Due to the superior pigment and high flexural strength, machinable lithium disilicate ceramics can be used as a monolithic crown or veneering porcelains on the zirconia core to form the all-ceramic crowns by sintering or bonding procedures. This paper reports the research on the differences in stress distributions amongst these three types of all-ceramic crowns under typical loading conditions. Three-dimensional numerical models of the restored crown based on the first mandibular molar were developed. The vertical concentrated load and 8-point uniformly distributed load were applied, respectively. The maximum stress and stress distribution were resulted from finite element evaluation. It was found that the maximum tensile stress in 3 types of restored crowns subjected to the concentrate load was less than the flexural strength of IPS e.max. The stress distributions in the sintered and bonded double layered crowns were basically identical, and different from the monolithic crown. The stress magnitude in veneer porcelain of the bonded crown was greater than that in the sintered crown. The use of IPS e.max computer aided design monolithic crown as molar restorations should be careful to avoid high stress as the cyclic stress is a concern of fatigue which may influence the longevity of the restored crown. The bonded double layer crowns bear greater risks of veneer chipping compared with the sintered crowns. The conclusions of this study provide helpful guidelines in clinical applications for preparation of computer aided design/computer aided manufacture lithium disilicate all-ceramic restorations.
In bone tissue engineering, fabrication of scaffold materials that are biodegradable with regenerative functions is one of the most important research fields. Silk fibroin exhibits many favorable characteristics used as scaffold materials. Among them, hybrid silk fibroin/inorganic composites prepared by biomimetic mineralization have better biocompatibility, biomechanical properties, and biodegradability. At the same time, the hybrid silk fibroin/inorganic materials have much better osteoinduction and conduction properties than silk fibroin. Here, the recent advances in the preparation of silk fibroin/silica hybrid materials by combination or biomimetic silicification are reviewed, and the future research prospects of silicification of silk fibroin are discussed.
Objective To investigate the effect of local injection of curcumin-loaded mesoporous silica nanoparticles (Cur@MSN) on the repair and treatment of degenerative intervertebral disc tissue in rats, and provide a new strategy for the treatment of intervertebral disc degeneration. Methods Mesoporous silica nanoparticles (MSN) and Cur@MSN were prepared according to the method reported in the literature. Rat nucleus pulposus cells were co-cultured with curcumin and Cur@MSN, respectively, and the growth status and activity of cells in normal environment and inflammatory environment (adding lipopolysaccharide) were observed respectively. Twelve 8-week-old SD rats were randomly divided into 4 groups, including normal group, degeneration group, curcumin group, and Cur@MSN group, with 3 rats in each group. Acupuncture degeneration model was established in coccygeal intervertebral discs (Co7-8, Co8-9) of rats, and corresponding intervention were injected. Imaging, gross pathology, and histological examination were performed after 4 weeks, respectively, to observe the tissue structure and pathological changes of intervertebral discs. Results Under scanning electron microscope, Cur@MSN was spherical in shape, with groove-like pores on its surface. Particle size analysis showed that the particle size of MSN was concentrated in 120-160 nm, and that of Cur@MSN was distributed in 130-170 nm. Zeta potential analysis showed that the average Zeta potential of MSN, curcumin, and Cur@MSN was −12.5, −22.5 and −13.5 mV, respectively. The entrapment efficiency of Cur@MSN was 20.4%, and the drug loading rate was 0.2%. Curcumin released by Cur@MSN in 12 h accounted for about 60% of the total drug dose, and curcumin released in 28 h accounted for about 70%. In cell experiment, there was no significant difference in cell proliferation absorbance among the groups in normal environment (P>0.05), but the cell proliferation absorbance in the Cur@MSN group on the 3rd and 5th day in inflammatory environment was significantly higher than that in the control group and the curcumin group (P<0.01). The percentage of disc height index and the Pfirrmann grade of the Cur@MSN group were better than those of the degeneration group and the curcumin group (P<0.01). The histological score of the Cur@MSN group was lower than that of the degeneration group and the curcumin group (P<0.01). Conclusions Cur@MSN can delay the degeneration process of rat coccygeal intervertebral disc, and has certain repair and treatment effects on its degenerated intervertebral disc. Among them, curcumin can delay the degeneration of intervertebral disc by inhibiting inflammation, and the loading of MSN is helpful for curcumin to exert its biological effects.