Murali Ramamoorthi 1 and Mohammed Bakkar 1, 2 and Jack Jordan 1 and Simon D. Tran 1
Academic Editor:Long Bi
1, Craniofacial Tissue Engineering and Stem Cells Laboratory, Faculty of Dentistry, McGill University, Montreal, QC, Canada
2, King Fahad Armed Forces Hospital, Jeddah, Saudi Arabia
Received 27 November 2014; Accepted 1 February 2015; 28 May 2015
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction
Bone is a multifunctional organ that provides protection, structure, and mechanical support to the body [1]. The integrity of human bone is challenged by infections, trauma, congenital malformation, and surgical removal of tumor [2-4]. Repair and regeneration of bone are a series of biological events involving a number of cell types and signaling pathways in a temporal and spatial sequence [2-6]. When these natural mechanisms/events are compromised, bone grafting is commonly used to augment bone repair and regeneration. Autologous bone grafting has been considered as a "gold standard" because it possesses osteogenesis (osteoprogenitor cells), osteoinduction (BMPs, growth factors), and osteoconduction (scaffold) [7]. However, limitations such as a limited supply, resorption, donor site morbidity, deformity, chronic infection, and rejection demand other alternative treatment approaches [7, 8].
Cell-based bone tissue engineering emerges as a potential alternative as it aims to generate new cell-driven, functional tissue rather than to fill a defect with a nonliving scaffold. It is a combination of principles of orthopedic surgery with biology, physics, material science, and engineering [7]. Classic bone tissue engineering is comprised of osteogenic cells (to form bone tissue matrix), morphogenic signals (help the cells to be the desired phenotype), biocompatible scaffold (to mimic an extracellular matrix niche), and vascular supply (to meet the nutrient supply and clearance of the growing tissue) [7, 8]. Stem cells play a pivotal role in bone tissue engineering [9-15].
Multipotent mesenchymal stromal cells (commonly referred to as mesenchymal stem cells, MSCs) are the most frequently used cell population in tissue engineering because of its multilineage potential, multiple sources, and ability to self-renew [16, 17]. Bone marrow-derived mesenchymal stem cells (BMMSCs) are being considered as a gold standard [7, 9, 16, 17]. However, because of the difficulty to harvest a sufficient cell number as well as the pain and morbidity involved during the harvesting procedure, researchers have been exploring other sources/locations for MSCs. Many anatomical locations have been researched to yield MSC populations [1, 7, 18, 19]. One of the potential sources identified was the dental/oral tissues. Research on using MSCs of dental origin has increased exponentially in the last decade [20-22].
Dental stem/progenitor cells were isolated, characterized, and categorized into six major types [22, 23]: (1) dental pulp-derived stem cells/postnatal dental pulp stem cells (DPSCs), (2) stem cell from exfoliated human dentition (SHED), (3) stem cell from the apical papilla (SCAP), (4) periodontal ligament-derived stem cells (PDLSCs), (5) dental follicle-derived stem cells (DFSCs), and (6) gingival mesenchymal stem cells (GMSCs). The major attractions towards using dental MSCs are ease of access, less invasive approach for harvest, ability to produce higher colony forming units (CFUs), and a higher cell proliferation rate and survival time than bone marrow-derived MSCs [24, 25].
A significant body of literature has been published in the past five years on various types of dental MSCs and its applications [24]. However, there is still limited evidence regarding the capacity of dental MSCs for bone regeneration. An in-depth review and understanding of preclinical in vitro and in vivo studies is a prerequisite to assess the efficacy of dental MSCs and to translate their use into the clinics [26]. Thus the aim of this paper is to perform a systematic review of the literature on dental MSCs for bone regeneration, including in vitro and in vivo studies.
2. Materials and Methods
2.1. Review Protocol
We focused our review question to address: "Do dental-derived stem cells possess osteogenic potential and regenerate bone defects in in vitro and in animal models"?
2.2. Search Strategy
A comprehensive literature search published up to September 2014 was performed on the article databases: Ovid Medline, Embase, PubMed, and Web of Science. The search strategy used a combination of medical subject headings (MeSH) terms and keywords for Medline, PubMed, Web of Science, and EMBASE. The keywords and MeSH terms used for the search were stem cells, mesenchymal stromal cells, progenitor cells, tooth, dental pulp, dental sac, periodontal ligament, deciduous tooth, neural crest, gingiva, SCAP, DPSC, DFSC, GMSC, PDLSC, SHED, bone repair, bone regeneration, bone transplantation, bone substitute, bone tissue engineering, tissue engineering, bone reconstruction, bone defect, osteogenesis, tissue scaffolds, bioreactor, bone morphogenetic protein, intercellular signaling peptide, in vitro, in vivo, animal model, and preclinical. In addition, a hand search strategy was performed by the authors from the citation/reference list of the primary studies and reviews.
2.3. Outcomes Measure
(i) Osteogenic potential/calcified nodule formation/mineralized tissue formation with evidence of osteocyte/osteoblast confirmed by either histology or alkaline phosphatase (ALP) assay or histochemical staining for in vitro studies.
(ii) New bone formation/bone regeneration/defect closure/defect bridging/hard tissue formation (bone)/mineralized tissue or calcified tissue (evidence of osteoblast/osteocyte) confirmed at least by histology or radiography for in vivo studies.
2.4. Inclusion Criteria
The selection was limited to the studies which should have
(i) used at least one type of stem cell derived from dental tissue,
(ii) studied either osteogenic potential or bone regeneration,
(iii): evaluated at least one of the outcomes mentioned above.
2.5. Exclusion Criteria
Studies those used Mesenchymal stem cells derived from mandibular bone, maxillary bone, palatal bone, alveolar bone, buccal mucosa. Conference proceedings, abstracts, expert opinion, and letters were excluded from the initial search phase. The manual examination of titles and abstracts further excluded studies that did not meet the inclusion criteria. Odontogenic/periodontal ligament/cementum/dentin regeneration systematic reviews, clinical studies, and non-English articles were omitted after the proofreading of full-text articles.
2.6. Screening Methods and Data Extraction
The studies were selected and screened by two authors (Murali Ramamoorthi and Mohammed Bakkar). Disagreements between the reviewers were resolved by consensus with all the authors. Data were extracted based on authors, year of publication, population characteristics (animal species, gender, age, weight, number of animals, stem cell source, intervention, defect location and dynamics, scaffold/carrier/cues, period of observation, and evaluation methods) for in vivo studies, experimental characteristics (stem cell source, osteogenic medium, scaffold/carrier/cues, and evaluation methods) for in vitro studies, and methodological characteristics (study quality/risk bias assessment) for both in vivo and in vitro studies.
2.7. Study Quality Assessment
As there are no established sets of criteria/guidelines for assessing the quality or risk of bias for in vivo and in vitro studies [27-32], we assessed the quality of all selected full-text articles using the ARRIVE (animal research: reporting in in vivo experiments) guidelines [27] for in vivo and a modified ARRIVE combined with CONSORT (consolidated reporting of trials) guidelines for in vitro experiments, based on the previous studies [25, 26, 28-30]. The evaluation was based on a predefined grading system of the checklist for in vitro studies (Table 1) and (Table 2) for in vivo studies.
Table 1: Categories used to assess the quality of selected in vitro studies (modified from the ARRIVE and CONSORT guidelines) [26].
Item | Description | Grade |
1 | Title | (0) Inaccurate/nonconcise(1) Concise/adequate |
| ||
2 | Abstract: either a structured summary of background, research objectives, key experiment methods, principal findings, and conclusion of the study or self-contained (should contain enough information to enable a good understanding of the rationale for the approach) | (1) Clearly inadequate(2) Possibly accurate(3) Clearly accurate |
| ||
3 | Introduction: background, experimental approach, and explanation of rationale/hypothesis | (1) Insufficient(2) Possibly sufficient/some information(3) Clearly meets/sufficient |
| ||
4 | Introduction: preprimary and secondary objectives for the experiments (specific primary/secondary objectives) | (1) Not clearly stated(2) Clearly stated |
| ||
5 | Methods: study design explained number of experimental and control groups, steps to reduce bias (demonstrating the consistency of the experiment (done more than once), sufficient detail for replication, blinding in evaluation, etc.) | (1) Clearly insufficient(2) Possibly sufficient(3) Clearly sufficient |
| ||
6 | Methods: precise details of experimental procedure (i.e., how, when, where, and why) | (1) Clearly insufficient(2) Possibly sufficient(3) Clearly sufficient |
| ||
7 | Methods: How sample size was determined (details of control and experimental group) and sample size calculation. | (1) No(2) Unclear/not complete(3) Adequate/clear |
| ||
8 | Methods: Details of statistical methods and analysis (statistical methods used to compare groups) | (1) No(2) Unclear/not complete(3) Adequate/clear |
| ||
9 | Results: explanation for any excluded data, results of each analysis with a measure of precision as standard deviation or standard error or confidence interval | (1) No(2) Unclear/not complete(3) Adequate/clear |
| ||
10 | Discussion: interpretation/scientific implication, limitations, and generalizability/translation | (0) Clearly inadequate(1) Possibly accurate(2) Clearly accurate |
| ||
11 | Statement of potential conflicts and funding disclosure | (0) No(1) Yes |
| ||
12 | Publication in a peer-review journal | (0) No(1) Yes |
Table 2: Categories used to assess the quality of selected in vivo studies (based on the ARRIVE guidelines).
Item | Description | Grade |
1 | Title | (0) Inaccurate/nonconcise(1) Concise/adequate |
| ||
2 | Abstract: either a structured summary of background, research objectives, key experiment methods, principal findings, and conclusion of the study or enough information to enable good understanding of the rationale for the approach (self-contained) | (1) Clearly inadequate(2) Possibly accurate(3) Clearly accurate |
| ||
3 | Introduction: background, experimental approach, and rationale | (0) Insufficient(1) Possibly sufficient/some information(2) Clearly meets/sufficient |
| ||
4 | Introduction: primary and secondary objectives | (0) Not clearly stated (1) Clearly stated |
| ||
5 | Methods: ethical statement (nature of the review permission, relevant license, and national guidelines for the care and use of animals) | (1) Clearly insufficient(2) Possibly sufficient(3) Clearly sufficient |
| ||
6 | Methods: study design explained number of experimental and control groups, steps to reduce bias by allocation concealment, randomization, and binding | (1) Clearly insufficient(2) Possibly sufficient(3) Clearly sufficient |
| ||
7 | Methods: precise details of experimental procedure (i.e., how, when, where, and why) | (0) Clearly insufficient(1) Possibly sufficient(2) Clearly sufficient |
| ||
8 | Methods: experimental animal species, strains, sex, development stage, weight, and source of animals | (1) Clearly insufficient(2) Possibly sufficient(3) Clearly sufficient |
| ||
9 | Methods: housing and husbandry conditions (welfare related assessments and interventions include type of cage, bedding material, number of cage companions, temperature, light or dark cycle, and access to food and water) | (1) Clearly insufficient(2) Possibly sufficient(3) Clearly sufficient |
| ||
10 | Methods: total number of animals used in each experimental group and sample size calculation | (1) No(2) Unclear/not complete(3) Adequate/clear |
| ||
11 | Methods: allocation animals to experimental groups (randomization or matching), order in which animals were treated and assessed | (1) No(2) Yes |
| ||
12 | Methods: outcomes (clearly defines the experimental methods to evaluate the prespecified outcomes) | (1) No(2) Unclear/not complete(3) Clear/complete |
| ||
13 | Methods: details of statistical methods and analysis | (0) No(1) Unclear/not complete(2) Adequate/clear |
| ||
14 | Results: baseline data (characteristic and health status of animals) | (0) No(1) Yes |
| ||
15 | Results: numbers analyzed and explanation for any excluded | (0) No(1) Unclear/not complete(2) Adequate/clear |
| ||
16 | Results for each analysis with a measure of precision as standard error or confidence interval | (1) No(2) Unclear/not complete(3) Yes |
| ||
17 | Adverse events details and modification for reduction | (0) No(1) Unclear/not complete (2) Yes |
| ||
18 | Discussion: interpretation/scientific implication, limitations including animal model, implication for the 3 Rs (replacement, reduction, and refinement) | (1) Clearly inadequate(2) Possibly accurate(3) Clearly accurate |
| ||
19 | Discussion: generalizability/translation | (0) Clearly inadequate (1) Possibly adequate (2) Clearly adequate |
| ||
20 | Statement of potential conflicts and funding disclosure | (0) No(1) Unclear/not complete(2) Yes |
The quality of the articles was assessed by the authors using a checklist of ARRIVE (animal research: reporting in in vivo experiments) guidelines for in vivo studies and using modified ARRIVE and CONSORT (consolidated reporting of trials) guidelines for in vitro studies (the evaluation was based on predefined grading system) (Table 2).
Risk of bias is commonly used to assess clinical trials. Thus we included a risk of bias assessment, as suggested by Bright et al. [25] and the Cochrane Review handbook to improve the quality of our review on dental MSCs. The parameters used were (i) power calculation to determine the samples, (ii) allocation concealment, randomization/replication/multiple experiments done to show consistency, and (iii) blinding in allotment/evaluation of results. A simple Yes or No was used to score selected articles, based on these parameters above.
2.8. Statistical Analysis
Because of heterogeneity of sources of dental MSCs, different animal species, diverse defect characteristics, various evaluation times, and different scaffolds/cues among our selected 137 articles, a (statistical) meta-analysis for quantitative review was not possible. We were able to perform a qualitative systematic review.
3. Results
3.1. Search Results
A total of 1,914 articles were retrieved from the literature search; 1,480 were excluded because of duplication. Four hundred and thirty-four articles were eligible for title and abstract screening. 227 articles were excluded as they did not meet the inclusion criteria. Thus 207 articles were qualified for full-text evaluation. 70 articles were excluded after proofreading the full text. The reasons for exclusion were as follows: odontogenic/dentin/cementum/periodontal ligament regeneration ( [figure omitted; refer to PDF] ), clinical studies ( [figure omitted; refer to PDF] ), reviews ( [figure omitted; refer to PDF] ), language restrictions ( [figure omitted; refer to PDF] ), and multiple reports of the same experiment ( [figure omitted; refer to PDF] ), thus leaving 137 full articles to be included in this systematic qualitative review. The outline of articles selection is summarized in a flow chart (Figure 1). The details of the included studies are described in Table 3.
Table 3: The details and number of studies included in this qualitative review.
Dental stem cell source | In vivo | In vitro | Both in vivo and in vitro |
Dental papilla | 0 | 1 | 0 |
Apical papilla | 0 | 4 | 4 |
Dental follicle | 1 | 6 | 3 |
Neural crest | 0 | 1 | 0 |
Gingiva | 2 | 0 | 1 |
Dental pulp of exfoliated deciduous teeth | 5 | 5 | 2 |
Dental pulp of deciduous/permanent teeth | 14 | 29 | 6 |
Periodontal ligament | 16 | 19 | 6 |
Multiple dental source | 3 | 7 | 2 |
Figure 1: Flow chart demonstrating the strategy used to identify in vitro and in vivo studies for this systematic review of dental stem cells on bone regeneration (PRISMA guidelines is used to design this search strategy).
[figure omitted; refer to PDF]
3.2. Characteristics of the Selected Studies
Out of 137 articles, 80.5% of the studies were published between 2010 and September 2014. Dental pulp-derived (35.5%) and periodontal ligament-derived (30.4%) stem cells were more predominantly studied among the eight different dental sources of stem cells reported in this review. Detailed characteristics (year, source, species, scaffolds/cues, medium, transplanted cell number, evaluation methods, and conclusion of the study) of these studies are shown in Tables 4 and 5.
Table 4: Study characteristics of included in vivo experiments with the application of dental stem cells on Bone regeneration.
(a) Stem cells from apical papilla (SCAPs)
Reference | Cell source | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total number of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Abe et al. 2008 [61] | Human | Rat | na | na | na | na | SC pouch | 5 × 105 | HA | 12 wk | Histology | Ectopic bone like tissue on the border of the scaffold |
| ||||||||||||
Abe et al. 2012 [62] | Human | Mice | M | 4 wk | na | na | SC pouch | 5 × 104 | Porous HA | 12 wk | Histology | Ectopic bone like tissue on the border of the scaffold |
| ||||||||||||
Wang et al. 2013 [63] | Human | Mice | na | na | na | 12 | Renal capsule | 1 × 106 | Absorbable gelatin sponge | 2 wk | Histology | Calcified tissue formation |
| ||||||||||||
Qu et al. 2014 [64] | Human | Mice | F | 10 wk | na | na | SC | 4 × 106 | HA/TCPBMP4 | 8 wk | Histology | DLX2 overexpression enhances mineralized tissue formation. |
(b) Dental follicular stem cells (DFCSs)
Reference | Cell source | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total number of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Xu et al. 2009 [37] | Rat | Mice | na | na | na | na | Sc pouch | 4 × 106 | 3D-β TCPBMP 2 | 8 wk | Histology | Lacked new bone formation |
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Tsuchiya et al. 2010 [38] | Porcine | Rat | na | na | na | 12 | CSD calvarium 5 mm | 1 × 106 | None | 1 wk4 wk | Histology | No new bone formation. Apparent bone like structure |
| ||||||||||||
Honda et al. 2011 [39] | Human | Rat | na | na | na | 24 | CSD calvarium8 mm | 2 × 106 /pellet | None | 1 wk4 wk | Histology | Bone formation with evidence of vascular invasion similar to intramembranous ossification |
| ||||||||||||
Park et al. 2012 [65] | Human | Mice | m | 8 wk | na | 4 | SC pouch | 1 × 106 | DBMFibrin glue | 4 wk | CTHistology | Trabecular bone generation with vessels |
(c) Gingival mesenchymal stem cells (GMSCs)
Reference | Cell source | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total number of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Wang et al. 2011 [66] | Human | Rat Mice | F | 6-8 wk 8-10 wk | 160-180 g na | 10 3 | Mandibular body defect (5 × 2 × 1 mm)SC pouch | na 5 × 106 | Type 1 collagen | Histology | 8 wk 6 wk | Bone formation in the defected area |
| ||||||||||||
Yu et al. 2014 [67] | Dog | Dog | M | na | 10-11 kg | 4 | Class III furcation defect |
| eGFP | Histology | 8 wk | Enhanced new bone formation GMSC (47.11 ± 7.91%) versus control group ( 37 ± 9.53) |
| ||||||||||||
Xu et al. 2014 [68] | Human | Mice | M | 7 wk | na | 36 | Rt mandibular body (1.5 mm diameter) | 1 × 106 | GFP as marker | Histology | 1 wk2 wk3 wk | Active bone formation at 3 wk |
(d) Stem cells from human exfoliated dentition (SHEDs)
Reference | Cell source | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total number of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Miura et al. 2003 [69] | Human | Mice | na | na | na | na | SC | 2 × 106 | HA/TCP | 8 wk | Histology | Induce new bone formation |
| ||||||||||||
Seo et al. 2008 [70] | Human | Mice | na | na | na | 18 | Calvaria (2.7 mm) | 2 × 106 | HA/TCP | 6-8 wk6 month | Histology | Robust bone formation without hematopoietic bone marrow |
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Zheng et al. 2009 [71] | Minipig | Minipig | F | 4-6 m | 20-30 kg | 16 | Bilateral parasymphyseal CSD (2.5 × 1.5 × 1.5 cm3 ) [figure omitted; refer to PDF] 1 × 1 × 0.5 cm3 [figure omitted; refer to PDF] | 2 × 107 to 4 × 108 | PT67/eGFPβ TCPHA/TCP | 24 wk2 wk [3]4 wk [3] | [figure omitted; refer to PDF] -CTHistology | Defects restored with new bone at 6 m |
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Li et al. 2012 [72] | Human | Mice | F | 8-12 wk | na | na | SC pouch | 4 × 106 | HA/TCPbFGF | 8 wk | Histology | b FGF downregulated STRO-1, CD146, CD90, and CD73 expression of SHED |
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Vakhrushev et al. 2012 [73] | Human | Mice | na | na | na | na | na | na | 3D PLGA | 1 month | DAPI staining | More intense expression of osteocalcin on scaffolds with SHED |
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Alkaisi et al. 2013 [74] | Human | New Zealand Rabbit | na | 3-5 months | 2.7 ± 0.31 kg | 22 | Distraction of 6.2 mm between first lower premolar and mental foramen | 6 × 106 | None | 2 wk4 wk6 wk | RadiologyHistology | New bone formation with thick cortices and marrow cavity at 6 wk |
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Behina et al. 2014 [41] | Human SHED 5 yr ago | Dog | M | na | 15-25 kg | 4 | Mandibular through-through (9 mm diameter) | na | Collagen | 12 wk | Histology | 5-year cryopreserved SHED able to proliferate and osteogenesis without immune response. Bone formation is same as control group |
(e) Dental pulp derived stem cells (DPSCSs) from deciduous/permanent teeth
Reference | Cell source | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total number of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Laino et al. 2006 [75] | Human (deciduous teeth) | Rat | na | 10-12 wk | na | 5 | SC | Woven bone obtained by in vitro SHED culture | Woven bone | 4 wk | Histology | Woven bone remodeled to lamellar bone with osteocytes entrapped within the lamella |
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Otaki et al. 2007 [76] | Human | Mice | na | 7 wk | na | na | SC | 2 × 106 to 1.8 × 107 | HA/TCP | 7 wk15 wk | Histology | 50% bone formation seen |
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de Mendonça Costa et al. 2008 [77] | Human | Rat | M | 4 months | 320-420 gm | 8 | Cranium (5 × 8 mm) | 1 × 106 | Collagen membrane | 7 d20 d30 d60 d120 d | Histology | Defect healed with new bone formation |
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Zhang et al. 2008 [44] | Rat | Mice | na | 10 wk | na | 10 | SC | 5 × 106 | HA/TCP | 5 wk10 wk | Histology | No evidence of bone formation |
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Morito et al. 2009 [78] | Human | Mice | na | 10 wk | na | na | SC | 4 × 105 | PLGA with Calcium Phosphate | 5 wk10 wk | Histology | Confirmed bone and cartilage formation |
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Yang et al. 2009 [79] | Rat | Mice | na | 10 wk | na | 12 | SC | 5 × 106 | AdBMP-2HA/TCP | 1 wk4 wk12 wk | Histology | Enhance mineral tissue formation |
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Kraft et al. 2010 [80] | Human | Mice | F | 8 wk | na | 2 | 1.5 cm deep pouch | 5 × 105 | HA-TCP | 8 wk | Histology | Lamellar bone like structure |
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Chan et al. 2011 [81] | Human | Mice | na | 6 wk | na | 5 | SC pouch | 1 × 105 | SAPN | 4 wk | Histology | Mineralized tissue formed |
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Ito et al. 2011 [82] | Dog | Dog | na | 2 yr | na | 3 | Hemimandible 10 × 10 mm | 1 × 107 | PRP gel | 8 wk | Histology | Significant amount of new bone formation seen in the defect |
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Li et al. 2011 [83] | Human | Mice | na | 6 wk | na | 8 | SC | na | None | 4 wk | HistologyX ray | Bone formation seen. |
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Liu et al. 2011 [84] | Rabbit | New Zealand Rabbit | F | Na | 2.5-3 kg | 36 | Segmental 10 × 4 × 3 mm | 1 × 108 | n HAC/PLArh-BMP-2eFG | 12 wk | HistologyX ray | Bone regenerated in the defect area |
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Pisciotta et al. 2012 [85] | Human | Rat | M | 14 wk | na | 10 | 5.8 × 1.5 mm cranial | 1 × 106 | Collagen sponge | 6 wk | Histology | Regeneration of resected bone |
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Riccio et al. 2012 [86] | Human | Rat | M | 12-14 wk | na | 15 | 5 × 8 mm parietal | na | Silk fibroin | 4 wk | Histology | Induce new bone formation in the critical sized defect |
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Annibali et al. 2013 [42] | Human | Mice | na | 50 days | na | 75 | Parietal (4 × 1 mm) | 1 × 106 | DBB β TCPHydrogel-ceramic composite sponge | 1 wk2 wk4 wk8 wk | Histology | TE constructs did not significantly improve bone regeneration |
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Khorsand et al. 2013 [87] | Dog | Dog | M | 1-2 yr | 14-22 kg | 10 | 3 × 5 × 8 mm | 2 × 107 | BIO-OSS | 8 wk | Histology | Woven bone formation seen and no significant difference seen between control and experimental group |
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Maraldi et al. 2013 [88] | Human | Rat | M | 12-14 wk | na | 30 | Parietal 5 × 8 mm | na | Collagen | 4 wk8 wk | Histology | New bone formation seen in the defect |
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Wang et al. 2013 [89] | Rat | Rat | F | 8 wk | na | 30 | OvariectomyRenal capsule | 1 × 106 | Absorbable gelatin sponge | 14 days | Histology | Estrogen deficiency inhibits osteogenic potential of DPSCS (downregulated by NF- [figure omitted; refer to PDF] B pathway) |
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Annibali et al. 2014 [43] | Human | Rat | na | 50 days | na | 8 | Parietal (5 × 1 mm) | na | GDPBβ TCP | 2 wk4 wk8 wk12 wk | µ -CTµ -PET | Addition of stem cell did not increase new bone formation |
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Ling et al. 2014 [90] | Rabbit | New Zealand Rabbit | na | na | 2.5-3 kg | 6 | SC | 1 × 106 | n HAC/PLA β TCP | 8 wk | Histology | Mature bone formation seen |
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Niu et al. 2014 [91] | Human | Mice | M | 5 wk | na | 6 | SC | 5 × 106 | ISCSNCS | 8 wk | Histology | New bone formation seen. |
(f) Periodontal ligament derived stem cells (PDLSCs)
Reference | Cell source | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total no of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Do[gcaron]an et al. 2002 [92] | Dog | Dog | na | na | na | 1 | Class II furcation defect | 2 × 105 | Blood clot | 42 days | Histology | PDLSC promote bone regeneration |
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Seo et al. 2004 [46] | Human | RatMice | na | 12-10 wk | na | Rat-6Mice-12 | Rat-2 mm2 periodontal defectMice-SC | Rat-2 × 106 Mice-4 × 106 | HA-TCP | 6-8 wk | Histology | No bone formation seen |
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Murano et al. 2006 [93] | Dog | Dog | na | na | na | 15 | Class III furcation defect | na | None | 2 wk4 wk8 wk | Histology | Bone regeneration with filling of most defect along with cementum formation |
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Iwata et al. 2009 [94] | Dog | Dog | M | na | 10 kg | 4 | 3-wall defect (5 × 5 × 4 mm) | na | PGA | 6 wk | HistologyMicro-CT | Significant new bone formation compared to control group |
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Kim et al. 2009 [95] | Dog | Dog | M | na | 12-15 Kg | 4 | Mandibular 5 × 10 mm saddle defect | 1 × 106 | HA/TCP | 16 wk | Histology | Defect regenerated new bone |
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Ding et al. 2010 [96] | Minipig | Minipig | M & F | 6-8 m | 30-40 kg | 15 | 3 × 7 × 5 mm periodontal defect | 2-cell sheet/defect | HA/TCP | 0 wk12 wk | CT-ScanHistology | PDLSC sheet repair allogeneic bone defect |
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He et al. 2011 [97] | Dog | Dog | na | 2 year | na | na | SC pocket | 2 × 106 | nHAC/PLA | 8 wk | Histology | New bone like tissue seen |
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Grimm et al. 2011 [98] | Human | Rats | na | 10 wk | na | 17 | 2.5 × 2.5 × 2 mm3 periodontal defect | 1 × 105 | Collagen sponge | 2 wk6 wk8 wk | Histology | PDLSC able to regenerate bone |
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Lee et al. 2012 [47] | Human | Mice | M | 6-8 wk | na | na | SC | na | HA/TCPVEGFFGF-2 | 8 wk | Histology | Hard tissue formation seen. |
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Suaid et al. 2012 [99] | Dog | Dog | na | 1.46 ± 0.18 years | 10-20 kg | 7 | Bilateral Class III defect | 3 × 105 | Collagen | 12 wk | Histology | New bone formation seen in the defect |
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Tour et al. 2012 [100] | Rat | Rat | M | na | 350 gm | 24 | CSD Calvaria8 mm | 2 × 105 | HA-ECM | 12 wk | Histology | Bone regeneration observed in the CSD |
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Yu et al. 2012 [48] | Human | Mice | na | na | na | na | Renal capsule | 1 × 106 | Absorbable gelatin spongeIGF-1 | 6-8 wk | Histology | IGF-1 enhances osteogenic differentiation of PDLSCImmature bone like structure formed |
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Gao et al. 2013 [101] | Human | Mice | M | 4-6 wk | na | 12 | SC | na | Osthole HA-TCP | 4 wk | Histology | Significant bone formation seen |
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Ge et al. 2013 [102] | Human | Rat | M | 8 wk | 180-220 gm | 18 | Bilateral parietal defect5 mm diameter | 1 × 107 | HGCCSGCF | 12 wk | Histology | Bone formation seen in the defect |
| ||||||||||||
Mrozik et al. 2013 [103] | Sheep | Sheep | na | 3-5 years | 63.5-72 kg | 13 | Rectangular 0-wall defect (10 mm deep) | 1 × 107 | Gelfoam | 4 wk | Histology | New alveolar bone formation seen, not significant with gelfoam alone group but significant with control group |
| ||||||||||||
Yu et al. 2013 [104] | Rat | Rat | na | 7 wk | na | 12 | Bilateral 3 wall bone defect (2 × 2 × 1.7 mm3 ) | 4 × 106 | Gelatin sponges | 6 wk | Histology | New bone formed in the defect |
| ||||||||||||
Han et al. 2014 [105] | Rat | Rat | F | na | 220-250 g | 36 | Periodontal defect | 1 × 106 | Gel foam | 1 wk2 wk3 wk4 wk | Histology | Complete bridging of osseous defect with mineralized tissue containing osteocytes |
| ||||||||||||
Jung et al. 2014 [106] | Human | Mice | na | 6 wk | na | 14 | SC | na | rAD-EGFPhBMP2 | 2 wk8 wk | Histology | Ectopic Bone formation seen |
| ||||||||||||
Park et al. 2015 [107] | Dog | Dog | na | na | 10-12 kg | 6 | Peri-implantitis | na | HAAd BMP2 | 7.5 months | Histology | New bone formation and re osseointegration of implants seen |
| ||||||||||||
Yu et al. 2014 [108] | Dog | Rat | M | 2 m | 150 g | 24 | CSD calvaria (4 mm wide) | 2 × 106 | Bio-oss | 8 wk | Micro-CTHistology | Defect regenerated new bone |
| ||||||||||||
Yu et al. 2014 [109] | Dog | Dog | M | 18 m | 14.5 kg | 6 | Maxillary sinus floor augmentation | 2 × 106 | Bio-oss | 8 wk | Micro-CTHistology | New bone formation seen |
| ||||||||||||
Zhao and Liu 2014 [110] | Human | Mice | na | na | na | na | SC | 4 × 106 | Ceramic bovine bone simvastatin | 8 wk | Histology | Bone like hard tissue formation on the scaffold. Larger amount seen in PDLSC and scaffold with simvastatin group |
(g) Multiple dental stem cells
Reference | Cell source | Type compared | Species | Gender | AgeWeek/months | Weight (mg/kg) | Total number of animals | Defect type and location | Transplanted cell number | Scaffold/growth factors/cues | Period | Evaluation methods | Observation |
Yamada et al. 2011 [52] | Dog | c DPSCp DTSC | Dog | na | 2 yr | na | na | Three 10 mm diameter mandibular defects | na | PRP | 8 wk16 wk | Histology | Well-formed new bone with vascularity is seen in all groups studied. |
| |||||||||||||
Wang et al. 2012 [53] | Human | SHEDDPSC | Mice | na | 8 wk | na | na | SC | 2 × 106 | CBBFibrin gel | 8 wk | Histology | Higher osteogenic differentiation and bone formation seen in SHED compared to DPSC. |
| |||||||||||||
Moshaverinia et al. 2013 [54] | Human | PDLSCGMSC | Mice | na | 5 months | na | na | SC | 2 × 106 | Injectable alginate hydrogel | 8 wk | Micro-CTHistology | ALP activity as well as mineralized tissue formation of PDLSC is better than GMSC but comparatively less than BMMSC. |
| |||||||||||||
Yang et al. 2013 [56] | Human | PDLSCGMSC | Mice | M | 6 wk | na | na | SC | 2 × 105 | Artificial bone repair material | 8 wk | Histology | Significant bone formation seen. However GMSC demonstrated better osteogenic potential and bone formation in inflammatory condition compared to PDLSC. |
| |||||||||||||
Moshaverinia et al. 2014 [55] | Human | PDLSCGMSC | Mice | na | 5 months | na | 16 | 5 mm diameter calvarial defect | 4 × 106 | RGD-coupled alginate | 8 wk | Micro-CTHistology | Bone regeneration in defect area (greater in BMMSC, moderate in PDLSC, lesser in GMSC groups) |
Table 5: Study characteristics of in vitro experiments with the application of dental stem cells on bone regeneration/osteogenesis potential
(a) Stem cells from apical papilla (SCAPs)
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Abe et al. 2008 [61] | Human | OIM | HA | ALP assayStaining, SEM | Time dependent ALP activity seen. |
| |||||
Park et al. 2009 [111] | Human | OIM | None | Histochemical staining | Osteoblast differentiation and mineralized nodule formation seen. |
| |||||
Abe et al. 2012 [62] | Human | OIM | None | Histochemical staining | SCAPs differentiate into osteoblasts, adipocytes, chondrocytes, and smooth muscle. |
| |||||
Wang et al. 2012 [35] | Human | OIM | IGF-1 | ALP assayHistochemical staining | IGF-1 enhances osteogenic differentiation but weakens odontogenic differentiation of SCAPs. |
| |||||
Wu et al. 2012 [36] | Human | OIM | bFGF | ALP assayHistochemical staining | SCAP cultured with bFGF shows decreased mineralized nodule formation and ALP activity, but if pretreated with bFGF increased mineralized nodule formation is seen. |
| |||||
Wang et al. 2013 [63] | Human | OIM | None | ALP assayHistochemical staining | High ALP activity and RUNX2 upregulation seen. |
| |||||
Qu et al. 2014 [64] | Human | OIM | None | ALP assayHistochemical staining | Significant mineralization observed and enhanced osteogenesis is linked to DLX2. |
(b) Dental papilla stem cells
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Ikeda et al. 2006 [112] | Human | OIM | HA | ALP assay | In vitro osteogenic differentiation observed if cultured in presence of OIM. |
(c) Dental follicular stem cells (DFCSs)
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Tsuchiya et al. 2010 [38] | Porcine | OIM | None | ALP assayHistochemical staining | DFCS has osteogenic potential. |
| |||||
Honda et al. 2011 [39] | Human | GCM | None | ALP assayHistochemical staining | 3 distinct cell populations were identified with DFCS. Among the three, two of them showed strong calcium accumulation. |
| |||||
Viale-Bouroncle et al. 2011 [113] | Human | OIM | PolydimethylsiloxaneFibronectin | ALP assay | Soft surface improved the induction of osteogenesis differentiation of DFSC compared to higher stiffness. |
| |||||
Aonuma et al. 2012 [114] | Human | OIM | None | ALP assayHistochemical staining | ALP activity higher than hMSC. |
| |||||
Li et al. 2012 [115] | Rat | OIM | Ad-BMP9Ad-GFP | Histological staining | BMP 9 enhances osteogenesis of DFCS. |
| |||||
Park et al. 2012 [65] | Human | OIM | None | Histochemical staining | DFSC able to undergo osteogenic differentiation. |
| |||||
Mori et al. 2012 [116] | Human | OIM | None | ALP assayHistochemical staining | High level of ALP expression, osteogenic potential, and mineralized nodule formation seen. |
| |||||
Rezai Rad et al. 2013 [40] | Rat | OIM | None | ALP assayHistochemical staining | Osteogenesis of DFSC increased with temperature from 37°C to 40°C but lost its potential at 41°C. |
| |||||
Takahashi et al. 2013 [117] | Human | OIM | None | ALP assay | DFSC can undergo osteogenic differentiation in the absence of dexamethasone and BMP 6 is the key gene in osteogenic differentiation of DFSC. |
| |||||
Yao et al. 2013 [118] | Rat | OIM | hr-BMP6 | ALP assay | DFSC lost its osteogenesis during in vitro expansion; addition of BMP-6 dramatically enhances osteogenesis of late passage. |
(d) Gingival mesenchymal stem cells (GMSCs)
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Yu et al. 2014 [67] | Human | OIM | None | ALP assayHistochemical staining | Mineralized nodule formed in the experimental group. |
(e) Dental neural crest stem cells
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Degistirici et al. 2010 [119] | Human | OIM | None | ALP assayHistology | Bone like matrix formation seen. |
(f) Stem cells from human exfoliated dentition (SHEDs)
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Miura et al. 2003 [69] | Human | OIM | rhBMP 4 | Histochemical staining | Osteogenic differentiation observed. |
| |||||
Vakhrushev et al. 2010 [120] | Human | Serum-free OIM | 3D polylactide matrix | Histochemical staining | SHED and BMMSC have similar phenotype and identical osteogenic potential. |
| |||||
Li et al. 2012 [72] | Human | OIM | bFGF | Histochemical staining | bFGF inhibits osteogenic induction. |
| |||||
Viale-Bouroncle et al. 2012 [121] | Human | OIM | PDMSFibronectin | ALP assayHistochemical staining | Rigid scaffold supports proliferation and osteogenesis of SHED. |
| |||||
Vakhrushev et al. 2013 [122] | Human | Serum-free OIM | TCP | Histochemical staining | TCP increases osteogenic differentiation, ossification foci and enhances ECM production by SHED. |
| |||||
Karadzic et al. 2014 [123] | Human | OIM | 3D HAP, PLGA, alginate, EVA/EVV | ALP assayHistology | All four are suitable carrier for SHED. Low level of osteoblastic differentiation is demonstrated in EVA/EVV. |
| |||||
Yu et al. 2014 [124] | Human | OIM | None | ALP assayHistochemical staining | ALP activity and in vitro mineralization were not different between SCID and SHED. However more TNF-α is seen with SCID. |
(g) Dental pulp derived stem cells (DPSCSs) from deciduous/permanent teeth
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Gronthos et al. 2000 [33] | Human | OIM | None | ALP assay | DPSC shows osteogenic potential (formed condensed nodule with high level of calcium) and forms more CFU than BMMSC. |
| |||||
Laino et al. 2005 [45] | Human | OIM | None | ALP assayHistochemical staining | DPSC able to generate living autologous fibrous bone tissue (LAB). |
| |||||
Laino et al. 2006 [75] | Human | OIM | None | Calcium staining | Demonstrated pluripotency. Able to differentiate into osteoblast. |
| |||||
d'Aquino et al. 2007 [125] | Human | OIM | None | ALP assayHistochemical staining | DPSC able to form woven bone in vitro. |
| |||||
Cheng et al. 2008 [126] | Chimpanzee | OIM | None | Histochemical staining | Osteogenic capacity of cDPSC was comparable to human BMMSC, DPSC, and rBMSC. |
| |||||
Graziano et al. 2008 [127] | Human | OIMRotating culture | HA, Ti, PLGA | ALP assayHistochemical staining | PLGA shows better scaffold suitability for DPSC (1 mm bone tissue on PLGA, 0.3 mm in Ti, and no bone tissue formation seen in titanium covered with HA). |
| |||||
Morito et al. 2009 [78] | Human | OIM | PLGAbFGF | ALP assayHistochemical staining | Membrane bone like tissue formed around PLGA. |
| |||||
Alge et al. 2010 [128] | Rat | OIM | None | ALP assayHistochemical staining | Significantly higher ALP activity than control group. |
| |||||
Han et al. 2010 [129] | Human | OIMMechanical bioreactor | None | ALP assayHistochemical staining | Mechanical stimulation promotes osteogenic differentiation and osteogenesis of DPSC. |
| |||||
Mangano et al. 2010 [130] | Human | OIM | LST Ti | HistologySEM | More osteoblast and bone formation seen with laser treated titanium surface. |
| |||||
Mori et al. 2010 [131] | Human | OIM | None | ALP assay | DPSC formed mineralized matrix nodules showing osteoblast features. |
| |||||
Spath et al. 2010 [132] | Human | OIM | Lenti virus vector expressing β galactoside | ALP assayHistochemical staining | DPSC by explant culture method exhibits elevated proliferation and osteogenic potential. |
| |||||
Chan et al. 2011 [81] | Human | OIM | SAPN | Histochemical staining | DPSC survives encapsulation by SAPN and calcium salt deposition seen. |
| |||||
Galli et al. 2011 [133] | Human | OIM | 3DTi | ALP assayHistochemical staining | Increased expression of ALP genes and BMP 2 genes and increased osteogenic differentiation. |
| |||||
D'Alimonte et al. 2011 [134] | Human | OIM | VEGF-A165 peptide | ALP assayHistochemical staining | VEGF enhances differentiation of DPSC towards osteoblast and DPSC showed negative hematopoietic marker. |
| |||||
Li et al. 2011 [83] | Human | OIM | 3D gelatin | ALP assayHistochemical staining | Increased ALP activity and osteoblast compared to control group. |
| |||||
Mangano et al. 2011 [135] | Human | OIM | Biocoral | HistologySEM | Diffuse bone formation seen in the scaffold. |
| |||||
Struys et al. 2011 [136] | Human | OIM | None | TEMStainingImage analysis | Presence of multiple mineralization nuclei. |
| |||||
Huang et al. 2012 [137] | Rat | OIM | Flavanoid | ALP assayHistochemical staining | Flavonoid increases DPSCs ALP activity by 1.47-fold and upregulation of RUNX2by 2.5-fold. |
| |||||
Huang et al. 2012 [138] | Rat | OIM | MAO Ti | ALP assay | Osteogenic potential of DPSC similar to BMMSC. |
| |||||
Khann-Jain et al. 2012 [139] | Human | Human serum (serum-free OIM) | β TCP | ALP assayHistochemical staining | Matrix mineralization seen. Human serum can be substituted for FBS which facilitates translating from in vitro to clinical trials. |
| |||||
Pisciotta et al. 2012 [85] | Human | Human serumOIM | Collagen sponge | ALP assayHistochemical staining | High proliferation rate and osteogenic differentiation of DPSC in human serum compared to FCS. |
| |||||
Tasli et al. 2014 [140] | Human | OIM | BMP2,7Plasmids, GFP | ALP assayHistochemical staining | Transfection of human tooth germ cells with BMP2,7, induced osteogenic, and odontogenic differentiation. |
| |||||
Palumbo et al. 2013 [141] | Human | OIM | 3D scaffold matrigelTitanium | SEMConfocalTEM | Human osteoblasts from bone biopsies are appropriate compared to DPSCs. |
| |||||
Zavatti et al. 2013 [142] | Human | FerutininOIM | None | Staining | Ferutinin enhances osteoblastic differentiation of DPSC. |
| |||||
Akkouch et al. 2014 [143] | Human | OIM | 3D Col/HA/PLCL | Micro-CTALP assayHistochemical staining | 30% increase in bone nodule formation and tissue mineralization seen on surface as well inside the scaffold. |
| |||||
Amir et al. 2014 [144] | Macaque Nemestrima | ChitosanOIM | None | ALP assayHistochemical staining | Chitosan stimulates proliferation and early osteogenic differentiation of DPSC compared to dexamethasone. |
| |||||
Guo et al. 2014 [145] | Human | OIM | FluorapatitePCL | ALP assayHistochemical staining | Scaffolds provided favorable ECM microenvironment for proliferation and osteogenic differentiation. |
| |||||
Huang et al. 2014 [146] | Human | OIM | Lenti virusCloned human OCT4, Nanog | ALP assayHistochemical staining | OCT 4 and Nanog act as a major regulator in maintaining mesenchymal properties in DPSC. |
| |||||
Jensen et al. 2014 [147] | Human | OIM | NSP-PCLHT-PCL | ALP assayHistochemical staining | Both scaffolds promote calcium deposition, but HT-PCL supports only cell proliferation and migration. |
| |||||
Ji et al. 2014 [148] | Human | OIMBiomimetic bioreactor | 3D agarose gel | ALP assayHistochemical staining | Mechanical loading enhances osteogenesis and bone formation |
| |||||
Kanafi et al. 2014 [149] | Human | OIM | Alginate hydrogel | Calcium quantification assayStaining | DPSC immobilized in alginate hydrogel exhibits enhanced osteogenic potential |
| |||||
Niu et al. 2014 [91] | Human | OIM cocultured with silicic acid | Collagen | ALP assayHistochemical staining | ISCS promotes proliferation, osteogenic differentiation, and mineralization compared with NCS. |
| |||||
Tasli et al. 2013 [150] | Human | OIM | NaB | ALP assayHistochemical staining | NaB significantly increases level of ALP activity and mineralization with higher expression of osteogenic and odontogenic genes. |
| |||||
Woloszyk et al. 2014 [151] | Human | OIMSpinner flask bioreactor | Silk fibroin | Micro-CTHistologyALP assay | DPSCs have the potential to form mineralized matrix when grown on 3D scaffold enhanced by mechanical loading. |
(h) Periodontal ligament derived stem cells (PDLSCs)
Reference | Cell source | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Gay et al. 2007 [152] | Human | OIM | None | Histochemical staining | PDLSC has osteogenic differentiation and mineralization potential. |
| |||||
Trubiani et al. 2007 [153] | Human | OIM | Xenogenic Porcine substitute | ALP assayHistochemical staining | Scaffold able to support PDLSC and demonstrated osteogenic potential. |
| |||||
Zhou et al. 2008 [154] | Human | OIM | None | ALP assayHistochemical staining | Time dependent increase in matrix calcification observed with PDLSC. |
| |||||
Orciani et al. 2009 [155] | Human | OIM | None | TEMSEMALP assay | NO involved in osteogenesis of PDLSC. In vitro osteogenesis of PDLSC resulted in osteoblast like cells with calcium deposits. |
| |||||
He et al. 2011 [97] | Dog | OIM | Porous n HAC/PLA | ALP assay | Osteogenic differentiation seen on the scaffolds. |
| |||||
Silverio et al. 2010 [51] | Human | OIM | None | Histochemical staining | Deciduous periodontal ligament derived cells promoted 100% mineral nodule formation, while permanent showed 60%. |
| |||||
Zhang et al. 2011 [156] | Rats | OIM | None | Histochemical staining | Decreased osteogenic differentiation seen in PDLSC derived from ovariectomised rats. |
| |||||
Zhou et al. 2011 [49] | Human | OIM | Ibandronate | qRT-PCR | Ibandronate promoted osteoblastic differentiation of PDLSC. |
| |||||
Ge et al. 2012 [157] | Human | OIM | IHGCCS | ALP assayHistochemical staining | HGCS showed higher ALP activity. |
| |||||
Lee et al. 2012 [47] | Human | OIM | VEGF2FGF2 | ALP assayHistochemical staining | VEGF has positive effect on osteogenic differentiation. FGF has positive effect on proliferation rate. |
| |||||
Sununliganon and Singhatanadgit 2012 [158] | Human | OIM | None | Staining | PDLSC able to form mineralized mass. |
| |||||
Yu et al. 2012 [48] | Human | OIM | IGF-1 | ALP assayHistochemical staining | IGF-1 stimulates osteogenic potential of PDLSC. |
| |||||
Zhang et al. 2012 [50] | Human | OIMLMHF | None | ALP assayHistochemical staining | LMHF promoted osteogenic potential of PDLSC. |
| |||||
Gao et al. 2013 [101] | Human | OIM | None | ALP assayHistochemical staining | PDLSC able to form mineralized nodule. |
| |||||
Ge et al. 2013 [102] | Human | OIM | HApPADM | ALP assayHistochemical staining | Higher ALP activity and osteogenic differentiation seen in Hap-PADM than pure PADM. |
| |||||
Houshmand et al. 2013 [159] | Human | OIM | EMD | Histochemical staining | EMD has no effect on osteoblastic differentiation of BMMSC or PDLSC. |
| |||||
Kato et al. 2013 [160] | Human | OIM | Synthetic peptide | ALP assay | More number of calcified nodules seen in culture with synthetic peptide. |
| |||||
Kim et al. 2013 [161] | Human | HesperetinOIM | None | ALP assay | Significant increase in ALP activity. |
| |||||
Kong et al. 2013 [162] | Human | OIM | None | ALP assay | Periodontal disease derived PDLSC displayed impaired osteogenesis compared to healthy PDLSC. |
| |||||
Singhatanadgit and Varodomrujiranon 2013 [163] | Human | OIMspheroid culture | Conical polypropylene tube | Staining | Bone like deposit seen. PDLSC may undergo osteogenic differentiation in an osteogenic scaffold-free 3D spheroidal culture. |
| |||||
Yu et al. 2013 [164] | Human | OIM | None | ALP assayHistochemical staining | Osteogenic differentiation of PDLSC far superior to WJCMSC. |
| |||||
Hakki et al. 2014 [165] | Human | OIM | Type I collagenBMP6 | Histochemical staining | BMP application stimulated mineralized nodule formation. |
| |||||
Jung et al. 2014 [106] | Human | OIM | rAd-EGFP, BMP2 | Histochemical staining | Mineralized nodule formation seen. BMP 2 effectively promoted osteogenesis. |
| |||||
Tang et al. 2014 [166] | Human | OIM | None | ALP assayHistochemical staining | PDLSCs have osteogenic potential and low immunogenicity. |
| |||||
Ye et al. 2014 [167] | Human | OIM | Ad-BMP9 | ALP assayHistochemical staining | BMP 9 promoted matrix mineralization. |
(i) Multiple dental stem cells
Reference | Cell source | Comparison | Medium | Scaffold/carriers/cues/markers | Evaluation methods | Observation |
Koyama et al. 2009 [168] | Human | DPSCSHED | OIM | BMP2 | ALP assayHistochemical staining | No difference observed between DPSC and SHED for osteogenic potential. |
| ||||||
Chadipiralla et al. 2010 [169] | Human | SHEDPDLSC | Serum-free OIM | Retinoic acidITS | ALP assayHistochemical staining | High proliferation rate seen in PDLSC makes it a better osteogenic cell source. However SHED is more responsive to retinoic acid. |
| ||||||
Bakopoulou et al. 2011 [170] | Human | DPSCSCAP | OIM | None | ALP assayHistochemical staining | DPSC and SCAP positive for markers of both osteogenic and odontogenic differentiation. |
| ||||||
Lee et al. 2011 [171] | Human | DPSCPDLSC | PRPOIM | None | ALP assayHistochemical staining | PRP induces osteogenic and odontogenic differentiation. |
| ||||||
Atari et al. 2012 [172] | Human | DPSCDPMSC | OIM | 3D glass scaffold | ALP assayHistochemical staining | DPPSCs have higher expression of bone markers than DPMSC. |
| ||||||
Moshaverinia et al. 2012 [173] | Human | PDLSCGMSC | OIM | Alginate hydrogel | SEMXRDStaining | Osteogenic potential is observed higher for BMMSC followed by PDLSC and lowest in GMSC. |
| ||||||
Yang et al. 2013 [56] | Human | PDLSCGMSC | OIM | None | ALP assayHistochemical staining | PDLSC showed more effective osteogenic differentiation than GMSC |
| ||||||
Davies et al. 2014 [174] | Human | DPSCADSCBMSC | OIM | None | Micro-CTHistochemical stainingSEM | High volume of mineralized matrix seen in DPSC group but diffused layer of low density seen in SEM. |
| ||||||
Moshaverinia et al. 2014 [55] | Human | PDLSCGMSC | OIM | RGD coupled alginate microsphere | Western blotFluorescent image analysis | Osteogenic potential of BMMSC is greater than PDLSC. However PDLSC shows better osteogenic potential than GMSC. Stem cells encapsulated in RGD showed enhanced osteogenesis. |
Five different species of animals (rat/mice, dog, minipig, rabbit, and sheep) were used for the in vivo experiments. A total of 704 animals were used to study the osteogenic potential/bone regeneration of dental stem cells. Out of 65 in vivo studies, 46 used either rats or mice, 13 used dogs, two used minipigs, three used rabbits, and one used sheep to transplant dental stem cells. In 39 out of 65 studies, the dental stem cell source was from humans. Then 13 studies used dental MSCs from dogs, seven from a rat source, two from rabbits, two from minipigs, one from porcine, and one from sheep. The defect type and location were not uniform. Twenty-four studies used subcutaneous implantation on animals, 12 in periodontal defects, nine in mandibular defects, seven in critical-size defects of the calvarium, three in the renal capsule, and one in maxillary sinus augmentation as a defect model to observe osteogenic potential or bone formation in vivo.
In the selected in vitro studies, 85 of the 96 studies used dental MSCs from humans. The remaining 11 studies obtain dental stem cells from rats (7), porcine (1), dog (1), chimpanzee (1), and macaque nemestrima (1). Four in vitro studies used a bioreactor in their experiments. Ninety studies used osteogenic induction medium with serum, while four studies used serum-free medium and two studies used human serum. Nine in vitro studies and five in vivo studies compared the osteogenic potential of different dental derived stem cells. Most of the studies compared the osteogenic potential of PDLSC and GMSC (3 in vivo, 3 in vitro). All these six studies confirmed that PDLSC showed better osteogenic potential compared to GMSC. Based on the included studies that compared osteogenic potential of multiple dental stem cells, PDLSC showed better osteogenic differentiation, followed by DPSC and SHED.
Almost all of the selected studies employed histology (in vivo) or ALP assay and histochemical staining (in vitro) to evaluate the outcomes. Among the 65 in vivo studies, only six studies reported no in vivo bone formation seen with dental stem cells (DFCS-2, DPSC-3, and PDLSC-1). The comparisons of in vivo osteogenic differentiation of different dental stem cells are shown in Table 6. The total number of studies in each type of dental stem cell in this comparison is increased due to the five in vivo studies compared to the osteogenic behavior of different dental stem cells.
Table 6: Invivo comparison of osteogenic potential different Dental stem cells.
Type of dental stem cells | Total no of selected invivo studies | No. of studies failed to show osteogenic potential | % of Studies showed osteogenic potential |
SCAP | 4 | 0 | 100% |
DFCS | 4 | 2 | 50% |
GMSC | 6 | 0 | 100% |
DPSC | 22 | 3 | 86.36% |
SHED | 8 | 0 | 100% |
PDLSC | 25 | 1 | 96% |
3.3. Quality Assessment of the Selected Literature
In general, most of the studies included some information related to the animals they used. However the majority of the literature lacked the quality based on ARRIVE guidelines. Only two studies reported a sample size calculation, four studies reported blinding in assessment of the outcomes, and 17/65 studies mentioned randomization in their articles. None of the sixty-five studies mentioned the 3Rs (replacement, reduction, and refinement) in their articles. However, one study mentioned that they followed the ARRIVE guidelines.
In 96 in vitro studies, only one study mentioned the power calculation to sample size. Blinding in evaluation was reported in one in vitro study. Sixteen selected in vitro studies gave information that they repeated their experiments or measurement more than once. Supplemental Tables i, ii, iii, and iv (in Supplementary Material available online at http://dx.doi.org/10.1155/2015/378368) summarize the quality of the in vitro and in vivo studies selected in this review.
4. Discussion
The purpose of this review was to summarize the role of dental-derived stem cells (dental MSCs) and their effects on the osteogenic differentiation potential and bone regeneration. Both in vivo and in vitro studies were included in this review. In total, 137 studies were qualitatively reviewed. No randomized controlled trials (RCTs) were found in in vivo studies. The in vitro studies were mainly experimental studies on the osteogenic differentiation or factors enhancing/decreasing the osteogenic potential of various dental stem cells. Dental MSCs used in these studies were derived from the dental pulp, apical papilla, dental papilla, gingiva, dental follicle, dental-neural crest, and periodontal ligament.
The literature stated that dental pulp stem cells were the first to be identified as having mesenchymal properties in the year 2000 by Gronthos and coworkers [33]. To date, four clinical studies were reported using dental stem cells for bone regeneration [9, 22, 24]. Due to the paucity of published clinical studies, we did not include clinical studies in this review. We strongly believe that an in-depth appraisal of the literature on preclinical in vivo and in vitro studies is a prerequisite to understanding the efficacy of a new therapeutic approach before its translation into human use. Dental stem cells such as DPSC, SHED, PDLSC, SCAP, and DFSC fulfill the requirements for mesenchymal stem cell as described by the International Society for cellular therapy [34], that is, adhering to plastic, multilineage differentiation potential, positive to stromal cell markers (CD73, CD90, CD105, STRO1, Nanog) and absence of hematopoietic markers (CD14, CD34, CD45).
4.1. SCAPs
The soft tissue covering the root apex of developing teeth serves as a source for SCAPs. All the studies reported in humans are a source for obtaining SCAPs for their experiments. The four in vivo studies conducted in rats and mice revealed ectopic bone-like tissue formation seen at 12 weeks. The in vitro study by Wang and colleagues [35] found an interesting observation, that insulin growth factor 1 (IGF-1) enhanced the osteogenic differentiation but weakened the odontogenic differentiation of SCAPs. Studies by Wu and coworkers [36] confirmed that basic-fibroblast growth factor b FGF inhibited the osteogenic differentiation of SCAP.
4.2. DFSCs
Among the four in vivo studies conducted in rats/mice, two studies [37, 38] reported a lack of new bone formation by using DFSCs. However the in vitro study conducted by Tsuchiya et al. reported an osteogenic potential with DFSCs in an appropriate osteogenic induction medium. The two failed studies used porcine or rat as their stem cell source [37, 38]. The study done by Honda et al. [39] demonstrated bone formation similar to intramembranous ossification in rat critical sized calvarial defects. In vitro studies showed that BMP-9 and BMP-6 promoted osteogenesis of DFSCs. A later report [40] mentioned that 37°C to 40°C was optimal for osteogenesis and DFSCs lost its osteogenesis at 41°C.
4.3. GMSCs
Two different sources were used in the studies (human, dog). Rats/mice and dogs were used to study the bone regeneration effect. All studies showed that GMSCs were capable of undergoing osteogenic differentiation and forming new bone in the defect area. The cell number used to transplant ranged from 1 × 106 to 5 × 106 .
4.4. SHEDs
Being a biological waste, SHEDs are an interesting candidate for stem cell therapies. Studies showed that they were capable of rapid proliferation and more frequent population doubling than bone marrow-derived MSCs. In vitro studies confirmed the osteogenic differentiation that rigid scaffolds supported osteogenesis, and bovine fibroblast growth factor inhibited osteogenesis. Almost all the in vivo studies used scaffolds; HA/TCP was the most frequently used carrier. All the in vivo studies confirmed the osteogenic differentiation and bone regeneration potential of SHEDs. A recent report showed that 5-year cryopreserved SHEDs were able to proliferate and undergo osteogenesis without immune reaction in a 9 mm mandibular defect in dogs [41].
4.5. DPSCs
Stem cell derived from dental pulp was the most studied dental stem cell for bone regeneration. Among the twenty in vivo studies, three reported that DPSCs were not able to regenerate new bone in subcutaneously implanted mice. Two studies by Annibali et al. in 2013 and 2014 [42, 43] failed to show new bone formation using human DPSCs. Zhang et al. in 2008 [44] demonstrated no evidence of bone formation in mice with rat DPSCs. Almost all the studies used scaffold. Laino et al. in 2005 [45] was able to generate in vitro living autologous bone (LAB) tissue from DPSCs, on subcutaneous implantation in rats LAB remodeled to lamellar bone in 4 weeks.
4.6. PDLSCs
PDLSC studies showed diverse source in obtaining periodontal ligament cell. More than half of the in vivo studies used dogs as a source to obtain PDLSCs, and the periodontal defect model was widely used to assess the osteogenic potential. Seo et al. [46] showed human PDLSCs failed to generate new bone in rat periodontal defects after 8 weeks of observation. Ibandronate, simvastin, VEGF, LMHF, BMP 2, and BMP 6 all seemed to enhance osteogenic potential of PDLSCs [47-50]. Silverio et al. [51] in 2010 demonstrated deciduous derived PDLSCs promoted more mineral nodule formation compared to PDLSC derived from permanent teeth in vitro.
Studies by Yamada et al. [52] showed PDLSCs derived from dog and puppy sources were able to generate 10 mm diameter mandibular defects with high vascularity. Wang et al. [53] demonstrated SHEDs have more osteogenic potential than DPSC in mice. Studies confirmed that PDLSC had more osteogenic and bone formation potential than GMSCs [54, 55]. However, Yang et al. [56] studies showed GMSCs had better osteogenic potential than PDLSCs in inflammatory conditions. On average, the 3rd cell passage was used in most of the studies and the addition of scaffolds or growth factors (except b-FGF) improved osteogenesis of the dental stem cells. Although some studies used critical sized defect, most of these studies used either a small size defect or subcutaneous implantation. This jeopardized the extrapolation on outcomes in clinical situations.
Among the various osteogenic induction and growth factors (BMP, IGF, dexamethasone, VEGF, EGF, and FGF) used in the selected studies, it lacks information about the cost effectiveness, safety, and clinical relevance information. Future research should aim to address these parameters.
Most of the selected studies used FBS for culturing dental stem cells. Serum supplementation is important in ex vivo expansion of these cells for clinical use. Using serum containing medium during stem cell culture for human cell therapy is unsafe as it may transfer viral/prion disease, xenogenic antibodies especially if repeated infusions are needed [57]. While FBS based medium may be acceptable for preclinical studies, xeno-free medium is required for expanding these cells in large scale good manufacturing practices (GMP) for clinical applications [57-59]. Furthermore human cells have the possibility to take up animal proteins and present them on their membranes; thus initiating xenogeneic immune response leads to rejection [58]. As the serum condition can significantly affect cell response, it is important to obtain research data with more clinical relevance [58, 59]. Future studies are recommended to compare the safety and efficacy, surface antigen expression, stemness, growth potential, osteogenic differentiation potential of different dental stem cells cultured in FBS, serum-free medium, allogenic human serum, autologous human serum, plasma rich protein, and plasma lysate.
To increase the scientific validity of animal studies, experiments should be appropriately designed, analyzed, and reported transparently. This not only maximizes scientific knowledge, but also is for ethical and economic reasons [30]. The robustness of the research increases by using sufficient animals to achieve scientific objectives and using appropriate statistical analyses to maximize the validity of the experimental outcomes [31]. Using the NC3Rs (National Center for replacement, refinement and reduction of animals in research) ARRIVE guidelines, we performed a detailed analysis of the quality of reporting and statistical analysis of the included in vivo studies. The analysis revealed a number of issues relating to reporting omissions. The majority of the articles reported age of the animals used. However, there was a lack of information about the weight, gender, and housing conditions of the animals used. The availability of online supplementary results offered by many journals to include additional information results negates the argument that researchers are constrained by the page limit [26, 31]. In some of the in vivo studies ( [figure omitted; refer to PDF] ), the number of animals were simply not reported anywhere in the methodology, results, or discussion sections. Reporting the number of animals is essential to replicate the experiments or to reanalyze the data. Furthermore, 63 of 65 studies did not mention how the sample size was chosen. Determining sample size by power size or simple calculations help to design an animal research with an appropriate number of animals to detect a biologically important effect [28-32]. We cannot rule out that the researchers may have calculated/determined the number of animals but did not report that in the article. However, reporting omission can be easily rectified, as incomplete reporting means potentially flawed research [28].
In vitro preclinical research is the basic foundation for any new therapeutic approach. Although it may not replicate a dynamic environment, in vitro research provides valuable information for future research steps. The methodological quality analysis of the selected in vitro articles revealed the possibility of selection bias. Most of the articles lacked randomization, blinding, sample size calculation, and repetition of the experiments. This affects the scientific validity of experimental results. Although CONSORT guidelines are designed to be used in RCTs, we found it reasonable to apply these guidelines to in vitro studies to emphasize the quality and importance of avoiding bias in reporting or in research, because all phases of research process are interlinked [26, 28, 32]. An inadequate sample size might report incorrect results, which could eventually result in failed animal studies or clinical trials. Comparing the performance of dental stem cells with autologous bone grafts or adipose-derived MSCs or BMMSCs will be an interesting approach. Immune modulation property shown by most of the dental stem cells may provide a solution for graft rejection.
To date few clinical cases of bone tissue engineering used dental stem cells [9, 22, 24]. The main reason for the slow progress is attributed to the extrapolation of outcome from preclinical studies. Based on our observation with the selected literatures and guidelines [26-32, 60], we believe that animal study design should include well defined inclusion and exclusion criteria (study setting), a period to test the participating animals short term ability to adhere to the experimental/treatment regimen (run in period), process of random allocation of animals to the different study groups (randomization), reporting of baseline characteristics (age, sex, and weight) for the all animals in the experimental and control group, animal housing conditions, blinding in outcome assessment and data analyses, clear reporting of number of animals enrolled, followed up, and any addition or number of animals dropped out (attrition), disclosing any adverse effects to the animals during and after intervention/experiment, reporting sample size and methods used to do sample size calculation, and reporting confidence interval in addition to [figure omitted; refer to PDF] value (for the effect estimate and precision). These parameters will minimize the risk of confounding and selection bias. It also ensures that the outcome of the study is not affected by conscious or unconscious bias or factors unrelated to biological action. Thus improving the internal and external validity of the study. Further well designed and conducted animal randomized control trials (RCTs) will help us to generate high level of scientific evidence similar to human RCTs.
In summary, although selected studies showed dental stem cells have remarkable potential for use in bone regeneration, further well designed preclinical studies addressing optimal differentiating factors, culture medium, critical sized defect model, comparison of osteogenic potential of different dental progenitor cells, biological activity, cost effectiveness, efficacy, and safety of dental stem cells are required before clinical translation.
5. Conclusion
Several dental tissues identified by this review possessed dental MSCs with an osteogenic differentiation in vitro and in vivo. Regenerating lost bone tissue was feasible with dental MSCs. The easy accessibility to obtain dental MSCs made them an attractive alternative to BMMSCs for use in clinical trials to evaluate their safety and efficacy. However the current limitation, based on the quality of the literature, requires better designed in vitro or randomized control animal trials before going into clinical trials.
Abbreviations
AdBMP2:
Adenovirus carrying bone morphogenetic protein
ALP:
Alkaline phosphatase
b FGF:
Basic fibroblast growth factor
BMMSC:
Bone marrow derived mesenchymal stromal cell
BMP:
Bone morphogenetic protein
Cap:
Calcium phosphate
CBB:
Ceramic bovine bone
cDPSC:
Dental pulp stem cell derived from chimpanzee
Col:
Collagen
CSD:
Critical sized defect
CT:
Computed tomography
DFSC:
Dental follicle stem cell
DLX2:
Distal less homeobox 2
DPSC:
Dental pulp stem cell
ECM:
Extracellular matrix
EMD:
Enamel matrix derivative
F:
Female
FBS:
Fetal bovine serum
FCS:
Fetal calf serum
FGF:
Fibroblast growth factor
GCF:
Genipin chitosan framework
GCM:
Growth culture medium
GFP:
Green fluorescent protein
GDPB:
Granular deproteinized bone
GMSC:
Gingiva derived mesenchymal cell
HAP:
Hydroxy apatite
HGCCS:
Nanohydroxyl apatite coated genipin chitosan conjugated scaffold
IGF-1:
Insulin growth factor
ISCS:
Intrafibrillar silicified collagen scaffold
ITS:
Insulin transferring selenous acid
Kg:
Kilogram
LMHF:
Low magnitude high frequency
LST:
Laser sintered
m:
Month
M:
Male
MAO:
Mono arc oxygen
Na; na:
Not available
nHAC:
Nanohydroxyl apatite collagen
OIM:
Osteogenic induction medium
PCL:
Polycaprolactone
PDMS:
Polydimethyl siloxane
PET:
Positive emission tomography
PLCL:
Poly(L-lactide-co-epsilon-caprolactone)
rh:
Recombinant
RGD:
Arginine-glycine-aspartic acid tripeptide
SAPN:
Self-assembling peptide nanofibre hydrogel
SC:
Subcutaneous
SCAP:
Stem cell from apical papilla
SCID:
Stem cell from inflamed pulp
SEM:
Scanning electron microscope
SHED:
Stem cell from human exfoliated dentition
Ti:
Titanium
TCP:
Tricalcium phosphate
TNF-α :
Tumor necrosis factor-alpha
VEGF:
Vascular endothelial growth factor
Wk:
Week
WJCMSC:
Wharton jelly of umbilical cord stem cells.
Acknowledgments
The authors would like to thank the following funding agencies: Natural Sciences and Engineering Research Council (NSERC) of Canada and the Canada Research Chairs.
Conflict of Interests
No conflict of interests exists.
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Copyright © 2015 Murali Ramamoorthi et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Abstract
Background and Objective. Dental stem cell-based tissue engineered constructs are emerging as a promising alternative to autologous bone transfer for treating bone defects. The purpose of this review is to systematically assess the preclinical in vivo and in vitro studies which have evaluated the efficacy of dental stem cells on bone regeneration. Methods. A literature search was conducted in Ovid Medline, Embase, PubMed, and Web of Science up to October 2014. Implantation of dental stem cells in animal models for evaluating bone regeneration and/or in vitro studies demonstrating osteogenic potential of dental stem cells were included. The preferred reporting items for systematic reviews and meta-analyses (PRISMA) guidelines were used to ensure the quality of the search. Modified ARRIVE (Animal research: reporting in invivo experiments) and CONSORT (Consolidated reporting of trials) were used to critically analyze the selected studies. Results. From 1914 citations, 207 full-text articles were screened and 137 studies were included in this review. Because of the heterogeneity observed in the studies selected, meta-analysis was not possible. Conclusion. Both in vivo and in vitro studies indicate the potential use of dental stem cells in bone regeneration. However well-designed randomized animal trials are needed before moving into clinical trials.
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Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer