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Journal of Stomatology
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Original paper

The effect of Winter’s red line, angle of impaction, and radio-morphometric indices on surgical difficulty of impacted mandibular third molar: a prospective observational study

Mohammed Ahmed Muter
1
,
Salwan Y. Bede
1

  1. Department of Oral and Maxillofacial Surgery, College of Dentistry, University of Baghdad, Baghdad, Iraq
J Stoma 2024; 77, 1: 1-6
Online publish date: 2024/02/29
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INTRODUCTION

The most common intervention in oral and maxil­lofacial surgery is the surgical extraction of impacted teeth. However, many complications are associated with this procedure and in order to avoid them, proper clinical and radi-ographic assessments are mandatory before third molar surgery [1]. To determine the difficulty of extracting mandib-ular third molars, Winter used three lines: white, amber, and red. The red line represents the depth of impaction that is drawn perpendicularly from the amber line to the anticipated point of application at the cemento-enamel junction of third molar. It indicates the amount of bone that needs to be removed before the elevation of the tooth [2].
It was suggested that with each millimeter increase in the red line measurement, surgical difficulty will increase three times, with a greater risk of inferior alveolar nerve injury [2]. Few clinical studies have investigated the effect of Winter’s red line as an indicator of the depth of impaction [3-5] on the extraction difficulty of impacted teeth, as many studies used the position of impaction as per Pell and Gregory classification [6-12].
Zhang et al. [13] proposed an index that included the angle of impaction as a factor to assess the surgical difficulty among Asian population. This was determined by drawing lines from the cemento-enamel junction of third molar to the contact point between the second and third molars, and then along the lamina dura of lower second molar. The authors found that the difficulty of extraction increases when the angle is 30 degrees or more [13].
One of the factors that may influence the difficulty of removing impacted teeth is bone density [14]. Bone density can be measured using computed tomography (CT) or cone beam CT, but these methods are associated with high doses of radiation compared with panoramic radiographs [14]. Various radio-morphometric indices are used to quan-tify the density of mandible with panoramic radiographs, such as the gonial index and antegonial index. These indices are used to assess mandibular cortical shape and width, either qualitatively or quantitatively, and together with other criteria, such as symptoms and family history, can be used to assess osteoporosis risk [15]. There are no previous clini-cal studies that addressed the effect of radio-morphometric indices on the difficulty of extraction of impacted mandib-ular third molars.

OBJECTIVES

The aim of this study was to assess how the Winter’s red line, angle of impaction, and gonial and antegonial indices of bone density affect the surgical difficulty of impacted mandibular third molars, assessed by duration of surgery and surgical technique.

MATERIAL AND METHODS

This prospective observational study was done between December 2021 and June 2022 at the University of Baghdad, College of Dentistry, Department of Oral and Maxillofacial Surgery. Every patient signed an informed consent to participate in this research after Institutional Research Ethics Committee accepted the study’s protocol (approval No.: 418121). The study was registered at clinicaltrials.gov (NCT05320744), and was guided by STROBE guidelines. The study involved 55 patients, who had undergone extractions of impacted mandibular third molars sur-gically under local anesthetic. There were 26 female and 29 male patients, with age ranging from 18 to 38 years old.
Inclusion criteria were healthy adult patients of at least 18 years old of both gender, who met the American Society of Anesthesiologists physical status classification level I (ASA I) and level II (ASA II), and presented with mesio-angular or horizontal impacted mandibular third molars. Patients with vertically and disto-angularly impacted teeth, those with uncontrolled systemic diseases, pregnant women, patients with an acute infection at the side of surgery at the time of procedure, those with cysts or tumors associated with impacted teeth, and patients who were missing sec-ond molars at the side of surgery, were all excluded. Similarly, patients with impacted teeth with unfavorable root morphology, such as dilacerations (which may increase difficulty of extraction), impacted teeth that demonstrated signs of close contact with the inferior alveolar canal in panoramic radiographs, such as dark-ening and deflection of the root and diversion of inferior alveolar canal, since such involvement may increase the duration of surgery and hence the degree of difficulty, were also excluded. Recurrent pericoronitis, orthodontic treatment planning, caries involving the impacted teeth and/or nearby mandibular second molars, and periodontal diseases were among the reasons for extracting mandibular impacted third molars.
A pre-operative panoramic radiograph was obtained for each patient with panoramic Planmeca ProOne®, Helsinki, Finland, with specifications: 66 KV, 9 mA, 14.9 S, and 97 mGy × cm2, and using Planmeca Romexis Viewer to measure the Winter’s red line, angle of impaction, gonial index, and antegonial index. Radiographic evaluation included check-ing the angulation, position, and depth of impaction, assessment of root formation and morphology, any pathological condition related to the surgical area, and relation between the impacted mandibular third molar and the inferior alveolar canal.
Surgical procedures were all performed under local anesthesia using lidocaine 2% with adrenaline 1 : 100,000 by one operator, who provided an inferior alveolar nerve block. Patients were instructed to rinse with 0.12% chlorhexi-dine mouthwash for 30-60 seconds before surgery. After achieving anesthesia, a full-thickness (muco-periosteal) buccal flap was reflected subperiosteally, and then the bone was removed buccally (bone guttering) with or without tooth sectioning, using a surgical handpiece and bur under copious irrigation with sterile normal saline. When the extraction was done by using an elevator only, the difficulty was considered low; when it required bone removal, the difficulty was considered moderate; when it required bone removal and tooth sectioning, the difficulty was consid-ered high [16]. Duration of surgery was measured in minutes from the first incision to the last suture. Independent (predictor) variables were pre-operative measurement of Winter’s red line in millimeters that was drawn perpendicular from the amber line to the anti­cipated point of application at the cemento-enamel junction of third molar from the amber line perpendicularly to the point of application of dental elevator in the cemento-enamel junction of third molar (Figure 1). The angle of impaction was measured in degrees by drawing lines from the cemento-enamel junction of third molar to the contact point between the second and third molars, and then along the lamina dura of lower second molar (Figure 2). Bone density was represented by two radio-morphic indices, such as gonial and antegonial indices. The gonial index was determined by measuring the mandibular cortical thickness in millimeters in the angle region at the intersection between the posterior border of mandibular ramus and the lower border of mandible. The antegonial index was determined by measuring the mandibular cortical thickness in millime-ters at the intersection of vertical line along the anterior border of ramus and horizontal line along the lower border of mandible (Figure 3). Dependent (outcome) variables included the surgical difficulty that was determined by the duration of surgery, and surgical technique.
For statistical analysis, GraphPad Prism version 9 for Windows was applied. Frequency and percentage of cate­gorical variables as well as mean and standard devia­tion (SD) of numerical variables were calculated as part of descriptive statistical analysis. Shapiro-Wilk normality test, ANOVA test, Spearman and Pearson correlation tests, and Kruskal-Wallis test were all used in inferential analyses. Probability values under 0.05 were deemed statistically signifi-cant.

RESULTS

The present study included 55 patients with impacted mandibular third teeth. The mean (SD) age of patients was 24.78 years (4.66), with age range of 18-38 years. The study group consisted of 29 (52.7%) males and 26 (47.3%) fe-males. According to the angulation, 29 (52.7%) patients had mesio-angularly impacted teeth, whereas 26 (47.3%) pa-tients had horizontally impacted teeth. Descriptive statistics of the study variables are summarized in Table 1.
Table 2 shows the correlation between the predictor variables and the duration of surgery, and it indicates that an increased red line, angle of impaction, and antegonial index resulted in an increased duration of extraction, and a decreased gonial index resulted in an increased duration of extraction. According to the technique of extraction, most of the cases (52.7%) were categorized as having high difficulty, followed by low (30.9%) and moderate (16.4%) difficulty categories. Table 3 presents the relationship between the predictor variables and the technique of surgery. All these variables were associated with an increased difficulty determined by the surgical technique.
Apart from the post-operative inflammatory sequelae, including pain, swelling, and trismus, which were reported by the patients, no post-operative problems in this study, such as infection, dry socket, or neurological damage were observed.

DISCUSSION

In order to predict surgical difficulty and complications, an adequate assessment must be performed, with appro-priate treatment plan and communication with the patient throughout the surgical procedure. The current study eval-uated the effects of Winter’s red line, angle of impaction, and bone density (gonial and antegonial indices) on the surgical difficulty measured by the duration of extraction and surgical technique. The mean age of the participants in this study (24.78 years) was comparable with that of other studies (range, 23.6-26.16 years) [17-20]. Third molar eruption times vary by ethnic group, and it was shown that Africans’ third molar eruption times are earlier than those of Caucasians and Asians [21, 22].
This study demonstrates that the Winter’s red line can serve as a reliable indicator of the surgical difficulty. The depth of impaction was represented in the literature as the red line according to Winter, or by the positional category according to Pell and Gregory classification. However, Almendros-Marqués et al. [23] found that Pell and Gregory classification lacks reproducibility because depth B of third molars is often confused with teeth in positions A or C. An increased depth of impaction will increase the amount of bone that covers the tooth, and hence, the tooth will become less accessible and more difficult for extraction [24]. Juodzbalys and Daugela [25] reported that the coronal position of impacted tooth should be assessed from the alveolar crest rather than the occlusal plane as per Pell and Gregory classification, because if the crown of third molar is small in size, it will locate below the occlusal plane; therefore, the difficulty of extraction is determined predominantly by the depth of impaction in the bone.
In the study, there was a positive correlation between the angle of impaction and the surgical difficulty measured by technique and duration of surgery. This may be explained by the fact that the difficulty of procedure is increased by the increased difficulty of accessing the impacted tooth due to the increased angle of impaction and increased contact surface between the second and third molars, which require more bone removal and tooth sectioning, and prolong the duration of surgery. This finding is in agreement with Zhang et al. [13], who studied the angle of impaction among other factors in 203 patients, and identified a cut-off angle of 30°, where impacted third molars with an angle of < 30° were considered less difficult for extraction than impacted teeth with an angle of ≥ 30°, and concluded that the angle of impaction can be used to predict third molar extrac­tion‘s difficulty.
In the current study, there was an inverse relationship between the gonial index and the surgical difficulty, which can be explained by the fact that when the third molar occupies more osseous space, it weakens the bone at the angle of the mandible, resulting in a decreased gonial index. The normal value of gonial index in healthy patients was re-ported to be more than 1.2 mm [15]. Kazim and Fattah [26] suggested that the mandibular cortical thickness in the angle region was influenced by the pre­sence and eruption status of the third molar, thus cases with mandibular third molar agenesis had higher index (mean, 2.13 mm) compared with cases with erupted and impacted third molars.
The relationship between the increased depth of impacted mandibular third molars and the decreased value of gonial index was linked to the increased possibility of mandibular angle fracture in patients with impacted teeth in some studies [26, 27].
This study demonstrated a weak positive relationship between the antegonial index and the surgical difficulty that is in line with previous studies, which observed that the antegonial index is a non-reliable indicator to detect low bone density, because it is affected by dental health, with lower values in edentulous patients compared with fully dentulous patients, who had higher values [28, 29]. The normal value of antegonial index in healthy patients should be more than 3.2 mm [15], and this is related to the fact that tooth extraction will impact masticatory function that will reduce osteo-genesis. According to Dutra et al. [30], methodological issues can arise when measuring this index, particularly when determining the location of line that best fits the inferior border of the ramus of the mandible, and runs down to the lower border of the mandible. Additionally, they reported that this index is influenced by patient age, and its value declines with aging. The mean age in their study was higher than that reported in our study. Also, all the subjects en-rolled in the current study were in good health and free from any metabolic conditions that could have impacted the bone structure. To the best of our knowledge, there are no studies that investigated the effect of gonial and ante-gonial indices on the difficulty of extraction of impacted mandibular third molars.

LIMITATIONS

The results of the current study need to be interpreted after considering its main limitations, which are related to the small sample size that may decrease generalizability of the results obtained. Also, the study included only two types of angulation (mesio-angular and horizontal), and excluded class III and position C of Pell and Gregory classification.

CONCLUSIONS

Taking into account the study’s limitations, the Winter’s red line and the angle of impaction have a strong influence in determining the surgical difficulty of impacted mandibular third molar, while the gonial and antegonial indices are not clinically relevant to determine the surgical difficulty.

CONFLICT OF INTERESTS

The authors declare no potential conflicts of interest concerning the research, authorship, and/or publication of this article.

References

1. Sánchez-Torres A, Soler-Capdevila J, Ustrell-Barral M, Gay-Escoda C. Patient, radiological, and operative factors associated with surgical difficulty in the extraction of third molars: a syste­matic review. Int J Oral Maxillofac Surg 2020; 49: 655-665.
2. Kumar S, Reddy MP, Chandra L , Bhatnagar A. The ‘red line’ conundrum: a concept beyond its expiry date? J Maxillofac Oral Surg 2013; 13: 612-614.
3. Idris AM, Al-Mashraqi AA, Abidi NH, et al. Third molar impaction in the jazan region: evaluation of the prevalence and clinical presentation. Saudi Dent J 2021; 33: 194-200.
4. Renton T, Smeeton N, McGurk M. Factors predictive of difficulty of mandibular third molar surgery. Br Dent J 2001; 190: 607-610.
5. Leung YY, Cheung LK. Correlation of radiographic signs, inferior dental nerve exposure, and deficit in third molar surgery. J Oral Maxillofac Surg 2011; 69: 1873-1879.
6. Bali A, Bali D, Sharma A, Verma G. Is pederson index a true predictive difficulty index for impacted mandibular third molar surgery? A meta-analysis. J Maxillofac Oral Surg 2012; 12: 359-364.
7. García AG, Sampedro FG, Rey JG, Vila PG, Martin, MS. Pell-Gregory classification is unreliable as a predictor of difficulty in extracting impacted lower third molars. Br J Oral Maxillofac Surg 2000; 38: 585-587.
8. Khojastepour L, Khaghaninejad MS, Hasanshahi R, Forghani M, Ahrari F. Does the winter or pell and gregory classification system indicate the apical position of impacted mandibular third molars? J Oral Maxillofac Surg 2019; 77: 2222.e1-2222.e9. DOI: 10.1016/j.joms.2019.06.004.
9. Santos KK, Lages FS, Maciel CAB, Glória JCR, Douglas-de-Oliveira DW. Prevalence of mandibular third molars according to the Pell & Gregory and Winter classifications. J Maxillofac Oral Surg 2020; 21: 627-633.
10. De Souza EF Jr, Silva JA, Pereira De Brito JI, de Souza Lucena E, Morais HHA. Association between pell and gregory classification and the difficulty of the extraction of the lower third molars. RGO Rev Gauch Odontol 2021; 69: 1-9. DOI: 10.1590/1981-86372021002120190101.
11. Kim JY, Yong HS, Park KH, Huh JK. Modified difficult index adding extremely difficult for fully impacted mandibular third molar extraction. J Korean Assoc Oral Maxillofac Surg 2019; 45: 309-315.
12. Santosh P. Impacted mandibular third molars: review of literature and a proposal of a combined clinical and radiological classification. Ann Med Health Sci Res 2015; 5: 229-234.
13. Zhang X, Wang L, Gao Z, Li J, Shan Z. Development of a new index to assess the difficulty level of surgical removal of impacted mandibular third molars in an asian population. J Oral Maxillofac Surg 2019; 77: 1358.e1-1358.e8. DOI: 10.1016/j.joms.2019.03.005.
14. Sammartino G, Gasparro R, Marenzi G, Trosino O, Mariniello M, Riccitiello F. Extraction of mandibular third molars: proposal of a new scale of difficulty. Br J Oral Maxillofac Surg 2017; 55: 952-957.
15. Bajoria AA, Asha ML, Kamath G, Babshet M, Patil P, Sukhija P. Evaluation of radiomorphometric indices in panoramic radiograph – a screening tool. Open Dent J 2015; 9: 303-310.
16. De Carvalho RWF, Vasconcelos BC. Pernambuco index: predictability of the complexity of surgery for impacted lower third molars. Int J Oral Maxillofac Surg 2018; 47: 234-240.
17. Deliverska EG, Petkova M. Complications after extraction of impacted third molars – literature review. J IMAB Annu Proceeding 2016; 22: 1202-1211.
18. Albyati MT, Bede S. The effect of the difficulty of surgical extraction of impacted mandibular third molars on the postoperative inflammatory response. J Res Med Dent Sci 2020; 8: 107-111.
19. Shabat M, Bede S. Effect of the local application of bupivacaine in early pain control following impacted mandibular third molar surgery: a randomized controlled study. Dent Med Probl 2021; 58: 483-488.
20. Thaer A, Bede S, Mohammed J. The influence of prophylactic prophylactic dexamethasone on postoperative swelling and trismus following impacted mandibular third molar surgical extraction. J Bagh Coll Dentistry 2010; 22: 85-90.
21. Olze A, van Niekerk P, Ishikawa T, et al. Comparative study on the effect of ethnicity on wisdom tooth eruption. Int J Legal Med 2007; 121: 445-448.
22. Chauhan P, Laskar S, Meena SS, Singh M, Suman A. Role of topical gel containing chitosan, 0.2% chlorhexidine, allantoin and dexpanthenol on the wound healing after surgical extraction of impacted mandibular third molar. Int J Health Sci 2022; 6: 1172-1186.
23. Almendros-Marqués N, Berini-Aytés L, Gay-Escoda C. Evaluation of intraexaminer and interexaminer agreement on classifying lower third molars according to the systems of Pell and Gregory and of Winter. J Oral Maxillofac Surg 2008; 66: 893-899.
24. Kim JY, Yong HS, Park KH, Huh JK. Modified difficult index adding extremely difficult for fully impacted mandibular third molar extraction. J Korean Assoc Oral Maxillofac Surg 2019; 45: 309-315.
25. Juodzbalys, G. and Daugela P. Mandibular third molar impaction: review of literature and a proposal of a classification. J Oral Maxil­lofac Res 2013; 4: e1. DOI: 10.5037/jomr.2013.4201.
26. Kazim N, Fattah A. Radiographic study of mandibular angular cortical thickness in relation to the presence and eruption status of mandibular third molar. J Bagh Coll Dentistry 2012; 24: 57-60.
27. Yeung AWK, Mozos I. The innovative and sustainable use of dental panoramic radiographs for the detection of osteoporosis. Int J Environ Res Public Health 2020; 17: 2449-2460.
28. Yalcin ED, Avcu N, Uysal S, Arslan U. Evaluation of radiomorphometric indices and bone findings on panoramic images in patients with scleroderma. Oral Surg Oral Med Oral Pathol Oral Radiol 2019; 127: e23-e30. DOI: 10.1016/j.oooo.2018.08.007.
29. Sghaireen MG, Alam MK, Patil SR, et al. Morphometric analysis of panoramic mandibular index, mental index, and antegonial index. J Int Med Res 2020; 48: 300060520912138. DOI: 10.1177/0300060520912138.
30. Dutra V, Yang J, Devlin H, Susin C. Radiomorphometric indices and their relation to gender, age, and dental status. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2005; 99: 479-484.
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