Journal of Baghdad College of Dentistry, Vol. 34, No. 1 (2022), ISSN (P): 1817-1869, ISSN (E): 2311-5270 29 Research Article The relationship of implant stability quotient and insertion torque in dental implant stability Ali T. Noaman1.*, Salwan Y., Bede2 1 PhD student, Oral surgery unit, specialized dental health center in AL-Sheikh Omar, Baghdad Health Directorate-Al-Rusafa, Ministry of Health 2 Professor, Department of Oral and Maxillofacial Surgery, College of Dentistry, University of Baghdad.Bab-Almoadham, P.O. Box 1417, Baghdad, Iraq *Correspondence: alitareef79@gmail.com Abstract: Background: The insertion torque (IT) values and implant stability quotient (ISQ) values are the measurements most used to assess primary implant stability. This study aimed to assess the relationship between ISQ values and IT. Materials and methods: This study included 24 patients with a mean (SD) age of 47.9 (13.64) years (range 25-75 years). The patients received 42 dental implants (DI), 33 in the mandible and 9 in the maxilla. The DI were installed using the motorized method with 35 Ncm torque, When DI could not be inserted to the requisite depth by the motorized method, a hand ratchet was used and the IT was recorded as ˃ 35 Ncm. Implant stability was measured utilizing Osstell® ISQ. The secondary stability was measured after 16 weeks postoperatively.Results: The DI installed in mandible demonstrated significantly higher primary stability ISQ values than those installed in maxilla (P=0.0101). There was no such significant correlation linked between the secondary stability and the recipient jaw (P=0.2026). A non-significant correlation was found between the primary and secondary implant stability ISQ values and IT (P=0.2785 and 0.4194, respectively). No significant difference was reported regarding the IT relative to the recipient jaw of DI (P=0.1349).Conclusion: This study demonstrated that there was no relationship between the ISQ values and the IT, and that they should be used independently. DI installed in mandible demonstrated significantly higher primary stability ISQ values than those installed in maxilla. Also, there was a non-significant correlation of the secondary stability and IT with the recipient jaw. Keywords: Dental implants, insertion torque, implant stability. Introduction The successful outcome of dental implants (DI) depends on a sequence of patient-related and procedure dependent elements, including general health conditions, biocompatibility of the implant material, the implant surface features, the surgical procedure, and the local bone quality and quantity (1). Implant stability may be defined as "the capacity of implant to withstand loading in axial, lateral and rotational direction", (2) it is split into two parts: primary and secondary. Primary stability refers to "the mechanical bracing of the implant in bone and absence of any micro-movement", While secondary stability is referred to "successful osseointegration of the implant with the surrounding" (3). At the time of implant insertion, primary stability is crucial. The most important factor for successful osseointegration is a solid anchoring of the implant within the host bone, free of micro- motions. Micro-motions may develop if an implant is not sufficiently stable at the time of implant placement, disrupting the normal healing process and forming a fibrous tissue capsule, resulting in clinical mobility and eventual implant failure (4). Received date: 1-11-2021 Accepted date:: 5-12-2021 Published date: 15-3-2022 Copyright: © 2022 by the authors. Submitted for possible open access publication under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by /4.0/). https://doi.org/10.26477/j bcd.v34i1.3089 https://creativecommons.org/licenses/by/4.0/ https://creativecommons.org/licenses/by/4.0/ https://doi.org/10.26477/jbcd.v34i1.3089 https://doi.org/10.26477/jbcd.v34i1.3089 J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022 Noaman and Bede 30 There are numerous techniques to assess implant stability. These can be divided into two categories: the invasive and noninvasive methods (3). The insertion torque (IT) (during surgery, for primary stability), and resonance frequency analysis (RFA) (during and after surgery to measure primary and secondary stability) are the two most common noninvasive approaches for determining implant stability nowadays. RFA device measurements (Implant stability quotient, ISQ) have been shown to give crucial information to the surgeon on the present status of the bone implant interface which, together with clinical/radiographic findings, can aid decision-making during implant placement and follow-up in terms of healing durations, loading technique, and the identification of implants at risk of failure (5). It is critical to determine whether or not the IT and ISQ values are equivalent. Both approaches can