제1대구치 기성금속관 생존율에 관한 후향적 연구

Retrospective Study on the Survival Rate of Preformed Metal Crowns in Permanent First Molars

Article information

J Korean Acad Pediatr Dent. 2020;47(2):140-147
Publication date (electronic) : 2020 May 31
doi : https://doi.org/10.5933/JKAPD.2020.47.2.140
1Department of Pediatric Dentistry, Kyungpook National University Dental Hospital
2Department of Pediatric Dentistry, College of Dentistry, Kyungpook National University
오나영1orcid_icon, 남순현2orcid_icon, 이제식2orcid_icon, 김현정,2orcid_icon
1경북대학교치과병원 소아치과
2경북대학교 치의학전문대학원 소아치과학교실
Corresponding author : Hyunjung Kim Department of Pediatric Dentistry, School of Dentistry, Kyungpook National University, 2177, Dalgubeol-daero, Jung-gu, Daegu, 41940, Republic of Korea Tel: +82-53-600-7201 / Fax: +82-53-426-6608 / E-mail: jungkim@knu.ac.kr
Received 2019 September 24; Revised 2019 November 20; Accepted 2019 November 4.

Abstract

이 연구는 영구 제1대구치 기성금속관에 있어서 장기간 생존율을 후향적으로 평가하고 생존율에 영향을 미치는 요소를 분석하고자 하였다. 10년 동안 수복된 115개의 제1대구치 기성금속관을 후향적으로 분석하였으며, 제1대구치 기성금속관의 5년 생존율 82.8%로 나타났으며 원심와동, 하악 치아에서 생존율이 유의하게 낮게 나타났다. 이 연구를 통해서 임상적으로 기성금속관 성공률에 영향을 미치는 요인들을 확인하였으며, 성공률을 높이기 위한 치료지침을 확립하는데 도움이 될 수 있으리라 생각된다.

Trans Abstract

This study analyzed the longevity of preformed metal crowns (PMCs) in first permanent molars and evaluated factors influencing their survival during a long-term follow-up period. In all, 115 first permanent molars treated with PMCs between June 2008 and June 2018 were retrospectively analyzed. The overall combined success rate for the study group was 84.3%. The 5-year survival rate was 82.8%. Multivariate Cox regression analyses identified distal cavities and mandibular PMC placement as risk factors for restoration failure. Careful placement of PMCs at the final try-in stage augments the longevity of the crown.

Ⅰ. Introduction

Among the permanent teeth, the first permanent molars play the greatest role in occlusion, function, and development of the dentition[1,2]. Proper crown coverage is essential when a permanent first molar is extensively damaged by severe caries or hereditary anomalies, such as molar incisor hypomineralization (MIH), dentinogenesis imperfecta (DI), or amelogenesis imperfecta (AI)[3]. This task is compounded by the fact that young permanent teeth are partially erupted and will continue to erupt and alter their position in the mouth, which will change the margins of any existing restoration[4]. Moreover, moisture-control problems, difficulty with coordination due to young age, and short crown height make treatment difficult. In such cases, preformed metal crowns (PMCs, also known as stainless steel crowns) may be useful.

PMCs have long been used to cover molars with defective enamel and they are still recommended as a treatment option for MIH of the posterior teeth[5,6]. In many cases of severely damaged permanent first molar crowns in children, PMCs are a successful interim restorative option until a permanent restoration, usually of the full coverage type, can be placed later[4]. No other type of restoration offers the convenience, low cost, durability, and reliability of such crowns when interim full coronal coverage is required[7]. They prevent further tooth loss, control sensitivity, and establish correct interproximal and proper occlusal contacts. PMCs have a very long history of use, although their use in the primary dentition is by far the most common. Several studies have reported survival times in excess of 5 years and success rates of 92 - 94% in the primary dentition[8]. Although the use of PMCs in permanent first molars is widespread, only limited data on their long-term prognosis are available[9]. Therefore, this study was carried out to evaluate the longevity of PMCs in permanent first molars and identified clinical preoperative variables that may correlate with treatment outcomes.

Ⅱ. Materials and Methods

The protocol was approved by the Institutional Review Board of Kyungpook National University Dental Hospital (IRB No. KNUDH-2019-05-02-00).

1. Subjects

This study retrospectively analyzed 158 children (212 teeth) treated with PMCs in permanent first molars between June 2008 and June 2018 at the Department of Pediatric Dentistry, College of Dentistry, Kyungpook National University. Children were excluded if they were older than 15 years old, lacked preoperative and postoperative radiographs, were lost to follow-up (minimum 1 year), or had a molar root incisor malformation with a questionable prognosis. Preoperative and postoperative radiographs were required for all teeth subjected to review, as was a record of at least one follow-up appointment that included a clinical and radiographic re-evaluation of the PMC during the cumulative 10-year period of study.

