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{{Short description|Custom medical device}}
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A '''root-analogue dental implant''' ('''RAI''') – also known as a truly anatomic [[dental implant]], or an anatomical/custom implant – is a [[medical device]] to replace one or more roots of a single tooth immediately after [[dental extraction|extraction]].<ref name=":0">{{Cite journal |last1=Liu |first1=Hui |last2=Xuan Gan |first2=Ming |last3=Zhai |first3=Wei |last4=Song |first4=Xu |date=2023-12-01 |title=Design and additive manufacturing of root analogue dental implants: A comprehensive review |journal=Materials & Design |volume=236 |pages=112462 |doi=10.1016/j.matdes.2023.112462 |issn=0264-1275|doi-access=free }}</ref> In contrast to common titanium screw type implants, these implants are custom-made to exactly match the extraction socket of the specific patient. Thus there is usually no need for surgery.<ref>{{Cite journal |last1=Dantas |first1=Telma |last2=Rodrigues |first2=Flávio |last3=Araújo |first3=João |last4=Vaz |first4=Paula |last5=Silva |first5=Filipe |date=2022-09-01 |title=Customized root-analogue dental implants - Procedure and errors associated with image acquisition, treatment, and manufacturing technology in an experimental study on a cadaver dog mandible |url=https://www.sciencedirect.com/science/article/pii/S1751616122002600 |journal=Journal of the Mechanical Behavior of Biomedical Materials |volume=133 |pages=105350 |doi=10.1016/j.jmbbm.2022.105350 |pmid=35792351 |issn=1751-6161}}</ref>


As the root analogue dental implant matches the [[dental alveolus]] (tooth socket) it can only be placed immediately after the tooth extraction. If the tooth has been already lost and the soft and hard tissue is already healed, an RAI can no longer be placed.<ref name=":0" />
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The basic principle of endosseous implants is a biological process described as [[osseointegration]], in which materials such as titanium or ceramic form an intimate bond to bone.<ref>{{Citation |last1=Ramazanoglu |first1=Mustafa |title=Osseointegration and Bioscience of Implant Surfaces - Current Concepts at Bone-Implant Interface |date=2011-08-29 |work=Implant Dentistry - A Rapidly Evolving Practice |url=https://www.intechopen.com/chapters/18415 |access-date=2024-07-19 |publisher=IntechOpen |language=en |isbn=978-953-307-658-4 |last2=Oshida |first2=Yoshiki}}</ref><ref>{{Cite web |title=What are dental implants? |url=https://www.valleydental.au/dental-implants |access-date=2024-07-19 |website=Valley Dental - Fortitude Valley, Brisbane |language=en-AU}}</ref> There are no particular differences between the osseointegration of a root analogue implant and a conventional screw type implant.
There is a long edit history of [[Root analogue dental implant]], which is now a redirect. Please review the history when reviewing this draft. [[User:Robert McClenon|Robert McClenon]] ([[User talk:Robert McClenon|talk]]) 16:32, 4 April 2021 (UTC)}}

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A '''root-analog [[dental implant]] (RAI)''' – also known as a truly anatomic dental implant, or an anatomical/custom implant – is a [[medical device]] to replace one or more roots of a single tooth immediately after [[Dental extraction|extraction]]. In contrast to common titanium screw type implants, these implants are custom-made to exactly match the extraction socket of the specific patient. Thus there is usually no need for surgery.

As the root analog dental implant matches the [[Dental alveolus|tooth socket]] (dental alveolus) it can only be placed in conjunction with the tooth extraction. If the tooth has been already lost and the soft and hard tissue is already healed a RAI can no longer be placed.

The basic principle of endosseous implants is a biological process described as [[osseointegration]], in which materials such as titanium or ceramic form an intimate bond to bone. There are no particular differences between the osseointegration of a root analog implant and a conventional screw type implant.


==Disadvantages of conventional implants==
==Disadvantages of conventional implants==
[[File:Root analogue ceramic dental implant vs titanium screw type implant.jpg|thumb|left|alt=Root Analogue Dental Implant|Root analogue ceramic dental implant in comparison with titanium screw type implant]]
[[File:Root analogue ceramic dental implant vs titanium screw type implant.jpg|thumb|left|alt=Root Analogue Dental Implant|Root analogue ceramic dental implant in comparison with titanium screw type implant]]
As technology has improved, so has implant success rate. However, this does not address fundamental problem with conventional implant technology: the patient must be altered to fit the screw or cylinder implant, rather than the other way around.
As technology has improved, so has implant success rate. Conventional titanium dental implants typically have success rates of 90–95% for 10-year follow-up periods, but this is based on questionable definitions of success.<ref name="Dantas2021">{{cite journal |last1=Dantas |first1=T |last2=Madeira |first2=S |last3=Gasik |first3=M |last4=Vaz |first4=P |last5=Silva |first5=F |title=Customized Root-Analogue Implants: A Review on Outcomes from Clinical Trials and Case Reports |journal=Materials |volume=14 |issue=April |year=2021 |pages=2296 |bibcode=2021Mate...14.2296D |pmid=33946678 |doi=10.3390/ma14092296 |doi-access=free |hdl=1822/73882 |hdl-access=free |pmc=8124429}}</ref> The fundamental problem with conventional implant technology is that the patient must be altered to fit the screw or cylinder implant, rather than the other way around.


A tooth has one or more [[Dental anatomy|roots]]. Even a single-rooted tooth is nearly twice as wide in one direction as in the other. A cylindrical screw-type implant does not resemble a tooth, so invasive surgery is needed to make it fit into an existing tooth socket. Such surgery involves drilling into healthy bone, filling gaps between implant and bone either with bone or bone substitutes, and frequently sinus lift procedures.
A tooth has one or more [[dental anatomy|roots]].<ref>{{Cite web |title=Tooth Root - an overview {{!}} ScienceDirect Topics |url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/tooth-root |access-date=2024-07-19 |website=www.sciencedirect.com}}</ref> Even a single-rooted tooth is nearly twice as wide in one direction as in the other. A cylindrical screw-type implant does not resemble a tooth, so invasive surgery is needed to make it fit into an existing tooth socket. Such surgery involves drilling into healthy bone, filling gaps between implant and bone either with bone or bone substitutes, and frequently sinus lift procedures.


Titanium screws are prone to [[peri-implantitis]] and plaque accumulation, leading to further interventions. The grey color of titanium tends to show through gums.<ref>{{cite journal |last1=Cai |first1=H |last2=Chen |first2=J |last3=Li |first3=C |last4=Wang |first4=J |last5=Wan |first5=Q |last6=Liang |first6=X |title=Quantitative discoloration assessment of peri-implant soft tissue around zirconia and other abutments with different colours: A systematic review and meta-analysis. |journal=J Dent. |volume=70 |issue=Mar |year=2018 |pages=110-117 |doi=10.1016/j.jdent.2018.01.003 |pmid=29371043}}</ref>, and in case of gum and bone recession, esthetic outcome is often highly unpredictable.
Titanium screws are prone to [[peri-implantitis]]<ref name="Dantas2021"/> and plaque accumulation, leading to further interventions. The grey colour of titanium tends to show through gums,<ref>{{cite journal |last1=Cai |first1=H |last2=Chen |first2=J |last3=Li |first3=C |last4=Wang |first4=J |last5=Wan |first5=Q |last6=Liang |first6=X |title=Quantitative discoloration assessment of peri-implant soft tissue around zirconia and other abutments with different colours: A systematic review and meta-analysis. |journal=Journal of Dentistry |volume=70 |issue=Mar |year=2018 |pages=110–117 |pmid=29371043 |doi=10.1016/j.jdent.2018.01.003}}</ref> and in case of gum and bone recession, esthetic outcome is often highly unpredictable. Moreover, there are concerns over possible long-term corrosion and release of ions to the body environment, so researchers are evaluating non-metallic alternatives.<ref name="Dantas2021"/>


==Root analogue implants==
==Root analogue implants==
[[File:Illustration showing comparison of screw type implant with root analogue implant.jpg|thumb|Illustration showing comparison of screw type implant with root analogue implant]]
[[File:Illustration showing comparison of screw type implant with root analogue implant.jpg|thumb|Illustration showing comparison of screw type implant with root analogue implant]]


{{multiple image
{{Multiple image
| align = right
| align = right
| direction = vertical
| direction = vertical
| header = X-rays of root analogue dental implants in different regions
| header = X-rays of root analogue dental implants in different regions
| width = 178
| width = 178
| image1 = X-ray of root analogue dental implant single rooted right lower second premolar.jpg
| image1 = X-ray of root analogue dental implant single rooted right lower second premolar.jpg
| alt1 = X-ray of root analogue dental implant single rooted right lower second premolar
| alt1 = X-ray of root analogue dental implant single rooted right lower second premolar
| caption1 = X-ray of root analogue dental implant single rooted right lower second premolar
| caption1 = X-ray of root analogue dental implant single rooted right lower second premolar
| image2 = X-ray of root analogue dental implant two rooted left lower molar.jpg
| image2 = X-ray of root analogue dental implant two rooted left lower molar.jpg
| alt2 = X-ray of root analogue dental implant two rooted left lower molar.jpg
| alt2 = X-ray of root analogue dental implant two rooted left lower molar
| caption2 = X-ray of root analogue dental implant two rooted left lower molar.jpg
| caption2 = X-ray of root analogue dental implant two rooted left lower molar
| image3 = X-ray of root analogue three rooted dental implant right first upper molar.jpg
| image3 = X-ray of root analogue three rooted dental implant right first upper molar.jpg
| alt3 = X-ray of root analogue three rooted dental implant right first upper molar.jpg
| alt3 = X-ray of root analogue three rooted dental implant right first upper molar
| caption3 = X-ray of root analogue three rooted dental implant right first upper molar.jpg
| caption3 = X-ray of root analogue three rooted dental implant right first upper molar
}}
}}


