A mandibular second molar with a middle mesial root canal.

The present case report describes the clinical detection and root canal management of a rare middle mesial canal of a Japanese mandibular second molar by troughing preparation using an operating microscope and cone-beam computed tomography.

INTRODUCTION

A pulpectomy of a 44‐year‐old Japanese mandibular second molar with a rare middle mesial canal was performed using troughing preparation. In addition, cone‐beam computed tomography images revealed the morphology of the three root canals in the mesial root.

Prior knowledge of root canal anatomy is essential for the success of endodontic therapy. To remove bacteria from the root canal system and prevent reinfection, it is important to find all the main canals in the tooth root in the initial root canal treatment. Though a root canal system is, in general, complicated, an operating microscope and cone‐beam computed tomography (CBCT) are effective for analyzing root canals.1, 2

A mandibular molar commonly has two roots. In two‐rooted mandibular second molars, the most common root canal configuration is Vertucci type IV (two root canals, two apical foramina) or Type II (two root canals, one apical foramen) in a mesial root, and Type I (one root canal, one apical foramen) in a distal root.3 In addition, C‐shaped root canals have been found more frequently in Asian populations than in other populations.4, 5, 6 Internal and external configurations of teeth vary depending on, not only geographic regions, but also sex, age, ethnicity, and population group.5, 7, 8, 9, 10, 11, 12 All these factors need to be taken into consideration in root canal treatment.

The mesial root canals of the first and second mandibular molars do not present a consistent pattern.13 MM canal, whose orifice is, in general, disclosed, is sometimes located as an intermediate canal in the developmental groove connecting a mesiobuccal (MB) canal and a mesiolingual (ML) canal.14, 15 Pomeranz et al16 classified MM canals into three types as follows: (a) fin, allowing free instrument movement between the main and accessory canal; (b) confluent, having a separate orifice but merging more apically with the MB or ML canals; and (c) independent, having a separate orifice and apical terminus. Since Vertucci and Williams17 as well as Barke et al18 first described the presence of a MM canal in a mandibular first molar, there have been multiple subsequent reports of aberrant canal morphology in mandibular second molars.7 Various published articles on the presence of a MM canal in Europeans, Asians, Africans, and South/North American populations, show that the incidence of a mandibular second molar with a MM canal ranges from 0% to 12.8%.3, 5, 7, 8, 10, 11, 12, 16, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48 Nosrat et al9 and Martins et al5 found significant differences in the incidence of a MM canal between Caucasian and non‐Caucasian populations. Surprisingly, our PubMed literature search did not reveal any clinical case reports or original research articles showing a MM root canal in an Asian mandibular second molar.3, 5, 7, 11, 42

The present case report describes the clinical detection and root canal management of a MM canal of a Japanese mandibular second molar by troughing preparation49, 50, 51 using an operating microscope and CBCT.

CASE REPORT

A 44‐year‐old male patient with a medical history of type II diabetes and hyperlipidemia was an inpatient at Nippon Kokan Fukuyama Hospital. The patient complained of difficulty masticating and was referred to the dental department by his physician. An oral examination showed that the maxillary first and second molars were missing, and that the vertical clearance was insufficient (Figure 1A). The left mandibular first premolar, and first and third molars had been extracted due to extensive dental caries, and the 5‐unit bridge at the abutment of the left mandibular canine, second premolar and second molar was fixed approximately 10 years prior to this first visit (Figure 1A). In order to assist the patient with mastication, a left maxillary prosthesis had been planned. However, due to the insufficient vertical clearance (Figure 1A), pulpectomy at the left mandibular second molar was necessary prior to the prosthesis.

Figure 1

Intraoral photograph and dental radiograph of tooth 37 at the first visit. (A) Clinical view of left maxillary and mandibular. Tooth 26 and 27 were missing. Tooth 33, 35, and 37 were set on the dental bridge prosthesis. There was no vertical clearance for prosthesis, (B) Dental radiograph. A radiograph showed no specifics

The pocket probing depth of the left mandibular second molar was 3 mm. The molar from which the full metal crown, which was a part of the 5‐unit bridge, had been removed, reacted to electric pulp vitality test using PULPER® (GC) and Digitest® (Parkell). A radiograph revealed no specific pathosis in the molar or the surrounding periapical and periodontal tissues (Figure 1B). Thus, the left mandibular second molar where the pulpectomy was planned, had normal pulp, dentin and periodontal tissues, including the periapical tissues. Informed consent for the pulpectomy and prosthesis was obtained.

