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Periodontitis is a chronic inflammatory disease that can lead to alveolar bone destruction, attachment loss around natural teeth, and, ultimately, tooth mobility and loss. Current epidemiological studies report that up to 50% of the US adult population will develop periodontitis during their life span.1 Periodontitis is caused by oral bacteria colonizing the tooth surface, and in susceptible patients this will lead to inflammation in the soft tissues and loss of supporting bone.2,3 Efforts have been made to reconstruct periodontal and peri-implant bone defects as well as edentulous atrophic areas of alveolar bone. To achieve true periodontal regeneration, four basic elements are needed: sufficient blood supply, provisional extracellular matrices, bone- and ligament-forming cells, and molecular mediators.4 Only the combination of all these factors allows a sufficient regeneration of osseous and soft-tissue defects.
This review highlights current bioengineering approaches for periodontal regeneration and discusses gene and stem cell therapy, 3-dimensional (3D) printing, and innovative scaffold designs.
Current Bioengineering Approaches for Periodontal Regenerative Medicine
In the field of tissue bioengineering the disciplines of engineering and the life sciences are collectively brought together to advance tissue reconstruction.5 The goal of periodontal regenerative therapies is to restore the periodontal-supporting structures and their function. Current approaches for treatment of periodontal bone loss include the use of barriers, scaffolds, bone grafts, and biologics.6 A common periodontal regenerative technique involves guided bone/tissue regeneration (GBR/GTR), which is based on use of a barrier membrane to separate bone-forming cells from soft tissue. GBR membranes limit rapid-growing epithelial cells from infiltrating into the bone defects so that the periodontal ligament (PDL) cells can re-populate the site and form a PDL. In recent years, barriers have been used not only as physical barriers but also as delivery tools for active substances such as antibiotics and growth factors.7,8
Scaffolds, in turn, provide mechanical support to improve tissue regeneration and replace bone lost as a consequence to disease. The configuration of a scaffold needs to be designed to not only maintain the 3D structure but also display the appropriate degradation properties, promoting osteogenic mechanisms and blood vessel formation to generate blood supply to the newly formed tissue. In addition, the scaffold material chosen should stimulate proliferation and migration of the surrounding cells to form new tissue that is as similar to the native tissue as possible.
Bone replacement grafts are a type of scaffold that is commonly used clinically. Such bone grafts can be segmented into autogenous (from the same patient), allogenic (from an individual of the same species), xenogenic (from a different species), and synthetic/alloplastic, and are characterized by their osteoconductive, osteoinductive, and osteogenic properties.9,10 Scaffolds are commonly used in combination with a barrier or with biologics such as growth factors. They are also being used as carriers for cells such as bone-marrow stromal cells and stem cells, which are currently garnering a lot of interest.
The term biologics refers to mediators that are molecules with biological activity administered directly to the defect. Examples of biologics include growth factors, stem cells, and gene therapy agents. Growth factors bind to receptors on cell membranes and influence cellular functions, inducing tissue formation and bone regeneration. Examples of growth factors and biologics that have been used for periodontal regeneration are enamel matrix derivative (EMD), platelet-derived growth factor (PDGF), bone morphogenetic proteins (BMPs), vascular endothelial growth factor (VEGF), and transforming growth factor beta (TGF-β).7 The growth factors work locally at the site of delivery and influence the cells to promote tissue formation and produce new bone. Clinical trials have demonstrated the use of PDGF, fibroblast growth factor (FGF)-2, and other growth factors to promote regeneration.11,12
Emerging Therapies: Stem Cells and Gene Transfer
At present, there are several limitations associated with the use of biologics in bone defects to regenerate new tissue. These limitations include short half-life of growth factors, limited control over the release and distribution of the proteins, and possible rapid dilution of the protein concentration due to exposure to the intraoral environment.13 Gene therapy provides an option to deliver a biologic to the site of regeneration for an extended time period using genetically modified cells; this can overcome some of the limitations of the current use of biologics.14
Generally speaking, gene therapy is performed to enhance or influence cellular expression of a protein of interest (eg, PDGF, BMPs, and VEGF) using a vector that delivers the gene of the particular protein into cells and influences subsequent cell activity. These influences on cell activity may include increased cell migration, proliferation, and differentiation and matrix synthesis for an extended time period (Table 1).6 The transfecting vectors used to deliver the gene of interest into target cells can be classified as viral or nonviral vectors. The most widely used viral vectors in dentistry are adenoviruses, while the most common nonviral vector is plasmid DNA.15
Delivery of the modified cells can also be achieved with different techniques, such as direct delivery, systemic delivery, local delivery through a scaffold or matrix, or via 3D bioprinting (Table 1).6 BMP and VEGF are two of the most commonly tested growth factor genes that can be transfected into cells and promote healing of bone or regeneration of tissues.15 The use of an adenovirus-mediated gene delivery system to deliver BMP-7 to titanium surfaces has been demonstrated to exhibit higher differentiation and attachment ability of bone cells. These results indicate a potential use of the gene transfer method for implant osseointegration and bone regeneration.16
Cell therapy is a treatment for clinical conditions that introduces new cells into a defect to enhance tissue regeneration via either somatic cells or stem cells. Somatic cells comprise humans' internal organs, skin, bones, blood, and connective tissue, and, thus, these cells do not have the self-renewal and differentiation potential that stem cells have.17 Hence, stem cell therapy has been utilized more widely for enhancing tissue regeneration, as it promotes formation of both hard and soft tissues.18-20 Stem cells can be harvested from different sources, including bone marrow, fat tissue, dental pulp, or PDL, and recent work in this area has focused on the use of pluripotent stem cells (iPSCs), bone repair cells (also termed ixmyelocel-T), and periosteum-derived cells to induce tissue regeneration.
Recently, ixmyelocel-T stem cells were evaluated in a randomized, controlled clinical trial to evaluate sinus floor augmentation with transplantation of autologous cells enriched with stem cells. Ixmyelocel-T is derived from enriched CD90+ and CD14+ bone marrow-derived cell populations and carries a unique expression of markers for tissue repair and regeneration.20 Patients with maxillary sinus bone deficiencies who needed sinus lifting procedures prior to dental implant therapy were allocated to receive either stem cells delivered on a β-tricalcium phosphate scaffold or the scaffold alone. Four months after the surgery, findings from histology and cone-beam computed tomography (CBCT) analyses indicated that stem cell therapy yielded better regenerated bone quality than standard-of-care matrix alone (Figure 1 and Figure 2).20 By targeting specific signaling pathways, oral tissue regenerative outcomes may be improved through delivery of stem cells to increase bone regeneration.
Three-dimensional Printing and Innovative Scaffold Design
Three-dimensional printing, also referred to as additive manufacturing, allows for the use of a variety of materials, including metals and polymers, to create 3D structures with defined geometries.21 Formation of 3D constructs is achieved via printing with inkjet, laser-assisted, or extrusion-based techniques, with variability in the use of selected materials and final resolution capabilities. Designs generated for 3D printing are developed from computer-aided design (CAD) software or clinical radiographic images scanned using computed tomography (CT) or magnetic resonance imaging (MRI). Although the most common approach has been to use synthetic polymers to generate material "scaffolds," most recently bioprinting has allowed for direct printing of living cells in combination with materials-increasing the complexity of these constructs yet improving their biological properties.21,22
Synthetic polymers such as polycaprolactone (PCL) and poly-L-lactic acid (PLA) can be combined with natural polymers such as hydroxyapatite and β-tricalcium phosphate to allow the formation of biphasic constructs with tailored mechanical properties and rates of degradation. Recently, a first-in-human case report of a custom-designed, 3D-printed PCL scaffold for the treatment of a large periodontal defect was reported in combination with PDGF administration (Figure 3 through Figure 20).23 The scaffold was fabricated using selective laser sintering, which allowed for material powder to be fused together to form a structure based on a CAD file of the scaffold that was designed from CBCT scans of the patient defect. This novel approach offers a promising future application of 3D printing for customized scaffold designs that can be tailored to meet patient-specific needs based on defect site and location, with the added ability to deliver growth factors.
In addition to a diverse selection of materials that can be used for 3D printing of scaffolds, the macro- and microstructure of scaffolds is especially critical to ensuring proper tissue guidance and formation. This guidance can be achieved in the development of the scaffold architecture by incorporating microgrooves for intended alignment of PDL tissues.24 Three-dimensional-printed materials with a specific focus on bone regeneration have been more prevalent in oral-based tissue engineering applications. Scaffold porosity is especially relevant in the design and fabrication of these constructs, as it is critical for ensuring adequate micro-architecture for tissue ingrowth at the defect site, in addition to proper vascularization and a tailored rate of biodegradation. Three-dimensional printing technology can further help customize pore size, morphology, and interconnectivity. These scaffold designs have high potential for use in dental applications at load-bearing sites.
Given that the periodontium is comprised of multiple tissues, it is appropriate to use 3D-printed constructs that have defined areas for bone and PDL tissue regeneration. Such materials include both biphasic and triphasic scaffold constructs, which have areas for the cementum/dentin interface, as well as the PDL/alveolar bone interface.25-28 Another advantage of compartmentalizing these scaffolds is that each compartment can be used to deliver cells (eg, dental, PDL, and bone stem/progenitor cells), and/or growth factors such as PDGF or BMP.
Future Directions
Over the past decade, important advances have been made in bioengineering for oral and periodontal tissue regeneration using biologics, cell therapy, and, more recently, scaffold design using 3D printing. The future holds great promise as these regenerative technologies increasingly enter the human clinical trial arena, and, undoubtedly, some of these innovations will reach clinical practice for the betterment of dental patients.
Acknowledgments
The work was supported by National Institutes of Health (NIH) DE 13397. Dr. Fretwurst was supported by a Research Scholarship of the Osteology Foundation, Lucerne, Switzerland. Dr. Pilipchuk was supported by a National Science Foundation Grant (NSF-GRFP DGE1256260). Dr. Kaigler was supported by a National Institute of Dental and Craniofacial Research (NIDCR)/NIH Grant (R56DE025097).
About the Authors
Tobias Fretwurst, DDS, DMD
Department of Periodontics and Oral Medicine, University of Michigan, School of Dentistry, Ann Arbor, Michigan; Department of Oral and Craniomaxillofacial Surgery, Center for Dental Medicine, University Medical Center Freiburg, Freiburg, Germany
Lena Larsson, PhD
Department of Periodontics and Oral Medicine, University of Michigan, School of Dentistry, Ann Arbor, Michigan; Department of Periodontology, Institute of Odontology, University of Gothenburg, Gothenburg, Sweden
Shan Huey Yu, DDS
Department of Periodontics and Oral Medicine, University of Michigan, School of Dentistry, Ann Arbor, Michigan
Sophia P. Pilipchuk, PhD
Department of Periodontics and Oral Medicine, University of Michigan, School of Dentistry, Ann Arbor, Michigan; Department of Biomedical Engineering, College of Engineering, University of Michigan, Ann Arbor, Michigan
Darnell Kaigler, DDS, MS, PhD
Department of Periodontics and Oral Medicine, University of Michigan, School of Dentistry, Ann Arbor, Michigan
William V. Giannobile, DDS, DMSc
Department of Periodontics and Oral Medicine, University of Michigan, School of Dentistry, Ann Arbor, Michigan; Department of Biomedical Engineering, College of Engineering, University of Michigan, Ann Arbor, Michigan
Queries to the author regarding this course may be submitted to authorqueries@aegiscomm.com.
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