be employed in clinics, particularly because the ISQ has been widely used owing to its applicability in a variety of settings, including implant placement, healing, and with the prosthesis in place (6). The aim of this study was to assess the relationship between the ISQ values and IT as a measurement of implant stability. Materials and methods This clinical prospective observational study was conducted at the Department of Oral and Maxillofacial surgery, College of Dentistry, University of Baghdad from September 2019 to June 2021. It included patients who presented with missing teeth that were restored with implant supported fixed prostheses. The institutional Research Ethics Committee approved the protocol of this study (protocol number 036118), and patients were informed about the nature of the study and they signed an informed consent to participate in this study. The inclusion criteria were; adult patients ≥ 18 years old of both genders with good general health presenting with partially edentulous maxilla or mandible with a minimum of 6 months after teeth extraction. The patients should have sufficient alveolar bone ridge dimensions with a minimum 6 mm width and 10 mm height. The exclusion criteria were; any uncontrolled systemic disease that could interfere with normal healing, current pregnancy, history of irradiation of the head and neck region or chemotherapy over the past 5 years, patients treated with bisphosphonate drugs which affect bone metabolism, any local condition such as the presence of infection or local pathological conditions in the proposed implant zone, active periodontitis and patients with clinical evidence of para-functional habits. A CBCT (cone beam 3D system Kavo OP 3D PRO, Germany), set at 90 KV, 9.2 mA and 8.1s with (13 × Ø15) c FOV and 0.5 mm slice in thickness, was taken for preoperative assessment of the planned implant site. The assessment was performed using OnDemand3D™ software (Cybermed Inc.©, Seoul, Korea), it included the bone height and width of alveolar ridge at the proposed implant site and also to determine the dimensions of the implant to be installed so that the implant apex is to be at least 2 mm above mandibular canal and 2 mm away from mental foramen, 1 mm below nasal cavity and 1 mm below the floor and the anterior wall of maxillary sinus as shown in (Fig. 1). Figure 1: The CBCT cross section view with bone dimensions measurement. J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022 Noaman and Bede 31 All the procedures were performed under local anesthesia lidocaine hydrochloride 2% with epinephrine (1:80,000). A mucoperiosteal flap was reflected and the implant site preparation proceeded using osteotomy drills of increasing diameter corresponding to the implant dimensions with an implant micromotor (Dental surgery micromotor iCT, Dentium, Korea) rotating at a speed of 800 rpm with copious saline irrigation. The implants (Superline, Dentium, Seoul, Korea) were installed into the osteotomy site using the motorized method with the engine set at 50 rpm and 35 Ncm torque, so that the implant platform is 0.5-1 mm below the bone level. When the implant could not be inserted to the requisite depth by the motorized method, a hand ratchet was used and the IT was recorded as ˃ 35 Ncm. Accordingly, in this study, implants were categorized into two groups regarding the IT; one group with 35 Ncm insertion torque and the other ˃ 35 Ncm. Immediately after insertion of DI, the primary stability was measured using Osstell®ISQ (Osstell®, Gothenburg, Sweden). Two repeated measurements were obtained for each implant along the buccolingual and mesiodistal axis and the mean of these two readings was taken (Fig. 2). Figure 2: Implant stability measurement using Osstell® ISQ. Patients were instructed for follow up visit at 16 weeks postoperatively. The implants were uncovered and the secondary stability was measured in the same manner described in primary stability measurement. The outcome variables were the primary and secondary stability measured as implant stability quotient (ISQ) and the IT and their correlations with the recipient jaw. GraphPad Prism version 6 for Windows was used to carry out the statistical analysis (GraphPad Software, La Jolla, CA, USA). Percentages, mean, standard deviation (SD) were all computed as part of descriptive statistical analysis. The inferential analysis included using Shapiro-Wilk normality test, unpaired t-test, and Chi-square test. The probability value <0.05 was considered statistically significant. Results This study included 24 patients, 14 females (58.3%) and 10 males (41.7%). The mean (SD) age of patients was 47.9 (13.64) years (range 25-75). The patients received 42 DI, of which 33 (78.6%) were installed in the mandible and the remaining 9 (21.4%) in the maxilla. The mean (SD) of the primary stability was 79.58 (5.27) ISQ, while