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256 results on '"Moradian-Oldak J"'

1. Triple Function of Amelogenin Peptide-Chitosan Hydrogel for Dentin Repair.

Author

Cai, J. and Moradian-Oldak, J.

Subjects
DENTIN, AMELOGENIN, BIOMIMETIC polymers, DENTINAL tubules, ATOMIC force microscopy, DENTAL adhesives, CHONDROITIN sulfates
Abstract

Biomimetic strategies like peptide-guided collagen mineralization promise to enhance the effectiveness of dentin remineralization. We recently reported that rationally designed amelogenin-derived peptides P26 and P32 promoted apatite nucleation, mineralized collagen, and showed potential in enamel regrowth and dentin remineralization. To facilitate the clinical application of amelogenin-derived peptides and to uncover their effectiveness in repairing dentin, we have now implemented a chitosan (CS) hydrogel for peptide delivery and have investigated the effects of P26-CS and P32-CS hydrogels on dentin remineralization using 2 in situ experimental models that exhibited different levels of demineralization. The efficacy of the peptide-CS hydrogels in dentin repair was evaluated by characterizing the microstructure, mineral density, mineral phase, and nanomechanical properties of the remineralized samples. The new strategy of atomic force microscopy PeakForce quantitative nanomechanical mapping was used for direct visualization and nanomechanical analysis of repaired dentin lesions across the lesion depth. Results from the 2 models indicated the potential triple functions of peptide-CS hydrogels for dentin repair: building a highly organized protective mineralized layer on dentin, occluding dentinal tubules by peptide-guided in situ mineralization, and promoting biomimetic dentinal collagen remineralization. Importantly, peptides released from the CS hydrogel could diffuse into the dentinal matrix and penetrate the dentinal tubules, leading to both surface and subsurface remineralization and tubule occlusion. Given our previous findings on peptide-CS hydrogels' potential for remineralizing enamel, we see further promise for hydrogels to treat tooth defects involving multiple hard tissues, as in the case of noncarious cervical lesions. [ABSTRACT FROM AUTHOR]

Published
2023
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19. The Presence of MMP-20 Reinforces Biomimetic Enamel Regrowth.

Author

Prajapati, S., Ruan, Q., Mukherjee, K., Nutt, S., and Moradian-Oldak, J.

Subjects
DENTAL enamel, MATRIX metalloproteinases, BIOMIMETIC chemicals, HYDROGELS in medicine, BIOMINERALIZATION, AMELOGENIN, PHOSPHATE metabolism, PHARMACEUTICAL gels, INDUSTRIES, POLYSACCHARIDES, PROTEOLYTIC enzymes, RECOMBINANT proteins, RESEARCH funding
Abstract

Biomimetic synthesis of artificial enamel is a promising strategy for the prevention and restoration of defective enamel. We have recently reported that a hydrogel system composed of chitosan-amelogenin (CS-AMEL) and calcium phosphate is effective in forming an enamel-like layer that has a seamless interface with natural tooth surfaces. Here, to improve the mechanical system function and to facilitate the biomimetic enamel regrowth, matrix metalloproteinase-20 (MMP-20) was introduced into the CS-AMEL hydrogel. Inspired by our recent finding that MMP-20 prevents protein occlusion inside enamel crystals, we hypothesized that addition of MMP-20 to CS-AMEL hydrogel could reinforce the newly grown layer. Recombinant human MMP-20 was added to the CS-AMEL hydrogel to cleave full-length amelogenin during the growth of enamel-like crystals on an etched enamel surface. The MMP-20 proteolysis of amelogenin was studied, and the morphology, composition, and mechanical properties of the newly grown layer were characterized. We found that amelogenin was gradually degraded by MMP-20 in the presence of chitosan. The newly grown crystals in the sample treated with MMP-20-CS-AMEL hydrogel showed more uniform orientation and greater crystallinity than the samples treated with CS-AMEL hydrogel without MMP-20. Stepwise processing of amelogenin by MMP-20 in the CS-AMEL hydrogel prevented undesirable protein occlusion within the newly formed crystals. As a result, both the modulus and hardness of the repaired enamel were significantly increased (1.8- and 2.4-fold, respectively) by the MMP-20-CS-AMEL hydrogel. Although future work is needed to further incorporate other enamel matrix proteins into the system, this study brings us one step closer to biomimetic enamel regrowth. [ABSTRACT FROM AUTHOR]

Published
2018
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48. Problem-based learning at the University of Southern California School of Dentistry

Author

Fincham, AG, primary, Baehner, R, additional, Chai, Y, additional, Crowe, DL, additional, Fincham, C, additional, Iskander, M, additional, Landesman, HM, additional, Lee, M, additional, Luo, W, additional, Paine, M, additional, Pereira, L, additional, Moradian-Oldak, J, additional, Rosenblum, A, additional, Snead, ML, additional, Thompson, P, additional, Wuenschell, C, additional, Zeichner-David, M, additional, and Shuler, CF, additional

Published
1997
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