Journal List > J Korean Assoc Oral Maxillofac Surg > v.41(5) > 1091864

Jeong, Kim, Lee, Kim, Lee, and Kim: Analysis of time to failure of orthodontic mini-implants after insertion or loading

Abstract

Objectives

This study was performed to evaluate patterns of failure time after insertion, failure rate according to loading time after insertion, and the patterns of failure after loading.

Materials and Methods

A total of 331 mini-implants were classified into the non-failure group (NFG) and failure group (FG), which was divided into failed group before loading (FGB) and failed group after loading (FGA). Orthodontic force was applied to both the NFG and FGA. Failed mini-implants after insertion, ratio of FGA to NFG according to loading time after insertion, and failed mini-implants according to failed time after loading were analyzed.

Results

Percentages of failed mini-implants after insertion were 15.79%, 36.84%, 12.28%, and 10.53% at 4, 8, 12, and 16 weeks, respectively. Mini-implant failure demonstrated a peak from 4 to 5 weeks after insertion. The failure rates according to loading time after insertion were 13.56%, 8.97%, 11.32%, and 5.00% at 4, 8, 12, and 16 weeks, respectively. Percentages of failed mini-implants after loading were 13.79%, 24.14%, 20.69%, and 6.9% at 4, 8, 12, and 16 weeks, respectively.

Conclusion

Mini-implant stability is typically acquired 12 to 16 weeks after insertion, and immediate loading can cause failure of the mini-implant. Failure after loading was observed during the first 12 weeks.

I. Introduction

Small-sized mini-implants have been applied for skeletal orthodontic anchorage1. Orthodontic mini-implants have a smaller diameter and a shorter length than the implants used for prosthodontic treatment23. Therefore, orthodontic mini-implants tend to demonstrate a higher failure rate than conventional implants4. The frequent failures of orthodontic mini-implants during treatment is a weak point of their use and can affect treatment plans and duration5. Other studies have reported 0% to 30% failure rates of orthodontic mini-implants inserted into alveolar bone67.
Because the size and surface of a mini-implant are small and the initial stability of it might be week, healing time is needed after insertion8. However, immediate loading on prosthodontic implants has shown a good success rate910. Other studies have reported that loading time did not affect the success rate of prosthetic implants11. In orthodontic mini-implants, an immediate, light orthodontic load did not affect the bone healing process12. Loading can reduce the sclerostin level13 and result in release of prostaglandin14. These changes can enhance bone formation15 and inhibit bone resorption16. There was no significant difference in marginal bone loss between immediate loading and delayed loading in such implants17.
However, the bone remodeling process involving bone resorption and apposition after insertion of a mini-implant needs time to heal in order to provide stable support of the mini-implant18.
Because of the high failure rates of orthodontic mini-implants, loading time is believed to be important. Analysis regarding the failure time of orthodontic mini-implant after insertion and loading could help guide clinical practice when using orthodontic mini-implants. This study was conducted to evaluate the pattern of failure time after insertion, failure rate according to loading time after insertion, and the pattern of failure after loading.

II. Materials and Methods

Subjects included 134 patients (mean age, 20.08±7.52 years) with 331 inserted mini-implants (Miangan; Biomaterials Korea, Seoul, Korea) with a diameter of 1.2 mm and length of 7.0 mm. This study was done from July 2006 to June 2010 in dental clinic of Seoul National University Bundang Hospital (Seongnam, Korea). The surfaces of the mini-implants were machined but not treated. All mini-implants were installed on the buccal alveolar bone between the first premolar and the second molar of the maxilla and mandible.
Mini-implants were inserted by 1 operator using a self-drilling method after orthodontic leveling and alignment.
The mini-implants were classified into the failure group (FG) and non-failure group (NFG). The FG was divided into the failed group before loading (FGB) and failed group after loading (FGA). Orthodontic force was applied to both the NFG and FGA.
The failure rate was calculated for FG and NFG. To evaluate the pattern of failure time after insertion of mini-implant, the failed mini-implants were analyzed according to the failure time (weeks) after insertion in the FG.(Fig. 1) For evaluation of failure rate according to loading time after insertion, the failure rate, calculated as the ratio of FGA to NFG, was analyzed according to loading time (weeks) after insertion. To analyze the patterns of failure after loading, the failed mini-implants were analyzed according to failure time (weeks) after loading. The statistic analysis was done using SPSS 12.0 for Windows (SPSS Inc., Chicago, IL, USA).
This study was approved by the Ethics Committee for Research (Seoul National University Bundang Hospital Ethical Board, B-1011-115-110).

