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A study of interleukin 1β levels in peri-miniscrew crevicular fluid (PMCF)

Abstract

Background

This study provides a vital insight in assessing the clinical and biochemical changes in interleukin (IL)-1β levels in peri-miniscrew crevicular fluid (PMCF) during the course of orthodontic tooth movement.

Methods

The study comprised the analysis of IL-1β in peri-miniscrew crevicular fluid obtained from crevices around the miniscrews inserted in 11 patients (eight females and three males, mean age 17.3 ± 4.64 years) with all first premolar extraction and maximum anchorage requirement using miniscrew-supported anchorage. Miniscrews were loaded at 3 weeks after placement by 200-g nitinol closed coil springs of 9-mm length for en masse retraction. Peri-miniscrew crevicular fluid was collected at miniscrew placement (T1), at 3 weeks (T2/baseline) and on loading at 0 (T3) and 1 day (T4), 21 (T5), 72 (T6), 120 (T7), 180 (T8) and 300 (T9) days. IL-1β levels were estimated by enzyme-linked immunosorbent assay (ELISA). Peri-miniscrew tissue was examined for signs of inflammation, and also, miniscrew mobility was assessed with Periotest and handles of two mouth mirrors.

Results

IL-1β levels in all miniscrews were significantly higher at T1 and peaked again at T4 showing a bimodal peak. However, there was a gradual and statistically significant decrease in IL-1β till T5, while further changes till the end of the study were statistically not significant.

Conclusions

The changing levels of IL-1β levels in PMCF over a duration of 300 days are suggestive of the underlying inflammatory process. IL-1β levels in PMCF show a significant rise during miniscrew insertion and on immediate loading. The trend of gradually reducing IL-1β levels around the miniscrew over the period after loading towards baseline is suggestive of adaptive bone response to stimulus.

Background

Miniscrews have drawn immense consideration in orthodontic armamentarium since they were initially used as contrivance for reinforcing orthodontic anchorage. These implements now stand poised to become one of the most imperative and useful means of orthodontic anchorage for eclectic clinical applications due to their ease in placement at various locations in the mouth. However, it is quite true that there is still some apprehension regarding their stability and hence usefulness in providing absolute orthodontic anchorage during the entire course of treatment.

The reported success rate of the miniscrews ranged from 71.4% to 100% [1, 2]. Peri-implantitis accounts for about 30% of miniscrew failures [3]. Peri-implantitis is a progressive peri-implant bone loss in conjunction with soft tissue inflammatory lesion. Initially, peri-mucositis (a reversible inflammation of the soft tissues surrounding the miniscrew) occurs, which if left untreated may progress to peri-implantitis [4]. An early and reliable detection of any adverse peri-miniscrew tissue reaction is essential for patients being treated with miniscrew [5].

Recent studies show that in periodontal and peri-miniscrew tissues, cytokines, tumour necrosis factor and transforming growth factor have important roles in regulating and amplifying inflammatory response [57]. Interleukin (IL)-1β is one of the most potent cytokine in the inflammatory process in the oral cavity triggered by various stimuli including neurotransmitters, bacterial products, other cytokines and mechanical forces. The action of IL-1β includes attracting leucocytes and stimulating fibroblasts, endothelial cells, osteoclasts and osteoblasts to promote bone resorption and to inhibit bone formation [8].

Peri-miniscrew crevicular fluid (PMCF) is an osmotically mediated inflammatory exudate originating from the vessels of the gingival plexus. Its composition is similar to that of the gingival crevicular fluid (GCF) containing host-derived enzymes and their inhibitors, inflammatory mediators, host response modifiers and tissue breakdown products [9]. Analysis of PMCF offers a non-invasive means of studying host response in peri-miniscrew disease and may provide an early indication of patients at risk for active disease [10].

There are several reports on IL-1β in dental implants; however, IL-1β in PMCF around miniscrews has not been explored enough. Sari and Ucar [7] studied the level of IL-1β around miniscrews starting 2 weeks after miniscrew placement and activation of coil spring, followed up to 21 days. No study has been reported so far about the changes in IL-1β levels at miniscrew placement, before loading and after loading during the course of extraction space closure. Therefore, this comprehensive study was undertaken with the aim to evaluate the changes in IL-1β levels in PMCF at miniscrew placement, before and after application of orthodontic forces and its correlation with the clinical parameters over the course of orthodontic treatment.

Methods

PMCF analysis was conducted from samples collected around the crevices of miniscrews placed in 11 bimaxillary protrusive patients (mean age 17.3 ± 4.64 years) requiring all first premolar extraction and treated with Roth prescription (0.022″ × 0.028″). The patients were followed for 300 days. In one of the patients, two miniscrews failed 2 weeks after placement; hence, the patient could not be followed throughout the period of the study. Therefore, the study was conducted to follow a total of 40 miniscrews in 10 patients for 300 days. Ethical clearance was obtained from the Ethics Committee of All India Institute of Medical Sciences, New Delhi with letter reference number IESC/T-20/29.01.10 dated 8 March 2010 and letter reference number IESC/T-22/2011 dated 13 January 2011. Written consent was obtained from each patient prior to their inclusion in the study. None of the patients had history of any systemic disease, hormonal imbalance or drug intake, and all had satisfactory periodontal health prior to the start of orthodontic treatment.

The buccal interradicular bone in the attached gingiva between the second premolar and first molar was chosen as site for miniscrew placement. Miniscrews (8-mm long, 1.5 mm in diameter, bracket head type; Absoanchor, Dentos, Daegu, South Korea) were placed at the intended sites at 60° to the long axis of the teeth under local anaesthesia [11]. Miniscrews were connected to the first molars using a 0.017″ × 0.025″ stainless steel wire passively, thereby providing indirect anchorage. En masse retraction was initiated 3 weeks after miniscrew insertion with a 9.0-mm nitinol closed coil spring (200-g force) attached to the soldered hook in between the lateral incisor and canine in a 0.019″ × 0.025″ stainless steel wire in both the arches. The retraction appliance was adjusted so as to provide constant force till space closure was achieved. However, the amount of force that was loaded to the miniscrew head at T3 and continued up to T9 might be different from 200-g because a sectional assembly was connected between the implant head and accessory buccal tube on the first molar (Figure 1).

Figure 1
figure 1

Assembly showing retraction mechanics using miniscrew as anchorage.

The patients were instructed and followed for oral hygiene, more so around the peri-miniscrew with frequent brushing using a soft brush and mouth rinsing with 0.5 oz of 0.2% chlorhexidine gluconate twice daily. No anti-inflammatory drug was prescribed prior to and after miniscrew placement.

Schedule of sample collection and clinical examination

Each sample of PMCF was collected by a 1 to 5-μl calibrated volumetric micro-capillary pipette (Sigma Aldrich Chemicals Company Limited, Bangalore, India) placed at the crevice, according to the method described by Griffiths [12]. The samples were collected at the following time observations: T1 (4 h after miniscrew placement), T2 (baseline, 3 weeks just prior to loading) and on loading T3 (0 day), T4 (1 day), T5 (21 days), T6 (72 days), T7 (120 days), T8 (180 days) and T9 (300 days) (Table 1). Although PMCF sample T1 was taken 4 h after miniscrew placement to allow cessation of bleeding, PMCF samples that were contaminated with the remaining blood during miniscrew placement procedure at T1 were discarded. Isolation of the miniscrew site was done with a cheek retractor, cotton rolls and a gentle air spray. PMCF (1 μl) was collected in Eppendorf tubes for 5 to 20 min from each test site at 25°C. Implant placement and PMCF sample collection was done in the morning hours between 9 a.m. and 11 a.m. except for T1 which was collected between 1 p.m. and 3 p.m. since it had to be collected 4 h after implant placement. GCF samples were gently collected, and extreme care was taken not to cause any slightest harm or injury during the sample collection. The samples thus obtained were diluted to 1:100 with Sorensen's buffer (0.05% bovine serum albumin in phosphate buffered saline, ph 7.0), centrifuged at 2,000 rpm for 1 min and stored at −70°C until assayed for interleukin levels.

Table 1 Schedule of PMCF sample collection and clinical examination

IL-1β levels were estimated using human IL-1β ELISA kit Diaclone-Eli-pair (Besancon, France). Optical density was measured at 450 nm using Omega Microplate Reader™ (BMG Labtech, Ortenberg, Germany). The quantification of IL-1β was determined using standard curves for IL-1β, which showed a direct relationship between optical density and cytokine concentration.

Presence of any signs of peri-miniscrew inflammation (redness, swelling, pain) was detected clinically. Miniscrew mobility was assessed by a single operator using Periotest™ (Bensheim, Germany) with values of 0 to 9 on the Periotest scale indicating that the miniscrew is mechanically stable and values above 9 indicating clinical failure, and blunt ends of mouth mirror handles were used for visual evaluation [13]. A miniscrew was considered healthy if there was no visible sign of inflammation with no or physiologic mobility (Periotest value ranging from 0 to 9). Presence of mobility (visual miniscrew mobility scales 1 to 3, Periotest value more than 9) was considered the distinguishing feature between mucositis and peri-implantitis (Table 2).

Table 2 Scale for assessment of peri-miniscrew tissue health and mobility

Statistical analysis

Data was analyzed using SPSS version 20 and represented in median, maximum and minimum. Changes in between the quadrants were analyzed using the Friedman test followed by multiple comparisons using Wilcoxon signed-rank non-parametric test with Bonferroni correction. A p value <0.05 was taken as statistically significant, and in multiple comparison, a p value is considered significant after Bonferroni test.

Results and discussion

Results

The levels of IL-1β at each site were first tabulated and compared for each quadrant in each patient. The trend was found to be the same with no statistically significant difference among the four quadrants. Figure 2 shows the average taken for all four quadrants of ten patients followed for 300 days.

Figure 2
figure 2

Trend of IL-1β levels in PMCF at different time intervals. 1-T1 (4 hours after Implant placement), 2-T2 (Baseline: 3 weeks, just prior to loading), 3-T3 (Just after loading: 0 day), 4-T4 (At 24 hours after loading: 1 day), 5-T5 (At 21 days), 6-T6 (At 72 days), 7-T7 (At 120 days), 8-T8 (At 180 days) and 9-T9 (At 300 days). The boxes represent the values from the 25th to the 75th percentile. The middle lines represent the medians. The vertical lines extend from the minimal to the maximal values, exluding the outliers marked with small dark circles.

IL-1β level at T1 was 266.33 pg/ml which was significantly higher as compared to that at baseline (T2) being 131.95 pg/ml (p = 0.001). The levels rose slightly to185.76 pg/ml at T3 compared to T2. At T4, the levels had risen significantly to 273.93 pg/ml (p = 0.001). The levels reduced to 153.57 pg/ml at T5 (p = 0.014) and further to 137.77 pg/ml at T6. The values were statistically significant till T5, following which the levels further declined but were not statistically significant (Table 3) with levels falling to 120.01 pg/ml at T9 (p = 0.737).

Table 3 Level of IL-1β (pg/ml; median) at various time observations

Three miniscrew sites were reported with mucositis initially at T2 and one site at T5 (Table 4). Periotest values for healthy as well as mucositis sites were between 0 and 9, and clinical miniscrew mobility scale was 0 with no clinically detectable mobility although miniscrews with mucositis did show variable amount of redness, swelling and/or pain. Peri-implantitis was reported in two sites in the same patient, the right and left sides of the mandible, at 2 weeks after placement, which was excluded from the study. IL-1β levels at T1 in these two sites were 274.83 and 228.13 pg/ml, respectively (Table 5). At miniscrew failure, the level of IL-1β rose significantly to 361.63 and 385.35 pg/ml, respectively, as against two stable miniscrews in the maxilla in the same patient where the level of IL-1β decreased to 93.71 and 103.24 pg/ml, respectively, at 2 weeks after placement, from 167.41 and 192.67 pg/ml, respectively, at T1. Two miniscrews with peri-implantitis had Periotest values of 22 and 29, respectively, and the clinical miniscrew mobility scale was 3 with mobility evident. Both the sites clinically showed redness and swelling, but the patient did not complain of pain.

Table 4 Trend in the levels of IL-1β (pg/ml) in mucositis patients
Table 5 Trend in the levels of IL-1β in pg/ml in a peri-implantitis patient

Discussion

Miniscrew success has been recognized as the ability of screw to sustain anchorage loads during orthodontic treatment without inflammation and mobility. Various studies present in the literature attempt to assess the stability of miniscrews from different perspectives such as clinical [3, 14, 15], biomechanical [1618], histological [15],[1921], or biochemical. Several biochemical markers have been associated with inflammation and remodelling of peri-implant tissue around osseo-integrated dental implants [2023], but only few studies were found in the literature in which biochemical assessments were used to investigate the stability of miniscrews [7],[2426]. In the study by Sari and Ucar [7], IL-1β levels in PMCF were collected only after loading to determine the effects of mechanical stress on the miniscrews. The mean IL-1β level in PMCF of healthy miniscrews did not increase significantly during orthodontic loading. Intachai et al. [24] assessed medians of chondroitin sulphate levels in PMCF around ‘immobile’ miniscrews, between the unloaded and loaded periods, which were not significantly different.

In our prospective study, IL-1β levels were observed at various times, both before and after the loading of miniscrew. It was started with the belief that the clinical stability of the miniscrew must reflect the activity of the underlying biomarkers.

In the present study, the first PMCF sample was collected 4 h after miniscrew placement, allowing cessation of bleeding. The early acute inflammatory changes account for junctional retraction that occurred in response to the cytokine (IL-1β) which begins within 4 to 6 h after injury and lasts for more than 24 h due to the trauma during the miniscrew placement procedure. Further, IL-1 elicits the release of histamine from mast cells at the site of inflammation which then triggers early vasodilatation and increased vascular permeability [27].

The fall of IL-1β level at T2 was observed at 3 weeks whereby miniscrew remained unloaded during this period. This decreased level suggests that at 21 days, there was no more cellular stress in the absence of load. A slight increase in the IL-1β level after loading can be explained by the fact that in orthodontics, mechanical stress appears to evoke biochemical and structural responses in a variety of cells in vivo and in vitro[28]. Alhashimi et al. [29] showed that the application of orthodontic force induces de novo synthesis of proinflammatory cytokines IL-1β and IL-6, which support the hypothesis that these proinflammatory cytokines play important roles in bone resorption during the application of orthodontic force. IL-1 upregulates receptor activator of nuclear factor κ B ligand (RANKL) which leads to bone resorption [30]. Further, according to Kanzaki et al. [31], bone resorption is regulated by cytokines released in response to the orthodontic force.

Although there were two peaks of IL-1β levels during the study attributed to delayed loading, it was done to assess the change in IL-1β level around the unloaded miniscrew apart from observing the effect of loading on IL-1β levels. A 3-week period before loading was selected based on the study which states that loading during the first 2 weeks of healing time would damage the stability of the implant-bone fixture [32, 33], further emphasizing on the loading period of 3 weeks.

Transient elevation of IL-1β 24 h after loading shows that the cells within the attached gingiva surrounding the miniscrew produce IL-1β in response to the orthodontic stimulus which can be detected in the PMCF. This level of IL-1β peaked since during acute inflammation, IL-1β which is released 1 to 2 h after mechanical stimulus peaks at 24 to 48 h [27]. Though IL-1β levels rose significantly, the miniscrews were stable. Huja et al. [34] also demonstrated that miniscrews could withstand significantly greater force levels and when loaded purely in an axial direction; they observed maximal force loads of 388.3 N.

Over the period, there was a gradual fall in IL-1β levels at 21 days after loading, and levels declined further over the 300-day study period reaching the baseline. This could be explained by the fact that cytokines are involved in extensive networks that involve synergistic as well as antagonistic interactions and exhibit both negative and positive regulatory effects on various target cells. IL-1 receptor antagonist (IL-1Ra) inhibits IL-1 action by competing with IL-1 to bind to the IL-1 receptor (IL-1R) [35, 36]. This kind of feedback or negative regulation is likely to modulate the remodelling process in vivo after a synergistic or an additive effect because a number of cytokines are simultaneously involved in the mechanically activated periodontal cells. Also, this decrease might be attributed to the adaptation of periodontal tissues to the orthodontic force, and feedback mechanisms might prevent an excessive increase in the inflammation mediators, thereby preventing harmful consequences [37].

An important regulatory step in the expression of the cytokines is gene transcription. Several positive and negative transcription factors function in a concerted manner to regulate the transcription of cytokine genes to initiate immediately on activation and to shut down quickly, even in the continuous presence of the stimulating agent [38]. IL-1β levels in this study are high as compared to those of a previous study [7] which could probably be attributed to racial variation [39].

Mucositis was reported in three miniscrew sites 3 weeks after miniscrew placement and in one site 21 days after loading. This could be due to the poor oral hygiene at these sites. Plaque around miniscrews acts as a local factor for inflammation. Chemoattractant effect of bacterial lipopolysaccharide present in plaque activates macrophages and polymorphonuclear leukocytes to produce inflammatory mediators like TNF-α, IL-1, IL-6 and other cytokines related to host response and tissue destruction [40]. With regular oral hygiene instructions and professional oral hygiene measures, the peri-miniscrew inflammation subsided.

Peri-implantitis was reported in two miniscrews 2 weeks after placement, before loading, both in the mandible of the same patient. It suggests that the primary factor causing miniscrew loss is peri-miniscrew soft tissue inflammation, not the application of orthodontic force. A further indication that low-magnitude static forces are not detrimental to miniscrew success was presented in a study [41], in which miniscrew losses were attributed to infection and occurred during healing periods, not after load activation. The levels of IL-1β from the failed miniscrews were high even at the time of miniscrew placement. The elevation of IL-1β levels before miniscrew failure might be attributed to underlying bone resorption around the miniscrew, but the sample size of peri-implantitis is too small to draw conclusions.

Animal and human studies have shown that the levels of sex steroids, including progesterone and oestradiol, fluctuate in accordance with oestrous or menstrual cycle. Osteoclast activity can be inhibited by oestrogen in a direct or indirect manner, thereby modulating bone resorption [42]. This aspect is beyond the scope of this study since it focused on changes in IL-1β levels with time and also due to the unequal and small sample size with a male/female ratio of 7:3.

In this study, PMCF sample collection was done 3 weeks after miniscrew placement. The authors believe that more frequent sample collection could have been done during this 3-week period and results of this study could be further confirmed with a larger sample size. Further, miniscrews were indirectly loaded; thereby, precise load on miniscrew cannot be calculated. Since IL-1β levels rise both during inflammation as well as during orthodontic loading, the IL-1B levels in PMCF may only represent the release of cytokine as an inflammatory response but may not represent the bone stress from orthodontic loading especially at T6 to T9. Thus, alveolar bone remodelling biomarkers, in addition to inflammatory mediators, are suggested to be monitored during further investigations.

Conclusions

The changing levels of IL-1β in PMCF over a duration of 300 days are suggestive of the underlying inflammatory process. IL-1β levels in PMCF show a significant rise during miniscrew insertion and on immediate loading. The trend of gradually reducing IL-1β levels around the mini-screw over the period after loading towards the baseline is suggestive of adaptive bone response to stimulus.

Abbreviations

IL-1β:

Interleukin 1β:

PMCF:

Peri-miniscrew crevicular fluid:

GCF:

Gingival crevicular fluid:

References

  1. Papadopoulos MA, Papageorgiou SN, Zogakis IP: Clinical effectiveness of orthodontic miniscrew implants: a meta-analysis. J Dent Res 2011, 90: 969–76. 10.1177/0022034511409236

    Article  PubMed  Google Scholar 

  2. Schatzle M, Mannchen R, Zwahlen M, Lang NP: Survival and failure rates of orthodontic temporary anchorage devices: a systematic review. Clin Oral Implants Res 2009, 20: 1351–9. 10.1111/j.1600-0501.2009.01754.x

    Article  PubMed  Google Scholar 

  3. Miyawaki S, Koyama I, Inoue M, Mishima K, Sugahara T, Takano-Yamamoto T: Factors associated with the stability of titanium screws placed in the posterior region for orthodontic anchorage. Am J Orthod Dentofacial Orthop 2003, 124: 373–8. 10.1016/S0889-5406(03)00565-1

    Article  PubMed  Google Scholar 

  4. Mombelli A, Lang NP: The diagnosis and treatment of peri-implantitis. Periodontol 2000 1998, 17: 63–76. 10.1111/j.1600-0757.1998.tb00124.x

    Article  PubMed  Google Scholar 

  5. Javed F, Al-Hezaimi K, Salameh Z, Almas K, Romanos GE: Proinflammatory cytokines in the crevicular fluid of patients with peri-implantitis. Cytokine 2011, 53: 8–12. 10.1016/j.cyto.2010.08.013

    Article  PubMed  Google Scholar 

  6. Graves DT, Cochran D: The contribution of interleukin-1 and tumor necrosis factor to periodontal tissue destruction. J Periodontol 2003, 74(3):391–401. 10.1902/jop.2003.74.3.391

    Article  PubMed  Google Scholar 

  7. Sari E, Uçar C: Interleukin 1beta levels around microscrew implants during orthodontic tooth movement. Angle Orthod 2007, 77: 1073–8. 10.2319/100506-405.1

    Article  PubMed  Google Scholar 

  8. Moxham BJ, Berkovitz BKB: The effects of external forces on the periodontal ligament. In The Periodontal Ligament in Health and Disease. 2nd edition. Edited by: Berkovitz BKB, Moxham BJ, Newman HN. Mosby-Wolfe, London; 1995:215–41.

    Google Scholar 

  9. Wennstrom JL, Ekestubbe A, Grondahl K, Karlsson S, Lindhe J: Oral rehabilitation with implant-supported fixed partial dentures in periodontitis susceptible subjects. J Clin Periodontol 2004, 31: 713–24. 10.1111/j.1600-051X.2004.00568.x

    Article  PubMed  Google Scholar 

  10. Severino VO, Napimoga MH, de Lima Pereira SA: Expression of IL-6, IL-10, IL-17 and IL-8 in the peri-implant crevicular fluid of patients with peri-implantitis. Arch Oral Biol 2011, 56: 823–8. 10.1016/j.archoralbio.2011.01.006

    Article  PubMed  Google Scholar 

  11. Wilmes B, Su YY, Drescher D: Insertion angle impact on primary stability of orthodontic mini implant. Angle Orthod 2008, 78: 1065–70. 10.2319/100707-484.1

    Article  PubMed  Google Scholar 

  12. Griffiths GS: Formation, collection and significance of gingival crevice fluid. Periodontol 2000 2003, 31: 32–42. 10.1034/j.1600-0757.2003.03103.x

    Article  PubMed  Google Scholar 

  13. Woods PW, Buschang PH, Owens SE, Rossouw PE, Opperman LA: The effect of force, timing, and location on bone-to-implant contact of miniscrews. Eur J Orthod 2009, 31: 232–40. 10.1093/ejo/cjn091

    Article  PubMed  Google Scholar 

  14. Park HS, Jeong SH, Kwon OW: Factors affecting the clinical success of screw implants used as orthodontic anchorage. Am J Orthod Dentofacial Orthop 2006, 130: 18–25. 10.1016/j.ajodo.2004.11.032

    Article  PubMed  Google Scholar 

  15. Ohmae M, Saito S, Morohashi T, Seki K, Qu H, Kanomi R, Yamasaki KI, Okano T, Yamada S, Shibasaki Y: A clinical and histological evaluation of titanium miniimplants as anchors for orthodontic intrusion in the beagle dog. Am J Orthod Dentofacial Orthop 2001, 119: 489–97. 10.1067/mod.2001.114300

    Article  PubMed  Google Scholar 

  16. 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. 10.1016/j.ajodo.2006.07.038

    Article  PubMed  Google Scholar 

  17. Florvaag B, Kneuertz P, Lazar F, Koebke J, Zoller JE, Braumann B, Mischkowski RA: Biomechanical properties of orthodontic miniscrews: an in-vitro study. J Orofac Orthop 2010, 71: 53–67. 10.1007/s00056-010-9933-y

    Article  PubMed  Google Scholar 

  18. Suzuki EY, Suzuki B: Placement and removal torque values of orthodontic miniscrews. Am J Orthod Dentofacial Orthop 2011, 139: 669–78. 10.1016/j.ajodo.2010.11.017

    Article  PubMed  Google Scholar 

  19. Hou X, Weiler MA, Winger JN, Morris JR, Borke JL: Rat model for studying tissue changes induced by the mechanical environment surrounding loaded titanium implants. Int J Oral Maxillofac Implants 2009, 24: 800–7.

