Literature Review Regarding the Applicability and Clinical Outcome of Basal Implant

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REVIEW ARTICLE

Literature Review Regarding the Applicability and Clinical Outcome of Basal Implant

Ghassan Habash1 , 2 , * Open Modal Soher Nagi Jayash3 , * Open Modal Sajeda Jawad Albanna4 Mahmoud K. Al-Omiri5 , 6
Authors Info & Affiliations
The Open Dentistry Journal 06 Jun 2024 REVIEW ARTICLE DOI: 10.2174/0118742106283694240422063539
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Abstract

Objective

Restoring moderate to severely atrophic jaws with conventional implants often involves extensive surgical procedures. Basal implants, designed for immediate use in atrophied jawbones, offer an alternative by supporting single and multiple-unit restorations in the upper and lower jaws without the need for risky and expensive bone augmentation. However, their success rate diminishes significantly in areas with limited residual bone. This review aims to assess the applicability of basal implants compared to conventional endosseous implants.

Methods

A comprehensive literature review was conducted utilizing PubMed, Scopus, the Cochrane Library, EMBASE, and Google Scholar. The analysis focused on manuscripts and overviews published over a span of 20 years until September 8, 2022.

Results

Studies indicate that basal implants are a reliable option in specific cases, especially when other implants are not feasible, such as in severe alveolar bone atrophy. However, there is insufficient strong evidence to recommend basal implants over conventional ones. The evidence level of the reviewed papers all belong to evidence level V, which encompasses case reports and studies lacking controls.

Conclusions

The advantages of basal implants over conventional implants remain uncertain. The standard of care in dentistry should prioritize evidence-based practices, which commonly include the use of conventional implants. Further research is necessary to establish their efficacy and suitability in various clinical scenarios.

Keywords: Basal implant, Conventional implant, Implant applicability, Dental implants, Jaw bones, Orthopedic implants.

1. INTRODUCTION

Dental implants have become highly popular for replacing missing teeth, with numerous implant systems and techniques documented in the literature. One such approach in dental implantology is basal implantology, which relies on the dense basal cortical jawbones to anchor implants and bear the load. This concept draws inspiration from orthopedic implants used in knee or hip replacements, applying similar principles for stability and support [1, 2]. The concept of basal single-piece dental implants, where the fixture and abutment are integrated into one piece, was introduced in 1972 by Dr. Jean-Marc Julliet [3]. This concept was later extended with the development of Disk implants, Basal Osseo-Integrated implants, and Lateral Basal Implants [2, 4]. Dr. Stefan Idhe introduced advancements in dental implant technology, introducing bendable vertical implant shafts. Subsequently, screw-shaped immediate basal implants, referred to as Basal Cortical Screws, were developed as part of these ongoing innovations [5].

In the existing literature, diverse viewpoints on basal implants can be found. Certain researchers view this treatment approach as superior and more beneficial when compared to conventional (crestal) implants [1, 2, 5]. A conventional implant typically refers to a dental implant that follows traditional protocols and procedures for placement and restoration. This implant comes in two pieces - a component for the root and a component for the teeth. These two components are joined together using a small screw. However, contrasting these views, other researchers do not support these claims [6]. According to Garg et al., in 2017, basal implants were found to be associated with higher pain levels compared to immediately loaded and delayed-loaded conventional implants [6]. Additionally, it was noted that cantilever prostheses experienced reduced bone stress when supported by endosseous implants [7]. For bicortical basal implants, certain researchers reported a 15% incidence of biological complications and a 56% incidence of mechanical complications [8]. There were also reports of basal implant fractures, with endosteal implants being proposed as a straightforward solution in such cases [9].

Given the ongoing debate and the need to delve into the supporting evidence for basal dental implants, this review is undertaken. The primary objective of this review is to examine the available evidence regarding basal implants and assess the claims suggesting their superiority over conventional endosseous implants.

2. MATERIALS AND METHODS

2.1. Research Question and Search Strategy

Is there clinical superiority in use behind basal implants over conventional endosseous implants?

The literature search of PubMed, Scopus, Cochrane Library, EMBASE, Google Scholar, and Research Gate databases was performed until 8th of September 2022. A supplementary manual search of reference lists from the identified literature was performed to find further literature. Keyword search included “Basal Implants,” “Bicortical Implants,” “Strategic Implants,” “Basal Cortical Screw,” “Lateral Basal Implants,” “Basal Osseo-Integrated implants,” “Disk Implants,” “single piece implants,” OR “Bicortical anchorage.”

Case reports and original articles were all included in the search. Abstracts of the resulting articles were reviewed according to inclusion criteria. Full-text studies published in any language in scientific journals were included for further scrutiny, and an initial list of eligible papers was generated. The results of 17 studies were included in this review. Unpublished data and unrelated articles were excluded.

2.1.1. Inclusion Criteria

  • Clinical studies in the scope of basal implants
  • Full-text articles
  • English language studies
  • Studies published in the period between 2000 and 2022

2.1.2. Exclusive Criteria

  • Preclinical studies
  • Conference reports or abstracts,
  • In vitro studies
  • Review or systematic review papers.

2.2. Level of Evidence

The level of evidence was described by Sacket, based on the levels of evidence used in previous studies [10, 11].

3. RESULTS

3.1. Analysis of Literature Search

A total of 932 titles were retrieved from the initial search. These titles were filtered using dentistry-related keywords and subjected to inclusion as well as exclusion criteria, and discussions among the authors. Ultimately, 17 papers were selected for this review, each addressing various aspects of basal implants.

3.2. Applicability of Basal Implant

Among the retrieved papers, only six constitute clinical studies (Table 1), while the remaining 11 are clinical case reports (Table 2). Clinical studies suggest that basal implants enhance the rehabilitation of patients with compromised bone quality and/or quantity, as immediate rigid implant splinting helps distribute peak forces. However, these studies indicate the need for further research to solidify the clinical benefits of basal implants and emphasize the importance of controlling occlusion to reduce the risk of mechanical complications [8, 12-15]. Conversely, two studies highlight challenges associated with basal implants, such as difficulty in replacement, increased intraoperative pain and time, and the shifting of maximum stress regions during osseointegration from the early healing phase to full osseointegration [6, 16].

In terms of clinical case reports, although most are short-term and lack optimal tools for analyzing peri-implant bone, they primarily focus on patients' masticatory function and aesthetics with immediate loading of basal implants [1, 17-23]. Some reports suggest basal implants are a viable option in specific cases, such as patients with head and neck cancer with a history of radiation therapy. Some reports suggest basal implants are a viable option in specific cases, such as patients with head and neck cancer with a history of radiation therapy [19] and severe atrophic alveolar bone cases [24-26].

Table 1.
The main aims and findings of clinical studies are included in this review.
Reference Year Type of Study Aims Findings
Anuradha et al. [12] 2020 Clinical study Evaluate clinically, radiographically, and functionally the outcomes of basal implants in the compromised bone. Basal implants improve the rehabilitation of patients where compromised quality and/or quantity of bone is present.
Fadia Awadalkreem et al. [13] 2020 Clinical study Evaluate and compare patients' satisfaction when changing from fixed, removable, and/or conventional implant prostheses to basal implant-supported prostheses. Basal implant-supported prostheses have a positive impact on oral health and highly increase patient satisfaction.
Łukasz R Pałka [14] 2019 Clinical study This study aimed to assess many aspects of bicortical screw implants used to retain full-arch and segmental cemented prostheses in the rehabilitation of the mandible and maxilla in patients with or without a history of periodontal disease. Bicortical smooth surface implant with immediate loading protocol provided predictable outcomes. More studies are needed to further support the clinical advantage of bicortical anchorage smooth surface implants.
Ritesh Garg et al. [6] 2017 Clinical study Evaluate the survival of endo-osseous immediate loading implant and basal implants in atrophic jaws with an objective to compare implant survival in atrophic jaws for full mouth rehabilitation during 3-year follow-up. It is difficult to replace a basal implant.
Intraoperative pain and time are more frequent with basal implants.
Mild bone loss and gingival recession.
Sigmar Kopp et al. [15] 2011 Clinical study To study the amount and distribution of pressure, stress, and deformation energy when basal implants are used in the mandible. The immediate rigid implant splinting distributes peak forces.
Stefan Ihde et al. [16] 2008 Clinical study To develop a model to accurately represent the interface between bone and basal implant throughout the healing process. Basal implants undergo an intrinsic shift of maximum stress regions during osseointegration. There is a gradual shift from the early healing phase until full osseointegration is achieved.
Table 2.
The main aims and findings of clinical case reports included in this review.
Reference Year Type of Study Aims Findings
Motaz Osman et al. [17] 2020 Case report Rehabilitation of a 22-year-old female with a subtotal maxillectomy using an immediately loaded basal implant-supported prosthesis. Basal implant restored the patient’s masticatory function, esthetics, and phonetics and improved the patient’s self-esteem and quality of life.
Fadia Awadalkreem et al 2020 Case report Use of fixed basal implant-supported prostheses in irradiated bone, in conjunction with hyperbaric oxygen therapy. Hyperbaric oxygen therapy in combination with basal implants is a successful treatment modality for patients with head and neck cancer who have a history of radiation therapy.
Fadia Awadalkreem et al. [19] 2020 Case report Basal implant is used for full-mouth rehabilitation in a gunshot mandibular defect patient. The fixed hybrid basal implant-supported prosthesis produced highly acceptable aesthetic and phonetic results and greatly improved the patient's life.
Abdelnasir G Ahmad [23] 2019 Case report Basal implant-based full-mouth rehabilitation is used in a patient with cleidocranial dysplasia. The basal implant-supported fixed prostheses improve aesthetics, speech, function, and overall quality of life.
Stefan Ihde [20] 2018 Case report Immediate restoration is used with bicortical implants The use of a cortically anchored strategic implant allowed for the fixed reconstruction of a severe defect to restore masticatory function to some extent.
Ilker Keskiner [24] 2016 Case report This case report presents the surgical removal of basal-type dental implants due to failure of osseointegration. Implants may be useful for severely atrophic alveolar bone, and the clinician should have the skill set and experience to overcome the potential complications associated with the removal of implants.
Mayur Khairnar et al. [26] 2015 Case report Smooth polished surface bi-cortical implants are used in atrophied maxilla. Observation of significant bone formation in severely atrophied jaws after indirect lifting of the nasal membrane with smooth polished surface bi-cortical implants.
Sumit Narang [21] 2014 Case report The report highlights the placement of three bicortical screw implants into the extraction sockets. Implants were placed and loaded immediately, which showed promising results at a follow-up of 6 months.
Meningaud et al. [25] 2009 Case report Total oral rehabilitation with basal implants (cortically anchored disk-design implants) on a patient who received a facial allograft 1 year earlier. The cortical anchorage only relies on this patient, allowing to avoidbone grafting. The particular thinness of the implant emergence limits the communication between the bone and the oral cavity to the minimum.
Kalinga K Sahoo
[22]		 2007 Case report Placement of a bicortical screw implant to anchor a metal-ceramic crown in the missing right lateral incisor region and restoring esthetics. The final restoration was outstanding
except for the fact that the gingival emergence profile
was missing.
S Ihde [1] 2001 Case report Restoration of the atrophied mandible using basal osseointegrated implants and fixed prosthetic superstructures. The basal osseointegration procedure allows speedy reconstruction of the masticatory function, and the cost of treatment is very moderate.
Table 3.
Overview of the advantages and disadvantages of basal implants compared to conventional implants.
Aspect Basal Implants Conventional Implants
Advantages - -
Time Less time needed More time needed
Disadvantages - -
Evidence-Based No sufficient evidence Evidence-based practice
Retrievable Not retrievable Retrievable
Prosthetic solutions No prosthetic solutions All prosthetic solutions available
Surgical Technique Invasive may reach the second cortical and could potentially affect vital structures, utilizing a blind, flapless technique. Less invasive surgical procedure
Prosthetic Driven (Guided) Surgical Driven inapplicable Prosthetic driven Prosthetic-driven and computer guided
Preparation technique High-speed drilling is necessary to penetrate the cortical bone, which may induce heat during the process. Highspeed drilling is not necessary
Peri-Implantitis treatment Inaccessible Accessible and allows for the removal of the abutment and subsequent treatment.
Prosthetic preparation Intraoral preparation induces heat plus bending the abutment, which may cause stress on the bone. Abutments were prepared in the lab.
Single Implant Not suitable choice Suitable
Aesthetic No Aesthetic guidelines Well documented Aesthetic guidelines

Notably, no randomized controlled trials were found in the search, preventing the possibility of conducting a meta-analysis for this review. Additionally, the majority of the literature comprised case reports and follow-ups involving small case numbers. Regarding the evidence level of the reviewed papers, all fall under level V (Case reports, studies with no controls). Moreover, most papers were published in journals that were not indexed in Scopus and Thompson Reuters ISI databases.

