Safaa F.doc J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry160 Corticotomy assisted orthodontic canine retraction Safaa S. Abed, B.D.S. (1) Ali I. Al-Bustani, B.D.S., M.Sc. (2) ABSTRACT Background: Surgical injury to alveolar bone can temporarily accelerate tooth movement by increasing the remodeling rate of alveolar bone. The purpose of this study was to clinically evaluate maxillary canine retraction acceleration with corticotomy-facilitated orthodontics, and its effect on vitality of pulp and gingival sulcus depth. Materials and method: The sample consisted of 12 adult patients (4 males, 8 females; mean age, 21.7 years) requiring the therapeutic extraction of the maxillary first premolars, with subsequent retraction of the maxillary canines. Surgical holes were done mesially and distally to the side with more space between canine and second premolar, and the other side served as the control. Canine retraction was done by power chain applying 200 g of force per side. Rate of canine movement and potential molar anchorage loss were measured after one month using study model and acrylic plug. Bleeding on probing, radiographical assessment, gingival sulcus depth, and vitality test have also been investigated throughout the study. Result: The surgical side showed a statistically higher retraction mean value as compared with the non-surgical side. In other words, the surgical side demonstrated 42.6% greater net canine distalization than the non-surgical side. Anchorage loss showed no significant difference between sides. There was no significant difference between the pre and post-surgery gingival sulcus depth and pulp vitality response values of surgical side. Conclusion: It has been concluded that surgical holes introduction is effective in accelerating orthodontic tooth movement, and has no harmful effects on surrounding vital structures and/or pulp vitality. Key words: canine retraction, corticotomy, tooth movement acceleration. (J Bagh Coll Dentistry 2013; 25(Special Issue 1):160-166). INTRODUCTION Conventional orthodontic treatment with fixed appliances is likely to last for 20 to 24 months. The duration of orthodontic treatment is one of the major concerns that patients complain about, most-especially the adult patient (1). To shorten the time of orthodontic treatment, various attempts have been made to accelerate orthodontic tooth movement. These attempts mainly direct electrical current (2), micro pulsed electricity (3), electromagnetic field application (4,5), low energy laser (6,7), injection of prostaglandin, Sand calcium gluconate (8,9), local injection of Vit. D3 (Calcitriol) (10,11). The last is oral surgery, including gingival fiberotomy, alveolar surgery and distraction osteogenesis. The effect of gingival fiberotomy is controversial (12). Distraction osteogenesis should not be routine in orthodontic treatment, and rapid tooth movement into immature bone regenerating after distraction osteogenesis is not recommended to avoid severe root resorption (13), individual canine retractors are bulky and unavailable on the market, and their long-term effects are unknown (14). Surgical injury to alveolar bone can temporarily accelerate tooth movement by increasing the remodeling rate of alveolar bone and decreasing its mineral density, thus decreasing the mechanical resistance of dento- alveolar tissues to orthodontic force. (1)M.Sc. student. Department of Orthodontics. College of Dentistry. University of Baghdad. (2)Assistant professor. Department of Orthodontics. College of Dentistry. University of Baghdad. A corticotomy is the procedure by which a flap is elevated and the cortical bone is cut with a bur or piezosurgical instrument approximately 1 -2 mm in depth (16). Corticotomies have recently become popularized, which were bone healing mechanisms in combination with orthodontic loadings to decrease treatment times. Although this procedure, termed corticotomy-assisted orthodontics (CAO) or accelerated osteogenic orthodontics (AOO) was first described in 1893, it has only recently gained wide usage. Significantly reduced treatment time has been reported using this procedure with reductions of 75% to 80% of routine treatment time (17). No previous Iraqi studies have dealt with this aspect of orthodontics. Furthermore, this study will, for the first time, involve surgical holes technique for canine distalization. PATIENTS AND METHODS Twelve orthodontic patients (4 males, 8 females); with an age ranged from 17- 28 years and mean age 21.7 years, requiring the therapeutic extraction of the maxillary first premolars, with subsequent retraction of the maxillary canines. The sample was set up to use each patient as his own control, thereby increasing the power of small sample. After the patients prepared for the fixed orthodontic treatment; the study started at second stage of treatment (stage of canine retraction). In this stage of treatment arch wire 0.016*0.022 S.S was placed with stopper and tip back bend just mesial to maxillary first molar, ligation of maxillary anterior teeth from right J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry161 lateral incisor to left lateral incisor, ligation of maxillary second premolar and maxillary first molar in each side. Peri-apical radiograph was taken for both maxillary canines by using self- processing x-ray film; Evaluation of periodontium, roots and surrounding bone was done. Vitality test was done for each patient for maxillary lateral incisors, canines and second premolars for each side by using electric pulp tester. The pathway for the electric current is thought to be from the probe tip of the test device to the tooth, along the lines of the enamel prisms and dentinal tubules, and through the pulp tissue (18). The circuit was completed via the operator having one gloveless hand that touches the patients’skin (19,20). Tingling sensation was felt by patient once increasing the voltage reaching the pain threshold and the reading from device for each tooth was recorded. Pocket depth of both canines was measured by inserting graduated probe and identifying the deepest point at each surface of canine (mesial, distal and palatal). The mean of these readings was calculated for each canine (21). Impression for each patient was taken then poured by stone. The anterior palatal vault could be used as a stable reference point (22). An acrylic plug was fabricated from acrylic with stainless steel reference wires (1.0mm) embedded in the acrylic and extended to the cusp tips of canines and to the central fossae of first molars (23).The patient was re-instructed to maintain good oral hygiene, showing them a video about the procedure of brushing with orthodontic appliance, and prescribing a mouth wash (2% chlorhexidine). Surgery and retraction The surgery was done on the side of canine which needed more distalization i.e. the canine in more Class II relation or the side having more space between canine and second premolar. Local anesthesia infiltration was injected in buccal vestibule from lateral incisor to second premolar at side of surgery and palatally, when the area got anesthetized (examined by probe) incision was made and two sided gingival mucoperiosteal flap was raised to expose cortical bone on the buccal side of the canine (special care was taken not to perforate the flaps, and any interdental papillary tissue that remained inter proximally left in place, the flap retracted beyond the apices of teeth as much as possible). A series of circular holes (3 to 4 holes, the number of holes was determined according to the length of canine root) were made along the bone mesially and distally adjacent to canine, these holes were made with a 1.5 mm round bur spaced approximately 2mm apart, under normal saline solution irrigation and depth of each hole was carefully determined to reach the medullary bone by putting stopper on bur at (3mm), the bleeding through the holes was confirmed by probe, the flap was returned to its position carefully and sutured with 3/0 non absorbable silk braded suture fig.(1), fig.(2). Antibiotic (Amoxicillin capsules, 500 mg 3 times daily) was prescribed for patients with analgesic (Paracetamol tablet, 500 mg 2 on need). None of the patients was allergic to penicillin excepting one patient who was given Erythromycin (250 mg 4 times daily) instead. Force was applied for both sides by elastomeric chain to retract canine at time of surgery with 200 g (24) measured by force gauge. Fig.1 Fig.2 Monitoring Visits The patients came after one week of surgery date to remove suture and examine the area of surgery for any inflammation or complication. Every patient was instructed to come in regular visits with intervals of one week for: 1. Checking gingival health by using (Gingival Sulcus Bleeding Index) scoring system (21,25). Bleeding after probing to the base of the probable gingival sulcus has been a common way of assessing J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry162 presence of sub gingival inflammation (25). In this system registration, "1" is scored in case bleeding emerges within 15 seconds after probing while absence of bleeding scored (0). 