    PubMed  Google Scholar 

  20. Dao V, Renjen R, Prasad HS, Rohrer MD, Maganzini AL, Kraut RA: Cementum, pulp, periodontal ligament, and bone response after direct injury with orthodontic anchorage screws: a histomorphologic study in an animal model. J Oral Maxillofac Surg 2009, 67: 2440–5. 10.1016/j.joms.2009.04.138

    Article  PubMed  Google Scholar 

  21. Johansson B, Smedberg JI, Langley M, Embery G: Glycosaminoglycans in peri-implant sulcus fluid from implants placed in sinus-inlay bone grafts. Clin Oral Implants Res 2001, 12: 202–6. 10.1034/j.1600-0501.2001.012003202.x

    Article  PubMed  Google Scholar 

  22. Plagnat D, Giannopoulou C, Carrel A, Bernard JP, Mombelli A, Belser UC: Elastase, alpha2-macroglobulin and alkaline phosphatase in crevicular fluid from implants with and without peri-implantitis. Clin Oral Implants Res 2002, 13: 227–33. 10.1034/j.1600-0501.2002.130301.x

    Article  PubMed  Google Scholar 

  23. Liskmann S, Zilmer M, Vihalemm T, Salum O, Fischer K: Correlation of peri-implant health and myeloperoxidase levels: a cross-sectional clinical study. Clin Oral Implants Res 2004, 15: 546–52. 10.1111/j.1600-0501.2004.01061.x

    Article  PubMed  Google Scholar 

  24. Intachai I, Krisanaprakornkit S, Kongtawelert P, Ong-chai S, Buranastidporn B, Suzuki EY, Jotikasthira D: Chondroitin sulphate (WF6 epitope) levels in peri-miniscrew implant crevicular fluid during orthodontic loading. Eur J Orthod 2010, 32: 60–5. 10.1093/ejo/cjp056

    Article  PubMed  Google Scholar 

  25. Kaya FA, Hamamcı N, Uysal E, Yokuş B: Identification of tumor necrosis factor-α levels around miniscrews during canine distalization. Korean J Orthod 2011, 41: 36–41. 10.4041/kjod.2011.41.1.36

    Article  Google Scholar 

  26. Hamamcı N, Acun Kaya F, Uysal E, Yokuş B: Identification of interleukin 2, 6, and 8 levels around miniscrews during orthodontic tooth movement. Eur J Orthod 2012, 34: 357–61. 10.1093/ejo/cjr019

    Article  PubMed  Google Scholar 

  27. Billingham ME: Cytokines as inflammatory mediators. Br Med Bull 1987, 43: 350–70.

    PubMed  Google Scholar 

  28. Tzannetou S, Efstratiadis S, Nicolay O, Grbic J, Lamster I: Interleukin-1β and β-glucuronidase in gingival crevicular fluid from molars during rapid palatal expansion. Am J Orthod Dentofacial Orthop 1999, 115: 686–96. 10.1016/S0889-5406(99)70295-7

    Article  PubMed  Google Scholar 

  29. Alhashimi N, Frithiof L, Brudvik P, Bakhiet M: Orthodontic tooth movement and de novo synthesis of proinflammatory cytokines. Am J Orthod Dentofacial Orthop 2001, 119: 307–12. 10.1067/mod.2001.110809

    Article  PubMed  Google Scholar 

  30. Meikle MC: The tissue, cellular, and molecular regulation of orthodontic tooth movement: 100 years after Carl Sandstedt. Eur J Orthod 2006, 28: 221–40. 10.1093/ejo/cjl001

    Article  PubMed  Google Scholar 

  31. Kanzaki H, Chiba M, Shimizu Y, Mitani H: Periodontal ligament cells under mechanical stress induce osteoclastogenesis by receptor activator of nuclear factor kappa B ligand up-regulation via prostaglandin E2 synthesis. J Bone Miner Res 2002, 17: 210–20. 10.1359/jbmr.2002.17.2.210

    Article  PubMed  Google Scholar 

  32. Wu J, Bai YX, Wang BK: Biomechanical and histomorphometric characterizations of osseointegration during mini-screw healing in rabbit tibiae. Angle Orthod 2009, 79: 558–63. 10.2319/031108-138.1

    Article  PubMed  Google Scholar 

  33. Deguchi T, Hasegawa M, Seiryu M, Daimaruya T, Yamamoto T: Histomorphometric study of alveolar bone-implant (miniscrew) interface used as an orthodontic anchorage. In Interface Oral Health Science 2009. Edited by: Sasano T, Suzuki O. Springer, Heidelberg; 2010:126. 10.1007/978-4-431-99644-6_20

    Chapter  Google Scholar 

  34. Huja SS, Litsky AS, Beck FM, Johnson KA, Larsen PE: Pull-out strength of monocortical screws placed in the maxillae and mandibles of dogs. Am J Orthod Dentofacial Orthop 2005, 127: 307–13. 10.1016/j.ajodo.2003.12.023

    Article  PubMed  Google Scholar 

  35. Dinarello CA: Reduction of inflammation by decreasing production of interleukin-1 or by specific receptor antagonism. Int J Tissue React 1992, 14: 65–75.

    PubMed  Google Scholar 

  36. Dinarello CA: Interleukin-1. In The Cytokine Handbook. Edited by: Thomson A. Academic Press, San Diego, CA; 1994.

    Google Scholar 

  37. Jager A, Zhang D, Kawarizadeh A, Tolba R, Braumann B, Lossdorfer S, Gotz W: Soluble cytokine receptor treatment in experimental orthodontic tooth movement in the rat. Eur J Orthod 2005, 27: 1–11. 10.1093/ejo/cjh089

    Article  PubMed  Google Scholar 

  38. Ertel W, Kremer JP, Kenney J, Steckholzer U, Jarrar D, Trentz O, Schildberg FW: Downregulation of proinflammatory cytokine release in whole blood from septic patients. Blood 1995, 85: 1341–7.

    PubMed  Google Scholar 

  39. Ness RB, Haggerty CL, Harger G, Ferrell R: Differential distribution of allelic variants in cytokine genes among African Americans and White Americans. Am J Epidemiol 2004, 160: 1033–8. 10.1093/aje/kwh325

    Article  PubMed  Google Scholar 

  40. Taba M Jr, Kinney J, Kim AS, Giannobile WV: Diagnostic biomarkers for oral and periodontal diseases. Dent Clin North Am 2005, 49(3):551–71. vi vi 10.1016/j.cden.2005.03.009

    Article  PubMed Central  PubMed  Google Scholar 

  41. Freire JN, Silva NR, Gil JN, Magini RS, Coelho PG: Histomorphologic and histomorphometric evaluation of immediately and early loaded mini-implants for orthodontic anchorage. Am J Orthod Dentofacial Orthop 2007, 131: 704. e1–9.

    Article  PubMed  Google Scholar 

  42. Celebi AA, Demirer S, Catalbas B, Arikan S: Effect of ovarian activity on orthodontic tooth movement and gingival crevicular fluid levels of interleukin-1β and prostaglandin E2 in cats. Angle Orthod 2013, 83: 70–5. 10.2319/012912-78.1

    Article  PubMed  Google Scholar 

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Acknowledgements

The authors are grateful to Indian Council of Medical Research, New Delhi India for providing a partial grant for the study. The authors also want to thank Md. Zahid Akhtar for helping out with the biochemical analysis and data interpretation and Dr. Kalaivani Mani for her contribution in statistical analysis.

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Correspondence to Om Prakash Kharbanda.

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Authors’ contributions

NM started the initial seven cases and followed the cases up to 72 days. SC followed the same cases up to 300 days and, in addition, completed three more cases. OPK and RD conceived and supervised the study, participated in its design and coordination and helped draft the manuscript. RMR helped with all biochemical assays. All authors read and approved the final manuscript.

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Monga, N., Chaurasia, S., Kharbanda, O.P. et al. A study of interleukin 1β levels in peri-miniscrew crevicular fluid (PMCF). Prog Orthod. 15, 30 (2014). https://doi.org/10.1186/s40510-014-0030-4

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