Abstract
Impaction of the lower second molar is not a common problem, but it is very challenging for both orthodontist and oral surgeon. Treatment options depend on the degree of tooth inclination, the position of the third molars, and the desired type of movement, which may be surgical and/or orthodontic in nature. A good treatment alternative is surgical uncovering with orthodontically-assisted eruption. A case of successful uprighting using a 0.017 × 0.025–inch titanium molybdenum alloy (TMA) tip-back cantilever is presented. Different aspects of uprighting impacted second molars are discussed in light of the literature. The iatrogenic character of lower second molar impaction is emphasized.
INTRODUCTION
The impaction of permanent teeth usually concerns the maxillary or mandibular third molars, maxillary canines or central incisors, and mandibular second premolars.1 Eruption disturbances of mandibular second permanent molars are rather rare. The incidence of second molar impaction revealed by panoramic radiograph studies has been reported as 0.03%2 to 0.04%3 of all impacted teeth.
The etiology of impaction is related to some disturbance of physiological mandibular growth and tooth development. The space for second permanent molars is obtained by resorption of the bone at the anterior border of the mandibular ramus and mesial migration of the first molar into the leeway space. The tooth bud of the second permanent molar develops with some mesial axial inclination and the ability for natural self-correction manifests as the remodeling changes occur.4
Disturbances of this natural process may lead to impaction and be associated with an arch length deficiency5 because of inadequate mandible growth. Excess space between the developing second molar and first molar may also result in impaction, probably because the second molar crown needs the first molar distal root for proper eruption.6 The most important iatrogenic factors include an incorrectly fitted band cemented on the first mandibular molar, previous orthodontic sagittal expansion,7 and prevention of the mesial shift of the first permanent molar caused by lip-bumper or lingual arch therapy. Sometimes the second molar gets impacted spontaneously, which is probably related to the third molar position.8
Advantages of impacted molar uprighting and extrusion are functional, periodontal, and restorative. Uprighting second molars allows avoidance of a shortening of the occlusal plane that may result from impacted tooth loss, especially in cases of unpredictable third molar position. Moreover, unopposed teeth have a tendency to erupt excessively. The periodontal benefit of molar uprighting is the elimination of the pseudopocket, which facilitates plaque control in the area.9 Because proper oral hygiene in the area of impacted teeth is difficult, caries may easily affect unerupted teeth. Uprighting of impacted molars, therefore, seems beneficial in caries prevention. Undiagnosed second molar impaction may damage the distal root of the first molar, as shown in the panoramic radiograph of a 24-year-old woman in Figure 1.
Panoramic radiograph of 24-year-old woman showing damage of first molar distal root by impacted left second molar
Panoramic radiograph of 24-year-old woman showing damage of first molar distal root by impacted left second molar
The best time to treat impacted mandibular second molars is between 11 and 14 years of age, when development of the second permanent molar roots is still incomplete. The treatment options depend on the degree of tooth inclination as well as the required tooth movement. The position of a slightly-tipped molar can be corrected by placing a brass wire separator between the teeth.10 A more severe inclination requires surgical methods or orthodontically-assisted eruption with or without surgical uncovering. Surgical methods include surgical repositioning with or without extraction of the third molar11–17 or extraction of the impacted second molar to allow either eruption of the third molar or transplanting the third molar to the second molar socket18
A good treatment option is orthodontically-assisted eruption with or without surgical uncovering. The general treatment approach is an attachment, if necessary, bonded to the surgically uncovered buccal or distobuccal surface and subsequently some uprighting force delivered by means of applying a NiTi-coil spring,19 superelastic NiTi wire,7 a variety of uprighting springs,20–25 or a sectional arch wire.26
Some authors have suggested bracketing techniques after surgical exposure and the use of the NiTi wire for molar uprighting.8,27 Some appliances are located lingually and are therefore very useful in cases with limited buccal access.28,29 Placing titanium miniscrews in the retromolar area for molar uprighting was recommended by Giancotti et al.30 This paper discusses the biomechanics of a simple tip-back cantilever31 and presents a successful orthodontic treatment that corrected a patient's partially impacted second mandibular molars.