that of the secondary stability was 74.3 (6.34) ISQ. In 22 DI (52.4%), the IT was 35 Ncm, while in the remaining 20 DI (47.6%), an IT of ˃ 35 Ncm was needed for the final seating of the DI. At the end of this study all the implants were clinically stable achieving an early survival rate 100%. The effect of the recipient jaw on the primary stability ISQ values The DI installed in the mandible demonstrated significantly higher primary stability ISQ values than those installed in the maxilla, Table (1). J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022 Noaman and Bede 32 Table (1): The differences of the primary stability ISQ value in relation to the recipient jaw. Abbreviations: ISQ, Implant stability quotient; SD, Standard deviation; S, Significant; *, Unpaired t- test. The effect of the recipient jaw on the secondary stability ISQ values There was a non-significant difference in the secondary stability ISQ values relative to the recipient jaw, Table (2). Table (2): The differences of the secondary stability ISQ value in relation to the recipient jaw. Recipient jaw Number of values Secondary stability/ ISQ P value Mean SD Mandible 33 75.09 6.44 0.2026 [NS]* Maxilla 9 72.00 5.87 Abbreviations: ISQ, Implant stability quotient; SD, Standard deviation; NS, Non-Significant; *, Unpaired t-test. Correlation of IT and the primary stability ISQ values There was a non-significant difference in the primary stability ISQ values between the DI that were installed with an IT of 35 Ncm and those installed with an IT > 35 Ncm, Table (3). Table (3): The differences of the primary stability ISQ value between the DI that were installed with an IT of 35 and > 35 Ncm. Abbreviations: IT, Insertion torque; ISQ, Implant stability quotient; SD, Standard deviation; NS, Non- Significant; *, Unpaired t-test. Correlation of IT and the secondary stability ISQ values There was a non-significant difference regarding the secondary stability ISQ values between DI that were installed with an IT of 35 Ncm and those installed with an IT > 35 Ncm, Table (4). Recipient jaw Number of values Primary stability/ ISQ P value Mean SD Mandible 33 80.65 5.23 0.0101 [S]* Maxilla 9 75.67 3.33 Insertion torque/ Ncm Number of values Primary stability/ ISQ P value Mean SD 35 22 78.93 5.32 0.2785 [NS]* > 35 20 80.30 5.26 J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022 Noaman and Bede 33 Table (4): The differences of the secondary stability ISQ value between the DI that were installed with an IT of 35 and > 35 Ncm. Insertion torque/ Ncm Number of values Secondary stability/ ISQ P value Mean SD 35 22 73.55 6.40 0.4194 [NS]* > 35 20 75.15 6.32 Abbreviations: IT, Insertion torque; ISQ, Implant stability quotient; SD, Standard deviation; NS, Non- Significant; *, Unpaired t-test. The effect of the recipient jaw on the IT There was a non-significant difference regarding the IT relative to the recipient jaw, Table (5). Table (5): The differences of the IT in relation to the recipient jaw. Recipient jaw IT 35 Ncm/ number of implants IT>35 Ncm/ number of implants P value Mandible 15 18 0.1349 [NS]* Maxilla 7 2 Abbreviations: IT, Insertion torque; NS, Non-Significant; *, Fisher's exact test. Discussion The most commonly used methods for assessing primary implant stability are IT and RFA (7). The link between these methods is poorly understood in the literature. The downside of IT is that it can only be measured once, at the moment of implant placement, whereas RFA may be utilized during the whole implant treatment phases (8). Meredith et al. (9) stated that RFA is a method that may be used as a research tool and is beneficial in evaluating the behavior of implants in surrounding tissue. Also, Jaramillo et al. (10) reported that RFA technologies in Osstell® Mentor and Osstell® ISQ provide nearly perfect reproducibility, repeatability, and precision. However, Degidi et al. (11) demonstrated that in clinical practice, the IT is still a simple and accurate metric for assessing the primary stability of DI. The findings of this study revealed that DI installed in the mandible demonstrated significantly higher primary stability ISQ values than those installed in the maxilla. This finding is in line with other studies, (12,13) and it may be explained by the fact that the mandible is characterized by denser bone than the maxilla (14). Primary stability arises from the compression of bone and it is linked to the mechanical engagement of implant with the surrounding bone and it depends on the quantity and quality of local bone in addition to other factors (15). Moreover, many studies indicated a positive correlation of primary implant stability and bone density (16–18). Conversely, Other studies (19) reported that there was no significant relationship between the implant stability and bone density. Secondary stability, on the other hand, demonstrated a