Pre-Clinical Models in Implant Dentistry: Past, Present, Future
Abstract
:1. Introduction
2. Large Animal Models in Implantology
2.1. Non-Human Primate Models
Pros and Cons of the Models
2.2. Canine Models
Pros and Cons of the Models
2.3. Swine Models
Pros and Cons of the Models
2.4. Other Large Animal Models
2.5. Conclusion on the Use of Large Animal Models in Dental Implant Research
- NHPs are no longer used in Europe and are only used elsewhere in already accredited procedures. NHP models, particularly the baboon, should be considered a confirmation model reserved for studies on major advances providing substantial added scientific value, already validated in another model.
- Pigs and minipigs are the new pioneers, having replaced dogs in procedures. The minipig appears to be an ideal model for studies of bone regeneration around dental implants when placed at intraoral sites.
- Dogs should only be used when pigs cannot be used to address the question of interest (mainly for compromised oral conditions, sinus surgery, and peri-implantitis procedures). In particular, dog models should be preferentially employed for studies conducted under compromised oral conditions (biofilm).
3. Small Animal Models in Implantology
3.1. Rabbit Models
Pros and Cons of the Models
3.2. Rat Models
Pros and Cons of the Models
3.3. Mouse Models
Pros and Cons of the Models
3.4. Conclusion on the Use of Small Animal Models in Dental Implant Research
- Rabbits should be recommended for biocompatibility studies if large numbers of implants are needed per animal, their availability in large numbers appearing to be the only advantage of this model.
- Other questions should be addressed using rats, which are suitable for biocompatibility and common bone analysis in healthy models.
- Mice are still the best option for human disease models with the existence of numerous knockout and transgenic mice models. Peri-implantitis procedures are also an emerging field in this species.
4. Future Challenges and Strategies
4.1. The Outlook for Animal Models
4.2. Development of Replacement Strategies
4.2.1. In vitro Biocompatibility and Cytotoxicity Analyses
4.2.2. In Vitro Models of Response to Implant and Associated Biofilm
4.2.3. In Vitro Physical and Mechanical Evaluation
5. Conclusions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
Appendix A.1. Research in Non-Human Primates
Appendix A.2. Research in Canine Models
Non-Human Primates | Pigs | Canines | Rabbits | Rats | Mice | |
---|---|---|---|---|---|---|
Species most frequently used | Baboon, mandrill and macaques | Pigs: Domestic pigs Minipigs: Hanford of Göttingen breed | Beagle | New Zealand White rabbit | Wistar rats, Sprague Dawley rats | C57 Black/6 |
Age of use | 7 to 10 years old | 2 to 3 years old | 1 to 2 years old | 6 to 9 months old | 2 to 3 months old | 8 weeks old |
Protocol duration | 6 to 9 months | 12 months | 5 months | 2 to 4 weeks (long bone) Up to 3 months (oral bone) | 2 to 6 weeks (long bone) 2.5 months(oral bone) | 4 weeks (long bone) 2 to 3 months (oral bone) |
Weight | 21.5 kg | Pig: 350 kg Mini-Pig: 35 to 95 kg | 15 kg | 5 to 6 kg | Sprague dawley: 70 to 300 g Wistar rats: up to 500 g | 30 g |
Implant size | Human-sized | Human-sized | Human-sized | Human-sized Adapted implant | Adapted implant: 1.5 mm diameter, 2.5 mm length | Adapted implant: 1 mm diameter, 2 to 3 mm length (long bone) 0.6 mm diameter, 2 mm length (maxilla) |
Trend | Falling into disuse | Any study related to implant surgery under healthy conditions | Peri-implantitis, sinus and genetic studies | Falling into disuse | Systemic conditions (diabetes, hormones), poor bone quality models, ease of breed and use | Genetic studies, knock-out protocols, peri-implantitis |
Appendix A.2.1. Long Bone Models
2010 | 2011 | 2012 | 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | 2019 | 2020 | Sum | ||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Canines | 12 | 4 | 17 | 18 | 24 | 40 | 37 | 26 | 20 | 10 | 7 | 215 | |
Long bone | 1 | 5 | 3 | 2 | 3 | 2 | 1 | 2 | 19 | ||||
Oral bone | 12 | 3 | 12 | 15 | 22 | 37 | 35 | 25 | 18 | 10 | 7 | 196 | |
Non-human primates | 1 | 1 | 1 | 1 | 4 | ||||||||
Oral bone | 1 | 1 | 1 | 1 | 4 | ||||||||
Mice | 1 | 2 | 3 | 3 | 1 | 5 | 5 | 2 | 1 | 23 | |||
Long bone | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 7 | |||||
Oral bone | 1 | 2 | 2 | 1 | 4 | 4 | 1 | 15 | |||||
Other | 1 | 1 | |||||||||||
Pigs | 4 | 1 | 4 | 6 | 10 | 7 | 11 | 7 | 3 | 1 | 54 | ||
Long bone | 1 | 1 | 2 | 4 | |||||||||
Oral bone | 4 | 1 | 3 | 2 | 9 | 4 | 10 | 2 | 3 | 38 | |||
Skull | 1 | 4 | 1 | 2 | 3 | 1 | 12 | ||||||
Rabbits | 6 | 6 | 5 | 4 | 14 | 12 | 8 | 10 | 11 | 6 | 4 | 86 | |
Long bone | 6 | 6 | 5 | 4 | 11 | 9 | 6 | 10 | 9 | 4 | 3 | 73 | |
Oral bone | 3 | 2 | 2 | 2 | 2 | 1 | 12 | ||||||
Skull | 1 | 1 | |||||||||||
Rats | 6 | 7 | 5 | 9 | 7 | 11 | 7 | 7 | 5 | 1 | 3 | 68 | |
Long bone | 3 | 5 | 4 | 7 | 4 | 9 | 6 | 6 | 4 | 1 | 1 | 50 | |
Oral bone | 3 | 2 | 2 | 1 | 2 | 1 | 1 | 1 | 2 | 15 | |||
Skull | 1 | 2 | 3 | ||||||||||
Other | 3 | 2 | 2 | 5 | 3 | 4 | 2 | 6 | 1 | 28 | |||
Long bone | 2 | 1 | 1 | 2 | 2 | 2 | 1 | 1 | 12 | ||||
Oral bone | 3 | 2 | 1 | 2 | 8 | ||||||||
Other | 1 | 1 | 1 | 1 | 3 | 1 | 8 | ||||||
Sum | 33 | 20 | 32 | 41 | 63 | 77 | 69 | 57 | 50 | 21 | 15 | 478 |
Appendix A.2.2. Oral Bone Models
- Studies in the maxilla: Rehabilitation of the posterior area is still challenging in clinical practice. Due to sinus pneumatization, the use of small implants versus sinus augmentation is a routine clinical question. The main advantage of the maxillary bone in dogs is the possibility to perform sinus grafting or sinus augmentation procedures. The model is now well established [144] and provides data on, for example, the effect of different depth implant penetration [145], utility of bone grafts [146], and the effect of new materials such as platelet-rich fibrin [147] which inform clinical decision making. Guided bone regeneration substitutes have been tested for augmentation at peri-implant defects to assess the biocompatibility and efficiency of new materials [148], membranes [149], and different implant compositions [150]. The anterior area has also been used to test ridge expansion. This type of surgery can be followed by vertical and horizontal resorption of the bony wall. As histological measurements are not possible in humans for ethical reasons, the performance of such techniques in the dog maxilla has made it possible to investigate the healing process and bone remodeling [151,152].
- Studies in the mandible: Healing patterns of the mandible, both of the bone [31,153] and soft tissue compartment, are now well characterized [154,155,156,157]. As a result, new techniques have been developed to standardize or even to automate [158] osseointegration analysis. New robotization tools have been developed for biomechanical testing in parallel with 3D modeling [159]. Combined technologies, like the overlaying of micro-computed tomography and STL images of an implant, have been developed to analyze hard and soft tissue volume [160].
- Successfully applied to the mandible, conventional protocols have provided clues to answering other clinical questions concerning issues such as the importance of the vertical position [161,162,163], the implant–crown ratio [164], and implantation in residual roots [165]. Drilling protocols with new techniques [166], sizes [167] or speeds [168] have been analyzed. New surgical methods, like the socket-shield technique [169,170], bone-ring technique [171,172], flapless protocols, and ridge augmentation have improved our understanding of peri-implant tissue healing. The influence of immediate/delayed implant placement on the peri-implant bone [173] and soft-tissue [174] formation has been well documented [175,176]. Post-extraction socket healing, with or without implants [177], has been tested, allowing the basic protocol to be modified to prevent dehiscence [178] or manage the jumping distance between implant and vestibular bone [179]. Bone response to biomechanical loading over time [180,181] or compressive stress [143], excessive loading [182], or lateral force [183] has been studied.
- Biomaterials is a major field of implant research in dogs, especially for tissue augmentation with membranes [184,185,186], xenografts (DBBM [187,188,189,190]), allografts [191], or alloplastics [18,192], but also biotherapeutic proteins (rhBMP-2) [193,194,195,196], progenitor cells [197], and stem-cells [198,199], and the use of platelet-rich fibrin [200,201,202].
- Studies in the mandible have also allowed comparisons between implants. The mandible is large enough to test different implant systems [203], as well as implants with different shapes [204,205], lengths [206], surfaces, and grooves [207,208,209]. The race to find the best alloy, or surface finish, is still open. New materials like zirconium [210], PEEK [211], tentalum [212], and titanium alloys [213] have also been used to enhance osseointegration. Implant surface properties is a field that attracts the attention of many researchers. Old techniques have been improved with the addition of molecules like magnesium [214], plasma projection [215], or chemical treatment [216] and new techniques have been developed with nanocoatings [217] or biofunctionalization [218]. Comparisons have been made between implants with differing abutment shape [219,220], composition [221,222], or microstructure, [223] and different protocols, e.g., platform switching [224,225], have been tested to support the best peri-implant tissue healing.
- Finally, only a few articles were found combining implants and drugs. Pilot studies have been performed to test topical use of implant surface treatments with melatonin coating or vitamin D [226,227] and the efficacy of mouth rinses for prevention of peri-implant mucositis and peri-implantitis, and more recently, the impact of hyperbaric oxygen on tissue healing was analyzed [228]. From a systemic point of view, vaccines have been developed seeking to prevent alveolar bone loss in peri-implantitis [229,230].
- Contribution of peri-implantitis studies in dog models to implantology: A specific strength of this model is the ability to perform periodontitis and peri-implantitis protocols, the dog being the large animal model most widely used in periodontitis studies [231]. A new line of research is the characterization of the peri-implantitis microbiota and changes therein during and after ligature placement, as well as after treatment [232,233,234,235]. Silk and cotton ligatures have been extensively used to initiate plaque formation and therefore an inflammatory process in gingival tissues [236]. New protocols have been developed to accelerate or exacerbate the inflammatory process [237]. For their flexibility and ease of handling, stainless steel ligatures have been proposed to replace soft ligatures which can be tricky to place and retain on the implantation site in the long term. Immediate induction of peri-implantitis has shown similar results to conventional methods with a shorter 6-month protocol [238].
- A better understanding has been obtained of implants’ susceptibility to bacterial contamination depending on the surface condition or composition [239] and characteristics [240,241,242] and tools have been developed to treat them mechanically (Ti-Brush [243], ER:YAG laser [243]) or with drugs (antimicrobials [244], chlorexidine [245], mouth rinse [246], or even plasma [247]) and to reconstruct bone tissue lost [248].
Models | Cost | Housing/Husbandry Requirement | Biological Interest | N per Animal | Ethical Issues | Protocol Duration | Surgical Relevance | Implant Model | Total |
---|---|---|---|---|---|---|---|---|---|
Mice | 1 | 1 | 1 | 5 | 1 | 1 | 5 | 6 | 21 |
Rats | 2 | 1 | 4 | 4 | 2 | 2 | 4 | 6 | 25 |
Rabbits | 3 | 3 | 6 | 3 | 3 | 3 | 3 | 3 | 27 |
Pigs | 4 | 4 | 4 | 1 | 4 | 5 | 2 | 1 | 25 |
Canines | 5 | 5 | 3 | 2 | 5 | 4 | 2 | 1 | 27 |
Non-human primates | 6 | 6 | 2 | 2 | 6 | 6 | 1 | 1 | 34 |
In vitro/in silico/biomaterials | 1 | 1 | - | - | 1 | 1 | 7 | 7 | / |
Appendix A.3. Research in Pig Models
Appendix A.3.1. Oral Bone Models
Appendix A.3.2. Skull Bone Models
Appendix A.3.3. Oral Bone Models
Appendix A.4. Research in Rabbit Models
Appendix A.4.1. Long Bone Models
- Protocols using the tibia: The anatomy and histology of rabbit tibia are well known, the rabbit being used for the first attempt to develop an animal model of osteomyelitis [303] for bone fracture analysis [304]. Numerous research protocols have been developed on the tibia, as the relatively good volume accessible has allowed analysis of as many as 112 implants in 28 rabbits in one study [305]. In this area, 3- to 4-mm diameter implants can be used with lengths of up to 7 mm [306]. Rabbit tibia has been widely used to analyze the osseointegration of zirconia implants [307], titanium–zirconium implants [308], implants coated with calcium carbonate [309], and implants with surface modifications [306,310,311].Bilateral procedures are generally described including (i) two implants per animal with one implant in each tibia [311]; (ii) four implants per animal with two implants in each [312] or (iii) six implants per animal with three implants per tibia [313,314]. The metaphysis and diaphysis of the bone can be used. Thanks to fast healing, osseointegration can be analyzed 1 month after implantation [312]. The tibia has also been used for drilling studies seeking to improve implant stability [315] with drilling speed [316] or drill diameter and implant torque [312] analysis. The large volume of the tibia and ease of surgery have allowed this bone to be used for the creation of peri-implant defects [317] and the use of a bone substitute model [318] and spacers [319], as well as for pathophysiological purposes, mainly for reduced bone models (osteopenic or osteoporotic conditions) [320,321,322,323]. Environmental parameters have been investigated in contexts such as a high-fat diet [324] and irradiation [325].
- The femur is thicker than the tibia and the medullary space is large [326], allowing multiple implant fixations [63]. Experiments can also be performed on both sides of the knee (distal part of the femur and proximal part of the tibia) [327]. The disadvantages of this model are related to the general differences between humans and rabbits as mentioned above. In particular, rabbit long bones show a distinctive physiological variability of the bone architecture with a longitudinal vascular pattern [26]. Another point to consider is the age of the animal. Indeed, due to endosteal bone remodeling, the bone shows cortical thinning and an increase in bone marrow volume by as much as 24% with age [328]. It has also been reported that rabbit bone marrow contains a significant proportion of adipose tissue [5], a characteristic not present in the oral cavity in humans, and this reduces the usefulness of the model.
Appendix A.4.2. Skull Bone Models
Appendix A.4.3. Oral Bone Models
- Studies in the maxilla: Studies in the maxilla are mainly used for related sinus augmentation therapies. Medications such as anti-inflammatory drugs and painkillers can be tested for postoperative pain [332]. Newly formed bone height is measurable following sinus floor elevation using a blood clot [333] or for pre-clinical testing of new bone substitute [334], giving an idea of how such materials are accepted in in vivo models. The poor bone quality of the maxillary sinus is also exploited for studying the impact of innovative surface properties in poor quality bone [335].
- Studies in the mandible: Procedures are short, immediate extraction/implantation protocols being the most common. The healing period after implantation is at least 3 weeks [336] and up to 3 months [337]. The incisor area provides a great volume for osseointegration in immediate extraction/implantation protocols with 3-mm diameter and 12-mm length implants [338]. Except for the study by Schiegnitz et al. using 9-month-old New Zealand rabbits (4–5 kg) [336], the age of rabbits is generally not specified accurately; rather, it is reported as “adult age” which corresponds to 2.5 to 6 Kg. Only one study found was performed in younger rabbits (4 months old), these having been exposed to fluoride since 2 months of age [337]. Studies in the rabbit mandible have been used to assess osseointegration of implants with different surface properties [339] or positions [336,340], and the systemic effect of exposure to molecules like fluoride [337] or the effect of thyroid hormone production [65]. It should be noted that one proof of concept study for a peri-implantitis model was conducted on the first mandible anterior tooth with silk ligatures in 2015 (reported only in Chinese, except for the abstract [341]). In the mandible, an extra-oral approach by opening a flap from the skin to the mandible angle has been used for vertical bone growth, making it possible to extend the scope of already known materials [342]. The great volume available in this area allows the use of human-sized implants, with a length of 8 mm and a diameter of 4.1 mm.
Appendix A.5. Research in Rat Models
Appendix A.5.1. Long Bone Models
- Studies in the tibia: The rat tibia is suitable for bone implantation due to the ease of access and relatively good volume. Notably, 32 out of the 68 studies found have been performed with this bone. The medial tibial plate of the bone is commonly used as it is flat and can receive implants [343]. Depending on the prototype used, the number of tests and their size differ. At least one implant per tibia can be tested with a nearly human-size implant (2.0 mm in diameter and 4- to 5-mm in length [83,344,345,346]). On this kind of model, bi-cortical anchorage can be achieved. For multi-implant protocols, a diameter of 1.5 mm and length of 2.5 mm are more appropriate [343,347].
- Research using the rat tibia model has commonly investigated the effects of the implant surface on osseointegration [343,344], but a new trend has emerged, with growing numbers of studies in the areas of the drug delivery and/or physiopathology: effects on osseointegration of different doses of drugs in rats that are healthy [345] or have certain diseases, e.g., diabetes [348,349,350,351,352,353,354], or in peri-implant bone defects [346]. Nevertheless, the framework of choice is implantation osseointegration in poor quality bone with drug treatments [355,356]. Research into bisphosphonates [347,355,357,358,359] or agonists like selective estrogen receptor modulators [347,360] is typically conducted in the rat as it is an excellent model of osteoporosis. Other diseases, such as arthritis [361] or Crohn’s disease [362] and the effects of severe dietary magnesium deficiency on systemic bone density, have been investigated [363]. Finally, the rat tibia can also be used for mechanical testing, including in dynamic loading models [364,365], as well as for exploring the effects of pulsed ultrasound [366] or laser therapy [367].
- Studies in the femur: Only a few studies have been conducted in femoral bone mainly due to (i) the short length of the bone and (ii) the amount of muscle and tissue surrounding it. Nonetheless, titanium mesh [368] and implants have been placed for surface testing [369] in diabetic rats [370,371,372] or in combination with dietary supplements [373] or cell therapy [374].
Appendix A.5.2. Oral Bone Models
- Studies in the maxilla: Numerous studies have assessed the validity of the maxillary molar site, but with no established guidelines and considerable heterogeneity between protocols. For this procedure, the implants or “mini-screws” measure approximately 1 mm in width and 2 mm in length, though some authors prefer longer and wider implants for good primary stability despite the increase in the risk of sinus perforation [375]. In any case, maxillary molars seem to be an adequate place for implant–prototype anchorage immediately after extraction [376] or with a delay [375,377]. Another possibility is to use the maxillary diastema, mesial to the molars. A recent study has successfully shown a model of peri-implantitis in this area [378], but the validity of this model has yet to be demonstrated [379]. The maxilla is also used for classic implant surface comparisons [376], mechanical testing [380], and analysis of pathophysiological processes [381,382,383,384,385].
- Studies in the mandible: Beyond the maxilla, two studies have been found that used the mandibular region: one protocol used the posterior part of the mandible in the ramus through an extra-oral approach [386]; and in the other, the implant took the place of the first mandibular molar after extraction and healing for a month [387]. Both protocols led to significant osseointegration, but the latter seems to be more physiologically relevant as it replaces a previous tooth in alveolar bone.
- Contribution of peri-implantitis studies in rat models to implantology: In periodontology, in humans, as in many other animals, chronic inflammation needs to be produced at the sulci of the tooth (with silk ligatures and/or microbial gavage) to produce periodontal destruction [388]. In the same way, peri-implantitis can be induced with a mixed bacterial infection (Streptococcus oralis and Aggregatibacter actinomycetemcomitans) [378].
Appendix A.6. Research in Mouse Models
Appendix A.6.1. Back of the Mouse
Appendix A.6.2. Long Bone Models
- Studies in the tibia: with only two studies found from this decade, it seems that the shin has fallen into disuse. One was considered a mouse study but the animal species used was actually Rattus norvegicus, that is, the article had been erroneously classified [390], and the other was conducted to analyze peri-implant bone density in senescence-accelerated mice, but the choice of the shin over femur was not explained in detail [391].
- Studies in the femur: The femur is more commonly used, but nonetheless only a few studies were found. The most common topic is the evaluation of implant osseointegration associated with disease. Diabetes is the most studied disease in association, for example, with drug therapies (1α,25-Dihydroxyvitamin D3 [392]; transcription factors [HIF-1α] [393]). Innovative genetic technologies for lentiviral vector transfection are also useful for testing new treatments [394], or a specific molecular pathway [395]. For this bone, the common prototype is an implant-like model, mostly with a pin-shaped implant 1 mm in diameter and 2- to 3-mm in length [392,394]. Titanium discs are also used if the aim is to test the biocompatibility of the material [395].
Appendix A.6.3. Oral Bone Models
- Studies in the maxilla: No studies were found on the mandible due to the difficulty of access and mechanical difficulties for manufacturing miniature implants [4]. The maxilla is a relatively recent model, having been developed during the last 10 years [396]. It has become the most common model used in mice (Table A2). Nonetheless, due to the recent description of this model, research is focused on the development of the model itself more than on its implementation. The first model in the dental area, reported in 2014, used “retopins” (0.6-mm diameter cut to a 2-mm length, NTI Kahla GmbH, Germany) positioned in the mesial part of the first maxillary molar. This model demonstrated that osseointegration in oral bone cannot be compared to long bone studies [87,397], but it has recently been shown to be a suitable tool for the assessment of biological events associated with the osseointegration process [398]. This protocol has also been adapted for analysis of (i) immediate post-extraction implant placement [399,400,401] and (ii) the involvement of different pathways [397,402]. This site can also be used to test new implant compositions, such as a bio-implant [403].
- Contribution of peri-implantitis studies in mouse models to implantology: In order to investigate how to manage infectious conditions, there is also a need to identify a new model of peri-implantitis in the maxilla. Five different studies have proposed different peri-implantitis models:
- o The first one was also the first study to anchor an implant in the oral cavity [396]. The pin-shaped implant was placed in the medial line of the hard palate and peri-implantitis was induced with a special diet enriched with sugar and flavorings.
- o Peri-implantitis was also obtained in a recent study of oral infection with Porphyromonas gingivalis [408]. Since the model has been well established, some applications have emerged, namely, analysis of the impact of different implant surfaces on peri-implantitis [409] or inflammation pathways [410].
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Blanc-Sylvestre, N.; Bouchard, P.; Chaussain, C.; Bardet, C. Pre-Clinical Models in Implant Dentistry: Past, Present, Future. Biomedicines 2021, 9, 1538. https://doi.org/10.3390/biomedicines9111538
Blanc-Sylvestre N, Bouchard P, Chaussain C, Bardet C. Pre-Clinical Models in Implant Dentistry: Past, Present, Future. Biomedicines. 2021; 9(11):1538. https://doi.org/10.3390/biomedicines9111538
Chicago/Turabian StyleBlanc-Sylvestre, Nicolas, Philippe Bouchard, Catherine Chaussain, and Claire Bardet. 2021. "Pre-Clinical Models in Implant Dentistry: Past, Present, Future" Biomedicines 9, no. 11: 1538. https://doi.org/10.3390/biomedicines9111538
APA StyleBlanc-Sylvestre, N., Bouchard, P., Chaussain, C., & Bardet, C. (2021). Pre-Clinical Models in Implant Dentistry: Past, Present, Future. Biomedicines, 9(11), 1538. https://doi.org/10.3390/biomedicines9111538