4. DISCUSSION

The restoration of the edentulous maxilla or mandible typically involves dental implants, among which basal implants utilize the basal cortical portion of the jaws for retention. These implants have become a viable option for atrophied jaws, as they allow for immediate loading without extensive augmentation, making them particularly suitable for cases with limited bone [27]. Despite their potential, basal implants have not gained widespread trust among conventional implantologists due to limited data on their success rates. In our review, we identified only six clinical studies focusing on patient rehabilitation with immediate loading, lacking long-term follow-ups. Additionally, there were 11 low-evidence case reports emphasizing aesthetics and functions, with only one case report evaluating bone formation in severely atrophic alveolar bone after a one-year follow-up using cone beam imaging. While basal implants show promise in cases with insufficient bone [28], there is insufficient evidence to recommend them over conventional implants. Some dentists might opt for basal implants due to their lower cost and simplified work protocol.

This table provides a concise overview of the advantages and disadvantages associated with basal implants compared to conventional implants (Table 3).

Further research on clinical cases is necessary to establish the efficacy of basal implants as a viable alternative to conventional implants.

CONCLUSION

Further research on clinical cases is necessary to establish the efficacy of basal implants as a viable alternative to conventional implants. The standard of care in dentistry should prioritize evidence-based practices, which commonly include the use of conventional implants. This review has limitations, notably the scarcity of clinical studies focused on basal implants and the inherent study design and follow-up limitations in most of the included papers.

AUTHORS' CONTRIBUTIONS

It is hereby acknowledged that all authors have accepted responsibility for the manuscript's content and consented to itssubmission. They have meticulously reviewed all results and unanimously approved the final version of the manuscript.

AVAILABILITY OF DATA AND MATERIALS

All data generated or analysed during this study are included in the article.

CONSENT FOR PUBLICATION

Not applicable.

FUNDING

We are grateful to the Biotechnology and Biological Sciences Research Council (BBSRC) for the Institute Strategic Programme Grant Funding BBS/E/RL/230001C to SNJ which provided salary support during manuscript writing.

CONFLICT OF INTEREST

The authors declare no conflict of interest.

ACKNOWLEDGEMENTS

Declared none.

REFERENCES

1
Ihde S. Restoration of the atrophied mandible using basal osseointegrated implants and fixed prosthetic superstructures. Implant Dent 2001; 10(1): 41-5.
2
Yadav R, Sangur R, Mahajan T, Rajanikant A, Singh N, Singh R. An alternative to conventional dental implants: Basal implants. Rama Univ J Dent Sci 2015; 2: 22-8.
3
Ihde S. Principles of BOI: Clinical, Scientific and Practical Guidelines to 4-D Dental Implantology; 8 Tables 2004.
4
Nair C, Bharathi S, Jawade R, Jain M. Basal implants-a panacea for atrophic ridges. J Dent Sci Oral Rehabil 2013; 2013: 1-4.
5
Stefan I. Comparison of basal and crestal implants and their modus of application. Smile Dent J 2009; 4(1): 36-46.
6
Garg R, Mishra N, Alexander M, Gupta S. Implant survival between endo-osseous dental implants in immediate loading, delayed loading, and basal immediate loading dental implants a 3-year follow-up. Ann Maxillofac Surg 2017; 7(2): 237-44.
7
Pratheep KV, Abraham A, Annapoorni H, Vigneshwaran S. Comparative evaluation of stresses in tooth implant connected fixed partial denture by varying the implant design and position: A 3D finite element study. Indian J Dent Res 2013; 24(4): 439-45.
8
Maló P, de Araújo Nobre M, Lopes A, Moss S. Posterior maxillary implants inserted with bicortical anchorage and placed in immediate function for partial or complete edentulous rehabilitations. A retrospective clinical study with a median follow-up of 7 years. Oral Maxillofac Surg 2015; 19(1): 19-27.
9
Kan JY, Lozada JL, Boyne PJ, Goodacre CJ, Rungcharassaeng K. Mandibular fracture after endosseous implant placement in conjunction with inferior alveolar nerve transposition: a patient treatment report. Int J Oral Maxillofac Implants 1997; 12(5): 655-9.
10
Burns PB, Rohrich RJ, Chung KC. The levels of evidence and their role in evidence-based medicine. Plast Reconstr Surg 2011; 128(1): 305-10.
11
Sackett DL. Rules of evidence and clinical recommendations on the use of antithrombotic agents. Chest 1986; 89(2)(Suppl.): 2S-3S.
12
Verma S, Anuradha M, Babaji HV, et al. Assessment of basal implants in compromised ridges. J Family Med Prim Care 2020; 9(4): 2067-70.
13
Awadalkreem F, Khalifa N, Satti A, Suleiman AM. The influence of immediately loaded basal implant treatment on patient satisfaction. Int J Dent 2020; 2020: 6590202.
14
Pałka Ł, Lazarov A. Immediately loaded bicortical implants inserted in fresh extraction and healed sites in patients with and without a history of periodontal disease. Ann Maxillofac Surg 2019; 9(2): 371-8.
15
Kopp S, Kuzelka J, Goldmann T, Himmlova L, Ihde S. Modeling of load transmission and distribution of deformation energy before and after healing of basal dental implants in the human mandible. Biomed Tech 2011; 56(1): 53-8.
16
Ihde S, Goldmann T, Himmlova L, Aleksic Z. The use of finite element analysis to model bone-implant contact with basal implants. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2008; 106(1): 39-48.
17
Osman M, Ahmad AG, Awadalkreem F. A novel approach for rehabilitation of a subtotal maxillectomy patient with immediately loaded basal implant-supported prosthesis: 4 years follow-up. Case Rep Dent 2020; 2020: 9650164-.
18
Awadalkreem F, Khalifa N, Ahmad AG, Suliman AM, Osman M. Prosthetic rehabilitation of maxillary and mandibular gunshot defects with fixed basal implant-supported prostheses: A 5-year follow-up case report. Int J Surg Case Rep 2020; 68: 27-31.
19
Awadalkreem F, Khalifa N, Ahmad AG, Suliman AM, Osman M. Rehabilitation of an irradiated marginal mandibulectomy patient using immediately loaded basal implant-supported fixed prostheses and hyperbaric oxygen therapy: A 2-year follow-up. Int J Surg Case Rep 2020; 71: 297-302.
20
Ihde S, Pałka Ł, Janeczek M, Kosior P, Kiryk J, Dobrzyński M. Bite reconstruction in the aesthetic zone using one-piece bicortical screw implants. Case Rep Dent 2018; 2018: 4671482.
21
Narang S, Narang A, Jain K, Bhatia V. Multiple immediate implants placement with immediate loading. J Indian Soc Periodontol 2014; 18(5): 648-50.
22
Sahoo K, Bhandari A. Treatment of an anterior single edentulous space with a bicortical screw implant. J Indian Prosthodont Soc 2007; 7(2): 92.
23
Ahmad AG, Osman M, Awadalkreem F. Full-mouth rehabilitation of a patient with cleidocranial dysplasia using immediately loaded basal implant-supported fixed prostheses: A case report. Int J Surg Case Rep 2019; 65: 344-8.
24
Keskiner I, Aydogdu A, Ozturan S. Surgical removal of poly-ether-ether-ketone-derived basal type implants: A case report. J Oral Implantol 2016; 42(5): 432-5.
25
Meningaud JP, Donsimoni JM, Lantieri L. [Facial allograft transplantation and basal implantology(cortically anchored disk-design implants)]. Rev Stomatol Chir Maxillofac 2009; 110(6): 353-8.
26
Khairnar M, Gaur V. Evidence of bone formation in the nasal floor around polished surface bi-cortical screw implants after indirect nasal lift in an atrophied maxilla: Cone beam computed tomography-based case report. J Indian Soc Periodontol 2015; 19(2): 236-8.
27
Gupta AD, Verma A, Dubey T, Thakur S. Basal osseointegrated implants: Classification and review. Int J Contemp Med Res 2017; 4: 2329-35.
28
Trivedi V, Patel K, Madan S, Mehta D, Shah SP, Seta H. Basal implants: An asset for rehabilitation of atrophied resorbed maxillary and mandibular jaw – A prospective study. Ann Maxillofac Surg 2021; 11(1): 64-9.