non-significant association relative to the recipient jaw, which concords with Gómez-Polo et al. (20) who stated that regardless of bone type, the progressive development of bone surrounding the implant associated with secondary stability compensates for any differences in mechanical anchoring primary stability. In this study, there was a non-significant difference in primary stability ISQ values between the DI that were installed with an IT 35 Ncm and those installed with IT > 35 Ncm. Other authors (6, 21) J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022 Noaman and Bede 34 also reported that IT and RFA appeared as two independent features of primary stability. A recent systematic review (6) concluded that irrespective of the implant dimensions and protocol used in the previous studies, there was no relationship between the two methods of assessing primary stability, it proposed that the two values should be assessed separately, because a high torque does not always imply a high ISQ and vice versa. A plausible explanation could be related to the relaxation that would take place immediately after implant insertion, this can have an effect on both ISQ and bone implant contact measurements. Furthermore, it is well understood that both ISQ and bone contact measurements may be influenced by the viscoelastic nature of the bone and possibly simultaneous relaxation that occurs directly after implant placement (22). However, other studies (12, 20) reported a significant relationship between IT and primary stability ISQ values, indicating that a higher IT predicts greater primary ISQ values. In this study, there was no relationship between secondary stability and IT of DI. This finding is in a line with Gómez-Polo (20), and can be attributed to the fact that bone remodeling and bone apposition on DI surface (osseointegation) that occurs during the healing period may reduce the effect of implant IT. A non-significant difference regarding IT was observed relative to the recipient jaw of DI. This coincides with Farré-pagès et al. (12) who found no statistically significant differences according to different jaws locations. They observed only a slight trend of IT increase in the mandible than in the maxilla (42.34 and 40.22 Ncm, respectively). On the other hand, Salimov et al. (13) indicated higher IT values for DI placed in the mandible when compared to the maxilla. Conclusions The small sample size may limit the generalization obtained in this study; nevertheless it demonstrated that there was no relationship between the ISQ values and the IT, and that they should be used independently for estimating the bone implant interface condition. The findings of this study also showed that DI installed in mandible demonstrated significantly higher primary stability ISQ values than those installed in maxilla. Whereas, there was no such significant correlation of the secondary stability and IT with the recipient jaw. Conflict of interest: None declared References 1. Turkyilmaz I, Tözüm TF, Tumer C. Bone density assessments of oral implant sites using computerized tomography. J Oral Rehabil. 2007;34(4):267–72 . 2. Mesa F, Muñoz R, Noguerol B, et al. Multivariate study of factors influencing primary dental implant stability. Clin Oral Implants Res. 2008;19(2):196–200 . 3. Sennerby L. MN. 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Odontology. 2017;105(3):347–53 . العالقة بين حاصل ثبات الغرسة وعزم األدخال في ثباتية غرسة السن العنوان: سلوان يوسف حنا, 1 علي طريف نعمانالباحثون: المستخلص: قيم حاصل هذه الدراسة إلى تقييم العالقة بين هدفت . األولية استخداًما لتقييم استقرار الغرسةهي القياسات األكثر ( ISQ)وقيم حاصل استقرار الغرسة ( IT)قيم عزم اإلدخال الخلفية: . (IT)و قيم عزم اإلدخال ISQ استقرار الغرسة في زرعة أسنان 33)زرعة أسنان 42تلقى المرضى (. سنة 75-25المدى )سنة ( 13.64) 47.9عمر المرضى كان متوسط . مريضا 24شملت هذه الدراسة المواد وطرق العمل: ، تم إجراء عملية تحضير موقع الزرع بطريقة متسلسلة ، وتم تثبيت (CBCT)تم أخذ التصوير المقطعي المحوسب بحزمة مخروطية قبل الجراحة . في الفك العلوي 9الفك السفلي و قيم تسجيل قاطة اليدوية وخدام السإلى العمق المطلوب ، تم است زرعة أسنانإدخال ، عندما تعذر نيوتن سم 35 بعزم دورانباستخدام الطريقة اآللية ( ، كوريا دنتيوم) زرعة أسنان أسبوعًا من الجراحة ، وتم قياس 16تم توجيه المرضى لزيارة المتابعة بعد . Osstell® ISQ جهاز تم قياس ثبات الغرسة باستخدام. نيوتن سم 35 اكثر من على أنهاعزم اإلدخال بين الثبات لم يكن هناك ارتباط معنوي. للثبات األولي أعلى بكثير من تلك المثبتة في الفك العلوي ISQفي الفك السفلي قيم ة المثبت زرعات أالسنان ت أظهر النتائج: . االستقرار الثانوي بقيم عزم اإلدخال فيما يتعلق لم يتم اإلبالغ عن اختالف كبير . وقيم عزم اإلدخال ةاستقرار الزرع ISQتم العثور على عالقة غير ذات داللة إحصائية بين قيم . الثانوي والفك المستلم .زرعات أالسنانبالنسبة إلى الفك المستلم لـ .العظم االسنان مع واجهة غير مرتبطة ، ويجب استخدامها بشكل مستقل لتقدير حالة زرعةوقيم عزم اإلدخال ISQخلصت هذه الدراسة إلى أن قيم االستنتاج: