Abstract

Guided implant surgery gained acceptance and credit in implant dentistry. The aim of this study is to find out and evaluate the relationship between implant size and success rate following computed tomography scan guided implant surgery. Sixty-four (36 females, 28 males) completely and partially edentulous patients aged between 42 and 65 years old were participated and fulfilled the inclusion criteria of the study. Two hundred and seventeen dental implants (length: 10, 11.5, and 13 mm; Diameter: 3.3, 3.75, and 4.2 mm) were placed using computed tomography scan guided implant surgery, 117 implants were placed in the maxilla, while 100 implants were placed in the mandible. The implants were evaluated for clinical parameters at 2, 4, and 12 weeks intervals after installation. The overall success rate was 95.4%. Clinical stability of the implant size (Diameter 3.3 mm, Length 10 mm) was the least as compared to other dimensions (P ≤ 0.05). Medium and large size implants (Diameter 3.75 and 4.2 mm, Length 11.5 and 13 mm) were the highest success rate in implant surgery. Implants width (diameter 3.3 mm) and length (10 mm) are best avoided in guided computed tomography surgery as compared with other implant sizes especially in atrophic bony areas. Computer-guided implant surgery remains exciting. Watchful planning and precise stability of the surgical guide are mandatory for successful protocol. Further investigations should be performed to assess such technique among dental patients from satisfactory point of view. Intensive cooperation between dentists and software engineering discipline should be aimed to maximize the success of such technique.

Keywords

Guided Surgery, Surgical Template, Accuracy, Implants Dimension

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1. INTRODUCTION

Guided surgery is a flapless procedure that offers a more precise, predictable and safe procedure with minimal postoperative discomfort and pain in implant treatment [1]. Such procedure using techniques derived from three-dimensional oral implant planning software, of both surgical templates for flapless surgery and dental prostheses for immediate loading, is a very preferable treatment choice [2]. Immediate loading can be defined as occlusal or nonocclusal restoration of implants on the same day the implants were inserted [3] or within the first two days following implant insertion, while conventional treatment returned to complete the restoration after 3 to six months [4]. The longer the implant, the better the primary stability. Implants shorter than 10 mm present a high risk of failure [5].

The mean survival rate of computer guided surgery is 97.2% with mean marginal bone loss of 1.45 mm in 1 - 4 years follow up [6]. Surgical guidance helps the operator in installing the implant in the most preferable position and angulations to the final restorations [7]. Complete guided implant surgery can help operators in placing dental implants for rehabilitation of the edentulous maxilla without extraction of impacted teeth [8].

Patients exposed computer assisted implant surgery felt less pain and were more satisfied than conventional implant patients [9]. Computer guided implant surgery depends upon careful planning and perfect stability of the surgical templates [10]. Good bone quality, adequate thickness of keratinized gingiva and high primary stability are key factors for successful guided implant surgery [11]. Different computer guided implant surgery procedures are available with inaccuracy of ±2.0 mm smaller than for nonguided surgery [12]. Existing dental implants in an overdenture can be used to fixate a surgical guide to place more implants to convert existing overdenture into fixed prosthesis [13]. Flapless implant surgery has a survival rate (96.5% to 97.9%) comparable to conventional flap techniques [14]. Computed guided implant placement is useful and suitable approach for rehabilitation of edentulous maxilla without the extraction of impacted canines [15].

Computer-guided planning and placement of dental implants has become broadly used and has been considered to be a rather reliable tool for implant positioning without endangering the adjacent anatomical structures [16].

Computer-generated planning permits for improved imagining of bone morphology prior to the positioning of implants and improves the construction of implant supported restorations according to a predictable planning of implants [17].

In this context, the literature lacks valid studies of the relationship between implant size (length and width) and success rate in computer guided implant surgery. Therefore, this prompted the conduction of the current study in order to cast the light on this issue.

2. MATERIALS AND METHODS

The study population consisted of Sixty-four (36 females, 28 males) (Table 1) completely and partially edentulous patients aged between 42 and 65 years old were participated and fulfilled the inclusion criteria of the study (Table 2).

The patients were referred by general practitioners to a specialized Guided Implant Surgery Center in Jerusalem-Palestine in the period between 2012-2016. This center receives dental implant patients from the whole country.

Each patient was a given a brief explanation of the investigation and the procedures to be undertaken. An informed consent was obtained from each patient before implant surgery. To be included in the study, the recruited patients must be 18 years old or above in order to receive dental implant treatment and must be indicated to receive dental implant therapy.

The prosthetically guided maxillofacial surgery computer-aided design/computer-aided manufacturing surgical protocol was applied to sixty-four (partially and completely edentulous) patients between September of 2012 and March of 2016.

Prosthetically guided surgery computer-aided procedure involved four steps: 1) the virtual planning of the surgical treatment, 2) planning of edentulous site in the patients’ casts (area where dental implants are going to be installed, 3) computer-aided design/computer-aided manufacturing and rapid prototyping procedures for the design and manufacture of the customized surgical devices, and 4) the surgical procedure itself. Virtual Planning began with the acquisition of a high-resolution tomographic scan of the patient’s mouth. Computed tomographic imaging was performed using a multidetector computed tomography scanner (Carestream Dental Cone Beam Computed Tomography 3-D CBCT with CS 9300 and CS 8100-Kodack, New York, USA) for both the patients’ mouth and the dental casts. All patients were asked to do CT Scan for their jaws, after making impressions in the dental clinics. Impressions were scanned to create digital models. Surgical templates were fabricated to suit every case in the study population regarding, number, diameter and length of dental implants used.

Surgical phase implants success was assessed according to the first three points of Albrektsson et al. (1986) who suggested the following criteria to judge the success of dental implants as:

1) A stable dental implant that lacks mobility.

2) Radiographic examination reveals no radiolucency around the installed dental implant.

3) The absence of pain, paresthesia, infection or any signs and symptoms complained by the patient.

4) The radiographic vertical bone loss is less than 0.2 mm per year, after one year of function.

5) The implant should accomplish the above mentioned guidelines with success rate of 85% at a 5-year follow up and 80% at the end of a 10-year period [18].

The null hypothesis was that in patients treated with guided implant surgery, no relationship could be established between implants’ dimensions (length and diameter), and patients’ parameters (age and gender) and the success of implant therapy.

This study was reviewed and ethically approved by the deanship of dental school at Al-Quds University.

3. RESULTS

Sixty four patients (36 were females and 28 were males) participated in the current study and received dental implants using guided implant technique.

A total of 217 implants were installed using computer guided surgical technique and three diameter dimensions namely: (3.3, 3.75 and 4.2 mm) were used and three implants length (10, 11.5 and 13 mm) were also used, and their distribution according to site and size is clarified in (Table 3).

According to the site of implant insertion; 117 implants were placed in the maxilla, while 100 implants were placed in the mandible. The implants were evaluated for clinical parameters at 2, 4, and 12 weeks intervals after installation, 6 maxillary implants and 4 mandibular implants failed to osseointegrate (Table 4).

The overall success rate was 95.4% (10 implants failed out of 217). According to the diameter dimension 8 implants (3.3 mm in diameter) were failed to osseointegrate during the study. Meanwhile, 9 implants (10 mm in length) were also, failed to ossentegrate as noticed in (Table 5).

Clinical stability of implants dimensions (Diameter 3.3 mm, Length 10 mm) was the least as compared to other dimensions. Oneway ANOVA in SPSS (Statistical Package for the Social Sciences, version 20.0, Inc., Chicago, IL, USA) was used to compare the differences in implant failure according to implant parameters (length, diameter, and position). The results revealed that there is a significant effect between implant diameter as well as length and implant failure (P < 0.05), while anatomic position has no significant difference (Table 6).

In this context, patients’ parameters (age and gender) were also studied using Oneway ANOVA, and the results showed that there are no significant differences between patients age and gender and their effect on implants failure (P value > 0.05) (Table 7).

4. DISCUSSION

Patients and dentists seek new effective treatment options to replace conventional removable prosthodontic treatment. Dental implants provided the answer and the alternative in many cases, and have emerged as a viable treatment modality. During the last thirty years, dental implants gained credit and popularity and showed improvements in all aspects.

Alberktsson et al. (1981) defined osseintegration as a direct structural and functional connection between ordered, living bone and the surface of the load carrying implant [19]. Key factors for successful and high level osseintegration included careful surgery, meticulous prosthodontics, and good after care, linked with good patient selection [20].

*significant when P < 0.05.

Attempts have been made to enhance the success rate of implants. Oral implant success rate can be enhanced by improving the surgical technique [21]. The future of osseintegrated implants depends on the comprehension of the important contributions by a responsible surgeon and restorative dentist [22]. From there, the concept of guided surgery appeared to enhance success and lessen patients’ pain. Abu Hantash et al. (2006) found that pain consideration is a factor when assessing dental implant treatment acceptance and satisfaction [23]. Youk et al. (2014) showed that patients who have surgical implant therapy were more satisfied and gained acceptance than conventional implant technique due to safety and accuracy of surgical guide techniques [24].

The results of this study supported the effective and high success rates of guided implant surgery for medium and long implants (11.5 and 13) mm length and (3.75 and 4.2) mm diameter. These findings agreed with Lee et al. (2005) review who reported that wider and longer implants keep better success rates and prognosis in conventional implant surgical techniques [25].

There were no significant differences in success rates in relation of age, gender, and anatomic sites and guided implant surgery. On the contrary, previous studies [26 - 28] reported an early implant failure due to anatomical sites; especially anterior maxilla.

In addition, the results of this study showed that there was a significant difference between success rate of implants in guided surgery according to their sizes. Implant size (3.3 mm diameter and 10 mm length) had more failure rates compared to other dimensions. This could be justified by the fact that the alveolar ridge in the implant site of small ones (3.3 and 10 mm) was more atrophic and narrower than other sites if compared with other implant sites in the same patient and among different patients, also. High failure rate of small size implants as found in this study is best explained by the lack of control of the angle of drilling and implant placement blindly through the guide especially in the atrophic area of the alveolar ridges, which usually resulted in hidden and undiagnosed dehiscence or microfracture of alveolar bone which in future leads to more risk of infection, instability and failure.

Improving the prognosis of guided implant surgery of smaller sizes in atrophic bone could be achieved through two criteria: first, meticulous treatment planning and patient selection in regard to bone quality and quantity should be accomplished. Second, the need of open surgical instrumentation (drilling and insertion) in the area of atrophic ridges after making drill through the guide to ensure a proper implant insertion without chipping or future dehiscence. This could also be managed by inventing new guide implant systems designed carefully to avoid surgical complications in atrophic areas and ensure a gentler and more accurate placement of smaller implants.

5. CONCLUSIONS

The conclusion of this study can be summarized as the following:

1) Implants width (3.3 mm) and length (10 mm) are not recommended in guided computed tomography implant surgery as compared with other implant sizes.

2) Implant success rate is not correlated with patients’ age, gender and anatomic sites.

3) Computer-guided implant surgery remains exciting. Watchful planning and precise stability of the surgical guide are mandatory for successful protocol.

4) Further investigations should be performed to assess such technique among dental patients from satisfactory and acceptance point of view.

ACKNOWLEDGEMENTS

The authors would like to thank Dr Haitham Al-Alami and Prof. Mahmoud Al-Omiri for their kind contribution in this study.

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

References