Injury or infection of adult dental pulp often necessitates root canal therapy. This terminates dentin formation and subsequent tooth maturation. In addition, the synthetic materials currently utilized to replace lost tooth structure are not capable of completely replacing the function of the lost tissue, and often fail over time. This report describes a technique to engineer new pulp-like tissues utilizing cultured cells and synthetic extracellular matrices. Fibroblasts were obtained from human adult dental pulps and multiplied in culture. These cells were subsequently seeded onto synthetic matrices fabricated from fibers (approximately 15 microns in diameter) of polyglycolic acid (PGA). The pulp-derived fibroblasts adhered to the fibers, proliferated, and formed a new tissue over 60 days in culture with a cellularity similar to that of native pulp. These tissues may find application in the regeneration of oral tissues and may provide novel systems in which to study the biocompatibility of materials and chemicals used in dentistry.
In cases of damaged oral tissues, traditional therapies, such as a root canal, replace the injured tissue with a synthetic material. However, while the materials currently used can offer structural replacement of the lost tissue, they are incapable of completely replacing the function of the original tissue, and often fail over time. This report describes a tissue engineering approach to dental pulp tissue replacement utilizing cultured cells seeded upon synthetic extracellular matrices. Human pulp fibroblasts were obtained and multiplied in culture. These cells were then seeded onto three different synthetic matrices: scaffolds fabricated from polyglycolic acid (PGA) fibers, a type I collagen hydrogel, and alginate in an effort to examine which matrix is most suitable for dental pulp tissue formation. In addition, methods previously developed for seeding and culturing pulp cells on PGA were optimized. Culturing cells on PGA resulted in a very high cell density tissue with significant collagen deposition. No cell proliferation was observed on alginate, and the growth of cells in collagen gels after 45 days was only moderate. These studies indicate dental pulp-like tissues can be engineered, and this may provide the first step to engineering a complete tooth.
Several small (<25aa) peptides have been designed based on the sequence of the dentin phosphoprotein, one of the major noncollagenous proteins thought to be involved in the mineralization of the dentin extracellular matrix during tooth development. These peptides, consisting of multiple repeats of the tripeptide aspartate-serine-serine (DSS), bind with high affinity to calcium phosphate compounds and, when immobilized, can recruit calcium phosphate to peptide-derivatized polystyrene beads or to demineralized human dentin surfaces. The affinity of binding to hydroxyapatite surfaces increases with the number of (DSS)n repeats, and though similar repeated sequences—(NTT)n, (DTT)n, (ETT)n, (NSS)n, (ESS)n, (DAA)n, (ASS)n, and (NAA)n—also showed HA binding activity, it was generally not at the same level as the natural sequence. Binding of the (DSS)n peptides to sectioned human teeth was shown to be tissue-specific, with high levels of binding to the mantle dentin, lower levels of binding to the circumpulpal dentin, and little or no binding to healthy enamel. Phosphorylation of the serines of these peptides was found to affect the avidity, but not the affinity, of binding. The potential utility of these peptides in the detection of carious lesions, the delivery of therapeutic compounds to mineralized tissues, and the modulation of remineralization is discussed.
BMP‐7 is a member of the BMP family of signaling molecules that are thought to play key roles in mediating inductive events during embryogenesis. In the present study the possible roles of BMP‐7 in mediating inductive events during the initiation phase of odontogenesis and mandibular morphogenesis were investigated. To do so, we have examined the effects of agarose beads soaked in recombinant BMP‐7 on E11 mouse molar‐forming mesenchyme and stage 23 chick mandibular mesenchyme, and analyzed the patterns of expression of Bmp‐7 in developing mouse and chick first branchial arches. Beads releasing BMP‐7 induced a translucent zone, cellular proliferation, and expression of Msx‐1, Msx‐2, and Bmp‐4 in molar‐forming mesenchyme after 24 hr. The effects of BMP‐7 on molar‐forming mesenchyme are similar to the effects of BMP‐4 and are consistent with their overlapping patterns of expression in the thickened epithelium of the early developing tooth buds, which is suggestive of cooperative and/or redundant roles of BMPs in mediating the inductive interactions during the early stages of odontogenesis. Our studies in the developing chick mandible showed that Bmp‐7 is expressed in the mandibular epithelium. In the absence of mandibular epithelium, BMP‐7 beads maintained cell proliferation and Msx expression in the medial mandibular mesenchyme and were able to induce cell proliferation, cell death, and Msx expression in the lateral chick mandibular mesenchyme. The effects of BMP‐7 on the expression of Msx genes in lateral chick mandibular mesenchyme, although different from the effects of lateral mandibular epithelium, are similar to the effects of epithelium from the medial region where multiple Bmps are expressed. We also showed that laterally placed BMP‐7 beads induced ectopic expression of Msx genes and changes in the development of posterior skeletal elements in the maxillary and mandibular arches. However, despite its proliferative effects on mandibular mesenchyme, BMP‐7 did not support the directional outgrowth of the mandible. These observations suggest that epithelial–mesenchymal interactions in the medial region of the mandibular arch regulating directional outgrowth of the mandibular mesenchyme are mediated by cooperative interactions between BMPs and other growth factors. Our observations also indicated that EGF, another growth factor implicated in mediating epithelial–mesenchymal interactions in the initiation phase of odontogenesis and morphogenesis of the developing mandible, induces an extensive translucent zone and cellular proliferation in the E11 mouse molar‐forming mesenchyme and stage 23 chick mandibular mesenchyme. However, in contrast to BMPs, EGF did not induce Msx‐1, Msx‐2, and Bmp‐4, but modulated the effects of BMPs on the expression of Msx‐1 and Msx‐2 in these mesenchymes. Our combined data suggest that BMP‐7 is a component of the signaling network mediating epithelial–mesenchymal interactions during the initiation phase of odontogenesis and morphogenesis of the mandibular arch. Dev Dyn 1999;21...
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