2. Checking any interference of maxillary canines with opposing teeth in the line of tooth movement. If this interference was present, trimming from palatal surface of maxillary canine was done. 3. Reloading surgical and non-surgical side with 200g by elastomeric chain, the force was measured by force gauge as mentioned previously. One month post- surgical In this visit the following steps were done in the same way mentioned previously: P.a radiograph for maxillary canines, vitality test for lateral incisors, canines and second premolars, gingival sulcus depth measurement for maxillary canines and impression for maxillary arch. Canine movement and anchorage loss measurements A reference point was determined on each canine(on cusp tip) of the first model and transmitted on the canines of the final model (fig. 3), the acrylic plug that fabricated on first model then transmitted to the final model to measure the distance between reference wire and the reference point on canine as shown in fig. (4), this distance represented the net canine movement per month. The anchorage loss was measured by determining reference point on first molar (usually in the central fossa) of first model and also transmitting it to second model then the acrylic plug that fabricated on first model was transferred to final one with measuring the distance between projecting (reference) wire and reference point which represented the net anchorage loss per month (23,26,27). Fig.3 Fig.4 Statistical analysis All data were statistically evaluated using the Statistical Package for Social Sciences (SPSS) computer program. The statistical analyses included: Descriptive statistics (Means, Standard deviations, Minimum and maximum values, Graphical presentation by bar-charts) and inferential statistics using (Wilcoxon Signed-Rank test and Chi square test). Values of p < 0.05 evaluated as statistically significant. RESULTS Canine movement and Anchorage loss The surgical side showed a higher mean value as compared with the non-surgical side which was statistically highly significant according to the wilcoxon signed rank test. In other words, the surgical side demonstrated 42.6% greater net canine distalization than the non-surgical side as shown in Table (1). Mean of anchorage loss is 0.05mm per month in both sides, i.e. non- significant difference between sides as shown in Table (2). Radiographic assessment All the peri-apical radiographs showed almost similar normal sequence of orthodontic tooth movement for both the surgical and non-surgical sides. The periodontal ligament of retracted canines showed compression at the pressure (distalization) site, while widening at the tension (mesial) site. Fig (5) show radiographs patient for both canines pre-surgery and post-surgery. Surgical side cannot be differentiated from non- surgical side in respect of appearance of surgical holes and/or bone destruction. J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry163 Fig.5 Gingival sulcus depth A comparison between the pre and post- surgery gingival sulcus depth values of surgical side, the measurements did not exceed 2.5 mm pre and post – surgery. According to Wilcoxon signed rank test there is no significant change in the depth shown in table (3). Pulp vitality test In a comparison between pre- and post-surgery pulp vitality test in surgical side and a according to Chi square test there is no significant change in pulp vitality response of the teeth on surgical side between pre- and post-surgery testing as shown in table (4). Clinical complications and side effects All patients did not manifest any serious complication after surgery, four patients had post- operative swelling lasted for one to two days after the surgery. There was no sign of gingival inflammation according to bleeding in probing index during the monitoring visits. DISCUSSION Corticotomy assisted orthodontics has been reported in few clinical cases (28). The procedure enhances orthodontic tooth movement by accelerating bone metabolism due to controlled surgical damage. It was initially based more on techniques used ostectomy instead of approaches of corticotomy. It is considered an intermediate therapy between orthognathic surgery and conventional orthodontics (29). Surgical intervention or osteoporotic situation that is favorable for rapid orthodontic tooth movement can be induced within the alveolar bone without increasing the risk of root resorption (17) and localized osteoporosis (30-33). Surgery invokes RAP in both hard and soft tissue and reorganization is potentiated, leading to a transient catabolic condition. For bone, this transient osteoporosis means increased mobilization of calcium, decreased bone density, and increased bone turnover, all of which would facilitate more rapid tooth movement. Osteoporosis provided a favorable environment for increasing the rate of tooth movement without increasing the risk of root resorption in rats (34). Moreover, it has been demonstrated that the residual soft tissue matrix has the ability to induce remineralization after the cessation of tooth movement (35). All of this suggests that the dynamics of the accelerated tooth movement in this study might be more appropriately described as a demineralization/ remineralization process, rather than bony block movement or resorption/ apposition. This perspective is substantiated by the fact that there is a growth protein component in the soft tissue matrix of bone (36-38). Following cessation of the active tooth movement, this growth protein component may assist in stimulating an increase in osteoblastic activity, resulting in remineralization of the soft tissue matrix (17). Gingival bleeding on probing index was used in this study. This index, unlike other indices which give an assessment for a quadrant or the whole dentition, can assess the gingival inflammation for a specific tooth or a specific site. When assessing gingival health of canines in both sides, all involved teeth scored (0), indicating successful prevention of maxillary canine's gingival inflammation throughout the study period due to the firm instructions about the proper oral hygiene maintenance methods given to the patients throughout the study, in addition to the use of mouth rinses and special orthodontic brushes. In this study, the response of teeth was increased gradually from lateral incisor, canine to second premolars. Key variables known to affect the response to pulp testing are the thickness of the enamel and dentine, the number of nerve fibers in the underlying pulp, and the direction of the dentinal tubules is also important in establishing pulp test responses in various parts of the tooth crown. The dentinal tubules run an almost straight course from the incisal edge of anterior teeth to the pulp horn. In multi-cuspal teeth, the course of tubules is somewhat curved and resembles an ‘S’ shape (55). Because it is principally the fluid in the tubules that conducts electrical impulses from the pulp tester electrode to the pulp, the shorter the distance between the electrode and the pulp, responds faster and records lower score. Furthermore, orthodontic force increases the response threshold to electric pulp test. The effect J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry164 is almost instantaneous and could persist for up to 9month after treatment (39,40), this may give another explanation for the result of teeth responding at different levels of current intensity in this study, and this is in agreement with (41-44). Statistically, EPT readings regarding the three teeth did not differ significantly between the two sides both pre and post-surgery and between per and post-surgery for surgical side. This is attributed to the safe, non- traumatic surgical intervention for the canine and surrounding area, and the use of optimal physiologic force that did not endanger pulp vitality. As a conclusion; the introduction of surgical holes is effective in accelerating OTM and shortening orthodontic treatment time, Enhancement of bone turnover through demineralization/remineralization concept can serve as a successful clinical adjunct to the bone resorption /deposition concept and when done properly, surgical holes introduction produce no iatrogenic insult on periodontium and/or pulp vitality. Table 1: Descriptive and inferential statistics of net canines' movement Side Descriptive Statistics Side difference N Mean S.D. Min. Max. Wilcoxon Signed Ranks Test p-value Sig. Non-surgical side 12 1.22 0.40 0.55 1.82 -3.06 0.002 HS Surgical side 12 1.74 0.47 1 2.34 Table 2: Descriptive and inferential statistics of anchorage loss Side Descriptive Statistics Side difference N Mean S.D. Min. Max. Wilcoxon Signed Ranks Test p-value Sig. Non-surgical side 12 0.05 0.12 0 0.3 0 1 NS Surgical side 12 0.05 0.12 0 0.3 Table 3: Comparison the pre- and post- gingival sulcus depth in the surgical side Sulcus depth Descriptive Statistics Sulcus depth difference N Mean S.D. Min. Max. Wilcoxon Signed Ranks Test p-value Sig. Pre-gingival sulcus depth 12 1.98 0.22 1.5 2.5 -1.34 0.18 NS Post-gingival sulcus depth 12 1.94 0.26 1.5 2.5 Table 4: Comparison pre-surgery and post-surgery vitality test in surgical side Scores Lateral incisor Canine 2 nd premolar Pre-vitality Post-vitality Pre-vitality Post-vitality Pre-vitality Post-vitality 1 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 2 3 (12.5%) 4 (16.7%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 3 3 (12.5%) 2 (8.3%) 2 (8.3%) 2 (8.3%) 0 (0%) 0 (0%) 4 4 (16.7%) 4 (16.7%) 1 (4.2%) 1 (4.2%) 0 (0%) 0 (0%) 5 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 6 2 (8.3%) 2 (8.3%) 5 (20.8%) 6 (25%) 4 (28.6%) 4 (28.6%) 7 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 8 0 (0%) 0 (0%) 4 (16.7%) 3 (12.5%) 2 (14.3%) 2 (14.3%) 9 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 0 (0%) 10 0 (0%) 0 (0%) 0 (0%) 0 (0%) 1 (7.1%) 1 (7.1%) X2 0.34 0.23 0 Likelihood ratio 0.35 0.23 0 p-value 0.95 0.97 1 Sig. NS NS NS REFERENCES 1. Akhare PJ, Daga AM, Shilpa P. Rapid canine retraction and orthodontic treatment with dentoalveolar distraction osteogensis. J Clinical Diagnostic Research 2011;7:1473-1477. 2. Davidovitch Z, Finkelson M D, Steigman S, Shanfeld JL, Mongomery PC, Korostoff E. Electric current, bone remodeling, and orthodontic tooth movement; I. The effect of electric currents on periodontal nucleotides. Am J Orthod 1980a; 77: 14-32. II. Increase in rate of tooth movement and periodontal cyclic nucleotide levels by combined force and electric current. Am J Orthod 1980b; 77: 33-47. J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry165 3. Hashimoto H. Effect of micro-pulsed electricity on experimental tooth movement. Nippon Kyosei-Shika- Gakkai-Zasshi 1990; 49(4): 352-61. 4. Darendeliler MA, Sinclair PM, Kusy R P. The effects of samarium cobalt magnets and pulsed electromagnetic fields on tooth movement. Am J Dentofac Orthop 1995; 107: 578-88. 5. Halabyia SR. The effect of pulsed electro-magnetic field on orthodontic tooth movement (an experimental study). Master thesis, College of Dentistry, Baghdad University, 2005. 6. Kawasaki K, Tanaka V, Takagi O. Crystallographic analysis of demineralized human enamel treated by laser-irradiation or remineralization. Arch Oral Biol 2000; 45(9): 797-804. 7. Al-Me’mar ON. The effect of low-energy laser on periodontal ligament and bone during orthodontic movement. Master thesis, College of Dentistry, Baghdad University, 2002. 8. Leiker BJ, Nanda RS, Currier G F, Howes RI, Sinha P K. The effects of exogenous prostaglandins on orthodontic tooth movement in rats. Am J Orthod Dentofac Orthop 1995; 108: 380-388. 9. Seifi M, Eslami B, Saffar AS. The effect of prostaglandin E2 and calcium gluconate on orthodontic tooth movement and root resorption in rats. Eur J Orthod 2003; 25(2):199-204. 10. Collins MK, Sinclair P M. The local use of vitamin D to increase the rate of orthodontic tooth movement. Am J Orthod Dentofac Orthop 1988; 94:278-84 11. Al-Hasani NR. Clinical significance of calcitriol local injection in orthodontic tooth movement. Master thesis, College of Pharmacy, Baghdad University, 2011. 12. Ren A, Lv T, Zhao B, Chen Y, Bai D. Rapid orthodontic tooth movement aided by alveolar surgery in beagles. Am J Orthod Dentofac Orthop 2007; 131: 160.e1-10. 13. Nakamoto N, Nagasaka H, Daimaruya T, Takahashi T, Sugawara J, Mitani H. Experimental tooth movement through mature and immature bone regenerates after distraction osteogensis in dogs. Am J Orthod Dentofac Orthop 2002; 121: 358-95. 14. Sayin S, Bengi A O, Gurton A U, Ortakoglu K. Rapid canine distalization by using the distraction of periodontal ligament: a preliminary clinical validation of original technique. Angle Orthod 2004; 74: 304- 315. 15. Roberts WE. Bone physiology, metabolism and biomechanics in orthodontic practice. In: Graber T M, Vanarsdall RL (eds). Orthodontics current principles and techniques. 4th ed. St. Louis: Mosby; 2005. 16. Hao J. Accelerated orthodontic tooth movement with flapless corticotomy: a pilot study in beagle dogs. Master thesis, College of Dentistry, University of Illinois, Chicago, 2011. 17. Wilcko WM, Wilcko T, Bouquot JE, Ferguson DJ. Rapid orthodontics with alveolar reshaping: Two case reports of de-crowding. Int J Periodontics Restorative Dent 2001; 21: 9- 19. 18. Mumford JM. Pain perception threshold on stimulating human teeth and the histological condition of the pulp. Br Dent J 1967; 123:427 19. Cailleteau J G, Ludington J R. Using the electric pulp tester with gloves: a simplified approach. J Endod 1989; 15: 80-81. 20. Penna KJ, Sadoff RS. Simplified approach to use electric pulp tester. The New York State Dental Journal 1995; 61: 30-31. 21. Lindhe J, Karring T, Lang NP. Clinical periodontology and implant dentistry. 4th ed. Munksgaard: Blackwell; 2003. 22. Lebret L. Growth changes of the palate. J Dent Res 1962; 36: 39-47 23. Lotzof LP, Fine HA, Cisneros GJ. Canine retraction: A comparison of two preadjusted bracket systems. Am J Orthod Dentofac Orthop 1996; 110(2): 191-196. 24. Nanda R, Kapila S. Current therapy in orthodontics. 1st ed. St. Louis: Elsevier; 2010. 25. Miihlemann HR, Son S. Gingival sulcus bleeding a leading symptom in initial gingivitis. Helvetica Odontologica Acta 1971; 15:107-113 26. Al-Ghazi HAA. Mechanical behaviour and clinical efficiency of elastomeric chain nickel titanium closing coil spring. a comparative study. A master thesis, Department of Orthodontics, College of Dentistry, University of Baghdad, 2001. 27. Al- Jiburi QA. Evaluation of canine retraction rate and molar anchorage loss on implant and non-implant sides for Iraqi adult sample (clinical comparative study). Master thesis, College of Dentistry, Baghdad University, 2011. 28. Cano J, Campo J, Bonilla E, Colmenero C. Corticotomy-assisted orthodontics. J Clin Exp Dent 2012; 4(1): 54-59. 29. Kole H. Surgical operations on the alveolar ridge to correct occlusal abnormalities. Oral Surg Oral Med Oral Pathol 1959; 12: 277-288. 30. Shin MS, Norrdin RW. Regional acceleration of remodeling during healing of bone defects in beagles of various ages. Bone 1985; 5: 377–379. 31. Frost HM. The biology of fracture healing, an overview for clinicians, part I. Clin Orthop Relat Res 1989a; 248: 283-293. 32. Frost HM. The biology of fracture healing: An overview for clinicians. Part II. Clin Orthop Rel Res 1989b; 248:294–309. 33. Yaffe A, Fine N, Binderman I. Regional accelerated phenomenon in the mandible following mucoperiosteal flap surgery. J Periodontol 1994; 65:79–83. 34. Goldie RS, King GJ. Root resorption and tooth movement in orthodontically treated, calcium- deficient, and lactating rats. Am J Orthod 1984; 85: 424–430. 35. Nyman S, Karring T, Bergenholtz G. Bone regeneration in alveolar bone dehiscences produced by jiggling forces. J Periodontal Res 1982; 17: 316–322. 36. Urist MR, Iwata H, Ceccotti PL, Dorfman RL, Boyd SD, McDowell RM, Chien C. Bone morphogenesis in implants of insoluble bone gelatin. Proc Natl Acad Sci USA 1973; 70: 3511–3515. 37. Fiorellini J, Nevins M. Repair and regeneration of oral tissues: The molecular approach. Postgrad Dent Series 1996; 3(2): 3–10 38. Nevins M, Kirker-Head C, Nevins M, Wozney JA, Palmer R, Graham D. Bone formation in the goat maxillary sinus induced by absorbable collagen sponge implants impregnated with recombinant human bone morphogenetic protein-2. Int J Periodontics Restorative Dent 1996; 16: 8–19. J Bagh College Dentistry Vol. 25(Special Issue 1), June 2013 Corticotomy assisted Pedodontics, Orthodontics and Preventive Dentistry166 39. Gopikrishna V, Pradeep G, Venkateshbabu N. Assessment of pulp vitality: a review. Int J Paediatr Dent 2009; 19: 3–15. 40. Cave SG, Freer TJ, Podlich HM. Pulp-test responses in orthodontic patients. Aust Orthod J 2002; 18: 27– 34. 41. Burnside RR, Srenson FM, Buck DL. Electric vitality testing in orthodontic patients. Angle Orthod 1974; 44: 213–217. (IVSL). 42. Bender I B, Landau M A, Fonsecca S, Trowbridge H O. The optimum placement-site of electrode in electrical pulp testing of the 12 anterior teeth. J Am Dent Assoc 1989; 118: 305–310. 43. Hall CJ, Freer TJ. The effects of early orthodontic force application on pulp test responses. Austr Dent J 1998; 43: 359–361. 44. Veberiene R, Smailiene D, Baseviciene N,Toleikis A, Machiulskiene V. Change in dental pulp parameters in response to different modes of orthodontic force application. Angle Orthod 2010; 80: 1018-22. (IVSL).