III. Results

In this study, 57 of 331 inserted mini-implants experienced failure. Of these, 29 were in the FGA, and 28 were in the FGB. The mean age of the subjects was 22.08±7.52 years (NFG, 22.39±7.54 years; FG, 20.89±7.33 years).(Table 1)
Failure rates were 15.79%, 36.84%, 12.28%, and 10.53% after 4, 8, 12, and 16 weeks, respectively.(Table 2, Fig. 2) In the failed mini-implant group, 75.44% of failures occurred within 16 weeks after insertion. The failure of mini-implants had a peak from 4 to 5 weeks.(Fig. 2) The mini-implants loaded during the first 4 weeks after insertion showed the highest failure rate.(Table 3, Fig. 3) The failure rates in relation to loading time after insertion were 13.56%, 8.97%, 11.32%, and 5.00% at 4, 8, 12, and 16 weeks, respectively. Mini-implants loaded during the first week after insertion showed a 42.50% failure rate.(Fig. 3) Percentages of failed mini-implants after loading in this group were 13.79%, 24.14%, 20.69%, and 6.90% at 4, 8, 12, and 16 weeks, respectively.(Table 4, Fig. 4) Mini-implant failures after loading in this group occurred mostly during the first 12 weeks after loading. From 4 to 12 weeks after loading, the failure rate of mini-implants in this group was 58.62%. Failures were observed intermittently until 44 weeks after loading.(Fig. 4) Tables 2, 3, 4 illustrate the data in 4-week intervals. Fig. 2, 3, 4 present the data in 1-week intervals to provide greater detail.

IV. Discussion

The results of this study showed some initial failures after insertion. About 75% of failed mini-implants occurred during the 16 weeks after insertion.(Table 2) Specifically, when the loading time after insertion was less than 12 weeks, the failure rates of mini-implant were high. These results signify that the stability of the mini-implant is acquired 12 to 16 weeks after insertion. They indicate that the bone remodeling process after insertion occurs during the first 3 to 4 months after insertion. For implant success, loading time is important. Time for bone healing of tissue damaged through the process of implantation is needed. Therefore, delayed loading has been suggested by other studies focusing on implant stability1920.
Before loading, the failure rate during the first 4 to 5 weeks was the highest.(Fig. 2) It is possible that bone resorption in the bone remodeling process is most active around 4 weeks after insertion in humans, and that bone apposition is achieved 3 to 4 months after insertion.
Some studies have reported that immediate or early loading of mini-implants shows good stability212223. A previous animal study has suggested no significant differences in success rate or histological findings between immediate loading and delayed loading24. However, the failure rate in relation to loading time after insertion in the present study was highest during the first week.(Fig. 3) This might indicate that immediate loading after insertion activates bone resorption and results in mini-implant failure25.
Because mini-implants have a smaller diameter, shorter length, and less surface area contacting the bone compared to conventional implants, mechanical stability in the early stages could be affected and reduced by limited bone resorption around the mini-implant26.
In this study, the failure of loaded mini-implants happened in case of the load was applied during the first 12 weeks after insertion except 37 weeks. This suggests that the load until 12 weeks after insertion affects the stability of a mini-implant, and loading is thus recommended at approximately 12 weeks after insertion.
Failure after loading occurred frequently until 13 weeks (Fig. 4), with a high failure rate from 6 to 13 weeks. It is recommended that the clinician should be careful until 3 months after loading to sustain the mini-implant because of failure. Additionally, failure after loading was observed intermittently until 35 weeks. This suggests that the stability of the miniimplant is affected by bone remodeling after tooth movement through the end of treatment. This might be the result of insufficient surface area of the mini-implant in contact with bone in order to obtain sufficient surrounding support27.
Failure of the mini-implant results in difficulties and affects the treatment plan. Although there are various causes of miniimplant failure, selection of loading time after insertion is an important factor for avoiding failure. Immediate loading is not recommended, and delayed loading of the mini-implant is suggested until 12 to 16 weeks after insertion.
For more stable use of mini-implants in clinics, further studies regarding surface treatment of mini-implants are needed because implant surface might influence osseointegration time and implant failure. Additionally, if other factors, such as loading time, can be controlled in future studies, the more detailed results would be helpful to clinicians.

V. Conclusion

1. Approximately 75% of mini-implant failures occurred within 16 weeks of insertion. When the loading time after insertion was less than 12 weeks, the failure rate of the mini-implant was high. Proper stability of the mini-implant is acquired about 3 to 4 months after insertion.
2. The failure rate according to loading time after insertion was highest when the mini-implants were loaded during the first week after insertion. Immediate loading could cause failure of a mini-implant.
3. Failure after loading was frequently observed in the mini-implant until 13 weeks. Therefore, attention to the stability of the mini-implant is necessary until 3 months after loading.

Notes

This study was supported by grant no 04-2011-0056 from the SNUDH Research Fund.

Conflict of Interest: No potential conflict of interest relevant to this article was reported.

References

1. Suh HY, Lee SJ, Park HS. Use of mini-implants to avoid maxillary surgery for Class III mandibular prognathic patient: a long-term post-retention case. Korean J Orthod. 2014; 44:342–349. PMID: 25473650.
crossref
2. Kanomi R. Mini-implant for orthodontic anchorage. J Clin Orthod. 1997; 31:763–767. PMID: 9511584.
3. Lee HJ, Lee KS, Kim MJ, Chun YS. Effect of bite force on orthodontic mini-implants in the molar region: finite element analysis. Korean J Orthod. 2013; 43:218–224. PMID: 24228236.
crossref
4. Herrmann I, Lekholm U, Holm S, Kultje C. Evaluation of patient and implant characteristics as potential prognostic factors for oral implant failures. Int J Oral Maxillofac Implants. 2005; 20:220–230. PMID: 15839115.
5. Lee JH, Choo H, Kim SH, Chung KR, Giannuzzi LA, Ngan P. Replacing a failed mini-implant with a miniplate to prevent interruption during orthodontic treatment. Am J Orthod Dentofacial Orthop. 2011; 139:849–857. PMID: 21640893.
crossref
6. Wiechmann D, Meyer U, Büchter A. Success rate of mini- and micro-implants used for orthodontic anchorage: a prospective clinical study. Clin Oral Implants Res. 2007; 18:263–267. PMID: 17348892.
crossref
7. Kim JS, Choi SH, Cha SK, Kim JH, Lee HJ, Yeom SS, et al. Comparison of success rates of orthodontic mini-screws by the insertion method. Korean J Orthod. 2012; 42:242–248. PMID: 23173117.
crossref
8. Kim SH, Lee SJ, Cho IS, Kim SK, Kim TW. Rotational resistance of surface-treated mini-implants. Angle Orthod. 2009; 79:899–907. PMID: 19705943.
crossref
9. Grunder U. Immediate functional loading of immediate implants in edentulous arches: two-year results. Int J Periodontics Restorative Dent. 2001; 21:545–551. PMID: 11794565.
10. Kim YK, Kim BS, Yun PY, Mun SU, Yi YJ, Kim SG, et al. The seven-year cumulative survival rate of Osstem implants. J Korean Assoc Oral Maxillofac Surg. 2014; 40:68–75. PMID: 24868503.
crossref
11. Ioannidou E, Doufexi A. Does loading time affect implant survival? A meta-analysis of 1,266 implants. J Periodontol. 2005; 76:1252–1258. PMID: 16101355.
crossref
12. Catharino PC, Dominguez GC, Pinto Ddos S Jr, Morea C. Histologic, histomorphometric, and radiographic monitoring of bone healing around in-office-sterilized orthodontic mini-implants with or without immediate load: study in rabbit tibiae. Int J Oral Maxillofac Implants. 2014; 29:321–330. PMID: 24683557.
crossref
13. Robling AG, Niziolek PJ, Baldridge LA, Condon KW, Allen MR, Alam I, et al. Mechanical stimulation of bone in vivo reduces osteocyte expression of Sost/sclerostin. J Biol Chem. 2008; 283:5866–5875. PMID: 18089564.
crossref
14. Klein-Nulend J, van der Plas A, Semeins CM, Ajubi NE, Frangos JA, Nijweide PJ, et al. Sensitivity of osteocytes to biomechanical stress in vitro. FASEB J. 1995; 9:441–445. PMID: 7896017.
15. Forwood MR. Inducible cyclo-oxygenase (COX-2) mediates the induction of bone formation by mechanical loading in vivo. J Bone Miner Res. 1996; 11:1688–1693. PMID: 8915776.
crossref
16. Tatsumi S, Ishii K, Amizuka N, Li M, Kobayashi T, Kohno K, et al. Targeted ablation of osteocytes induces osteoporosis with defective mechanotransduction. Cell Metab. 2007; 5:464–475. PMID: 17550781.
crossref
17. Kim YK, Ahn KJ, Yun PY, Kim M, Yang HS, Yi YJ, et al. Effect of loading time on marginal bone loss around hydroxyapatite-coated implants. J Korean Assoc Oral Maxillofac Surg. 2013; 39:161–167. PMID: 24471037.
crossref
18. Rebaudi A, Laffi N, Benedicenti S, Angiero F, Romanos GE. Microcomputed tomographic analysis of bone reaction at insertion of orthodontic mini-implants in sheep. Int J Oral Maxillofac Implants. 2011; 26:1233–1240. PMID: 22167428.
19. Raghavendra S, Wood MC, Taylor TD. Early wound healing around endosseous implants: a review of the literature. Int J Oral Maxillofac Implants. 2005; 20:425–431. PMID: 15973954.
20. Atsumi M, Park SH, Wang HL. Methods used to assess implant stability: current status. Int J Oral Maxillofac Implants. 2007; 22:743–754. PMID: 17974108.
21. Al-Sawai AA, Labib H. Success of immediate loading implants compared to conventionally-loaded implants: a literature review. J Investig Clin Dent. 2015; DOI: 10.1111/jicd.12152. [Epub ahead of print].
crossref
22. Romanos G, Grizas E, Laukart E, Nentwig GH. Effects of early moderate loading on implant stability: a retrospective investigation of 634 implants with platform switching and morse-tapered connections. Clin Implant Dent Relat Res. 2015; DOI: 10.1111/cid.12314. [Epub ahead of print].
crossref
23. Kim YK, Kim JH, Yi YJ, Kwon MJ, Yun PY. Prospective comparative study of tapered implants with SLA surfaces in the maxillary posterior area according to 3- and 6-month loading time. Int J Periodontics Restorative Dent. 2015; 35:271–276. PMID: 25738348.
crossref
24. Ramazanzadeh BA, Fatemi K, Dehghani M, Mohtasham N, Jahanbin A, Sadeghian H. Effect of healing time on bone-implant contact of orthodontic micro-implants: a histologic study. ISRN Dent. 2014; DOI: 10.1155/2014/179037.
crossref
25. Lee SJ, Ahn SJ, Lee JW, Kim SH, Kim TW. Survival analysis of orthodontic mini-implants. Am J Orthod Dentofacial Orthop. 2010; 137:194–199. PMID: 20152674.
crossref
26. Kim SH, Cho JH, Chung KR, Kook YA, Nelson G. Removal torque values of surface-treated mini-implants after loading. Am J Orthod Dentofacial Orthop. 2008; 134:36–43. PMID: 18617101.
crossref
27. Kim JW, Ahn SJ, Chang YI. Histomorphometric and mechanical analyses of the drill-free screw as orthodontic anchorage. Am J Orthod Dentofacial Orthop. 2005; 128:190–194. PMID: 16102403.
crossref
Fig. 1

