Customized Root-Analogue Implants: A Review on Outcomes from Clinical Trials and Case Reports

Dantas, T.A.; Madeira, S.; Gasik, Michael; Silva, Filipe

doi:10.3390/ma14092296

Cited by 15 publications

(17 citation statements)

References 50 publications

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“…Due to deviations in precision, some researchers have incremented implant CAD models by dimension percentages (0%, 5%, and 10%) for clinical applications (F. G. Mangano F. G. et al, 2013). Another technique involves laser scanning of the root to construct the final implant after extraction, and design of macroretainers on the implant surface to increase its stability following placement (Dantas et al, 2021). Another class of implants, referred to as patient-matched implants, are less personalized than 3D printed root-analogue implants; for example, some scholars have used 3D printing to generate narrow-diameter implants for patients with insufficient alveolar bone width (F. Mangano et al, 2013b).…”

Section: Dental Implantsmentioning

confidence: 99%

Additive manufacturing technologies in the oral implant clinic: A review of current applications and progress

Huang

Wei

2023

Front. Bioeng. Biotechnol.

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Additive manufacturing (AM) technologies can enable the direct fabrication of customized physical objects with complex shapes, based on computer-aided design models. This technology is changing the digital manufacturing industry and has become a subject of considerable interest in digital implant dentistry. Personalized dentistry implant treatments for individual patients can be achieved through Additive manufacturing. Herein, we review the applications of Additive manufacturing technologies in oral implantology, including implant surgery, and implant and restoration products, such as surgical guides for implantation, custom titanium meshes for bone augmentation, personalized or non-personalized dental implants, custom trays, implant casts, and implant-support frameworks, among others. In addition, this review also focuses on Additive manufacturing technologies commonly used in oral implantology. Stereolithography, digital light processing, and fused deposition modeling are often used to construct surgical guides and implant casts, whereas direct metal laser sintering, selective laser melting, and electron beam melting can be applied to fabricate dental implants, personalized titanium meshes, and denture frameworks. Moreover, it is sometimes required to combine Additive manufacturing technology with milling and other cutting and finishing techniques to ensure that the product is suitable for its final application.

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Section: Dental Implantsmentioning

confidence: 99%

Additive manufacturing technologies in the oral implant clinic: A review of current applications and progress

Huang

Wei

2023

Front. Bioeng. Biotechnol.

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“…E 1 is in the mesiodistal direction, E 2 is in the buccal-lingual direction, and E 3 is in the direction of the mandible and maxilla. The initial densities of cancellous and cortical bones were set to 0.80 and 1.74 g/cm 3 , respectively.…”

Section: Establishment Of the Finite Element Modelmentioning

confidence: 99%

“…Dental implants have been widely used since the 1960s, although preformed implants are becoming increasingly difficult to adapt to the individual conditions of patients with the development of noninvasive and precision medicine. [1][2][3] With novel manufacturing technology, customized root implants (CRIs) based on the anatomical features of teeth can be produced by electron beam melting (EBM). 4 The customized design of the implant and the abutment has reduced the complexity of the prosthetic steps required.…”

mentioning

confidence: 99%

“…5,6 In clinical practice, the CRI adapts well to the soft and hard tissues of the patient because it is based on the anatomy of a natural root. 3 Mangano et al investigated the clinical effect of 15 CRIs prepared by direct laser metal sintering and found that there was no loosening or infection in any of the implants at the 1-year follow-up. 7 Liu et al confirmed the effect of porous microstructures on osseointegration of customized root dental implants through animal experiments.…”

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confidence: 99%

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Biomechanical evaluation of customized root implants in alveolar bone: A comparative study with traditional implants and natural teeth

Zhang

Wang

et al. 2022

Journal of Prosthodontics

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Purpose To compare and evaluate density changes in alveolar bones and biomechanical responses including stress/strain distributions around customized root implants (CRIs), traditional implants, and natural teeth. Materials and methods A three‐dimensional finite element model of the maxillary dentition defect, CRI models, traditional restored implant models, and natural teeth with periodontal tissue models were established. The chewing load of the central incisor, the traditional implant, and the CRI was 100N, and the load direction was inclined by 11° in the sagittal plane. According to the bone remodeling numerical algorithm, the bone mineral density and distribution were calculated and predicted. In addition, animal experiments were performed to verify the feasibility of the implant design. The results of the simulation calculations were compared with animal experimental data in vivo to verify their validity. Results No significant differences in bone mineral density and stress/strain distribution were found between the CRI and traditional implant models. The animal experimental results (X‐ray images and histological staining) were consistent with the numerical simulated results. Conclusions CRIs were more similar to traditional implants than to natural teeth in terms of biomechanical and biological evaluation. Considering the convenience of clinical application, this biomechanical evaluation provides basic theoretical support for further applications of CRI.

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“…In 1992, Lundgren and his research team used titanium to make RAIs, which were tested in a beagle dog experimental model of immediate implant placement and reported bony integration in 88% of the inserted implants [8]. Since then, many researchers have reported the successful use of RAIs in clinical cases [11,15,16]. However, there have also been some cases of failure [17,18].…”

Section: Introductionmentioning

confidence: 99%

Influence of different diameter reductions in the labial neck region on the stress distribution around custom‐made root‐analogue implants

Lin

Zhu

et al. 2022

European J Oral Sciences

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This study was designed to investigate the influence of diameter reductions on the stress distribution around root-analogue implants via 3D finite element analysis. Four root-analogue implant models with different diameter reductions (0, 1, 2, or 3 mm), a traditional threaded implant and congruent bone models were created through reverse engineering. A 100-N force was applied parallel with and in a 45˚angle to the implant axis, respectively. The stress concentration in the labial neck area around implants with 1-2 mm diameter reduction was lower than seen with no reduction. When the implant diameter was reduced by 3 mm, there were obvious stress concentrations in both implant and bone (the maximum stress was 206 and 111 MPa, respectively). In other groups, the maximum stress was 65.1 MPa in the bone and 108 MPa in the implant. Additionally, the stress concentration in the bone around the root-analogue implant when the implant diameter was reduced by 0-2 mm (maximum stress of 65.1 MPa) was obviously smaller than that around the traditional implant (maximum stress 130.4 MPa). Reducing the diameter of maxillary central incisor root-analogue implants by up to 2 mm next to the labial cortical bone could help disperse stress.

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Customized Root-Analogue Implants: A Review on Outcomes from Clinical Trials and Case Reports

Cited by 15 publications

References 50 publications

Additive manufacturing technologies in the oral implant clinic: A review of current applications and progress

Additive manufacturing technologies in the oral implant clinic: A review of current applications and progress

Biomechanical evaluation of customized root implants in alveolar bone: A comparative study with traditional implants and natural teeth

Influence of different diameter reductions in the labial neck region on the stress distribution around custom‐made root‐analogue implants

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