The Construction of Biomimetic Cementum Through a Combination of Bioskiving and Fluorine-Containing Biomineralization

“…In contrast to other mineralized tissues, cementum has a high concentration of fluoride, which is a great potential candidate as a catalysis to contribute to tissue mineralization and to accelerate cementum regeneration through mineral deposition on tooth-root surfaces [ 185 ]. Recently, Yang et al developed collagen scaffolds with fluorine-contained amorphous calcium phosphates (FACP) to promote mineralized tissue formation on tooth-root surfaces with specific micron-scaled dimensions [ 185 ].…”

“…In contrast to other mineralized tissues, cementum has a high concentration of fluoride, which is a great potential candidate as a catalysis to contribute to tissue mineralization and to accelerate cementum regeneration through mineral deposition on tooth-root surfaces [ 185 ]. Recently, Yang et al developed collagen scaffolds with fluorine-contained amorphous calcium phosphates (FACP) to promote mineralized tissue formation on tooth-root surfaces with specific micron-scaled dimensions [ 185 ]. To create similar hierarchical constructs to cementum with unique alternating collagen lamella (ACL) structures, the FACP–collagen scaffold was fabricated using the Bioskiving process, which is a newly developed method for the 3D scaffolding system using decellularized tendon tissues [ 185 ].…”

“…Recently, Yang et al developed collagen scaffolds with fluorine-contained amorphous calcium phosphates (FACP) to promote mineralized tissue formation on tooth-root surfaces with specific micron-scaled dimensions [ 185 ]. To create similar hierarchical constructs to cementum with unique alternating collagen lamella (ACL) structures, the FACP–collagen scaffold was fabricated using the Bioskiving process, which is a newly developed method for the 3D scaffolding system using decellularized tendon tissues [ 185 ]. In particular, the technique can three-dimensionally organize the nano-/microstructures of collagen constructs through a combination of processes, such as sectioning tendon-derived (tenton-decellularized) structures and stacking sheets with alternating orientations of collagen lamellae ( Figure 8 ) [ 185 , 186 ].…”

“…Because this study showed that biomimetic cementum structures with human PDL cells were found subcutaneously in immunodeficient mice, it was not demonstrated that the biomineralized collagen scaffold fabricated using the Bioskiving method was able to create a cementum layer on the tooth-root surface and tissue integration with the tooth dentin surface. However, the technique was able to mimic sophisticated hierarchies of human cementum with rotated-stacked angular microstructures and promoted mineralized tissue formation in physiological microenvironments [ 185 ].…”

“…In contrast to other mineralized tissues, cementum has a high concentration of fluoride, which is a great potential candidate as a catalysis to contribute to tissue mineralization and to accelerate cementum regeneration through mineral deposition on tooth-root surfaces [185]. Recently, Yang et Using the canine model, the periodontal defects around the tooth-root surfaces were surgically created and biomaterials were transplanted (traditional fibrin, ε-aminocaproic acid (ACA) modified fibrin (ACA-fibrin), and enamel matrix derivative (EMD)) (A).…”

Tooth-Supporting Hard Tissue Regeneration Using Biopolymeric Material Fabrication Strategies

“…In contrast to other mineralized tissues, cementum has a high concentration of fluoride, which is a great potential candidate as a catalysis to contribute to tissue mineralization and to accelerate cementum regeneration through mineral deposition on tooth-root surfaces [ 185 ]. Recently, Yang et al developed collagen scaffolds with fluorine-contained amorphous calcium phosphates (FACP) to promote mineralized tissue formation on tooth-root surfaces with specific micron-scaled dimensions [ 185 ].…”

“…In contrast to other mineralized tissues, cementum has a high concentration of fluoride, which is a great potential candidate as a catalysis to contribute to tissue mineralization and to accelerate cementum regeneration through mineral deposition on tooth-root surfaces [ 185 ]. Recently, Yang et al developed collagen scaffolds with fluorine-contained amorphous calcium phosphates (FACP) to promote mineralized tissue formation on tooth-root surfaces with specific micron-scaled dimensions [ 185 ]. To create similar hierarchical constructs to cementum with unique alternating collagen lamella (ACL) structures, the FACP–collagen scaffold was fabricated using the Bioskiving process, which is a newly developed method for the 3D scaffolding system using decellularized tendon tissues [ 185 ].…”

“…Recently, Yang et al developed collagen scaffolds with fluorine-contained amorphous calcium phosphates (FACP) to promote mineralized tissue formation on tooth-root surfaces with specific micron-scaled dimensions [ 185 ]. To create similar hierarchical constructs to cementum with unique alternating collagen lamella (ACL) structures, the FACP–collagen scaffold was fabricated using the Bioskiving process, which is a newly developed method for the 3D scaffolding system using decellularized tendon tissues [ 185 ]. In particular, the technique can three-dimensionally organize the nano-/microstructures of collagen constructs through a combination of processes, such as sectioning tendon-derived (tenton-decellularized) structures and stacking sheets with alternating orientations of collagen lamellae ( Figure 8 ) [ 185 , 186 ].…”

“…Because this study showed that biomimetic cementum structures with human PDL cells were found subcutaneously in immunodeficient mice, it was not demonstrated that the biomineralized collagen scaffold fabricated using the Bioskiving method was able to create a cementum layer on the tooth-root surface and tissue integration with the tooth dentin surface. However, the technique was able to mimic sophisticated hierarchies of human cementum with rotated-stacked angular microstructures and promoted mineralized tissue formation in physiological microenvironments [ 185 ].…”

“…In contrast to other mineralized tissues, cementum has a high concentration of fluoride, which is a great potential candidate as a catalysis to contribute to tissue mineralization and to accelerate cementum regeneration through mineral deposition on tooth-root surfaces [185]. Recently, Yang et Using the canine model, the periodontal defects around the tooth-root surfaces were surgically created and biomaterials were transplanted (traditional fibrin, ε-aminocaproic acid (ACA) modified fibrin (ACA-fibrin), and enamel matrix derivative (EMD)) (A).…”

Tooth-Supporting Hard Tissue Regeneration Using Biopolymeric Material Fabrication Strategies

Unraveling Nanomaterials in Biomimetic Mineralization of Dental Hard Tissue: Focusing on Advantages, Mechanisms, and Prospects

Cementum is key to periodontal tissue regeneration: A review on apatite microstructures for creation of novel cementum‐based dental implants