Surface Chemistry of Nanoscale Mineralized Collagen Regulates Periodontal Ligament Stem Cell Fate.

The interplay between stem cells and their extracellular microenvironment is of critical importance to the stem cell-based therapeutics in regenerative medicine. Mineralized collagen is the main component of bone extracellular matrix, but the effect of interfacial properties of mineralized collagen on subsequent cellular behaviors is unclear. This study examined the role of surface chemistry of nanoscale mineralized collagen on human periodontal ligament stem cell (hPDLSC) fate decisions. The intrafibrillarly mineralized collagen (IMC), fabricated by a biomimetic bottom-up approach, showed a bonelike hierarchy with nanohydroxyapatites (HAs) periodically embedded within fibrils. The infrared spectrum of the IMC showed the presence of phosphate, carbonate, amide I and II bands; and infrared mapping displayed uniform and higher spatial distribution of mineralization in the IMC. However, the distribution of the phosphate group differed far from that of the amide I group in the extrafibrillarly mineralized collagen (EMC), in which flowerlike HA clusters randomly depositing around the surface of the fibrils. Moreover, a large quantity of extrafibrillar HAs covered up the C═O stretch and N-H in-plane bend, resulting in substantial reduction of amide I and II bands. Cell experiments demonstrated that the hPDLSCs seeded on the IMC exhibited a highly branched, osteoblast-like polygonal shape with extended pseudopodia and thick stress fiber formation; while cells on the EMC displayed a spindle shape with less branch points and thin actin fibril formation. Furthermore, the biocompatibility of EMC was much lower than that of IMC. Interestingly, even without osteogenic induction, mRNA levels of major osteogenic differentiation genes were highly expressed in the IMC during cultivation time. These data suggest that the IMC with a similar nanotopography and surface chemistry to natural mineralized collagen directs hPDLSCs toward osteoblast differentiation, providing a promising scaffold in bone tissue regeneration.

Mineralized Collagen Regulates Macrophage Polarization During Bone Regeneration.

The host immune response to bone biomaterials is vital in determining the fate of scaffolds and also the outcomes of bone regeneration. Mineralized collagen is an ideal tissue-engineering scaffold for bone repair; however, little is known about its immunomodulatory properties after implantation. In this study, extrafibrillarly-mineralized collagen (EMC) and intrafibrillarly-mineralized collagen (IMC) scaffolds with different nanostructures were fabricated and their immunomodulatory properties via macrophage polarization during bone regeneration were investigated. Micro-CT findings showed that the IMC scaffold yielded more new bone formation than the EMC scaffold. In the defect area, more CD68 + CD163 + M2-like macrophages were observed in the IMC group, while M1-like macrophages positive for CD68 and inducible nitric oxide synthase (iNOS) increased dramatically in the EMC group. We further demonstrated, from the protein and RNA levels, that M2-associated anti-inflammatory cytokines interleukin (IL)-10 and arginase-1 were highly expressed in the macrophages seeded on the IMC scaffold, while those seeded on the EMC scaffold expressed more M1-related genes iNOS and IL-6. Moreover, the macrophage polarization in response to the nanostructure of mineralized collagen scaffolds influenced the osteogenesis of human bone marrow stromal cells. These findings suggest that the nanostructure of mineralized collagen scaffolds affects macrophage functional polarization during bone regeneration. The immunomodulatory properties of biomaterial scaffolds can be a dictator of bone regeneration outcomes.

Cobalt-catalyzed oxidative isocyanide insertion to amine-based bisnucleophiles: diverse synthesis of substituted 2-aminobenzimidazoles, 2-aminobenzothiazoles, and 2-aminobenzoxazoles.

Cobalt catalysis: Synthesis of substituted 2-aminobenzimidazoles, 2-aminobenzothiazoles, and 2-aminobenzoxazoles was achieved by using cobalt(II) acetate catalyzed isocyanide insertion to o-diaminobenzene, 2-aminobenzenethiol, and 2-aminophenol derivatives in 1,4-dioxane (see scheme). It was found that the reaction proceeded efficiently to give the desired products in up to 95 % isolated yields by C-N and C-S (O, N) formation in a single step.