Biomechanical Considerations
Molar uprighting may be secured by a pure rotation obtained by application of a pure couple force system with a high moment-to-force ratio (so that the center of rotation is very close to the center of resistance). A long cantilever gives a high moment-to-force ratio, which results in a clinical effect very close to that of pure rotation. The magnitude of the moment required to rotate a molar has been suggested to be 800–1500 g/mm.31,32
The cantilever produces effects on the tooth in three planes, mainly in the mesiodistal direction (distal crown tipping) and the vertical direction (molar extrusion). Determining the forces on teeth calls for defining the forces that are delivered to the cantilever inserted in the molar tube. The activation force (A) is directed to the occlusal and is opposed by the apically directed force (B) that the molar tube exerts on the wire. Mesial and distal aspects of the molar tube also exert forces (C and D) on the wire that oppose a counterclockwise rotation resulting from forces A and B (Figure 2). The forces acting on the teeth are of the same magnitude as, but of opposite direction to, the forces acting on the wire (Figure 3). Thus, the intrusive force is on the anterior segment and the extrusive force on the molar, and the couple distally rotates.9
CASE REPORT
A 14-year-old female presented with bilateral partial impactions of the lower second molars. Clinically, the patient had a Class I malocclusion with very mild crowding in the anterior segment and distal rotation of both lower canines and the lower right first premolar. The cephalometric measurements were within the norm. The patient's dental development showed an early permanent dentition with erupting upper second molars and malposition of the lower second molars. The distal cusps of the lower second molars were present in the mouth very close to the distal of the first molar.
A panoramic radiograph revealed the presence of all permanent teeth and a severe mesial inclination of both the lower second molars and developing third molars (Figure 4). Both mandibular second molars were obliquely impacted under the distal bulge of the first molars. The apex of the impacted molar roots was still incompletely formed. The third molar buds were located on top of the second molar distal roots.
Pretreatment panoramic radiograph shows bilaterally impacted lower second molars
Pretreatment panoramic radiograph shows bilaterally impacted lower second molars
The treatment plan was surgical-orthodontic in nature. The surgical procedure was performed in two stages. The first was the uncovering of the buccal aspect of the impacted tooth and bonding a tube to the exposed surface with Smart Bond (Gestenco International AB, Gothenburg, Sweden) adhesive. The second stage—germectomy of the third molars—was to be performed after orthodontic uprighting had been achieved. The orthodontic treatment plan involved the uprighting and extrusion of both second molars and fixed appliance therapy in the lower arch. The patient's parents did not agree to fixed appliance treatment in the upper arch.
One 0.017 × 0.025–inch titanium molybdenum alloy (TMA) cantilever was inserted into each second molar buccal tube and hooked distally to the canines (Figure 5). Initially, a partial fixed appliance (0.018-inch slot) was used. The activation force measured by a dynamometer amounted to 50 g. The cantilever was 30 mm in length and delivered a moment of 1500 g/mm. The anchorage was secured by the anterior segment with a stiff wire (0.017 × 0.025–inch stainless steel) and a figure eight steel ligature wire was inserted between the canines and by the lingual retainer. The patient was scheduled for follow-ups every 2 weeks to control anchorage and the movements of the impacted teeth. The initial change of inclination was noticed 4 weeks after the application of the device. At this stage, a full fixed appliance was employed.
Later, some 5 months after the beginning of treatment, a satisfactory lower second molar inclination was achieved bilaterally (Figure 6A, B). Subsequently, germectomy of third molars was performed. A corrected inclination of the impacted molars was obtained (Figure 7A–C), and was confirmed on the posttreatment panoramic radiograph (Figure 8).
(A) and (B) Intraoral photographs after 5 months showing corrected inclination of lower second molars
(A) and (B) Intraoral photographs after 5 months showing corrected inclination of lower second molars
(A), (B), and (C). Posttreatment intraoral photographs showing corrected inclination of lower second molars
(A), (B), and (C). Posttreatment intraoral photographs showing corrected inclination of lower second molars
DISCUSSION
Correction of impaction of the lower second molar has not been adequately presented in the literature. This particular disturbance is rather difficult to prevent because of its multifactorial and often hypothetical etiology, yet a careful orthodontic treatment is required according to the primum non nocere principle. Particular care is called for whenever doing a simple band cementation procedure or the more complex treatment of increasing arch length by distalizing lower first molars. An incorrectly fitted and/or cemented band on the lower first molar may cause second molar impaction and hinder the uprighting process, as is demonstrated in the panoramic radiograph of a 14-year-old girl (Figure 9).
Panoramic radiograph showing impacted second molar crown blocked under the distal edge of incorrectly fitted band
Panoramic radiograph showing impacted second molar crown blocked under the distal edge of incorrectly fitted band
Different treatment options are discussed in the literature. Generally, surgical repositioning and transplantation brings a higher risk of complications, such as pulp necrosis, ankylosis, or root resorption, and therefore should be applied only when orthodontic treatment is contraindicated.6,11 If surgical methods are a preferred treatment, it is important to know that surgical repositioning gives a better long-term prognosis than transplantation because the tooth is not removed from the socket. That helps the apical vessels to remain intact and prevents contamination of roots with saliva.15 Extraction of the impacted tooth to let the third molar erupt also has some disadvantages because of the long time interval between the extraction of the second molar (at age 12–14) and the eruption of the third molar (at age 17).6 As a result, the third molar may become tipped and impacted. However, Orton-Gibbs et al,33 in a study of eruptive path of third molars after second mandibular molar extraction, reported that none of these teeth became impacted and that all achieved the acceptable position, but suggested that this treatment option requires good case selection.
A less risky alternative is orthodontically assisted eruption with or without surgical uncovering; this depends on the degree of impaction. The choice of appliance should be based on proper evaluation of impacted molars and the developing third molar position. Other factors, such as the degree of impaction and desired type of movement, should also be considered when choosing an appliance.
Prior to orthodontic therapy, the need for third molar extraction should be evaluated.8 Frequently, the third molar position may impede the distal movement of the impacted molar, indicating the need for extraction. However, from a biomechanical perspective, sometimes it is better to leave the third molar bud to facilitate the second molar rotation.24
In the case presented, the evaluation of the position of the third molar buds in the mandibular ramus and a subsequent biomechanical analysis allowed us to plan the timing of the germectomy after orthodontic uprighting.
The most often recommended appliance for molar uprighting and extrusion is a simple tip-back spring31 The length of the cantilever determines the moment-to-force ratio, and so the achieved movement. A short cantilever delivers more extrusion than a longer one. Although some extrusion was indeed our aim, the cantilever wasn't planned short because a pure rotation of a tipped molar always increases its height and there is no need for an auxiliary extrusive force. Moreover, a longer cantilever gives a relatively low load/deflection rate leaving the force system with a high degree of constancy. Another important characteristic of the force system delivered by the cantilever is the constancy of the moment-to-force ratio, which results in more homogeneous tooth movement.32 The tip-back cantilever acts on the molar in three planes, so it is important to use the size wire that fills the slot in order to avoid lingual tipping of the molar. In the case presented, TMA wire (0.017 × 0.025–inch) in an 0.018-inch slot was used.
We started uprighting with a partial fixed appliance to allow the hook to move distally as the tooth uprighted. The anchorage secured by the anterior segment was controlled. When the initial change in inclination had taken place, the full fixed appliance was used.
CONCLUSION
Second molar impaction is a very challenging disturbance that requires proper clinical, radiological, and biomechanical evaluation and a good appliance selection for successful treatment results.
REFERENCES
Author notes
Corresponding author: Dr. Monika Sawicka, Department of Orthodontics, Medical University of Gdansk, Al. Zwyciestwa 42c, Gdansk, woj. Pomorskie 80-210, Poland ([email protected])