RAIs are custom made to perfectly fit the tooth socket of a specific patient immediately after tooth extraction. Therefore every implant is unique. As an optimized root-form it is much more than a simple 1:1 replica of a tooth. Since it exactly fills the gap left after the tooth is extracted, surgery is rarely needed. The implant can be produced from a copy of the extracted tooth, an impression of the tooth socket, or from a [[CT scan|CT scan]] or [[Cone beam computed tomography|CBCT scan]] <ref>{{cite journal |last1=Evans |first1=Zachary P. |last2=Renne |first2=Walter G. |last3=Bacro |first3=Thierry R. |last4=Mennito |first4=Anthony S. |last5=Ludlow |first5=Mark E. |last6=Lecholop |first6=Michael K. |title=Anatomic Customization of Root-Analog Dental Implants With Cone-Beam CT and CAD/CAM Fabrication: A Cadaver-Based Pilot Evaluation |journal=Journal of Oral Implantology |volume=XLIV |issue=1 |year=2018 |pages=15-25}}</ref>. The advantage of a CBCT scan is that the implant can be produced before extraction. With the former methods, it takes one or two days to fabricate an implant.
RAIs are custom made to perfectly fit the tooth socket of a specific patient immediately after tooth extraction. Therefore every implant is unique. As an optimised root-form it is much more than a simple 1:1 replica of a tooth. Since it exactly fills the gap left after the tooth is extracted, surgery is rarely needed. The implant can be produced from a copy of the extracted tooth, an impression of the tooth socket, or from a [[CT scan]] or [[cone-beam computed tomography|CBCT scan]].<ref>{{cite journal |last1=Evans |first1=Zachary P. |last2=Renne |first2=Walter G. |last3=Bacro |first3=Thierry R. |last4=Mennito |first4=Anthony S. |last5=Ludlow |first5=Mark E. |last6=Lecholop |first6=Michael K. |title=Anatomic Customization of Root-Analog Dental Implants With Cone-Beam CT and CAD/CAM Fabrication: A Cadaver-Based Pilot Evaluation |journal=Journal of Oral Implantology |volume=44 |issue=1 |year=2018 |pages=15–25 |pmid=29064779 |doi=10.1563/aaid-joi-D-17-00090 |doi-access=free}}</ref> The advantage of a CBCT scan is that the implant can be produced before extraction. With the former methods, it takes one or two days to fabricate an implant.


A root analogue implant can be fabricated from [[zirconium dioxide]] (zirconia) or [[titanium]]. Zirconia is the preferred material, because it is more esthetic in color, with no grey discoloration visible through gums.<ref>{{cite journal |last1=Happe |first1=Arndt |last2=Schulte-Mattler |first2=Verena |last3=Strassert |first3=Christian |last4=Naumann |first4=Michael |last5=Stimmelmayr |first5=Michael |last6=Zoller |first6=Joachim |last7=Rothamel |first7=Daniel |title=In Vitro Color Changes of Soft Tissues Caused by Dyed Fluorescent Zirconia and Nondyed, Nonfluorescent Zirconia in Thin Mucosa |journal=The International journal of periodontics & restorative dentistry |volume=33 |issue=01 |year=2013 |pages=e1-8 |doi=10.11607/prd.1303}}</ref>
A root analogue implant can be fabricated from [[zirconium dioxide]] (zirconia) or [[titanium]].<ref>{{Cite journal |last1=Cionca |first1=Norbert |last2=Hashim |first2=Dena |last3=Mombelli |first3=Andrea |date=21 December 2016 |title=Zirconia dental implants: where are we now, and where are we heading? |url=https://onlinelibrary.wiley.com/doi/10.1111/prd.12180 |journal=Periodontology 2000 |language=en |volume=73 |issue=1 |pages=241–258 |doi=10.1111/prd.12180 |pmid=28000266 |issn=0906-6713}}</ref> Successful titanium RAIs have been three-dimensionally printed as porous one-piece implants, using CAD software.<ref>{{cite journal |last1=Liu |first1=Changkui |last2=Huang |first2=Shuo |last3=Guo |first3=Fang |last4=Li |first4=Yongfeng |last5=Zhao |first5=Bingjing |last6=Luo |first6=Aimin |last7=Liu |first7=Huawei |last8=Wang |first8=Chao |last9=Hu |first9=Min |last10=Zhou |first10=Hongzhi |title=Immediate, non-submerged, three-dimensionally printed, one-piece mandibular molar porous root-analogue titanium implants: A 2-year prospective study involving 18 patients |journal=Journal of Stomatology, Oral and Maxillofacial Surgery |year=2022 |volume=123 |issue=6 |pages=e770–e776 |pmid=35598871 |doi=10.1016/j.jormas.2022.05.019 |s2cid=248954114}}</ref> However, zirconia is the preferred material, because it is more esthetic in colour, with no grey discolouration visible through gums.<ref>{{cite journal |last1=Happe |first1=Arndt |last2=Schulte-Mattler |first2=Verena |last3=Strassert |first3=Christian |last4=Naumann |first4=Michael |last5=Stimmelmayr |first5=Michael |last6=Zoller |first6=Joachim |last7=Rothamel |first7=Daniel |title=In Vitro Color Changes of Soft Tissues Caused by Dyed Fluorescent Zirconia and Nondyed, Nonfluorescent Zirconia in Thin Mucosa |journal=The International Journal of Periodontics & Restorative Dentistry |volume=33 |issue=1 |year=2013 |pages=e1-8 |pmid=23342353 |doi=10.11607/prd.1303}}</ref><ref name="Dantas2021"/>
Zirconium dioxide is doped with small amounts of yttria, which results in a material with superior thermal, mechanical, and electrical properties, and enhanced fracture toughness - ideal for surgical implants.<ref>{{cite journal |last1=Gautam |first1=C |last2=Joyner |first2=Jarin |last3=Gautam |first3=Amarendra |last4=Rao |first4=Jitendra |last5=Vajtai |first5=Robert |title=Zirconia Based Dental Ceramics: Structure, Mechanical Properties, Biocompatibility and Applications |journal=Dalton Trans. |year=2016 |volume=45 |issue=11 |doi=10.1039/C6DT03484E}}</ref><ref>{{cite journal |last1=El-Ghany |first1=Ossama Saleh Abd |last2=Sherief |first2=Ashraf Husein |title=Zirconia based ceramics, some clinical and biological aspects: Review |journal=Future Dental Journal |year=2016 |volume=2 |issue=2 |pages=55-64 |doi=10.1016/j.fdj.2016.10.002}}</ref> Zirconia is metal free and is [[Biocompatibility|biocompatible]].


Zirconium dioxide is doped with small amounts of yttria, which results in a material with superior thermal, mechanical, and electrical properties, and enhanced fracture toughness ideal for surgical implants.<ref>{{cite journal |last1=Gautam |first1=C |last2=Joyner |first2=Jarin |last3=Gautam |first3=Amarendra |last4=Rao |first4=Jitendra |last5=Vajtai |first5=Robert |title=Zirconia Based Dental Ceramics: Structure, Mechanical Properties, Biocompatibility and Applications |journal=Dalton Transactions |year=2016 |volume=45 |issue=11 |pages=19194–19215 |pmid=27892564 |doi=10.1039/C6DT03484E}}</ref><ref>{{cite journal |last1=El-Ghany |first1=Ossama Saleh Abd |last2=Sherief |first2=Ashraf Husein |title=Zirconia based ceramics, some clinical and biological aspects: Review |journal=Future Dental Journal |year=2016 |volume=2 |issue=2 |pages=55–64 |doi=10.1016/j.fdj.2016.10.002 |doi-access=free}}</ref> Zirconia is metal free and is [[biocompatibility|biocompatible]], and has low bacterial affinity in comparison to regular titanium.<ref name="Dantas2021"/>
An alternative technique used a titanium root fused to a zirconia abutment by a sintering process that eliminated any possible microgap (which could cause [[peri-implantitis]], leading to bone loss around the implant).<ref name="Pour2019">{{cite journal |last1=Saeidi Pour |first1=R. |last2=Freitas Rafael |first2=C. |last3=Engler |first3=M.L.P.D. |last4=Edelhoff |first4=D. |last5=Klaus |first5=G. |last6=Prandtner |first6=O. |last7=Berthold |first7=M. |last8=Liebermann |first8=A. |title=Historical development of root analogue implants: a review of published papers |journal=British Journal of Oral and Maxillofacial Surgery |year=2019 |volume=57 |issue=6 |pages=496-504 |doi=10.1016/j.bjoms.2019.01.021}}</ref>


An alternative technique uses a titanium root fused to a zirconia abutment by a sintering process that eliminates any possible microgap (which could cause [[peri-implantitis]], leading to bone loss around the implant).<ref name="Pour2019">{{cite journal |last1=Saeidi Pour |first1=R. |last2=Freitas Rafael |first2=C. |last3=Engler |first3=M.L.P.D. |last4=Edelhoff |first4=D. |last5=Klaus |first5=G. |last6=Prandtner |first6=O. |last7=Berthold |first7=M. |last8=Liebermann |first8=A. |title=Historical development of root analogue implants: a review of published papers |journal=British Journal of Oral and Maxillofacial Surgery |year=2019 |volume=57 |issue=6 |pages=496–504 |pmid=31085016 |doi=10.1016/j.bjoms.2019.01.021 |s2cid=155089688}}</ref>
True ‘root-form analogue’ or ‘anatomic’ dental implants have been attempted in the past. Those early attempts failed because of insufficient knowledge of healing of cortical and spongy bone, method, material, tooling, and technology. The principle of Differentiated Osseointegration, in conjunction with suitable material and technology, has enabled the first success in this field<ref>{{cite journal |last1=Pirker |first1=W |last2=Kocher |first2=A |title=Immediate, non-submerged, root-analogue zirconia implant in single tooth replacement. |journal=Int J Oral Maxillofac Surg. |year=2008 |volume=37 |issue=3 |pages=293-5 |doi=10.1016/j.ijom.2007.11.008 |pmid=18272340}}
</ref><ref>{{cite journal |last1=Pirker |first1=W |last2=Kocher |first2=A |title=Immediate, non-submerged, root-analogue zirconia implants placed into single-rooted extraction sockets: 2-year follow-up of a clinical study. |journal=Int J Oral Maxillofac Surg. |year=2009 |volume=38 |issue=11 |pages=1127-32 |doi= 10.1016/j.ijom.2009.07.008|pmid=19665354}}</ref><ref name="Pirker2011">{{cite journal |last1=Pirker |first1=W |last2=Wiedemann |first2=D |last3=Lidauer |first3=A |last4=Kocher |first4=A |title=Immediate, single stage, truly anatomic zirconia implant in lower molar replacement: a case report with 2.5 years follow-up. |journal=Int J Oral Maxillofac Surg. |year=2011 |volume=40 |issue=2 |pages=212-6 |doi=10.1016/j.ijom.2010.08.003 |pmid=20833511}}</ref>


True 'root-form analogue' or 'anatomic' dental implants have been attempted in the past. Those early attempts failed because of insufficient knowledge of healing of cortical and spongy bone, method, material, tooling, and technology. The principle of differentiated osseointegration, in conjunction with suitable material and technology, has enabled the first success in this field<ref>{{cite journal |last1=Pirker |first1=W |last2=Kocher |first2=A |title=Immediate, non-submerged, root-analogue zirconia implant in single tooth replacement. |journal=International Journal of Oral and Maxillofacial Surgery |year=2008 |volume=37 |issue=3 |pages=293–5 |pmid=18272340 |doi=10.1016/j.ijom.2007.11.008}}
==The Principle of “Differentiated Osseointegration”==
</ref><ref>{{cite journal |last1=Pirker |first1=W |last2=Kocher |first2=A |title=Immediate, non-submerged, root-analogue zirconia implants placed into single-rooted extraction sockets: 2-year follow-up of a clinical study. |journal=International Journal of Oral and Maxillofacial Surgery |year=2009 |volume=38 |issue=11 |pages=1127–32 |pmid=19665354 |doi=10.1016/j.ijom.2009.07.008}}</ref><ref name="Pirker2011">{{cite journal |last1=Pirker |first1=W |last2=Wiedemann |first2=D |last3=Lidauer |first3=A |last4=Kocher |first4=A |title=Immediate, single stage, truly anatomic zirconia implant in lower molar replacement: a case report with 2.5 years follow-up. |journal=International Journal of Oral and Maxillofacial Surgery |year=2011 |volume=40 |issue=2 |pages=212–6 |pmid=20833511 |doi=10.1016/j.ijom.2010.08.003}}</ref>


==The principle of "differentiated osseointegration"==
Differentiated Osseointegration<ref>{{cite journal |last1=Pirker |first1=W |last2=Kocher |first2=A |title=True Anatomic Immediate Dental Implant Method: A Clinical Case |journal=International Magazine of Oral Implantology |year=2009 |issue=4 |pages=10-14}}</ref> describes the guided equilibrium of bone-to-implant distance, contact and compression, taking into account spongy or cortical bone, in order to achieve secure [[osseointegration]] of individual anatomical dental implants.
Differentiated osseointegration<ref>{{cite journal |last1=Pirker |first1=W |last2=Kocher |first2=A |title=True Anatomic Immediate Dental Implant Method: A Clinical Case |journal=International Magazine of Oral Implantology |year=2009 |issue=4 |pages=10–14}}</ref> describes the guided equilibrium of bone-to-implant distance, contact and compression, taking into account spongy or cortical bone, in order to achieve secure [[osseointegration]] of individual anatomical dental implants.


The design of the implant surface is crucial in integrating all three possible primary bone-to-implant contact scenarios:
The design of the implant surface is crucial in integrating all three possible primary bone-to-implant contact scenarios:

* Contact in the area of the exact root replica, for an immediate start of primary osseointegration without bone trauma;
* Contact in the area of the exact root replica, for an immediate start of primary osseointegration without bone trauma;
* Distance at the thin buccal and lingual cortical plates, to safely avoid fracture and pressure resorption of this sensitive bone;
* Distance at the thin buccal and lingual cortical plates, to safely avoid fracture and pressure resorption of this sensitive bone;
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[[File:X-ray of root analogue dental implant left central incisor.jpg|thumb|X-ray of root analogue dental implant corresponding to above surgical video]]
[[File:X-ray of root analogue dental implant left central incisor.jpg|thumb|X-ray of root analogue dental implant corresponding to above surgical video]]


Treatment consists of three steps:
Treatment consists of three steps:<ref name="Dantas2021"/>
* Obtain the 3D form of the tooth to be replaced. This is done either through careful tooth extraction and scanning of the root, taking an impression of the tooth socket, or a pre-op [[cone-beam computed tomography|CBCT scan]]. The root analogue implant is produced using modern [[CAD/CAM dentistry|CAD/CAM]] technology, based on the principle of differentiated osseointegration;

* Obtain the 3D form of the tooth to be replaced. This is done either through careful tooth extraction and scanning of the root, taking an impression of the tooth socket, or a pre-op [[Cone beam computed tomography|CBCT scan]]. The root analogue implant is produced using modern [[CAD/CAM dentistry|CAD/CAM]] technology, based on the Principle of Differentiated Osseointegration;
* Atraumatic extraction of the hopeless tooth;
* Atraumatic extraction of the hopeless tooth;
* Placement of the root analogue implant by tapping it in. In general, no surgery is necessary. In particular, no sinus lift or invasive surgery is ever necessary. The implant is placed immediately if it has been produced beforehand from a CBCT scan, or the next day if root has to be scanned or an impression of the socket is used. A protective splint is fitted to protect the implant during the healing period.
* Placement of the root analogue implant by tapping it in. In general, no surgery is necessary. In particular, no sinus lift or invasive surgery is ever necessary. The implant is placed immediately if it has been produced beforehand from a CBCT scan, or the next day if root has to be scanned or an impression of the socket is used. A protective splint is fitted to protect the implant during the healing period.


Recovery time is very fast as neither soft nor hard tissue is traumatized. Typically, even the day after implant placement there is no swelling, bruising or pain. After 8–12 weeks' healing period, the final crown may be fitted by a family dentist.
Recovery time is very fast as neither soft nor hard tissue is traumatised. Typically, even the day after implant placement there is no swelling, bruising or pain. After 8–12 weeks' healing period, the final crown may be fitted by a family dentist.


==Advantages==
==Advantages<ref name="Pirker2011"></ref><ref name="Chong2020">{{cite journal |last1=Chong |first1=Chin Chen |last2=Pfaff |first2=Jacqueline A |title=Clinical Outcome of Root Analog Dental Zirconia Implants: A Systematic Literature Review |journal=On J Dent & Oral Health |year=2020 |volume=3 |issue=3 |doi=10.33552/OJDOH.2020.03.000564}}</ref><ref name="Pessanha-Andrade2018">{{cite journal |last1=Pessanha-Andrade |first1=M |last2=Sordi |first2=MB |last3=Henriques |first3=B |last4=Silva |first4=FS |last5=Teughels |first5=W |last6=Souza |first6=JCM |title=Custom-made root-analogue zirconia implants: A scoping review on mechanical and biological benefits. |journal=J Biomed Mater Res B Appl Biomater. |year=2018 |volume=8 |issue=106 |pages=2888-2900 |doi=10.1002/jbm.b.34147 |pmid=30070423}}</ref>==
* Can be placed by any family dentist, requiring no specific surgical skills; there are no guidelines besides indications and contra-indications. The implant is placed with simple tools, typically in less than a minute.
* Can be placed by any family dentist, requiring no specific surgical skills; there are no guidelines besides indications and contra-indications. The implant is placed with simple tools, typically in less than a minute.
* Natural form: a custom milled anatomic implant replicates the natural form of a tooth, so it simply fits into the tooth socket. Like the original tooth, a root analogue implant can have single- and multi-rooted forms.
* Natural form: a custom milled anatomic implant replicates the natural form of a tooth, so it simply fits into the tooth socket. Like the original tooth, a root analogue implant can have single- and multi-rooted forms.
* Esthetic: a ceramic RAI closely resembles a natural tooth in color. Thus there is no discoloration through the gums, as is commonly seen with titanium implants.
* Esthetic: a ceramic RAI closely resembles a natural tooth in colour. Thus there is no discolouration through the gums, as is commonly seen with titanium implants.
* No drilling or surgery, or bone augmentation, is necessary. The patient never needs a sinus lift. There is no additional bone loss, in contrast to a conventional implant where bone must be drilled. No antibiotics are necessary.
* No drilling or surgery, or bone augmentation, is necessary. The patient never needs a sinus lift. There is no additional bone loss, in contrast to a conventional implant where bone must be drilled. No antibiotics are necessary.
* Extremely low risk of [[peri-implantitis]]: a conventional implant has a screw winding which is prone to peri-implantitis if it is exposed to the mouth environment. A RAI has none of these problems. Similarly, as it is a single piece implant, there are no gaps which can be infected.
* Extremely low risk of [[peri-implantitis]]: a conventional implant has a screw winding which is prone to peri-implantitis if it is exposed to the mouth environment. A RAI has none of these problems. Similarly, as it is a single piece implant, there are no gaps which can be infected.
* Immediate: a RAI is placed into a tooth socket immediately or the next day after tooth removal. Injury to neighboring roots, nerves or sinus is impossible.
* Immediate: a RAI is placed into a tooth socket immediately or the next day after tooth removal. Injury to neighbouring roots, nerves or sinus is impossible.
* Widely applicable: RAIs can be used in approximately 30% of cases, as opposed to 5% for conventional implants. The technology is completely open to all common methods of crown reconstruction.
* Widely applicable: RAIs can be used in approximately 30% of cases, as opposed to 5% for conventional implants. The technology is completely open to all common methods of crown reconstruction.
* The consequences in case of implant failure are minimal: the patient's anatomy has not been altered (the tooth socket is unchanged), so there is still the option to switch to a conventional treatment.<ref name="Pirker2011"/><ref name="Chong2020">{{cite journal |last1=Chong |first1=Chin Chen |last2=Pfaff |first2=Jacqueline A |title=Clinical Outcome of Root Analog Dental Zirconia Implants: A Systematic Literature Review |journal=Online Journal of Dentistry & Oral Health |year=2020 |volume=3 |issue=3 |doi=10.33552/OJDOH.2020.03.000564 |doi-access=free}}</ref><ref name="Pessanha-Andrade2018">{{cite journal |last1=Pessanha-Andrade |first1=M |last2=Sordi |first2=MB |last3=Henriques |first3=B |last4=Silva |first4=FS |last5=Teughels |first5=W |last6=Souza |first6=JCM |title=Custom-made root-analogue zirconia implants: A scoping review on mechanical and biological benefits. |journal=Journal of Biomedical Materials Research Part B: Applied Biomaterials |year=2018 |volume=8 |issue=106 |pages=2888–2900 |pmid=30070423 |doi=10.1002/jbm.b.34147 |s2cid=51894536}}</ref><ref name="Dantas2021"/>
* The consequences in case of implant failure are minimal: the patient's anatomy has not been altered (the tooth socket is unchanged), so there is still the option to switch to a conventional treatment.


==Risks and complications==
==Risks and complications==
Form alterations to the RAI, in conjunction with the pathology of patient, can only be carried out by a practitioner with the requisite knowledge, experience and skills.<ref name="Pour2019"></ref><ref name="Böse2020">{{cite journal |last1=Böse |first1=MWH |last2=Hildebrand |first2=D |last3=Beuer |first3=F |last4=Wesemann |first4=C |last5=Schwerdtner |first5=P |last6=Pieralli |first6=S |last7=Spies |first7=BC |title=Clinical Outcomes of Root-Analogue Implants Restored with Single Crowns or Fixed Dental Prostheses: A Retrospective Case Series. |journal=Journal of Clinical Medicine |year=2020 |volume=9 |issue=8 |pages=2346 |doi=10.3390/jcm9082346}}</ref> A failure rate of 10% appears high because of the wider [[Indication (medicine)|indications]] for this implant solution; almost all failures occur within the first 4 weeks. After this period, it is rare to have an implant fail.
Form alterations to the RAI, in conjunction with the pathology of patient, can only be carried out by a practitioner with the requisite knowledge, experience and skills.<ref name="Pour2019"/><ref name="Böse2020">{{cite journal |last1=Böse |first1=MWH |last2=Hildebrand |first2=D |last3=Beuer |first3=F |last4=Wesemann |first4=C |last5=Schwerdtner |first5=P |last6=Pieralli |first6=S |last7=Spies |first7=BC |title=Clinical Outcomes of Root-Analogue Implants Restored with Single Crowns or Fixed Dental Prostheses: A Retrospective Case Series. |journal=Journal of Clinical Medicine |year=2020 |volume=9 |issue=8 |pages=2346 |pmid=32717843 |doi=10.3390/jcm9082346 |doi-access=free |pmc=7465378}}</ref> A failure rate of 10% appears high because of the wider [[indication (medicine)|indications]] for this implant solution; almost all failures occur within the first 4 weeks. After this period, it is rare to have an implant fail.<ref name="Dantas2021"/>


==History==
==History==
Tooth loss is as old as humanity. Examples from history show that it has always made sense to replace a tooth with an implant that is shaped like a tooth.<ref name="Misch2015">{{cite book |last=Misch |first=Carl E |date=2015 |title=Dental Implant Prosthetics |edition=2nd |url=https://www.elsevier.com/books/dental-implant-prosthetics/9780323078450 |publisher=Mosby |isbn=9780323078450 |pages=26-45 |chapter=Chapter 2: Generic Root Form Component Terminology}}</ref> The earliest known dental implant, discovered in Honduras and dating from 600 AD, is that of a Mayan woman who had several implanted incisors carved from sea shells. At least one of these implants had osseointegrated.<ref name="Misch2015"></ref>
The earliest known dental implant, discovered in Honduras and dating to 600 AD, is that of a Mayan woman who had several implanted incisors carved from sea shells. At least one of these implants had osseointegrated.<ref name="Misch2015">{{cite book |last=Misch |first=Carl E |date=2015 |title=Dental Implant Prosthetics |edition=2nd |publisher=Mosby |isbn=9780323078450 |pages=26–45 |chapter=Chapter 2: Generic Root Form Component Terminology |url=https://www.elsevier.com/books/dental-implant-prosthetics/9780323078450}}</ref>


In modern times, a tooth replica implant in baboons was reported as early as 1969 by Hodosh and colleagues, but the polymethacrylate tooth analogue was encapsulated by soft tissue rather than osseointegrated.<ref>{{cite journal |last1=Hodosh |first1=M |last2=Povar |first2=M |last3=Shklar |first3=G |title=The dental polymer implant concept |journal=J. Prosthet. Dent. |year=1969 |volume=22 |issue=3 |pages=371–380 |doi=10.1016/0022-3913(69)90200-5}}</ref><ref>{{cite journal |last1=Hodosh |first1=M |last2=Shklar |first2=G |last3=Povar |first3=M |title=The porous vitreous carbon/polymethacrylate tooth implant: Preliminary studies |journal=J. Prosthet. Dent. |year=1974 |volume=32 |issue=3 |pages=326–334 |doi=10.1016/0022-3913(74)90037-7}}</ref>
An early example of a dental implant in Western Europe was the discovery of an iron pin in place of an upper incisor, in an Iron Age burial site in Le Chêne, France.<ref>{{cite journal |last1=Seguin |first1=Guillaume |last2=d’Incau |first2=Emmanuel |last3=Murail |first3=Pascal |last4=Maureille |first4=Bruno |title=The earliest dental prosthesis in Celtic Gaul? The case of an Iron Age burial at Le Chêne, France |journal=Antiquity |year=2014 |volume=88 |issue=340 |pages=488–500 |doi=10.1017/S0003598X00101139 |s2cid=162612447}}</ref> The body was that of a wealthy young woman; the iron pin may have been inserted while she was alive. However, the nature of the material (iron) and the lack of sterile conditions suggest that the implant would probably not have osseointegrated.<ref>{{Cite journal |title=he earliest dental prosthesis in Celtic Gaul? The case of an Iron Age burial at Le Chene, France |url=https://www.researchgate.net/publication/269098613 |journal=Journal of Prosthodontics}}</ref>


In modern times, a tooth replica implant in baboons was reported as early as 1969 by Hodosh and colleagues, but the polymethacrylate tooth analogue was encapsulated by soft tissue rather than osseointegrated.<ref>{{cite journal |last1=Hodosh |first1=M |last2=Povar |first2=M |last3=Shklar |first3=G |title=The dental polymer implant concept |journal=The Journal of Prosthetic Dentistry |year=1969 |volume=22 |issue=3 |pages=371–380 |pmid=4979523 |doi=10.1016/0022-3913(69)90200-5}}</ref><ref>{{cite journal |last1=Hodosh |first1=M |last2=Shklar |first2=G |last3=Povar |first3=M |title=The porous vitreous carbon/polymethacrylate tooth implant: Preliminary studies |journal=The Journal of Prosthetic Dentistry |year=1974 |volume=32 |issue=3 |pages=326–334 |pmid=4612143 |doi=10.1016/0022-3913(74)90037-7}}</ref>
In 1992 Lundgren and colleagues used root analogue titanium implants in an experimental model of immediate implant placement in dogs, with bony integration in 88% of cases<ref>{{cite journal |last1=Lundgren |first1=D |last2=Rylander |first2=H |last3=Andersson |first3=M |last4=Johansson |first4=M |last5=Albrektsson |first5=T |title=Healing-in of root analogue titanium implants placed in extraction sockets. An experimental study in the beagle dog. |journal=Clin Oral Implants Res. |year=1992 |volume=3 |issue=3 |pages=136-43 |pmid=1290794}}</ref>. A good fit between implant and bone was considered an important factor for implant success.


For this reason, Kohal et al. in 1997 further refined the approach of root-analogue titanium implants in monkeys by using slightly larger implants to compensate for the lost periodontal ligament. This provided a better fit between implant and extraction socket. In several instances implant insertion led to fractures of the thin buccal wall of the alveolar bone.<ref>{{cite journal |last1=Kohal |first1=RJ |last2=Hürzeler |first2=MB |last3=Mota |first3=LF |last4=Klaus |first4=G |last5=Caffesse |first5=RG |first6=Strub |last6= JR |title=Custom-made root analogue titanium implants placed into extraction sockets. An experimental study in monkeys. |journal=Clin Oral Implants Res. |volume=8 |issue=5 |pages=386-392 |pmid=9612143 }}</ref>
In 1992 Lundgren and colleagues used root analogue titanium implants in an experimental model of immediate implant placement in dogs, with bony integration in 88% of cases.<ref>{{cite journal |last1=Lundgren |first1=D |last2=Rylander |first2=H |last3=Andersson |first3=M |last4=Johansson |first4=M |last5=Albrektsson |first5=T |title=Healing-in of root analogue titanium implants placed in extraction sockets. An experimental study in the beagle dog. |journal=Clinical Oral Implants Research |year=1992 |volume=3 |issue=3 |pages=136–43 |pmid=1290794 |doi=10.1034/j.1600-0501.1992.030306.x}}</ref> A good fit between implant and bone was considered an important factor for implant success.


An ensuing clinical study in humans in 2002 with root-identical titanium implants showed excellent primary stability, but, disappointingly, nearly half the implants failed after 9 months. This particular implant system was not recommended for clinical use, and clinical trials were stopped.<ref>{{cite journal |last1=Heydecke |first1=G |last2=Kohal |first2=R |last3=Gläser |first3=R |title=Optimal Esthetics in Single-Tooth Replacement with the Re-Implant System: A Case Report |journal=Int J Prosthodont |year=1999 |volume=12 |issue=2 |pages=184-189 |pmid=10371922 }}</ref><ref>{{cite journal |last1=Kohal |first1=R |last2=Klaus |first2=G |last3=Strub |first3=J |title=Clinical investigation of a new dental immediate implant system. The ReImplant-System. |journal=Dtsch Zahnärztl Z. |year=2002 |volume=57 |issue=8 |pages=495-497 }}</ref>
For this reason, Kohal et al. in 1997 further refined the approach of root-analogue titanium implants in monkeys by using slightly larger implants to compensate for the lost periodontal ligament. This provided a better fit between implant and extraction socket. In several instances implant insertion led to fractures of the thin buccal wall of the alveolar bone.<ref>{{cite journal |last1=Kohal |first1=RJ |last2=Hürzeler |first2=MB |last3=Mota |first3=LF |last4=Klaus |first4=G |last5=Caffesse |first5=RG |first6=Strub |last6=JR |title=Custom-made root analogue titanium implants placed into extraction sockets. An experimental study in monkeys. |journal=Clinical Oral Implants Research |year=1997 |volume=8 |issue=5 |pages=386–392 |pmid=9612143 |doi=10.1034/j.1600-0501.1997.080505.x |doi-access=free}}</ref>


An ensuing clinical study in humans in 2002 with root-identical titanium implants showed excellent primary stability, but, disappointingly, nearly half the implants failed after 9 months. This particular implant system was not recommended for clinical use, and clinical trials were stopped.<ref>{{cite journal |last1=Heydecke |first1=G |last2=Kohal |first2=R |last3=Gläser |first3=R |title=Optimal Esthetics in Single-Tooth Replacement with the Re-Implant System: A Case Report |journal=The International Journal of Prosthodontics |year=1999 |volume=12 |issue=2 |pages=184–189 |pmid=10371922}}</ref><ref>{{cite journal |last1=Kohal |first1=R |last2=Klaus |first2=G |last3=Strub |first3=J |title=Clinical investigation of a new dental immediate implant system. The ReImplant-System. |journal=Deutsche Zahnärztliche Zeitschrift |year=2002 |volume=57 |issue=8 |pages=495–497}}</ref>
A new attempt was made by Pirker et al 2004 in a human trial with root analogue zirconia implants, but this time by applying differentiated osseoingration on the surface. In 2011 he reported 90% success rate with this method in a 2.5 year human trial.<ref name="Pirker2011"></ref>


A new attempt was made by Pirker et al 2004 in a human trial with root analogue zirconia implants, but this time by applying differentiated osseoingration on the surface. In 2011 he reported 90% success rate with this method in a 2.5 year human trial.<ref name="Pirker2011"/>
Mangano et al in Italy in 2012 reported the successful clinical use of a custom-made root analogue implant made by direct laser metal forming (DLMF) from a CBCT scan. This demonstrated that it is possible to combine CBCT 3D data and CAD/CAM technology to manufacture root-analogue implants with sufficient precision.<ref name="Mangano2012">{{cite journal |last1=Mangano |first1=F |last2=Cirotti |first2=B |last3=Sammons |first3=R |last4=Mangano |first4=C |title=Custom-made, root-analogue direct laser metal forming implant: a case report |journal=Lasers Med Sci |year=2012 |volume=27 |pages=1241-1245 |doi=10.1007/s10103-012-1134-z}}</ref>


In 2012 Moin et al in The Netherlands investigated the accuracy of CBCT and CAD/CAM technology on individual root analogue implants, and concluded that this technique could potentially provide accurate dental implants for immediate placement.<ref name="Moin2013">{{cite journal |last1=Anssari Moin |first1=D |last2=Hassan |first2=B |last3=Mercelis |first3=P |last4=Wismeijer |first4=D |title=Designing a novel dental root analogue implant using cone beam computed tomography and CAD/CAM technology |journal=Clin. Oral Imp. Res. |year=2013 |volume=24 |pages=25–27 |doi=10.1111/j.1600-0501.2011.02359.x}}</ref>
Mangano et al in Italy in 2012 reported the successful clinical use of a custom-made root analogue implant made by direct laser metal forming (DLMF) from a CBCT scan. This demonstrated that it is possible to combine CBCT 3D data and CAD/CAM technology to manufacture root-analogue implants with sufficient precision.<ref name="Mangano2012">{{cite journal |last1=Mangano |first1=F |last2=Cirotti |first2=B |last3=Sammons |first3=R |last4=Mangano |first4=C |title=Custom-made, root-analogue direct laser metal forming implant: a case report |journal=Lasers in Medical Science |year=2012 |volume=27 |issue=6 |pages=1241–1245 |pmid=22699801 |doi=10.1007/s10103-012-1134-z |s2cid=9676516}}</ref>


Pour et al in Germany reported a single tooth replacement with a root-analog hybrid implant in 2017, using a titanium implant fused with a ceramic cover in the esthetic zone.<ref>{{cite journal |last1=Pour |first1=RS |last2=Randelzhofer |first2=P |last3=Edelhoff |first3=D |last4=Prandtner |first4=O |last5=Rafael |first5=CF |last6=Liebermann |first6=A |title=Innovative Single-Tooth Replacement with an Individual Root-Analog Hybrid Implant in the Esthetic Zone: Case Report |journal=Int J Oral Maxillofac Implants |year=2017 |volume=32 |pages=e153-e160 |doi=10.11607/jomi.5562}}</ref>
In 2012 Moin et al in The Netherlands investigated the accuracy of CBCT and CAD/CAM technology on individual root analogue implants, and concluded that this technique could potentially provide accurate dental implants for immediate placement.<ref name="Moin2013">{{cite journal |last1=Anssari Moin |first1=D |last2=Hassan |first2=B |last3=Mercelis |first3=P |last4=Wismeijer |first4=D |title=Designing a novel dental root analogue implant using cone beam computed tomography and CAD/CAM technology |journal=Clinical Oral Implants Research |year=2013 |volume=24 |pages=25–27 |pmid=22092354 |doi=10.1111/j.1600-0501.2011.02359.x |doi-access=free}}</ref>

Pour et al in Germany reported a single tooth replacement with a root-analogue hybrid implant in 2017, using a titanium implant fused with a ceramic cover in the esthetic zone.<ref>{{cite journal |last1=Pour |first1=RS |last2=Randelzhofer |first2=P |last3=Edelhoff |first3=D |last4=Prandtner |first4=O |last5=Rafael |first5=CF |last6=Liebermann |first6=A |title=Innovative Single-Tooth Replacement with an Individual Root-Analog Hybrid Implant in the Esthetic Zone: Case Report |journal=The International Journal of Oral & Maxillofacial Implants |year=2017 |volume=32 |issue=3 |pages=e153–e160 |pmid=28494041 |doi=10.11607/jomi.5562}}</ref>


==Current research and commercial success==
==Current research and commercial success==
Successful RAIs are a relatively young technology. In contrast to conventional geometric implants, only a handful of scientific groups have carried out any work in this area since 1964. There are ongoing efforts to combine CBCT scans with CAD/CAM technology, which would lead to further breakthroughs in this field.<ref name="Mangano2012"></ref><ref name="Moin2013"></ref>
Successful RAIs are a relatively young technology. In contrast to conventional geometric implants, only a handful of scientific groups have carried out any work in this area since 1964. Reliable data on the long-term use of RAIs in humans are still scarce.<ref name="Dantas2021"/> There are ongoing efforts to combine CBCT scans with CAD/CAM technology, which would lead to further breakthroughs in this field.<ref name="Mangano2012"/><ref name="Moin2013"/>

Various techniques are being devised to test the mechanical properties of RAIs, to assess their mechanical and biological safety.<ref>{{cite journal |last1=Lee |first1=Jungwon |last2=Seol |first2=Yang-Jo |last3=Lee |first3=Yong-Moo |last4=Koo |first4=Ki-Tae |title=A Narrative Review of Contemporary Evaluation Methods for Root Analog Implants |journal=Journal of Implantology and Applied Sciences |year=2022 |volume=26 |issue=1 |pages=51–72 |doi=10.32542/implantology.2022005 |doi-access=free |s2cid=248033256}}</ref> Several existing evaluation methods for conventional thread-type implants do not apply to RAIs because of their structural differences.

There is increasing concern in implantology about esthetics, biocompatibility, and the corrosive behaviour of materials.<ref name="Dantas2021"/><ref name="Pour2019"/> While custom root analogue zirconia implants offer significant benefits over conventional titanium implants, and follow-up studies with patients show high success rates and satisfactory esthetic results,<ref name="Dantas2021"/><ref name="Chong2020"/><ref name="Böse2020"/> further studies are needed to evaluate surface-bone interactions and mechanical behaviour of zirconia.<ref name="Pour2019"/><ref name="Chong2020"/><ref name="Pessanha-Andrade2018"/>

A number of root analogue dental implant systems have become commercially available, with varying degrees of success.<ref name="Pour2019"/> However, so far, no root analogue dental implant system has received [[regulation of therapeutic goods|regulatory approval]]. Despite satisfactory clinical results, none of these solutions is widely available on the market.<ref name="Dantas2021"/>


A commercially available root-analog dental implant was withdrawn from the market in 2019.<ref name="Pour2019"/>
There is increasing concern in implantology about esthetics, biocompatibility, and the corrosive behaviour of materials.<ref name="Pour2019"></ref> While custom root analogue zirconia implants offer significant benefits over conventional titanium implants, and follow-up studies with patients show high success rates and satisfactory esthetic results<ref name="Chong2020"></ref><ref name="Böse2020"></ref>, further studies are needed to evaluate surface-bone interactions and mechanical behavior of zirconia.<ref name="Pour2019"></ref><ref name="Chong2020"></ref><ref name="Pessanha-Andrade2018"></ref>


Nevertheless, modern CAD/CAM solutions appear to be the future for custom dental implants.<ref name="Dantas2021"/>
A number of root analogue dental implant systems have become commercially available, with varying degrees of success.<ref name="Pour2019"></ref> However, so far, no root analogue dental implant system has received [[Regulation of therapeutic goods|regulatory approval]].


==References==
==References==
{{Reflist|30em}}
{{Reflist|30em}}


{{Commons-inline|Root analogue dental implant}}
[[:Category:Implants (medicine)]]
[[:Category:Dental equipment]]
[[:Category:Restorative dentistry]]
[[:Category:Prosthetics]]
[[:Category:Oral surgery]]
[[:Category:Prosthodontology]]


[[Category:Dental equipment]]
== Root analogue dental implants ==
[[Category:Dental surgical procedures]]
[[Category:Implants (medicine)]]
[[Category:Prosthetics]]
[[Category:Prosthodontology]]
[[Category:Restorative dentistry]]

Latest revision as of 05:20, 16 November 2024

A root-analogue dental implant (RAI) – also known as a truly anatomic dental implant, or an anatomical/custom implant – is a medical device to replace one or more roots of a single tooth immediately after extraction.[1] In contrast to common titanium screw type implants, these implants are custom-made to exactly match the extraction socket of the specific patient. Thus there is usually no need for surgery.[2]

As the root analogue dental implant matches the dental alveolus (tooth socket) it can only be placed immediately after the tooth extraction. If the tooth has been already lost and the soft and hard tissue is already healed, an RAI can no longer be placed.[1]

The basic principle of endosseous implants is a biological process described as osseointegration, in which materials such as titanium or ceramic form an intimate bond to bone.[3][4] There are no particular differences between the osseointegration of a root analogue implant and a conventional screw type implant.

Disadvantages of conventional implants

[edit]
Root Analogue Dental Implant
Root analogue ceramic dental implant in comparison with titanium screw type implant

As technology has improved, so has implant success rate. Conventional titanium dental implants typically have success rates of 90–95% for 10-year follow-up periods, but this is based on questionable definitions of success.[5] The fundamental problem with conventional implant technology is that the patient must be altered to fit the screw or cylinder implant, rather than the other way around.

A tooth has one or more roots.[6] Even a single-rooted tooth is nearly twice as wide in one direction as in the other. A cylindrical screw-type implant does not resemble a tooth, so invasive surgery is needed to make it fit into an existing tooth socket. Such surgery involves drilling into healthy bone, filling gaps between implant and bone either with bone or bone substitutes, and frequently sinus lift procedures.

Titanium screws are prone to peri-implantitis[5] and plaque accumulation, leading to further interventions. The grey colour of titanium tends to show through gums,[7] and in case of gum and bone recession, esthetic outcome is often highly unpredictable. Moreover, there are concerns over possible long-term corrosion and release of ions to the body environment, so researchers are evaluating non-metallic alternatives.[5]

Root analogue implants

[edit]
Illustration showing comparison of screw type implant with root analogue implant
X-rays of root analogue dental implants in different regions
X-ray of root analogue dental implant single rooted right lower second premolar
X-ray of root analogue dental implant single rooted right lower second premolar
X-ray of root analogue dental implant two rooted left lower molar
X-ray of root analogue dental implant two rooted left lower molar
X-ray of root analogue three rooted dental implant right first upper molar
X-ray of root analogue three rooted dental implant right first upper molar

RAIs are custom made to perfectly fit the tooth socket of a specific patient immediately after tooth extraction. Therefore every implant is unique. As an optimised root-form it is much more than a simple 1:1 replica of a tooth. Since it exactly fills the gap left after the tooth is extracted, surgery is rarely needed. The implant can be produced from a copy of the extracted tooth, an impression of the tooth socket, or from a CT scan or CBCT scan.[8] The advantage of a CBCT scan is that the implant can be produced before extraction. With the former methods, it takes one or two days to fabricate an implant.

A root analogue implant can be fabricated from zirconium dioxide (zirconia) or titanium.[9] Successful titanium RAIs have been three-dimensionally printed as porous one-piece implants, using CAD software.[10] However, zirconia is the preferred material, because it is more esthetic in colour, with no grey discolouration visible through gums.[11][5]

Zirconium dioxide is doped with small amounts of yttria, which results in a material with superior thermal, mechanical, and electrical properties, and enhanced fracture toughness – ideal for surgical implants.[12][13] Zirconia is metal free and is biocompatible, and has low bacterial affinity in comparison to regular titanium.[5]

An alternative technique uses a titanium root fused to a zirconia abutment by a sintering process that eliminates any possible microgap (which could cause peri-implantitis, leading to bone loss around the implant).[14]

True 'root-form analogue' or 'anatomic' dental implants have been attempted in the past. Those early attempts failed because of insufficient knowledge of healing of cortical and spongy bone, method, material, tooling, and technology. The principle of differentiated osseointegration, in conjunction with suitable material and technology, has enabled the first success in this field[15][16][17]

The principle of "differentiated osseointegration"

[edit]

Differentiated osseointegration[18] describes the guided equilibrium of bone-to-implant distance, contact and compression, taking into account spongy or cortical bone, in order to achieve secure osseointegration of individual anatomical dental implants.

The design of the implant surface is crucial in integrating all three possible primary bone-to-implant contact scenarios:

  • Contact in the area of the exact root replica, for an immediate start of primary osseointegration without bone trauma;
  • Distance at the thin buccal and lingual cortical plates, to safely avoid fracture and pressure resorption of this sensitive bone;
  • Compression with macro retentions only in areas of spongy bone to maintain safe primary stability during the entire osseointegration phase.

The combination of all these factors is the most important condition for osseointegration of anatomically shaped dental implants.

Technique

[edit]
Video showing placement of root analogue ceramic dental implant without surgery, and outcome at one year follow-up
X-ray of root analogue dental implant corresponding to above surgical video

Treatment consists of three steps:[5]

  • Obtain the 3D form of the tooth to be replaced. This is done either through careful tooth extraction and scanning of the root, taking an impression of the tooth socket, or a pre-op CBCT scan. The root analogue implant is produced using modern CAD/CAM technology, based on the principle of differentiated osseointegration;
  • Atraumatic extraction of the hopeless tooth;
  • Placement of the root analogue implant by tapping it in. In general, no surgery is necessary. In particular, no sinus lift or invasive surgery is ever necessary. The implant is placed immediately if it has been produced beforehand from a CBCT scan, or the next day if root has to be scanned or an impression of the socket is used. A protective splint is fitted to protect the implant during the healing period.

Recovery time is very fast as neither soft nor hard tissue is traumatised. Typically, even the day after implant placement there is no swelling, bruising or pain. After 8–12 weeks' healing period, the final crown may be fitted by a family dentist.

Advantages

[edit]
  • Can be placed by any family dentist, requiring no specific surgical skills; there are no guidelines besides indications and contra-indications. The implant is placed with simple tools, typically in less than a minute.
  • Natural form: a custom milled anatomic implant replicates the natural form of a tooth, so it simply fits into the tooth socket. Like the original tooth, a root analogue implant can have single- and multi-rooted forms.
  • Esthetic: a ceramic RAI closely resembles a natural tooth in colour. Thus there is no discolouration through the gums, as is commonly seen with titanium implants.
  • No drilling or surgery, or bone augmentation, is necessary. The patient never needs a sinus lift. There is no additional bone loss, in contrast to a conventional implant where bone must be drilled. No antibiotics are necessary.
  • Extremely low risk of peri-implantitis: a conventional implant has a screw winding which is prone to peri-implantitis if it is exposed to the mouth environment. A RAI has none of these problems. Similarly, as it is a single piece implant, there are no gaps which can be infected.
  • Immediate: a RAI is placed into a tooth socket immediately or the next day after tooth removal. Injury to neighbouring roots, nerves or sinus is impossible.
  • Widely applicable: RAIs can be used in approximately 30% of cases, as opposed to 5% for conventional implants. The technology is completely open to all common methods of crown reconstruction.
  • The consequences in case of implant failure are minimal: the patient's anatomy has not been altered (the tooth socket is unchanged), so there is still the option to switch to a conventional treatment.[17][19][20][5]

Risks and complications

[edit]

Form alterations to the RAI, in conjunction with the pathology of patient, can only be carried out by a practitioner with the requisite knowledge, experience and skills.[14][21] A failure rate of 10% appears high because of the wider indications for this implant solution; almost all failures occur within the first 4 weeks. After this period, it is rare to have an implant fail.[5]

History

[edit]

The earliest known dental implant, discovered in Honduras and dating to 600 AD, is that of a Mayan woman who had several implanted incisors carved from sea shells. At least one of these implants had osseointegrated.[22]

An early example of a dental implant in Western Europe was the discovery of an iron pin in place of an upper incisor, in an Iron Age burial site in Le Chêne, France.[23] The body was that of a wealthy young woman; the iron pin may have been inserted while she was alive. However, the nature of the material (iron) and the lack of sterile conditions suggest that the implant would probably not have osseointegrated.[24]

In modern times, a tooth replica implant in baboons was reported as early as 1969 by Hodosh and colleagues, but the polymethacrylate tooth analogue was encapsulated by soft tissue rather than osseointegrated.[25][26]

In 1992 Lundgren and colleagues used root analogue titanium implants in an experimental model of immediate implant placement in dogs, with bony integration in 88% of cases.[27] A good fit between implant and bone was considered an important factor for implant success.

For this reason, Kohal et al. in 1997 further refined the approach of root-analogue titanium implants in monkeys by using slightly larger implants to compensate for the lost periodontal ligament. This provided a better fit between implant and extraction socket. In several instances implant insertion led to fractures of the thin buccal wall of the alveolar bone.[28]

An ensuing clinical study in humans in 2002 with root-identical titanium implants showed excellent primary stability, but, disappointingly, nearly half the implants failed after 9 months. This particular implant system was not recommended for clinical use, and clinical trials were stopped.[29][30]

A new attempt was made by Pirker et al 2004 in a human trial with root analogue zirconia implants, but this time by applying differentiated osseoingration on the surface. In 2011 he reported 90% success rate with this method in a 2.5 year human trial.[17]

Mangano et al in Italy in 2012 reported the successful clinical use of a custom-made root analogue implant made by direct laser metal forming (DLMF) from a CBCT scan. This demonstrated that it is possible to combine CBCT 3D data and CAD/CAM technology to manufacture root-analogue implants with sufficient precision.[31]

In 2012 Moin et al in The Netherlands investigated the accuracy of CBCT and CAD/CAM technology on individual root analogue implants, and concluded that this technique could potentially provide accurate dental implants for immediate placement.[32]

Pour et al in Germany reported a single tooth replacement with a root-analogue hybrid implant in 2017, using a titanium implant fused with a ceramic cover in the esthetic zone.[33]

Current research and commercial success

[edit]

Successful RAIs are a relatively young technology. In contrast to conventional geometric implants, only a handful of scientific groups have carried out any work in this area since 1964. Reliable data on the long-term use of RAIs in humans are still scarce.[5] There are ongoing efforts to combine CBCT scans with CAD/CAM technology, which would lead to further breakthroughs in this field.[31][32]

Various techniques are being devised to test the mechanical properties of RAIs, to assess their mechanical and biological safety.[34] Several existing evaluation methods for conventional thread-type implants do not apply to RAIs because of their structural differences.

There is increasing concern in implantology about esthetics, biocompatibility, and the corrosive behaviour of materials.[5][14] While custom root analogue zirconia implants offer significant benefits over conventional titanium implants, and follow-up studies with patients show high success rates and satisfactory esthetic results,[5][19][21] further studies are needed to evaluate surface-bone interactions and mechanical behaviour of zirconia.[14][19][20]

A number of root analogue dental implant systems have become commercially available, with varying degrees of success.[14] However, so far, no root analogue dental implant system has received regulatory approval. Despite satisfactory clinical results, none of these solutions is widely available on the market.[5]

A commercially available root-analog dental implant was withdrawn from the market in 2019.[14]

Nevertheless, modern CAD/CAM solutions appear to be the future for custom dental implants.[5]