The diagram to explain 'failed time after insertion', 'loading time after insertion', and 'failed time after loading'.

jkaoms-41-240-g001
Fig. 2

The number of failed mini-implants as to the time after insertion.

jkaoms-41-240-g002
Fig. 3

Failure rate as to the loading time after insertion.

jkaoms-41-240-g003
Fig. 4

The number of failed mini-implants as to the failed time after loading.

jkaoms-41-240-g004
Table 1

Number of mini-implants and age in the non-failed group (NFG) and failure group (FG)

jkaoms-41-240-i001
Value
Number of inserted mini-implants 331
 NFG 274 (82.78)
 FG 57 (17.22)
  Failed group before loading 28
  Failed group after loading 29
Age (yr) 22.08±7.52
 NFG 22.39±7.54
 FG 20.89±7.33

Values are presented as number only, number (%), or mean±standard deviation.

Table 2

Failed mini-implants according to time after insertion

jkaoms-41-240-i002
Time after insertion (wk) Failed group before loading Failed group after loading Total Accumulated total
4 9 (32.14) 0 9 (15.79) 9 (15.79)
8 17 (60.71) 4 (13.79) 21 (36.84) 30 (52.63)
12 2 (7.14) 5 (17.24) 7 (12.28) 37 (64.91)
16 0 6 (20.69) 6 (10.53) 43 (75.44)
20 0 1 (3.45) 1 (1.75) 44 (77.19)
24 0 2 (6.90) 2 (3.51) 46 (80.70)
28 0 2 (6.90) 2 (3.51) 48 (84.21)
32 0 1 (3.45) 1 (1.75) 49 (85.96)
36 0 2 (6.90) 2 (3.51) 51 (89.47)
40 0 4 (13.79) 4 (7.02) 55 (96.49)
44 0 1 (3.45) 1 (1.75) 56 (98.25)
48 0 0 0 56 (98.25)
52 0 1 (3.45) 1 (1.75) 57 (100.00)

Values are presented as number (%).

Table 3

Failed mini-implants according to loading time after insertion

jkaoms-41-240-i003
Loading time after insertion (wk) Loaded mini-implant (n) Failure rate (%)
Failed group after loading Non-failure group Total
4 8 51 59 13.56
8 13 132 145 8.97
12 6 47 53 11.32
16 1 19 20 5.00
20 0 7 7 0
24 0 9 9 0
28 0 4 4 0
32 0 0 0 0
36 0 2 2 0
40 1 3 4 25.00
Table 4

Failed mini-implants according to failed time after loading

jkaoms-41-240-i004
Time after loading (wk) Failed mini-implant after loading
Number (%) Accumulated number (%)
4 4 (13.79) 4 (13.79)
8 7 (24.14) 11 (37.93)
12 6 (20.69) 17 (58.62)
16 2 (6.90) 19 (65.52)
20 1 (3.45) 20 (68.97)
24 2 (6.90) 22 (75.86)
28 1 (3.45) 23 (79.31)
32 1 (3.45) 24 (82.76)
36 4 (13.79) 28 (96.55)
40 0 28 (96.55)
44 1 (3.45) 29 (100.00)
TOOLS
Similar articles