating treatment not allowing the crystallization of anatase until 1000 °C reveals that Nb⁵⁺ could inhibit the transition to titanium crystalline phases (anatase and rutile). The bandgap energies decreased with clay mineral support, averaging 2.50 eV, and absorbing up to 650 nm. The model reaction of terephthalic acid hydroxylation accomplished by photoluminescence spectroscopy demonstrated that KaolTiNb400 presented a higher rate of *OH production, achieving 591 mmol L⁻¹ min⁻¹ compared to pure KaolNb400 173 mmol L⁻¹ min⁻¹. Photodegradation studies revealed significant photocatalytic activity, with the KaolTiNb400 nanocomposite achieving the highest efficiency, demonstrating 90% removal of methylene blue (combining adsorption and degradation) after 24 h of UV light irradiation. These materials also exhibited promising results for the degradation of the antibiotics Triaxon^® (40%) and Loratadine (8%), highlighting their potential for organic pollutants’ removal. In both cases the presence of byproducts is detected. Full article

This study aimed to evaluate the effect of experimental bleaching gels containing chitosan and theobromine and compare their performance in terms of tooth surface roughness, microhardness, and colour change with the bleaching gels BioWhiten ProHome and FGM Whiteness Perfect. One hundred and forty-four upper central incisors were used for microhardness, surface roughness, and colour change analyses (n = 12). Prior to bleaching, surface roughness was measured using a profilometer, microhardness was analysed using a Vickers hardness test, and colour was measured using a spectrophotometer. For Group 1, the treatment consisted of an experimental gel containing chitosan–theobromine (16% CP); for Group 2, it was an experimental gel containing chitosan–theobromine (6% HP); for Group 3, it consisted of BioWhiten ProHome (6% HP); and for Group 4, it consisted of FGM Whiteness Perfect (16% CP). Microhardness and surface roughness tests were performed under the same conditions before bleaching, after bleaching, and 14 days after the initial treatment. Colour analysis was performed before the bleaching, during the application, 24 h after bleaching, and at 7 and 14 days after treatment. p < 0.05 was considered significant. No statistically significant increase in microhardness values after bleaching was detected in any group (p > 0.05), effective bleaching was detected in all groups, and the highest efficacy was observed in Group 4 (p < 0.05). The experimental gels containing theobromine and chitosan resulted in effective bleaching and did not exert any negative effects regarding surface roughness or microhardness. Full article

Solid waste-based cementitious materials (SWCMs) represent an innovative class of binders derived mainly from construction and demolition waste as well as industrial byproducts. Their application in recycled mortar offers a promising pathway to partially replace conventional cement, thereby advancing resource recycling and facilitating a low-carbon transition in the cement industry. This review systematically examines the properties, activation techniques, strength development, and corrosion resistance of recycled mortar prepared with SWCMs. Recycled powder (RP) and industrial solid waste have gelation potential, but their low reactivity requires activation treatment to enhance utilization efficiency. Activation methods, including thermal activation, carbonation, and alkali activation, effectively enhance reactivity and promote the formation of dense gel structures (e.g., C-(A)-S-H, N-A-S-H). While low replacement ratios optimize pore structure via the microfiller effect, higher ratios introduce excessive inert components, impairing mechanical properties. SWCMs demonstrate superior resistance to sulfate and chloride attacks, but their acid resistance is relatively limited. They also have excellent freeze–thaw resistance. SWCMs represent a viable and sustainable alternative to conventional cement, exhibiting commendable mechanical and durability properties when properly activated and formulated, thereby contributing to resource recycling and environmental sustainability in the cement industry. Full article

Silicone rubber from decommissioned composite insulators has become one of the major environmental challenges in the power industry due to its non-degradable nature. Therefore, the recycling and reuse of silicone rubber are of great environmental and economic significance. In this work, a method for preparing silica microspheres based on stepwise pyrolysis combined with post-treatment particle size fractionation is proposed. First, highly spherical silica microspheres were obtained by stepwise pyrolysis. Subsequently, glass fiber membrane filtration and aga-rose gel electrophoresis were employed as post-treatment methods to achieve particle size fractionation and enhanced uniformity. The results indicate that the post-treated silica microspheres exhibit high uniformity, high sphericity, and good dispersibility. This method significantly improves the structural uniformity and microscopic characteristics of the microspheres, making them promising high-value fillers for epoxy resin insulation modification. Comparative analysis with commercial nanosilica used as epoxy fillers shows that the recycled and fractionated silica microspheres achieve comparable improvements in breakdown strength and dielectric performance, confirming their potential for recycling and reuse in high-voltage insulation and electronic packaging applications. Full article

The valorization of extraction residues from biomass waste through a cascade approach contributes significantly to promote circular economy practices and facilitates the transition toward more sustainable functional materials, like chitosan. Virgin and spent fungal biomass, previously subjected to supercritical fluid extraction (SFE) using CO₂, was further processed through demineralization and deproteinization to isolate chitin. This chitin was then deacetylated to obtain chitosan, and the yield of each step was evaluated. Although the extraction process requires further optimization, all the samples were characterized using infrared spectroscopy to assess compositional changes resulting from the treatments and compared with commercial counterparts. Chitosan solutions in acidic water were used to formulate hydroalcoholic gels, with ethanol pretreatment enabling compatibility between chitosan and alcohol. This study highlights the potential of chitosan—sourced from shrimps or fungi—as a sustainable raw material for disinfecting-gel applications, offering promising insights into its role in polymer-based formulations. Full article