Overall, 115 teeth of 82 patients were selected for inclusion. Assessments of preoperative factors, prognosis of the PMC, and reasons for failure were examined by analyzing the patients’ electronic dental records and radiographs.

2. Methods

1) Determination of survival and failure.

The crown’s viability as an interim restoration was assessed at its follow-up appointment within the study period. Determination of survival and failure were defined as follows. For survival, the PMC not only survived in function until the completion of the study period, having served its purpose until a cast crown could be placed, but was also devoid of any major clinical or radiographic issues (Fig. 1A). The date of the last recall visit of the patient was recorded as the censoring date for PMC-treated teeth that survived. The time lapse between PMC placement and the last recall visit was calculated for these teeth. To be categorized as failure, the crown had to either be lost (debonded, intentionally sectioned and replaced, or extracted) or exhibit major clinical or radiographic issues (Fig. 1B, e.g., a short crown with open margins, impaction of adjacent teeth under the margins of the crown, perforation due to wear, or the presence of a periapical pathology). Failed PMCs were no longer suitable as an interim restoration and needed to be retreated.

Fig 1.

(A) A successful preformed metal crown restoration. (B) A failed preformed metal crown showing defective restoration with open margins and periapical pathology

2) Classification of preoperative parameters.

The following data were collected from the patients’ records: age at time of restoration, sex, dental arch (maxilla versus mandible), operator experience, number of proximal contacts, precipitating factors, and pulp involvement. The subjects were divided into three age groups: 6 - 8, 9 - 11, and 12 - 14 years old. The number of proximal contacts was classified as either 2 (both walls intact), 1 (distal cavity or mesial cavity), or 0 (broken-down wall) based on the remaining tooth structure (Fig. 2)[10]. The precipitating factors for crown placement included caries, AI or DI, MIH, and post-endodontic therapy. Pulp involvement was classified as no pulp treatment, indirect pulp capping, direct pulp capping and pulpotomy, or pulpectomy.

Fig 2.

Number of proximal contacts. (A) 2, Both walls intact. (B) 1, Distal cavity. (C) 1, Mesial cavity. (D) 0, Broken down wall.

3) Statistical analysis

Data were analyzed using SPSS software (ver. 23.0, SPSS Inc., Chicago, IL, USA). The 10-year survival rate of PMCs was analyzed using the Kaplan-Meier method and log-rank test for differences between groups. Multivariate Cox regression analyses were performed to analyze the influence of variables that showed significant differences.

Ⅲ. Results

1. Survival rate and reasons for failure

The minimum time of follow-up was 12 months and the maximum was 118 months (average 44.3 months). The patients ranged in age from 6 to 14 years old (average 9.27 years old). Success was documented in 97 of the 115 PMCs. The total number of failed PMCs was 18. Failures included defective restoration (n = 10), debonding (n = 4), periapical pathology (n = 3), and perforation from wear (n = 1). The overall success rate for the study group was 84.3% (Table 1).

Reasons for failure of preformed metal crowns in permanent first molars

The mean survival time was 98 months (range: 88.4-107 months, SD = 4.9 months). The survival rate was 97.4% at 1 year, 84.8% at 3 years, and 82.8% at 5 years (Fig. 3).

Fig 3.

Kaplan-Meier survival analyses of preformed metal crowns.

2. Analysis of risk factors

Prognostic variables for univariate survival analyses included sex, age, operator experience, pulp involvement, number of proximal contacts, dental arch, and precipitating factors (Table 2). The 115 PMCs were similarly distributed between males and females. The mean age of the patients at PMC placement was 9.17 years old. Log-rank tests revealed that pulp involvement, number of proximal contacts, dental arch, and precipitating need were correlated with the survival rate of the PMCs. Regarding pulp involvement, the success rate decreased in the following order: pulpectomy, no pulp treatment, indirect pulp capping, and pulpotomy. Notably, the success rate of pulpotomy was 66.7%.

Preoperative parameters influencing the overall survival rate and the results of univariate analyses using the Kaplan-Meier method

Based on precipitating the need for crown placement, the success rates of PMCs were 61.9% for caries, 84.3% for endodontically treated teeth, 86.0% for MIH, and 91.7% for AI and DI.

To analyze the effects of preoperative parameters on the PMC survival rate further, hazard ratios (HRs) were calculated for the variables that showed statistical significance on the Kaplan-Meier test. According to the Cox multivariate hazard model, the number of proximal contacts and dental arch were the factors that significantly affected the survival of the PMCs (Table 3). Teeth with distal cavities were 9.225 times more likely to fail (HR = 9.225). There were no failures among 6 cases of mesial cavity and 4 cases of broken-down wall. Thus, the hazard ratios for a mesial cavity and broken-down wall were 0, compared to cases with both walls intact. The number of sample cases was small and the results were not statistically significant (p= 0.990 and 0.993, respectively).

Multivariate Cox proportional hazard regression model for determining the survival rate of preformed metal crowns

In addition, lower permanent first molars were 12.925 times more likely to fail compared to upper first permanent molars. Precipitating need and pulp involvement showed no significance in failure rates.

Ⅳ. Discussion

The longevity of dental restorations depends on many different factors related to the restorative material, the patient, and to the dentist[11]. Although limited data are available on the longevity of PMCs, they are considered long-lasting by many dentists. This is confirmed by the 82.8% 5-year survival rate for PMCs on permanent molars in the present study. Similarly, other studies have shown promising results for PMCs. Chen et al.[12] found that most PMCs were judged as clinically acceptable (22/23, 96%) from an evaluation based on modified US Public Health Services criteria with at least 52 months of clinical service. Discepolo and Sultan[4] reported an 88% overall success rate during an average service period of 45.18 months. Moreover, significant success was noted in patients less than 9 years of age in their study. In contrast, greater success was noted for older subjects in the present study. Teeth emerge, and coordination improves, with age, which may promote proper tooth isolation and adaptation. However, there was no statistical correlation between age and success rate.

In this study, a commonly observed problem was defective restorations. This finding is in agreement with the report by Chen et al.[12], who studied permanent molars with AI. They found that 9 out of 27 PMCs were placed with faulty marginal limits, most likely due to the nature of a prefabricated crown and the operator’s inability to identify the size required correctly. Poor marginal sealing may allow microleakage along the interface between the tooth and crown[13]. This lack of adaptation would allow for bacterial invasion, and thus failure of any present endodontic treatment. Debonding failure can also occur if the crown is not seated properly or does not adapt well to the margins of the tooth, leading to cement washout[4,13]. Thus, defective restorations, debonding, and pulp pathology are all closely related.

Defective restorations, such as a short crown with open margins, an overall poor fit, or lodging, were predominantly related to initial seating. In view of the potential longevity of these crowns, a periapical or bitewing radiograph is recommended before cementation to check the marginal fit mesially and distally, as it is often not possible to check these areas adequately using an explorer[14].

The number of proximal contacts was significantly associated with survival, in that teeth with distal cavities failed at 9.225 times the rate of teeth with two proximal contacts. The significant decrease in the survival of teeth with distal cavities may be the result of increased difficulty of the preparation procedure due to compromised access, restricted visibility, and moisture-control problems[12]. It is often inevitable to place a PMC margin subgingivally in partially erupted permanent molars. Increased subgingival crown height makes isolation and margin placement difficult compared to mesial cavities[12,14]. This problem is particularly serious if the permanent second molar is close to emergence.

With regard to dental arch, mandibular molars showed a higher failure rate than did maxillary molars within the confines of this study. This may be related to the fact that the rate of distal cavities in the maxilla was 13.6%, whereas it was 26.8% in the mandible. Jeong et al.[15] reported that the repair rate of composite resin restorations in the permanent first molars of children under 12 years old was 1.4 times higher in the mandible than in the maxilla. This may be because the posterior operculum lasts longer in the mandible than in the maxilla, which makes it more difficult to isolate clinically[15,16].

In relation to pulp involvement, pulpotomy showed the lowest success rate, Presumably, the lower survival rate of PMCs with pulpotomy occurred because the failure of pulp treatment caused the failure of the PMCs. Moreover, bacterial contamination can occur through the marginal gap of the coronal restoration; thus jeopardizing the long-term success of the pulpotomy procedure[17]. However, this was not found to be significant according to the Cox multivariate hazard model.

Based on precipitating the need for crown placement, AI and DI had the highest success rate. This was probably because AI and DI teeth are often covered with PMCs for preventive purposes before post eruptive breakdown occurs. This might have led to the higher success rate of PMCs.

This study was performed retrospectively based on medical records, and thus it was difficult to establish a cause of failure when pulp pathology was involved, and failure may in fact have been multifactorial in origin. Roberts et al.[18] assessed PMC failure as ‘true’ and ‘false’ failures. Crown loss following cement failure or perforation of the occlusal surface as a result of wear was considered true failure, and failure related to endodontic treatment was considered false failure. False failure of PMCs may occur when a pulpotomy is not carried out when it should have been, or when a pulp treatment is performed but fails due to operator error. An example of true failure of a restoration resulting from pulp pathology would be when endodontic therapy is carried out but failure occurs as a result of restoration leakage leading to a recurrence of pulp inflammation[19]. In addition, coronal leakage is often associated with endodontic failure and a well-constructed coronal restoration has a greater effect on endodontic success than the quality of the endodontic obturation[20-22]. Therefore, it is not clear whether pulp pathology is due mainly to a defective restoration or a failed pulp treatment. However, in this study, all pulprelated complications were classified as failures, therefore overestimation of PMC failure might have occurred.

The record review method for identifying PMC failure relies exclusively on data from patients’ electronic dental records and radiographs. Only events documented in patients’ electronic dental records are included in the analysis; therefore, available information regarding events in the records may be insufficient for failure assessment. When conducting routine clinical examinations, perforation due to wear and loosening of PMCs due to cement loss may be overlooked, thus leading to underestimation of PMC failure.

The retrospective nature of this study made it impossible to identify a true causative relationship between preoperative parameters and survival rate. Therefore, the effects of preoperative parameters should be further evaluated in future prospective randomized controlled trials.

Nonetheless, this study is significant in that it evaluated sequelae of PMCs over a long-term follow-up period and determined factors influencing the outcome of PMCs in permanent first molars. The results imply that PMCs can be used in permanent first molars as interim restorations until a permanent restoration can be placed. Interim PMCs do not replace the need for permanent restorations in the future, but the interval allows for the practitioner to determine the optimal timing for replacement. This study identified the factors that influence the success rate of PMCs and may be helpful in establishing treatment guidelines for extensively damaged permanent first molars.

Ⅴ. Conclusion

PMCs can function as a viable treatment option for the interim restoration needs of extensively compromised permanent first molars, with an 89% overall success rate and an 82.8% 5-year survival rate. Distal cavities and mandibular placement are risk factors for failure. To increase their longevity, dentists should understand these failure factors and ensure careful placement of PMCs.

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Article information Continued

Fig 1.

(A) A successful preformed metal crown restoration. (B) A failed preformed metal crown showing defective restoration with open margins and periapical pathology

Fig 2.

Number of proximal contacts. (A) 2, Both walls intact. (B) 1, Distal cavity. (C) 1, Mesial cavity. (D) 0, Broken down wall.

Fig 3.

Kaplan-Meier survival analyses of preformed metal crowns.

Table 1.

Reasons for failure of preformed metal crowns in permanent first molars

Reasons for Failure Number of Failures (%)
Defective restoration 10 (55.6)
Debonding 4 (22.2)
Periapical pathology 3 (16.7)
Perforation due to wear 1 (5.6)
Total 18 (100.0)

Table 2.

Preoperative parameters influencing the overall survival rate and the results of univariate analyses using the Kaplan-Meier method

Parameters Preformed Metal Crowns p
No. Performed No. Survival (%)
Sex
 Male 49 41 (83.7) 0.732
 Female 66 56 (84.8)
Age
 6 - 8 39 32 (82.1) 0.668
 9 - 11 64 54 (84.4)
 12 - 14 12 11 (91.7)
Operator
 Professor 28 26 (92.9) 0.086
 Resident 87 71 (81.6)
Pulp involvement
 No pulp treatment 70 62 (88.6) 0.003
 Indirect pulp capping 7 5 (71.4)
 Pulpotomy 18 12 (66.7)
 Pulpectomy 20 18 (90.0)
Number of proximal contacts
 2, Both walls intact 80 74 (92.5) 0.000
 1, Distal cavity 25 13 (52.0)
 1, Mesial cavity 6 6 (100)
 0, Broken down wall 4 4 (100)
Dental arch
 Maxilla 44 43 (97.7) 0.003
 Mandible 71 54 (76.1)
Precipitating factors
 Caries 21 13 (61.9) 0.012
 AI,DI 24 22 (91.7)
 MIH 50 43 (86.0)
 Endodontically treated 20 19 (84.3)

p value from Kaplan-Meier test

AI = Amelogenesis imperfecta, DI = Dentinogenesis imperfecta

MIH = Molar incisor hypomineralization

Table 3.

Multivariate Cox proportional hazard regression model for determining the survival rate of preformed metal crowns

Parameter HR 95% CI p value
Pulp involvement
 No pulp treatment 1
 Indirect pulp capping 0.440 0.078 - 2.475 0.351
 Pulpotomy 2.991 0.816 - 10.964 0.098
 Pulpectomy 0.490 0.084 - 2.865 0.429
Number of proximal contacts
 2, Both walls intact 1
 1, Distal cavity 9.225 2.764 - 30.791 0.000
 1, Mesial cavity 0.000 0.000 0.990
 0, No walls 0.000 0.000 0.993
Dental arch
 Maxilla 1
 Mandible 12.925 1.656 - 100.899 0.015
Precipitating factors
 Caries 1
 AI, DI 0.641 0.076 - 5.393 0.682
 MIH 0.705 0.171 - 2.912 0.629
 Endodontically treated 0.755 0.081 - 7.084 0.806

p value from multivariate Cox-regression analyses

HR = Hazard ratio, CI = Confidence interval

AI = Amelogenesis imperfecta, DI = Dentinogenesis imperfecta, MIH = Molar incisor hypomineralization