Tooth loss accompanied by alveolar bone resorption presents a significant clinical problem. We have investigated the utility of a tissue-engineering approach to provide corrective therapies for tooth-bone loss. Hybrid tooth-bone tissues were bioengineered as follows. Tooth implants were generated from pig third molar tooth bud cells seeded onto polyglycolide (PGA) and polyglycolide-colactide (PLGA) scaffolds, and grown for 4 weeks in the omenta of adult rat hosts. Bone implants were generated from osteoblasts induced from bone marrow progenitor cells obtained from the same pig, seeded onto PLGA fused wafer scaffolds, and grown for 10 days in a rotational oxygen-permeable bioreactor system. The tooth and bone implants were harvested, sutured together, reimplanted, and grown in the omenta for an additional 8 weeks. Histological and immunohistochemical analyses of the excised hybrid tooth-bone constructs revealed the presence of tooth tissues, including primary and reparative dentin and enamel in the tooth portion of hybrid tooth-bone implants, and osteocalcin and bone sialoprotein-positive bone in the bone portion of hybrid tooth-bone constructs. Collagen type III-positive connective tissue resembling periodontal ligament and tooth root structures were present at the interface of bioengineered tooth and bone tissues. These results demonstrate the utility of a hybrid tooth-bone tissue-engineering approach for the eventual clinical treatment of tooth loss accompanied by alveolar bone resorption.
Our long-term objective is to develop methods to form, in the jaw, bioengineered replacement teeth that exhibit physical properties and functions similar to those of natural teeth. Our results show that cultured rat tooth bud cells, seeded onto biodegradable scaffolds, implanted into the jaws of adult rat hosts and grown for 12 weeks, formed small, organized, bioengineered tooth crowns, containing dentin, enamel, pulp, and periodontal ligament tissues, similar to identical cellseeded scaffolds implanted and grown in the omentum. Radiographic, histological, and immunohistochemical analyses showed that bioengineered teeth consisted of organized dentin, enamel, and pulp tissues. This study advances practical applications for dental tissue engineering by demonstrating that bioengineered tooth tissues can be regenerated at the site of previously lost teeth, and supports the use of tissue engineering strategies in humans, to regenerate previously lost and/or missing teeth. The results presented in this report support the feasibility of bioengineered replacement tooth formation in the jaw.
Based on the successful use of silk scaffolds in bone tissue engineering, we examined their utility for mineralized dental tissue engineering. Four types of hexafluoroisopropanol (HFIP) silk scaffolds-(250 and 550 microm diameter pores, with or without arginine-glycine-aspartic acid (RGD) peptide) were seeded with cultured 4-day postnatal rat tooth bud cells and grown in the rat omentum for 20 weeks. Analyses of harvested implants revealed the formation of bioengineered mineralized tissue that was most robust in 550 microm pore RGD-containing scaffolds and least robust in 250 microm pore sized scaffolds without RGD. The size and shape of the silk scaffold pores appeared to guide mineralized tissue formation, as revealed using polarized light imaging of collagen fiber alignment along the scaffold surfaces. This study is the first to characterize bioengineered tissues generated from tooth bud cells seeded onto silk scaffolds and indicates that silk scaffolds may be useful in forming mineralized osteodentin of specified sizes and shapes.
The well-established safety profile of the tuberculosis vaccine strain, Mycobacterium bovis bacille Calmette-Guérin (BCG), makes it an attractive vehicle for heterologous expression of antigens from clinically relevant pathogens. However, successful generation of recombinant BCG strains possessing consistent insert expression has encountered challenges in stability. Here, we describe a method for the development of large recombinant BCG accession lots which stably express the lentiviral antigens, human immunodeficiency virus (HIV) gp120 and simian immunodeficiency virus (SIV) Gag, using selectable leucine auxotrophic complementation. Successful establishment of vaccine stability stems from stringent quality control criteria which not only screen for highly stable complemented BCG ⌬leuCD transformants but also thoroughly characterize postproduction quality. These parameters include consistent production of correctly sized antigen, retention of sequence-pure plasmid DNA, freezethaw recovery, enumeration of CFU, and assessment of cellular aggregates. Importantly, these quality assurance procedures were indicative of overall vaccine stability, were predictive for successful antigen expression in subsequent passaging both in vitro and in vivo, and correlated with induction of immune responses in murine models. This study has yielded a quality-controlled BCG ⌬leuCD vaccine expressing HIV gp120 that retained stable full-length expression after 10 24 -fold amplification in vitro and following 60 days of growth in mice. A second vaccine lot expressed full-length SIV Gag for >10 68 -fold amplification in vitro and induced potent antigen-specific T cell populations in vaccinated mice. Production of large, well-defined recombinant BCG ⌬leuCD lots can allow confidence that vaccine materials for immunogenicity and protection studies are not negatively affected by instability or differences between freshly grown production batches. The immense global burden of human immunodeficiency virus (HIV) infection necessitates the development of an efficacious vaccine. There is increasing interest in the use of live recombinant bacterial vectors as HIV vaccines due to the inherent advantages of utilizing a replicating antigen delivery system that is itself an effective adjuvant (1, 2). Previous studies have examined the use of live Gram-positive and Gram-negative bacterial vectors, including recombinant Salmonella, Listeria, Streptococcus, and Escherichia coli, for heterologous expression of HIV antigens, with varying success (3-8).Mycobacterium bovis BCG is the most widely administered vaccine in the world (9). Its extensively documented safety in immunocompetent individuals, relatively low production cost, and well-established infrastructure for vaccine administration make it an ideal candidate for use as an anti-HIV vaccine vehicle (10-12). In addition to the logistical advantages of using BCG, mycobacterial antigen delivery systems possess inherent adjuvant properties which activate innate immunity (13,14). Mycobacteria such as BCG ...
Controlling the specific differentiation of stem cells (SCs) is a goal sought by many because of the benefits it would yield for repair or replacement of damaged tissues and organs. We report the discovery of signaling complexes and describe their use in predictably guiding the differentiation of mouse and human SCs. The signaling complexes (Signal-plexes [S-ps]) induce mouse and human SCs to express specific phenotypes. The S-ps have been used to identify a new source of human SCs (Hu abba-1) and have been shown to induce differentiation of multiple tissue-specific phenotypes selectively in mouse pluripotent embryonic cells as well as in Hu abba-1 cells. Endocrine and exocrine pancreas, liver, lung, kidney, heart, cartilage, bone, and other cell types have been induced in SCs by S-ps, as shown by morphology, immunostaining, enzyme-linked immunosorbent assay, and reverse transcriptase-polymerase chain reaction analysis.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.