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<< :,¢J,. a >> Home Infrabony Pockets and Reduced Alveolar Bone Height in Relation to Orthodontic Therapy Birgit Thilander Experimental animal studies have shown that orthodontic movement of teeth into infrabony pockets may be detrimental to the periodontal attachment. After elimination of subgingival plaque infection in the experimental animals, no additional loss of connective tissue attachment occurred. An experimental model has shown that a tooth with normal periodontal support can be orthodontically moved into an area of reduced bone height with maintenance of height of connective tissue attachment level and alveolar bone support. The results from these experimental studies have been tested clinically. (Semin Orthod 1996;2:55-61.) Copyright © 1996 by W.B. Saunders Company he question of whether orthodontic tooth T m o v e m e n t may have deleterious effects on the periodontal tissues has b e e n evaluated in a n u m b e r of clinical and experimental studies. The results have shown that, provided periodontal health and p r o p e r oral hygiene standards a r e maintained during the phase of orthodontic therapy, no injury, or only clinically insignificant injury to the supporting tissues will occur. However, if the oral hygiene is less effective and periodontal inflammation is present during the orthodontic treatment, the studies have indicated an increased risk for adverse effects on the periodontium. This is i m p o r t a n t to remember, if orthodontic tooth m o v e m e n t s should be perf o r m e d in areas with infrabony pockets or in areas of reduced height of alveolar bone. This article will discuss relevant studies, together with some clinical applications, to improve our understanding of the advantages as well as the disadvantages of orthodontic treatment in such patients. From the Department of Orthodontics, G6teborg University, G6teborg, Sweden. Address correspondenceto Bbgit Thiland~ Odont Dr, MD(hc), Department o[Orthodontics, Faculty of Odontology, G6teborgUnivo= sity, Medicinaregatan 12, S-41390 G&eborgSweden. Copyright© 1996 by W..B.Saunders Company 1073-8746/96/0201-000855.00/0 Periodontal Tissue Response to Orthodontic Movement of Teeth With Infrabony Pockets Experimental studies involving histological analysis have reported that orthodontic forces per se are unlikely to convert gingivitis into a destructive periodontitis. 1,2 T h e d e v e l o p m e n t of destructive periodontal disease, however, may result in the formation of infrabony pockets, ie, angular bony defects with inflamed connective tissues and the dentogingival epithelium located apical to the crest of the alveolar bone. 3 Thus, it can be stated that orthodontic movem e n t of teeth with healthy periodontal tissues will not cause loss of connective tissue attachment. 4-6 Also in areas with the presence of plaque-induced suprabony lesions, orthodontic forces per se have b e e n shown to be incapable of causing accelerated destruction of the periodontal support. 6,7 This may be explained by the fact that the effect of orthodontic forces is generally confined to that portion of the p e r i o d o n t i u m which is b o r d e r e d by hard tissues on both sides, whereas the suprabony connective tissue remains unaffected, because the latter portion will not be compressed between the hard tissues. However, it has also been shown that in buccal sites with gingival inflammation and where the tooth is moved out through the alveolar b o n e Seminars in Orthodontics, Vol 2, No 1 (March), 1996: pp 55-61 55 I TOC I Bndex <<AFJce >> Home I TOC I Bndex 56 Birigit Thilander (ie, a buccal b o n e dehiscence is created), gingival recession and c o n c o m i t a n t loss of connective tissue a t t a c h m e n t may occur, if the covering soft tissue is thin. 7,s It is most likely, however, that the causative factor for this destruction is the plaqueinduced lesion, rather than the orthodontic trauma, because similar orthodontic m o v e m e n t of teeth with healthy marginal periodontal tissues did not result in a t t a c h m e n t loss. 9,1° T h e position of the plaque-induced lesion may, however, be shifted f r o m a suprabony to an infrabony position, ie, into the area where orthodontic forces affect the periodontium, when tooth m o v e m e n t directed at tipping or intruding a tooth into the alveolar b o n e is p e r f o r m e d . U n d e r these conditions an e n h a n c e d rate of periodontal destruction is evident, u Thus, infrabony pockets may be created by orthodontic tipping a n d / o r intruding m o v e m e n t s of teeth h a r b o r i n g bacterial plaque. D e e p e n e d gingival pockets must be eliminated before any orthodontic tooth m o v e m e n t is started. After the orthodontic treatment, additional surgical pocket elimination is also p e r f o r m e d , if necessary. 2 In patients who have periodontal disease infrabony pockets are frequently found. W h e t h e r orthodontic tooth m o v e m e n t in areas with infrabony pockets may have a detrimental effect on the supporting tissues, has been discussed. O r t h o d o n t i c elimination of an infrabony pocket by tooth extrusion has shown a maintained relationship between the c e m e n t o - e n a m e l junction and the b o n e crest, ie, the b o n e followed the tooth during the extrusion movemerit. 12 In contrast, teeth subjected to extrusion with concomittant fiberotomy, ie, the coronal portion of the fiber a t t a c h m e n t was excised, the crestal part of the alveolar b o n e did not follow the root during extrusion, and consequently, the root m o v e m e n t resulted in an increased distance between the c e m e n t o - e n a m e l j u n c t i o n and the alveolar b o n e crest. 12q5 Because of the o r t h o d o n tic extrusion, the tooth will be in supraocclusion. Hence, the crown of the tooth will n e e d to be shortened, in some cases followed by e n d o d o n t i c treatment. T h e effect of bodily m o v e m e n t of teeth into infrabony periodontal defects has b e e n evaluated in experimental studies in the m o n k e y 5 and in the dog. 16 If periodontal t r e a t m e n t was perf o r m e d before the orthodontic tooth m o v e m e n t was started, and the monkeys were subjected to plaque control measures during the entire course of the experiment, no deleterious effect was obtained on the level of the connective tissue attachment. 5 It was reported, that the angular bony defect was eliminated by the orthodontic treatment, but no coronal shift (gain) of the connective tissue a t t a c h m e n t was found. Hence, a thin junctional epithelium covered the root surface to a level c o r r e s p o n d i n g to the pretreatmerit position of the connective tissue attachment. On the other hand, experiments in dogs have shown that orthodontic therapy involving bodily m o v e m e n t of teeth with inflamed, infrabony pockets may e n h a n c e the rate of loss of the connective tissue attachment. 16 In each dog, one p r e m o l a r was moved away f r o m the angular bony defect and one p r e m o l a r into and through the angular bony defect (Fig 1). After orthodontic t r e a t m e n t (5 to 6 months), the teeth were stabilized for 2 months. Clinical, radiographic, and histological evaluations showed that it was possible to establish and maintain an infrabony pocket with a subcrestal, plaque-induced inflamm a t o r y leason during the entire course of the study. Although the control teeth had maintained their a t t a c h m e n t levels, all but one of the orthodontically m o v e d teeth showed additional loss of a t t a c h m e n t (Fig 2). The risk for additional a t t a c h m e n t loss was particularly evident when the tooth was m o v e d into the infrabony pocket. In conclusion, e x p e r i m e n t a l studies in monkeys and dogs have shown that orthodontic m o v e m e n t of teeth into infrabony pockets may be detrimental for the periodontal attachment. After elimination of the subgingival plaque infection, no additional loss of connective tissue a t t a c h m e n t occurred. The consequence from these experimental results is that elimination of plaque-induced lesions must p r e c e d e the orthodontic treatment. This hypothesis has b e e n tested in a series of patients with infrabony pockets resulting f r o m periodontal disease (Fig 3) .2 Clinical and radiographic observations have shown, that orthodontic treatment can be successfully p e r f o r m e d in such cases, provided that periodontal t r e a t m e n t directed at the elimination of the plaque-induced lesion precedes the initiation of orthodontic therapy, and that p r o p e r oral hygiene is maintained during the course of orthodontic treatment. < < :"d-'.l,- Home I TOC I Bndex ¢:- > > Infrabony Pockets and Reduced Alveolar Bone Height Figure 1. Clinical appearance (A) of the two to three walled angular bony defect (arrow), extending to a level corresponding to about 50% of the root length. A notch was prepared at the bottom of the angular defect. The tooth was then moved away from, or into and through the defect (open arrows). Radiographs obtained at the start of the orthodontic tooth movement (B) and at termination of the experimental period (C). Arrow indicates the direction of tooth movement, ie, away from the defect. The displacement of the tooth is related to the titanium pins, inserted in the buccal cortical bone. (Figs 1 (B-C) reprinted with permission.16) P e r i o d o n t a l T i s s u e R e s p o n s e to O r t h o d o n t i c M o v e m e n t of T e e t h i n t o E d e n t u l o u s Areas w i t h R e d u c e d Bone Height In patients with partially edentulous dentitions, because of congenitally absent or the extraction of teeth, orthodontic treatment often has to be performed. By positioning the teeth toward, or 57 into, the e d e n t u l o u s area, i m p r o v e d esthetic a n d functional results may be g a i n e d J 8-2° In m a n y o f these individuals there is a r e d u c e d alveolar b o n e height. O r t h o d o n t i c forces, i n d u c e d for bodily t o o t h m o v e m e n t , will result in different reactions in the p e r i o d o n t a l tissues o n the pressure a n d o n the tension sides. B o n e r e s o r p t i o n occurs on the pressure side as a c o n s e q u e n c e o f t r a u m a i n d u c e d reactions within the p e r i o d o n t a l ligam e n t tissue, whereas o n the tension side a c o n t i n u o u s b o n e apposition will be seen resulting in a m a i n t a i n e d width o f the p e r i o d o n t a l ligament. 21 T h e tissue c h a n g e s o c c u r r i n g o n the pressure side d u r i n g o r t h o d o n t i c t o o t h m o v e m e n t are c o n f i n e d to the i n f r a b o n y area o f the root, ie, the area o f s u p p o r t i n g b o n e where the p e r i o d o n t a l l i g a m e n t will be c o m p r e s s e d between the two h a r d tissues. H e n c e , o r t h o d o n t i c t o o t h movem e n t will n o t i n d u c e reactions in the supracrestal area resulting in loss o f connective tissue attachment. 7,9,1° T h e applied forces will lead to demineralization o f the s u p p o r t i n g bone, which in t u r n allows the t o o t h to move in the direction o f the force. N o b o n e remineralization is observed adjacent to a t o o t h that has b e e n m o v e d o u t t h r o u g h the b o n y plate, ie, w h e n an alveolar b o n e d e h i s c e n c e has b e e n created. 7,8,9 However, w h e n such a t o o t h is m o v e d back into the alveolar b o n e housing, b o n e apposition will take place in t h e a r e a o f t h e p r e v i o u s dehiscence. 9,~°,22,23 T h e results o f these studies indicated that the soft tissue, facial to a p r o d u c e d b o n e dehiscence, contains a b o n e matrix with the capacity to remineralize following repositioning o f the t o o t h into the alveolar process. It may thus be speculated, that genetic factors controlling the d i m e n s i o n s o f the alveolar process may be the reason f o r the lack o f remineralization o f the b o n e matrix buccal to a t o o t h which has b e e n m o v e d buccally o u t o f the alveolar h o u s i n g o n the buccal side o f the dental arch. H e n c e , based on the findings in the studies r e f e r r e d to, it c o u l d be anticipated that, as long as o r t h o d o n t i c t o o t h m o v e m e n t is p e r f o r m e d within the genetically d e t e r m i n e d b o u n d a r i e s o f the jaw, the t o o t h will m a i n t a i n the original h e i g h t o f the s u p p o r t i n g apparatus, ie, its c o n n e c tive tissue a t t a c h m e n t level a n d its alveolar b o n e height. A n e x p e r i m e n t a l m o d e l in a beagle d o g << :,¢J,. a >> Home 58 Birigit Thilander Figure 2. Specimens from a tooth orthodontically moved into (A) and away from (B) the infrabony pocket, showing presence of an inflammatory cell infiltrate in the connective tissue adjacent to the pocket epithelium. The termination of the dentogingival epithelium (aJE) apical to the notch (N) indicates additional loss of connective tissue attachment, when the tooth is moved into the defect. (Fig 2(A) reprinted with permission. 16) Figure 3. A 40-year-old woman had had periodontal treatment for the infrabony pocket mesial to the maxillary left central incisor (A and D). Proper oral hygiene was maintained, and the spaces in the anterior segment were closed by means of a fixed appliance using very light forces. Semipermanent retention performed 6 months later. A further control 6 months later showed improvement of the bony defect (B and E). Permanent retention then was carried out. Posttreatment control 5 years later (C and F). Note the improveinent of the bony defect. (Reprinted with permission.21) I TOC I Bndex < < :"d-'J~- ?:- > > Home I TOC I Bndex [nfrabony Pockets and Reduced Alveolar Bone Height was designed to test this hypothesis by o r t h o d o n tically moving teeth into edentulous areas with reduced b o n e height (Fig 4).24 None of the teeth whether moved orthodontically or not, showed loss of connective tissue a t t a c h m e n t (Figs 5 and 6). Hence, at all teeth, the most apical cells of the junctional epithelium were located at the cem e n t o - e n a m e l junction (CEJ). T h e newly established periodontal ligament exhibited a n o r m a l width, both on the pressure and on the tension side of the displaced teeth. On the tension side both the original height and width of the supporting bone were fully maintained. On the pressure side, supporting alveolar b o n e was also present, extending far coronal to the surrounding, experimentally created b o n e level, but not reaching the complete height as the original supporting bone. It is obvious when analyzing the histological sections, that the supporting b o n e on the pressure side, not visualized in the radiograph, was m u c h thinner than the original bone. The histological picture of the b o n e tissue in the coronal portion of the root showed a high n u m b e r of cells in contrast to the compact a p p e a r a n c e of the m o r e apically located b o n e (Fig 6). The explanation for this finding can only be speculated on. )- Figure 5. Radiographs obtained at the start of the orthodontic movement (A) and at the termination of the experiment (B) of a test tooth and the contralateral control tooth. Note the difference in radiographic bone height (arrows). Titanium pins indicate the displacement of the test tooth. (Reprinted with permission. ~4) Following similar tooth m o v e m e n t in a facial direction outside the boundaries of the jaw, no b o n e remineralization will be found. 7,l° In contrast to the heavy forces used when moving teeth out buccally through the bony plate, only very light forces were applied when moving the teeth bodily into the area with reduced bone height. The use of light forces may explain that, only the inorganic c o m p o n e n t of the alveolar b o n e was lost, as a consequence of the biological response to the orthodontic force, and that the organic c o m p o n e n t was maintained which was likely to result in remineralization of bone. The interesting finding, that the newly f o r m e d b o n e on the pressure side shows resorption on the surface n e a r the root and apposition on the opposite side of the thin b o n e plate, may also be exp l a i n e d by the piezoelectrical theory. T h e changes that occur in alveolar b o n e during tooth m o v e m e n t have been interpreted to be related to a piezoelectrical effect through strain-generated potentials, arising as a result of mechanically induced deformation of collagen or hydroxyapatite crystals. 25 In conclusion, an experimental model has shown that a tooth with n o r m a l periodontal support can be orthodontically m o v e d into an area of reduced b o n e height with maintained height of the supporting apparatus, ie, main- iiii!!iiiiiiiiiiiii!iiiiiiiiiiiiiiliiiiiiiiiiiiiiiiiiiiii Figure 4. Schematic drawing (A) and clinical photograph (B) illustrating the bodily movement of the third premolar into tile area with reduced alveolar bone height. (Fig 4(A) reprinted with permission. 24) 59 << :,¢J,. ~ >> Home 60 Birigit Thilander Figure 6. Specimens from the control (A) and the test tooth (B and C magnification), shown in Figure 5. The thin bone along the pressure side of the test tooth is not visualized in the radiograph. (Reprinted with permission. 24) t a i n e d c o n n e c t i v e tissue a t t a c h m e n t level a n d in all essentials m a i n t a i n e d a l v e o l a r b o n e s u p p o r t . T h e s e e x p e r i m e n t a l results have b e e n t e s t e d in p a r t i a l l y e d e n t u l o u s p a t i e n t s with n o r m a l p e r i o d o n t a l tissue s u p p o r t , l o c a t e d a d j a c e n t to a n e d e n t u l o u s a r e a with r e d u c e d b o n e v o l u m e . T e e t h have b e e n o r t h o d o n t i c a l l y m o v e d i n t o such an a r e a a n d u s e d for a f i x e d p a r t i a l d e n t u r e (Fig 7).17 T h e results o f t h e s e clinical follow-up studies a r e e n c o u r a g i n g , p r o v i d e d t h a t b o d i l y t o o t h m o v e m e n t s with l i g h t o r t h o d o n t i c forces a r e used, a n d p r o p e r o r a l h y g i e n e is m a i n t a i n e d . Figure 7. A 25-year-old man partially edentulous because of trauma. Marked bone loss in the left maxillary alveolar process (A, B, C, and D) (indicated by arrows). The second premolar was moved bodily one cusp width into the area with reduced bone support (E). After a treatment period of 12 months, a prosthetic bridge was constructed. Note the regaining of alveolar bone (F). (Reprinted with permission. 21) I TOC I Bndex < < :"d-'J,- ?:- > > Home I TOC I Index Infrabony Pockets and Reduced Alveolar Bone Heigkt References 1. Lindhe J, Nyman S, Ericsson I. Trauma frmu occlusion, In: Lindhe J, editor. Textbook of Clinical Periodontology (ed 2). Copenhagen, Munksgaard, 1989:240-257. 2. Thilander B. Orthodontic tooth movement in periodontal therapy, In: Lindhe J, editor. Textbook of Clinical Periodontology (ed 2). Copenhagen, Munksgaard, 1989: 563-589. 3. WaerhaugJ. The infrabony pocket and its relationship to trauma from occlusion and subgingival plaque. J Periodonto11979;50:355-365. 4. Polson A, Zander H. Effect of periodontal trauma upon infrabony pockets.J Periodonto11983;54:586-591. 5. Polson A, CatonJ, Polson AP, et al. Periodontal response after tooth movement into infrabony defects. J Periodontol 1984;55:197-202. 6. Ericsson I, Thilander B, LindheJ. Periodontal conditions after orthodontic tooth movement in the dog. Angle Orthod 1978;48:210-218. 7. Wennstr6mJ, LindheJ, Sinclair F, et al. Some periodontal tissue reactions to orthodontic tooth movement in monkeys. J Clin Periodontol 1987;14:121-129. 8. Steiner G, Pearson J, AinamoJ. Changes of the marginal periodontium as a result of labial tooth movement in monkeys.J Periodonto11981;52:314-320. 9. Karring T, Nyman S, Thilander B, et al. Bone regeneration in orthodontically produced alveolar bone dehiscences. J Periodont Res 1982;17:309-315. 10. Thilander B, Nyman S, Karring T, et al. Bone regeneration in alveolar bone dehiscences related to orthodontic tooth movements. EurJ Orthod 1983;5:105-114. 11. Ericsson I, Thilander B, Lindhe J, et al. The effect of orthodontic tilting movements on the periodontal tissues of infected and non-infected dentitions in dogs. J Clin Periodontol 1977;4:278-293. 12. Berglundh T, Marinello C, Lindhe J, et al. Periodontal tissue reactions to orthodontic extrusion.J Clin Periodontol 1991;18:330-336. 13. Pontoriero R, Celenza E Ricci G, et al. Rapid extrusion with fiber resection: a combined orthodontic-periodon- 14. 15. 16. 17. 18. 19. 61 tic treatment modality. IntJ Period Restor Dent 1987;7:3143. Kozlowsky A, Tal H, Liebermann M. Forced eruption combined with gingival fiberotomy. J Clin Periodontol 1988;15:534-538. Schwimer CW, Rosenberg ES, Schwimer DH. Rapid extrusion with fiberotomy. J Esther Dent 1990;2:82-88. Wennstr6m J, Lindskog-Stokand B, Nyman S, et al. Periodontal tissue response to orthodontic movement of teeth with infrabony pockets. Am J Orthod Dentofacial Orthop 1993;103:313-319. Thilander B, Wisth PJ. Orthodontic treatment in adults, In: Thilander B, R6nning O, editors. Introduction to Orthodontics (ed 2). Solna, Gothia-LIC F6rlag, 1995;209238. Stepovich ML. A clinical study on closing edentulous spaces in the mandible. Angle Orthod 1979;49:227-233. Horn BM, Turley PK. The effects of space closure on the mandibular first molar area in adults. Am J Orthod 1984;85:457-469. 20. Goldberg D, Tnrley E Orthodontic space closure of edentulous maxillary first molar area in adults. Int J Adult Orthod Orthognath Surg 1989;4:255-266. 21. Rygh P. Orthodontic forces and tissue reactions, In: Thilander B, R6nning O, editors. Introduction to Orthodontics (ed 2). Solna, Gothia-LIC F6rlag, 1995:175-194. 22. Nyman S, Karring T, Bergenhohz G. Bone regeneration in alveolar bone dehiscences produced byjiggling forces. J Clin Periodonto11982;7:316-322. 23. Engelking G, Zachrisson B. Effects of incisor repositioning on monkey periodontium after expansion through the cortical plate. AnaJ Orthod 1982;82:2.3-32. 24. Lindskog-Stokland B, Wennstr6m J, Nyman S, et al. Orthodontic tooth movement into edentulous areas with reduced bone height. An experimental study in the dog. EurJ Orthod 1993;15:89-96. 25. Zengo A, Pawluk R, Basset C: Stress-induced bioelectric potentials in the dento-alveolar complex. Am J Orthod 1973;64:17.