References

[edit]
  1. ^ a b Liu, Hui; Xuan Gan, Ming; Zhai, Wei; Song, Xu (2023-12-01). "Design and additive manufacturing of root analogue dental implants: A comprehensive review". Materials & Design. 236: 112462. doi:10.1016/j.matdes.2023.112462. ISSN 0264-1275.
  2. ^ Dantas, Telma; Rodrigues, Flávio; Araújo, João; Vaz, Paula; Silva, Filipe (2022-09-01). "Customized root-analogue dental implants - Procedure and errors associated with image acquisition, treatment, and manufacturing technology in an experimental study on a cadaver dog mandible". Journal of the Mechanical Behavior of Biomedical Materials. 133: 105350. doi:10.1016/j.jmbbm.2022.105350. ISSN 1751-6161. PMID 35792351.
  3. ^ Ramazanoglu, Mustafa; Oshida, Yoshiki (2011-08-29), "Osseointegration and Bioscience of Implant Surfaces - Current Concepts at Bone-Implant Interface", Implant Dentistry - A Rapidly Evolving Practice, IntechOpen, ISBN 978-953-307-658-4, retrieved 2024-07-19
  4. ^ "What are dental implants?". Valley Dental - Fortitude Valley, Brisbane. Retrieved 2024-07-19.
  5. ^ a b c d e f g h i j k l m Dantas, T; Madeira, S; Gasik, M; Vaz, P; Silva, F (2021). "Customized Root-Analogue Implants: A Review on Outcomes from Clinical Trials and Case Reports". Materials. 14 (April): 2296. Bibcode:2021Mate...14.2296D. doi:10.3390/ma14092296. hdl:1822/73882. PMC 8124429. PMID 33946678.
  6. ^ "Tooth Root - an overview | ScienceDirect Topics". www.sciencedirect.com. Retrieved 2024-07-19.
  7. ^ Cai, H; Chen, J; Li, C; Wang, J; Wan, Q; Liang, X (2018). "Quantitative discoloration assessment of peri-implant soft tissue around zirconia and other abutments with different colours: A systematic review and meta-analysis". Journal of Dentistry. 70 (Mar): 110–117. doi:10.1016/j.jdent.2018.01.003. PMID 29371043.
  8. ^ Evans, Zachary P.; Renne, Walter G.; Bacro, Thierry R.; Mennito, Anthony S.; Ludlow, Mark E.; Lecholop, Michael K. (2018). "Anatomic Customization of Root-Analog Dental Implants With Cone-Beam CT and CAD/CAM Fabrication: A Cadaver-Based Pilot Evaluation". Journal of Oral Implantology. 44 (1): 15–25. doi:10.1563/aaid-joi-D-17-00090. PMID 29064779.
  9. ^ Cionca, Norbert; Hashim, Dena; Mombelli, Andrea (21 December 2016). "Zirconia dental implants: where are we now, and where are we heading?". Periodontology 2000. 73 (1): 241–258. doi:10.1111/prd.12180. ISSN 0906-6713. PMID 28000266.
  10. ^ Liu, Changkui; Huang, Shuo; Guo, Fang; Li, Yongfeng; Zhao, Bingjing; Luo, Aimin; Liu, Huawei; Wang, Chao; Hu, Min; Zhou, Hongzhi (2022). "Immediate, non-submerged, three-dimensionally printed, one-piece mandibular molar porous root-analogue titanium implants: A 2-year prospective study involving 18 patients". Journal of Stomatology, Oral and Maxillofacial Surgery. 123 (6): e770–e776. doi:10.1016/j.jormas.2022.05.019. PMID 35598871. S2CID 248954114.
  11. ^ Happe, Arndt; Schulte-Mattler, Verena; Strassert, Christian; Naumann, Michael; Stimmelmayr, Michael; Zoller, Joachim; Rothamel, Daniel (2013). "In Vitro Color Changes of Soft Tissues Caused by Dyed Fluorescent Zirconia and Nondyed, Nonfluorescent Zirconia in Thin Mucosa". The International Journal of Periodontics & Restorative Dentistry. 33 (1): e1-8. doi:10.11607/prd.1303. PMID 23342353.
  12. ^ Gautam, C; Joyner, Jarin; Gautam, Amarendra; Rao, Jitendra; Vajtai, Robert (2016). "Zirconia Based Dental Ceramics: Structure, Mechanical Properties, Biocompatibility and Applications". Dalton Transactions. 45 (11): 19194–19215. doi:10.1039/C6DT03484E. PMID 27892564.
  13. ^ El-Ghany, Ossama Saleh Abd; Sherief, Ashraf Husein (2016). "Zirconia based ceramics, some clinical and biological aspects: Review". Future Dental Journal. 2 (2): 55–64. doi:10.1016/j.fdj.2016.10.002.
  14. ^ a b c d e f Saeidi Pour, R.; Freitas Rafael, C.; Engler, M.L.P.D.; Edelhoff, D.; Klaus, G.; Prandtner, O.; Berthold, M.; Liebermann, A. (2019). "Historical development of root analogue implants: a review of published papers". British Journal of Oral and Maxillofacial Surgery. 57 (6): 496–504. doi:10.1016/j.bjoms.2019.01.021. PMID 31085016. S2CID 155089688.
  15. ^ Pirker, W; Kocher, A (2008). "Immediate, non-submerged, root-analogue zirconia implant in single tooth replacement". International Journal of Oral and Maxillofacial Surgery. 37 (3): 293–5. doi:10.1016/j.ijom.2007.11.008. PMID 18272340.
  16. ^ Pirker, W; Kocher, A (2009). "Immediate, non-submerged, root-analogue zirconia implants placed into single-rooted extraction sockets: 2-year follow-up of a clinical study". International Journal of Oral and Maxillofacial Surgery. 38 (11): 1127–32. doi:10.1016/j.ijom.2009.07.008. PMID 19665354.
  17. ^ a b c Pirker, W; Wiedemann, D; Lidauer, A; Kocher, A (2011). "Immediate, single stage, truly anatomic zirconia implant in lower molar replacement: a case report with 2.5 years follow-up". International Journal of Oral and Maxillofacial Surgery. 40 (2): 212–6. doi:10.1016/j.ijom.2010.08.003. PMID 20833511.
  18. ^ Pirker, W; Kocher, A (2009). "True Anatomic Immediate Dental Implant Method: A Clinical Case". International Magazine of Oral Implantology (4): 10–14.
  19. ^ a b c Chong, Chin Chen; Pfaff, Jacqueline A (2020). "Clinical Outcome of Root Analog Dental Zirconia Implants: A Systematic Literature Review". Online Journal of Dentistry & Oral Health. 3 (3). doi:10.33552/OJDOH.2020.03.000564.
  20. ^ a b Pessanha-Andrade, M; Sordi, MB; Henriques, B; Silva, FS; Teughels, W; Souza, JCM (2018). "Custom-made root-analogue zirconia implants: A scoping review on mechanical and biological benefits". Journal of Biomedical Materials Research Part B: Applied Biomaterials. 8 (106): 2888–2900. doi:10.1002/jbm.b.34147. PMID 30070423. S2CID 51894536.
  21. ^ a b Böse, MWH; Hildebrand, D; Beuer, F; Wesemann, C; Schwerdtner, P; Pieralli, S; Spies, BC (2020). "Clinical Outcomes of Root-Analogue Implants Restored with Single Crowns or Fixed Dental Prostheses: A Retrospective Case Series". Journal of Clinical Medicine. 9 (8): 2346. doi:10.3390/jcm9082346. PMC 7465378. PMID 32717843.
  22. ^ Misch, Carl E (2015). "Chapter 2: Generic Root Form Component Terminology". Dental Implant Prosthetics (2nd ed.). Mosby. pp. 26–45. ISBN 9780323078450.
  23. ^ Seguin, Guillaume; d’Incau, Emmanuel; Murail, Pascal; Maureille, Bruno (2014). "The earliest dental prosthesis in Celtic Gaul? The case of an Iron Age burial at Le Chêne, France". Antiquity. 88 (340): 488–500. doi:10.1017/S0003598X00101139. S2CID 162612447.
  24. ^ "he earliest dental prosthesis in Celtic Gaul? The case of an Iron Age burial at Le Chene, France". Journal of Prosthodontics.
  25. ^ Hodosh, M; Povar, M; Shklar, G (1969). "The dental polymer implant concept". The Journal of Prosthetic Dentistry. 22 (3): 371–380. doi:10.1016/0022-3913(69)90200-5. PMID 4979523.
  26. ^ Hodosh, M; Shklar, G; Povar, M (1974). "The porous vitreous carbon/polymethacrylate tooth implant: Preliminary studies". The Journal of Prosthetic Dentistry. 32 (3): 326–334. doi:10.1016/0022-3913(74)90037-7. PMID 4612143.
  27. ^ Lundgren, D; Rylander, H; Andersson, M; Johansson, M; Albrektsson, T (1992). "Healing-in of root analogue titanium implants placed in extraction sockets. An experimental study in the beagle dog". Clinical Oral Implants Research. 3 (3): 136–43. doi:10.1034/j.1600-0501.1992.030306.x. PMID 1290794.
  28. ^ Kohal, RJ; Hürzeler, MB; Mota, LF; Klaus, G; Caffesse, RG; JR, Strub (1997). "Custom-made root analogue titanium implants placed into extraction sockets. An experimental study in monkeys". Clinical Oral Implants Research. 8 (5): 386–392. doi:10.1034/j.1600-0501.1997.080505.x. PMID 9612143.
  29. ^ Heydecke, G; Kohal, R; Gläser, R (1999). "Optimal Esthetics in Single-Tooth Replacement with the Re-Implant System: A Case Report". The International Journal of Prosthodontics. 12 (2): 184–189. PMID 10371922.
  30. ^ Kohal, R; Klaus, G; Strub, J (2002). "Clinical investigation of a new dental immediate implant system. The ReImplant-System". Deutsche Zahnärztliche Zeitschrift. 57 (8): 495–497.
  31. ^ a b Mangano, F; Cirotti, B; Sammons, R; Mangano, C (2012). "Custom-made, root-analogue direct laser metal forming implant: a case report". Lasers in Medical Science. 27 (6): 1241–1245. doi:10.1007/s10103-012-1134-z. PMID 22699801. S2CID 9676516.
  32. ^ a b Anssari Moin, D; Hassan, B; Mercelis, P; Wismeijer, D (2013). "Designing a novel dental root analogue implant using cone beam computed tomography and CAD/CAM technology". Clinical Oral Implants Research. 24: 25–27. doi:10.1111/j.1600-0501.2011.02359.x. PMID 22092354.
  33. ^ Pour, RS; Randelzhofer, P; Edelhoff, D; Prandtner, O; Rafael, CF; Liebermann, A (2017). "Innovative Single-Tooth Replacement with an Individual Root-Analog Hybrid Implant in the Esthetic Zone: Case Report". The International Journal of Oral & Maxillofacial Implants. 32 (3): e153–e160. doi:10.11607/jomi.5562. PMID 28494041.
  34. ^ Lee, Jungwon; Seol, Yang-Jo; Lee, Yong-Moo; Koo, Ki-Tae (2022). "A Narrative Review of Contemporary Evaluation Methods for Root Analog Implants". Journal of Implantology and Applied Sciences. 26 (1): 51–72. doi:10.32542/implantology.2022005. S2CID 248033256.

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