Eruption of Bioengineered Teeth: A New Approach Based on a Polycaprolactone Biomembrane.

Obtaining a functional tooth is the ultimate goal of tooth engineering. However, the implantation of bioengineered teeth in the jawbone of adult animals never allows for spontaneous eruption due mainly to ankylosis within the bone crypt. The objective of this study was to develop an innovative approach allowing eruption of implanted bioengineered teeth through the isolation of the germ from the bone crypt using a polycaprolactone membrane (PCL). The germs of the first lower molars were harvested on the 14th day of embryonic development, cultured in vitro, and then implanted in the recipient site drilled in the maxillary bone of adult mice. To prevent the ankylosis of the dental germ, a PCL membrane synthesized by electrospinning was placed between the germ and the bone. After 10 weeks of follow-up, microtomography, and histology of the implantation site were performed. In control mice where germs were directly placed in contact with the bone, a spontaneous eruption of bioengineered teeth was only observed in 3.3% of the cases versus 19.2% in the test group where PCL biomembrane was used as a barrier (p < 0.1). This preliminary study is the first to describe an innovative method allowing the eruption of bioengineered tooth implanted directly in the jawbone of mice. This new approach is a hope for the field of tooth regeneration, especially in children with oligodontia in whom titanium implants are not an optimal solution.

Tooth bioengineering from single cell suspensions.

Recent advances in bioengineering and biomaterials, along with knowledge deriving from the fields of developmental biology and stem cell research, have rendered feasible functional replacement of full organs. Here, we describe the methodology for bioengineering a tooth, starting from embryonic epithelial and mesenchymal single cell suspensions. In addition, we describe the subsequent steps of processing this minute structure for use in applications such as histological examination, immunofluorescence and in situ hybridisation. This methodology can be used for any minute structure that needs to be used in paraffin blocks. •Detailed methodology for reproducible and reliable results•Extra step to ensure single cell populations•Subsequent minute structure processing for histological analysis.

Elaboración de un biodiente: enfoque actual y desafíos / Making a Bio-tooth: Current Approaches and Challenges

Antecedentes: El edentulismo es uno de los mayores problemas de salud oral que cause alteraciones fisiológicas, sociales, estéticas, fonéticas y nutricionales. Las terapias actuales para el remplazo dental son artificiales y no satisfacen los requisitos básicos de un diente natural. La bioingeniería de tejidos constituye una alternativa para la sustitución de dientes perdidos. Objetivo: Identificar los enfoques/técnicas disponibles actualmente para obtener un diente completo por bioingeniería (biodiente), así como puntualizar sus desafíos y perspectivas futuras. Métodos: Se realizó una revisión integrativa de la literatura, por medio de las siguientes palabras clave: biodiente, bioingeniería de tejidos, diente entero y células madre. Los años de la búsqueda fueron 2000-2018, en las bases de datos: PubMed, Scopus, EBSCO, Science Direct, Wiley Online Library, Lilacs y Google Académico/Scholar, en inglés y español. Se seleccionaron únicamente artículos y libros de mayor relevancia y pertinencia. Resultados: Se obtuvieron 53 artículos y 10 libros. Para la elaboración de un biodiente se emplean los siguientes métodos: andamios, sin andamios, células madre pluripotentes inducidas, germen de órganos, diente quimérico y estimulación de la formación de la tercera dentición. El tamaño y forma normales del diente, así como la obtención de células epiteliales, son los principales desafíos. Conclusiones: La posibilidad de crear y desarrollar un biodiente en un ambiente oral adulto es cada vez más real gracias a los avances biotecnológicos que ocurren diariamente. Es posible que estos conceptos sean la base de la odontología restauradora en un futuro próximo.

Background: Edentulism is one of the major oral health problems that cause physiological, social, aesthetic, phonetic, and nutritional issues. Current therapies for dental replacement are artificial and do not satisfy the basic requirements of a natural tooth. Tissue bioengineering could be a viable alternative to substitute lost teeth. Objective: To identify current available approaches/techniques to obtain a complete bioengineered tooth (bio-tooth) and to point out future challenges and perspectives. Methods: This was an integrative literature review. Search keywords used were: bio-tooth, tissue bioengineering, whole tooth, stem cells. The search included the years 2000 through 2018, using the databases PubMed, Scopus, EBSCO, Science Direct, Wiley Online Library, Lilacs and Google Scholar, both in English and Spanish. Only relevant and pertinent articles and books were selected. Results: 53 articles and 10 books were obtained. Methods for bio-tooth generation found were: scaffolds, scaffold-free, induced pluripotent stem cells, tooth organ germ, chimeric tooth, and stimulation of third dentition formation. Achieving normal tooth size and shape and obtaining epithelial cells are the main challenges. Conclusions: The possibility of creating and developing a whole bioengineered tooth (bio-tooth) in an adult oral environment is becoming more realistic, considering the daily biotechnological advances. It is possible that these concepts will be the basis of restorative dentistry in a near future.

An Evo-Devo perspective on ever-growing teeth in mammals and dental stem cell maintenance.

A major challenge for current evolutionary and developmental biology research is to understand the evolution of morphogenesis and the mechanisms involved. Teeth are well suited for the investigation of developmental processes. In addition, since teeth are composed of hard-mineralized tissues, primarily apatite, that are readily preserved, the evolution of mammals is well documented through their teeth in the fossil record. Hypsodonty, high crowned teeth with shallow roots, and hypselodonty, ever-growing teeth, are convergent innovations that have appeared multiple times since the mammalian radiation 65 million years ago, in all tooth categories (incisors, canines, premolars, and molars). A shift to hypsodonty, or hypselodonty, during mammalian evolution is often, but not necessarily, associated with increasingly abrasive diet during important environmental change events. Although the evolution of hypsodonty and hypselodonty is considered to be the result of heterochrony of development, little has been known about the exact developmental mechanisms at the origin of these morphological traits. Developmental biologists have been intrigued by the mechanism of hypselodonty since it requires the maintenance of continuous crown formation during development via stem cell niche activity. Understanding this mechanism may allow bioengineered tooth formation in humans. Hypsodonty and hypselodonty are thus examples of phenotypic features of teeth that have both impacts in understanding the evolution of mammals and holds promise for human tooth bioengineering.