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This study aimed to comprehensively investigate the degradation behavior of 3D printed polymethyl methacrylate (PMMA) dental materials, with a specific focus on the influential factors of temperature and moisture, by employing molecular dynamics simulations. Owing to their aesthetic properties, 3D-printed PMMA dental materials play a pivotal role in dental applications. However, understanding their degradation mechanisms, particularly in the context of temperature and moisture variations, is crucial for their long-term durability. A Large-scale Atomic/Molecular Massively Parallel Simulator (LAMMPS) was utilized for the molecular dynamics simulations. The simulation setup included temperature variations from 300 to 600 K and relative humidity (RH) levels ranging from 20 to 100%. Various mechanical properties and structural changes were analyzed to determine the degradation behavior. Energetic profiling during equilibration and the subsequent temperature variations were studied. The spatial distribution of the mean squared displacement, non-bond energy, Young’s modulus, bending stress, and volume expansion coefficient of the particles were quantitatively analyzed, revealing temperature- and moisture-dependent trends. The study concluded that temperature and moisture significantly affected the degradation behavior of 3D-printed PMMA dental materials. Higher temperatures and increased humidity levels contribute to reduced mechanical strength and altered structural properties, emphasizing the importance of controlling environmental conditions during fabrication.

Every year around the world road traffic accidents (RTAs) cause 1.19 to 1.35 million deaths and 20-50 million non-fatal injuries that result in long-term disabilities and loss of potential life years (YPLL). These injuries have far-reaching consequences that extend beyond the injured person to impact both their families and their wider communities. The Middle East shows a wide range of death rates from RTAs and Saudi Arabia experiences the highest fatality rate. This study aims to identify different maxillofacial fractures and other skeletal fractures in road traffic accident victims while investigating seatbelt usage's correlation with maxillofacial fractures and also examines demographic variables (age, gender) and crash-related factors (seating position, vehicle type) to contextualize seatbelt efficacy. The study evaluated road traffic accident cases from a retrospective record-based dataset spanning 2011-2021 during the period from January 2023 through May 15th 2023 and marked 542 records with complete details as eligible after filtering. Out of 3629 RTA records, 907 (25%) were randomly selected. Among these, 542 (65%) met the inclusion criteria and were analyzed. The male population comprised 76% of the 412 victims and 82.8% of the victims neglected seatbelt usage while 284 of the 542 participants experienced multiple bone fractures and 126 individuals suffered from single maxillofacial bone fractures. The mandible fracture was the most common facial bone injury with 246 cases (45.3%), followed by Lefort1 fractures which occurred 244 times (45.0%), and Zygomatic maxillary complex fractures which had 216 occurrences (39.8%). Research results highlight the necessity for stronger public health strategies and road safety programs to improve seatbelt usage and decrease injury severity in road traffic accidents. Research findings indicate specific vehicle safety design enhancements needed to prevent facial injuries more effectively.

This systematic review examines emerging delivery systems for bioactive molecules within regenerative endodontic therapy (RET) where hydrogels, nanogels, and polymeric nanoparticles along with advanced nanocarriers such as liposomes aquasomes, vesosomes, and mesoporous silica nanoparticles form the primary focus. The extensive literature search in PubMed, Scopus, and Web of Science databases (until August 2025) yielded a total of 47 eligible articles, including in vitro , ex vivo , animal, and a few clinical studies. Hydrogels emerged as a significant category, showcasing enhanced regenerative effects when used for the sustained release of various growth factors such as transforming growth factor-beta (TGF-β 1 ), bone morphogenetic protein-2 (BMP-2), and vascular endothelial growth factor (VEGF). This was associated with improved angiogenesis and odontogenic differentiation. Nanogels exhibited high protein-loading efficiency and facilitated the differentiation of dental pulp stem cells, while polymeric nanoparticles demonstrated prolonged antibiotic and growth factor delivery with lower cytotoxicity. Among advanced nanocarriers, mesoporous silica nanoparticles showed promising potential for controlled release of growth factors and the formation of pulp-like tissues in animal models. In summary, the selected platforms for the delivery of bioactive molecules within RET show significant promise in terms of enhancing cell viability, bioactivity, and tissue regeneration. The findings indicate a practical pathway for clinicians aiming to achieve successful pulp–dentin tissue regeneration through translation research.

Ultrasound is an effective tool for both diagnostic and therapeutic applications. As an imaging tool, ultrasound has mostly been used for real-time noninvasive diagnostic imaging. As ultrasound propagates through a material, a reflected radio-frequency (RF) signal is generated when encountering a mismatch in acoustic impedance. While traditionally recognized for its diagnostic imaging capabilities, the application of ultrasound has broadened to encompass therapeutic interventions, most notably in the form of Low-Intensity Pulsed Ultrasound (LIPUS). Low-Intensity Pulsed Ultrasound (LIPUS) is a form of mechanical energy transmitted transcutaneously by high-frequency acoustic pressure waves. The intensity of LIPUS (30 mW/cm2) is within the range of ultrasound intensities used for diagnostic purposes (1–50 mW/cm2) and is regarded as non-thermal, non-destructive, permeating living tissues and triggering a cascade of biochemical responses at the cellular level. The LIPUS device produces a 200 µs burst of 1.5 MHz acoustic sine waves, that repeats at a modulation frequency of 1 kHz and provides a peak pressure of 30 mW/cm2. Low-intensity pulsed ultrasound (LIPUS) forms one of the currently available non-invasive healing-enhancing devices besides electro-stimulation (pulsed electro-magnetic field, PEMF). This modality has been leveraged to enhance drug delivery, expedite injury recovery, improve muscle mobility, alleviate joint stiffness and muscle pain, and enhance bone fracture healing. Although LIPUS has been embraced within various medical disciplines, its integration into standard dental practices is still in its nascent stages, signifying an unexplored frontier with potentially transformative implications. Low-intensity pulsed ultrasound (LIPUS) has emerged as an attractive adjuvant therapy in various dental procedures, such as orthodontic treatment and maxillary sinus augmentation. Its appeal lies in its simplicity and non-invasive nature, positioning LIPUS as a promising avenue for clinical innovation. One particular area of interest is orthodontically induced inflammatory root resorption (OIIRR), an oftenunavoidable outcome of the orthodontic intervention, resulting in the permanent loss of root structure. Notably, OIIRR is the second most common form of root resorption (RR), surpassed only by root resorption related to pulpal infection. Given the high prevalence and potential long-term consequences of OIIRR, this literature review seeks to evaluate the efficacy of LIPUS as a therapeutic approach, with an emphasis on assessing its capacity to reduce the severity of OIIRR to a level of clinical significance. To conduct this systematic review, a comprehensive automated literature search was executed across multiple databases, including MEDLINE, Embase, PsycINFO, Web of Knowledge, Scopus, CINAHL, LILACS, SciELO, Cochrane, PubMed, trials registries, 3ie, and Google Scholar. Both forward and backward citation tracking was employed, encompassing studies published from database inception through January 2009 to April 2023. The review focused on randomized controlled trials (RCTs) that specifically evaluated the effects of low-intensity pulsed ultrasound therapy on orthodontically induced inflammatory root resorption (OIIRR), without restrictions of publication date. A stringent selection criterion was applied, and only studies demonstrating high levels of statistical significance were included. Ultimately, fourteen studies met the inclusion criteria and were subjected to further analysis. The overall quality of the included randomized controlled trials (RCTs) was rigorously assessed utilizing the Grading of Recommendations Assessment, Development, and Evaluation (GRADE) approach. This analysis revealed certain methodological limitations that posed challenges in drawing definitive conclusions from the available evidence. Despite these constraints, the review offers invaluable insights that can inform and guide future research. Specifically, it delineates recommendations for targeted populations, necessary interventions, appropriate outcome measures, suitable study designs, and essential infrastructure to facilitate further investigations. The synthesis of these insights aims to enhance the development and application of low-intensity pulsed ultrasound therapy within the field of dentistry, thereby contributing to improved patient outcomes.

Background Yttrium-stabilized zirconia (YSZ) and alumina are the most commonly used dental esthetic crown materials. This study aimed to provide detailed information on the comparison between yttrium-stabilized zirconia (YSZ) and alumina, the two materials most often used for esthetic crowns in dentistry. Methodology The ground-state energy of the materials was calculated using the Cambridge Serial Total Energy Package (CASTEP) code, which employs a first-principles method based on density functional theory (DFT). The electronic exchange–correlation energy was evaluated using the generalized gradient approximation (GGA) within the Perdew (Burke) Ernzerhof scheme. Results Optimization of the geometries and investigation of the optical properties, dynamic stability, band structures, refractive indices, and mechanical properties of these materials contribute to a holistic understanding of these materials. Geometric optimization of YSZ provides important insights into its dynamic stability based on observations of its crystal structure and polyhedral geometry, which show stable configurations. Alumina exhibits a distinctive charge, kinetic, and potential (CKP) geometry, which contributes to its interesting structural framework and molecular-level stability. The optical properties of alumina were evaluated using pseudo-atomic computations, demonstrating its responsiveness to external stimuli. The refractive indices, reflectance, and dielectric functions indicate that the transmission of light by alumina depends on numerous factors that are essential for the optical performance of alumina as a material for esthetic crowns. The band structures of both the materials were explored, and the band gap of alumina was determined to be 5.853 eV. In addition, the band structure describes electronic transitions that influence the conductivity and optical properties of a material. The stability of alumina can be deduced from its bandgap, an essential property that determines its use as a dental material. Refractive indices are vital optical properties of esthetic crown materials. Therefore, the ability to understand their refractive-index graphs explains their transparency and color distortion through how the material responds to light..The regulated absorption characteristics exhibited by YSZ render it a highly attractive option for the development of esthetic crowns, as it guarantees minimal color distortion. Conclusion The acceptability of materials for esthetic crowns is strongly determined by mechanical properties such as elastic stiffness constants, Young's modulus, and shear modulus. YSZ is a highly durable material for dental applications, owing to its superior mechanical strength.

Background Clear aligner therapy has gained popularity as a minimally invasive orthodontic treatment option. However, its impact on the masticatory musculature and the stomatognathic system is an area of growing interest, as it involves the adjustment of occlusion and tooth movement. This systematic review aims to comprehensively assess and synthesise existing evidence regarding the influence of clear aligner therapy on the masticatory musculature and the stomatognathic system. Methods An exhaustive search was performed on electronic databases that adhered to PRISMA guidelines. Clinical studies that evaluated the impact of patients receiving aligner orthodontic treatment on the muscles of the mastication and stomatognathic systems were included. A standardised data extraction form was devised for relevant variables. Two reviewers extracted the data variables. ROB-2 was used for bias evaluation in the selected studies. Results A total of six studies met the inclusion criteria. The wearing of clear aligners significantly impacted the muscles of mastication. Muscle activity and discomfort showed a significant alteration in the initial days of appliance placement. but this observation was temporary, with no significant changes thereafter in subsequent follow-up. Bite force reduction was also noted. All the studies evaluated showed good methodological quality. Conclusion The review found that aligned orthodontic treatment may have a variable impact on muscles of mastication, with a potential for initial exacerbation of symptoms followed by possible improvement. However, due to the limited number of studies and their heterogeneous nature, further robust research is recommended to fully understand the relationship between aligned orthodontic treatment and masticatory muscles.

Resin cement exhibits numerous therapeutic advantages over conventional luting materials. However, the effectiveness of the antibacterial properties of resin cement remains unclear. Nanotechnology provides a viable option, whereby the integration of nanoparticles (NPs) can potentially augment the antibacterial effectiveness of resin cement. The objective of this study was to conduct a comprehensive literature review to assess resin cement’s antibacterial effectiveness by incorporating nanoparticles. An extensive search of PubMed and Scopus databases up to September 12, 2023, was conducted to identify relevant scholarly articles that examined and evaluated resin cement’s antibacterial effectiveness with and without the incorporation of nanoparticles (NPs). This systematic review adhered to the PRISMA guidelines for reporting the results. The search retrieved seven eligible studies. Studies indicated that resin cement with NPs significantly reduced the colony forming unit (CFU) counts compared to resin cement without NPs. Furthermore, resin cement, in addition to NPs, significantly reduced the bacterial metabolic activity compared to the control group. The use of nanoparticles (NPs) in resin cement has been shown to enhance its antibacterial properties, possibly mitigating the occurrence of secondary caries. Future clinical trials are required to validate the beneficial effects of NPs in conjunction with resin cement in the prevention of secondary caries.

Background: Polyetheretherketone (PEEK) has provided the option to fabricate RPDs with aesthetics unlike metal RPDs, but little attention has been paid to its suitability, especially towards the retentive forces and deformation of the clasp. This study aimed to examine the retentive forces and the fitting surface (inner surface) deformation of clasps made from PEEK and compare it with cobalt–chromium (Co-Cr) clasp. Methods: Forty-two circumferential clasps (14 Co-Cr and 28 PEEK) were fabricated and divided into two groups with clasp undercuts (0.25 mm and 0.5 mm) with thicknesses of 1 mm and 1.5 mm. Each was examined for retentive forces after cycle test on its abutment for 360 cycles. Initial and final retentive forces were recorded. The fitting surface deformation was determined using 3-Matic research analysis software. Results: The results revealed that highest mean initial retentive force was of Co-Cr clasps with 0.50 mm undercut 22.26 N (±10.15 N), and the lowest was the 1 mm PEEK clasps with 0.25 mm undercut 3.35 N (±0.72 N) and highest mean final retentive force was the Co-Cr clasps with 0.50 mm undercut 21.40 N (±9.66 N), and the lowest was the 1 mm PEEK clasps with 0.25 mm undercut 2.71 N (±0.47 N). PEEK clasps had a lower retentive force than Co-Cr clasps with 0.50 undercut. PEEK clasps (1.5 mm) at 0.25 mm undercut had the least deformation (35.3 µm). PEEK showed significantly less deformation (p ≤ 0.014) than Co-Cr. Conclusion: The deformation of PEEK clasps fitting surface was lower than Co-Cr clasps and retentive forces were close to the Co-Cr clasps, suggesting the use of PEEK as an aesthetic clasp option for RPD framework.

Background Some of the noise-intensive processes in dental laboratories include the finishing of crowns, bridges, and removable partial dentures; blowing out workpieces with steam and compressed air; and deflating casting rings. High sound pressure levels are also present in dental vibrators, polishing equipment, and sandblasters. The aim of this study was to Evaluation of the effect of noise production in dental technology laboratory on dental technician hearing capacity. Methods For this cross-sectional study, a total of 120 dental technicians were chosen. Otoscopic evaluation and the Weber test were used to establish if they had sensorineural or transmission hearing loss at 500 Hz, 1000 Hz, 2000 Hz, and 4000 Hz, respectively. Then an OAER (objective auditory evoked response) and PTA (clinical aurimeter) test were administered (Neurosoft, Russia). The whole procedure was carried out by an audiologist and an ENT specialist. Results The PTA results showed that the patient had mild hearing impairment overall, with the loss being more severe in the left ear than in the right. The OAE test results revealed that in-ear of the left side, 84.5% of subjects passed and 15.5% of subjects struggled and were referred to an ear specialist, whereas in the right ear, 82.7% of subjects passed and 17.3% struggled and were referred to an ear specialist. According to this study, in a right-handed study participant, the ear on the left side is more vulnerable than the right side. Differences in the mean hearing threshold at 4000 and 6000 Hz in the left ear were statistically significant in the groups of workers with eleven to fifteen years of practical experience and twenty-one to twenty-five years of practical experience, respectively (Minervini, et al. J Clin Med 12:2652, 2023). Conclusions A statistically meaningful threshold shift from 4000 to 6000 Hz is observed as the working experience grows, and this is suggestive of sensorineural hearing impairment brought on by the noisy dental environment.

Objectives The present systematic review and meta‐analysis aimed to compare the efficacy of three‐dimensional (3D) imaging techniques in terms of accuracy and precision for periodontal disease assessment. Material and Methods A literature search was conducted across multiple databases (PubMed, Scopus, Web of Science, Google Scholar, and ScienceDirect) following Preferred Reporting Items for Systematic Reviews and Meta‐analysis (PRISMA) protocols. The primary outcomes focused on comparing the accuracy and precision of 3D versus two‐dimensional (2D) imaging techniques. Furthermore, it assessed their performance in determining periodontal diseases. Quality assessment was performed using the risk of bias (RoB)‐2 for randomized controlled trials (RCTs) and ROB in nonrandomized studies‐Intervention (ROBINS‐I) for non‐RCTs. Meta‐analysis was conducted using RevMan 5.4 with a significance level set at 0.01. While meta‐regression was performed using OpenMEE. Results After screening, 22 studies met the eligibility criteria for qualitative and quantitative analysis. Qualitatively, 3D imaging, particularly cone‐beam computed tomography (CBCT), showed superior accuracy and precision over 2D techniques. The meta‐analysis revealed significant differences in several areas: overall (p = 0.00001, Mean Difference (MD) = −0.36, 95% confidence interval [CI]: −0.96 to 0.24, I² = 93%), horizontal measurements (p = 0.00001, MD = −0.75, 95% CI: −2 to −0.49, I² = 92%), and vertical measurements (p = 0.00001, MD = −0.59, 95% CI: −2.40 to 1.23, I² = 92%). Nonsignificant differences were found for furcation height, width, and depth. Most studies showed good quality with a low risk of bias. Age of the participants and study quality were found to be the sources of heterogeneity. Conclusions Consistent trends highlight the advantages of 3D imaging in assessing both periodontal and nonperiodontal diseases. However, given the nonsignificant differences in furcation height, width, and depth, the recommended approach is to combine CBCT with digital intraoral radiography for more comprehensive periodontal bone assessment. Summary 3D imaging is more accurate and precise than 2D imaging or intra‐surgical measurement techniques. 3D imaging provides significant advantages in horizontal and vertical disc/plane measurements. More research is needed on furcation height, width, and depth, as the results showed no significant difference.