Activated Charcoal Dental Products: Evidence of Effectiveness Is Lacking.

With society trending toward the avoidance of artificial components, so-called "natural" products have been gaining space and people's attention in recent years. Activated charcoal-based dental products are a prominent example of this movement because of their promise of removal of extrinsic stains or whitening of teeth by a natural means. Such products have gained popularity among patients, and companies have explored this market, launching charcoal-based and activated charcoal-based dentifrices, mouthrinses, toothbrushes, and whitening products that can be easily found at nearby stores and on the internet.1.

Current Concepts and Best Evidence on Strategies to Prevent Dental Erosion.

Dental erosion is a multifactorial condition associated with chemical, biological, and behavioral factors whereby a non-bacterial chemical process leads to an irreversible loss of dental structure. Consequences of this erosive process include painful sensitivity, susceptibility to further erosion, mechanical wear, changes in occlusion, exposure of dental pulp, and poor esthetics. Substantial evidence has revealed new insights to diagnosing early stages of dental erosion and enabling novel preventive approaches to control its progression. In the context of outpatient medical/dental practice, clinicians often encounter patients with progressive dental erosion. This article summarizes published research in this area of dentistry to suggest guidelines that are clinically oriented but scientifically fundamental. It is aimed at helping clinicians effectively integrate this information into their professional evaluations of dental erosion with regard to diagnosis, risk factors, clinical signs, assessment, and clinical preventive strategies and treatment. Clinicians should address patient diet habits, educate patients on prevalence data, and inform them regarding potential acidic interactions, such as medically induced acidic conditions, that may ultimately lead to tooth destruction. Prevention of dental erosion, including the recognition of initial erosive lesions and the implementation of the early intervention, involves the clinical expertise of both the dentist and physician.

The dental curing light: A potential health risk.

Powerful blue-light emitting dental curing lights are used in dental offices to photocure resins in the mouth. In addition, many dental personnel use magnification loupes. This study measured the effect of magnification loupes on the "blue light hazard" when the light from a dental curing light was reflected off a human tooth. Loupes with 3.5x magnification (Design for Vision, Carl Zeiss, and Quality Aspirator) and 2.5x magnification (Design for Vision and Quality Aspirator) were placed at the entrance of an integrating sphere connected to a spectrometer (USB 4000, Ocean Optics). A model with human teeth was placed 40 cm away and in line with this sphere. The light guide tip of a broad-spectrum Sapphire Plus (Den-Mat) curing light was positioned at a 45° angle from the facial surface of the central incisor. The spectral radiant power reflected from the teeth was recorded five times with the loupes over the entrance into the sphere. The maximum permissible cumulative exposure times in an 8-hr day were calculated using guidelines set by the ACGIH. It was concluded that at a 40 cm distance, the maximum permissible cumulative daily exposure time to light reflected from the tooth was approximately 11 min without loupes. The weighted blue irradiance values were significantly different for each brand of loupe (Fisher's PLSD p < 0.05) and were up to eight times greater at the pupil than when loupes were not used. However, since the linear dimensions of the resulting images would be 2.5 to 3.5x larger on the retina, the image area was increased by the square of the magnification and the effective blue light hazard was reduced compared to without the loupes. Thus, although using magnification loupes increased the irradiance received at the pupil, the maximum cumulative daily exposure time to reflected light was increased up to 28 min. Further studies are required to determine the ocular hazards of a focused stare when using magnification loupes and the effects of other curing lights used in the dental office.

Effects of water-aging on self-healing dental composite containing microcapsules.

OBJECTIVES: The objectives of this study were to develop a self-healing dental composite containing poly(urea-formaldehyde) (PUF) shells with triethylene glycol dimethacrylate (TEGDMA) and N,N-dihydroxyethyl-p-toluidine (DHEPT) as healing liquid, and to investigate the mechanical properties of the composite and its self-healing efficacy after water-aging for 6 months. METHODS: PUF microspheres were synthesized encapsulating a TEGDMA-DHEPT healing liquid. Composite containing 30% of a resin matrix and 70% of glass fillers by mass was incorporated with 0%, 2.5%, 5%, 7.5% and 10% of microcapsules. A flexural test was used to measure flexural strength and elastic modulus. A single edge V-notched beam method was used to measure fracture toughness (KIC) and self-healing efficacy. Specimens were water-aged at 37 °C for 1 day to 6 months and then tested for self-healing. Fractured specimens were healed while being immersed in water to examine self-healing efficacy, in comparison with that in air. RESULTS: Incorporation of up to 7.5% of microcapsules into the resin composite achieved effective self-healing, without adverse effects on the virgin mechanical properties of the composite (p>0.1). An excellent self-healing efficacy of 64-77% recovery was obtained (mean±sd; n=6). Six months of water-aging did not decrease the self-healing efficacy compared to 1 day (p>0.1). Exposure to water did not decrease the healing efficacy, compared to that healed in air (p>0.1). CONCLUSIONS: A composite was developed with excellent self-healing efficacy even while being immersed in water. The self-healing efficacy did not decrease with increasing water-aging time for 6 months. CLINICAL SIGNIFICANCE: The novel self-healing composite may be promising for dental applications to heal cracks, resist fracture, and increase the durability and longevity.

Using fiber-optic transillumination as a diagnostic aid in dental practice.

Fiber-optic transillumination (FOTI) is a well-accepted and valuable adjunctive diagnostic tool with a wide range of clinical applications. In dentistry, FOTI has been primarily associated with caries diagnosis and has been corroborated through research studies to be a valid indicator of the histological presence or absence of bacterially infected tooth structure. In this review, techniques for using FOTI for tooth evaluation are presented along with examples of how FOTI can be effectively used as a supplemental diagnostic aid.

The effectiveness of using a patient simulator to teach light-curing skills.

BACKGROUND: The authors evaluated the effectiveness of using a patient simulator (MARC Patient Simulator [MARC PS], BlueLight analytics, Halifax, Nova Scotia, Canada), to instruct dental students (DS) on how to deliver energy optimally to a restoration from a curing light. Five months later, the authors evaluated the retention of the instruction provided to the DS. METHODS: Toward the end of the DS' first year of dental education, the authors evaluated the light-curing techniques of one-half of the class of first-year DS (Group 1) before and after receiving instruction by means of the patient simulator. Five months later, they retested DS in Group 1 and tested the remaining first-year DS who were then second-year DS and who had received no instruction by means of the patient simulator (Group 2). They gave DS in Group 1 and Group 2 MARC PS instruction and retested them. The authors also the tested fourth-year DS (Group 3) and dentists (Group 4) by using the MARC PS before giving any instruction by means of the MARC PS. RESULTS: The results of one-way analysis of variance (ANOVA) showed that there were no significant differences in the ability of dentists and DS to light cure a simulated restoration before they received instruction by means of the patient simulator (P = .26). The results of two-way ANOVA and Fisher protected least significant difference tests showed that after receiving instruction by means of the patient simulator, DS delivered significantly more energy to a simulated restoration, and this skill was retained. There were no significant differences between DS in Group 1 and Group 2 after they had received instruction by means of the patient simulator. CONCLUSIONS: The abilities of dentists and DS to light cure a simulated restoration were not significantly different. Hands-on teaching using a patient simulator enhanced the ability of DS to use a curing light. This skill was retained for at least five months. PRACTICAL IMPLICATIONS: The education provided to dentists and DS is insufficient to teach them how to deliver the optimum amount of energy from a curing light. Better teaching and understanding of the importance of light curing is required.

Fixed prosthodontics provisional materials: making the right selection.

Clinicians have many choices when selecting an appropriate material for interim restorations for both single crowns and multi-units. Interim restorations serve as a diagnostic as well as biologic and biomechanical component of fixed prosthodontics treatment; in the anterior, they are also important in evaluating the esthetics for the definitive restoration. Factors to be considered when choosing provisional materials are physical properties, handling characteristics, patient response to the appearance of the interim restoration, durability of the restoration, and the cost of the material. Practitioners should, therefore, base their choice on the clinical needs for each situation.

Nanocomposite containing CaF(2) nanoparticles: thermal cycling, wear and long-term water-aging.

OBJECTIVES: Fluoride (F) releasing dental restoratives are promising to promote remineralization and combat caries. The objectives of this study were to develop nanocomposite containing calcium fluoride nanoparticles (nCaF(2)), and to investigate the long-term mechanical durability including wear, thermal-cycling and long-term water-aging behavior. METHODS: Two types of fillers were used: nCaF(2) with a diameter of 53 nm, and glass particles of 1.4 µm. Four composites were fabricated with fillers of: (1) 0% nCaF(2)+65% glass; (2) 10% nCaF(2)+55% glass; (3) 20% nCaF(2)+45% glass; (4) 30% nCaF(2)+35% glass. Three commercial materials were also tested. Specimens were subjected to thermal-cycling between 5°C and 60°C for 10(5) cycles, three-body wear for 4×10(5) cycles, and water-aging for 2 years. RESULTS: After thermal-cycling, the nCaF(2) nanocomposites had flexural strengths in the range of 100-150 MPa, five times higher than the 20-30 MPa for resin-modified glass ionomer (RMGI). The wear scar depth showed an increasing trend with increasing nCaF(2) filler level. Wear of nCaF(2) nanocomposites was within the range of wear for commercial controls. Water-aging decreased the strength of all materials. At 2 years, flexural strength was 94 MPa for nanocomposite with 10% nCaF(2), 60 MPa with 20% nCaF(2), and 48 MPa with 30% nCaF(2). They are 3-6 fold higher than the 15 MPa for RMGI (p<0.05). SEM revealed air bubbles and cracks in a RMGI, while composite control and nCaF(2) nanocomposites appeared dense and solid. SIGNIFICANCE: Combining nCaF(2) with glass particles yielded nanocomposites with long-term mechanical properties that were comparable to those of a commercial composite with little F release, and much better than those of RMGI controls. These strong long-term properties, together with their F release being comparable to RMGI as previously reported, indicate that the nCaF(2) nanocomposites are promising for load-bearing and caries-inhibiting restorations.

Chairside resin-based provisional restorative materials for fixed prosthodontics.

Provisional restorations are vital to fixed prosthodontics treatment, providing an important diagnostic function while in place. In addition to protecting the prepared teeth, provisionalization enables clinicians to refine biologic and biomechanical issues before the final restoration is fabricated. Adjustments can be made in the provisional restoration to achieve both the clinician's and patient's desired results. The fabrication of temporary restorations requires that clinicians be proficient with a variety of materials and techniques that can be used to make well-adapted and functional provisionals. There are many material choices available to temporize a single crown as well as multi-unit fixed partial dentures, and the selection of provisional materials should be made based on a case-by-case evaluation. This article provides a review of polymeric resin provisional materials.