After disinfection with povidone iodine (Meiji Seika Pharma CO., Ltd.), Xylocaine® (DENTSPLY‐Sankin Co, Ltd.) local anesthetic was administered in the left mandibular region. The left mandibular second molar was isolated with a rubber dam. After access cavity preparation, three main root canal orifices (MB canal, ML canal, and distal canal) were found under the operating microscope (ManiScope Z®, Mani). A protuberance from the mesial axial wall, which impaired direct access to the developmental groove between MB and ML root canal orifices, was removed using a long‐shank round bur (#2 Stainless Bur Hard®, Mani). After its removal, stickiness was encountered, while exploring the fissure with a sharp endodontic explorer (DG 16®, Hu‐Friedy). This was followed by the appearance of a bleeding point between the MB and ML canal orifices. The bleeding point, which could be negotiated with a size 8/10 K‐file (Mani), was found to be a root canal orifice of a MM canal. The four root canal orifices were shaped with Gates Glidden drills (#1 and #2, Mani). The working length was determined with a size 15 K‐file (Mani) by using the electric apex locator (Root ZX®; J Morita). The working length for the MB, ML, and distal canals was determined to be 16 mm. The working length for the MM canal was determined to be 15 mm. Apical preparations in the three mesial canals and the distal canal were enlarged using K‐files (Mani) to size 35 and 45, respectively. Figure 2A shows the chamber floor after the root canal enlargement. The chamber floor had three root canal orifices in the mesial and one in the distal root. The root canals were irrigated with 10% sodium hypochlorite (Neo Cleaner®, Neo Dental) and ethylenediaminetetraacetic acid (EDTA) (Smear Clean®, Nippon Shika Yakuhin KK), while calcium hydroxide (Calcipex II®, Nippon Shika Yakuhin KK) was employed as an intracanal medication. The access cavity was then temporarily double sealed with temporary stopping (Temporasy stopping®, GC Dental Industrial Corp.) and glass ionomer cement (Base cement®, Shofu Inc). The patient was recalled after one week, and the tooth was found to be asymptomatic. Multi‐slice CBCT scans of the left mandibular second molar were performed in order to confirm the anatomical structure of the mesial root. The four root canals were irrigated with sodium hypochlorite and EDTA to remove any remaining calcium hydroxide, and sterile paper points (Dentsplay) were placed. The cavity was then double sealed with temporary stopping and glass ionomer cement. The morphology of the second molar was obtained in coronal, axial, and sagittal sections using the CBCT images (3DX Multi‐Image Micro CT FPD8, J Morita). The CBCT images demonstrated that the left mandibular second molar had two roots (Figure 2B‐D), but not the C‐shaped root. The coronal and axial images revealed that the mesial root had three root canals (Figure 2C,D). On sagittal view, it seemed each mesial canal had been shaped to appropriate working length around each apex (Figure 2B). The three prepared canals in the mesial root in fact each originated from a separate root canal orifice, but the MB and MM canals joined apically (Figure 2C,D). This morphology of the MB, MM, and ML canals was thus termed “confluent” according to Pomeranz's classification.16 Since the tooth was asymptomatic, the root canals were filled with gutta‐perche (GC, GC Dental Industrial Corp.) and sealers (NISHIKA CANAL SEALER BG®, nishika nippon shika yakuhin Co., Ltd.) using the lateral condensation technique (Figure 3A).

Figure 2

Location of root canal orifices and CBCT images after the root canal preparation. (A) Location of root canal orifices. Mesiobuccal canal; MBC, middle mesial canal; MMC, mesiolingual canal; MLC, distal canal; DC. (B, C, and D) A series of CBCT; Sagittal slices (B), coronal slice (C), and axial slices (D) clearly show MBC, MMC, and MLC. MMC joined MBC at an apical side (black arrow). Buccal; Bu, Lingual; Li

Figure 3

The root canal filling and one‐year follow‐up. A, Dental radiograph after the root canal filling. B, Intraoral photograph at the 1‐year follow‐up. A dental bridge was set on the tooth (maxillary bridge; the 5‐unit bridge at the abutment of tooth 24, 25, and 28. Mandibular bridge; the 5‐unit bridge at the abutment of tooth 33, 35, and 37). Clinically, the left mandibular second molar was asymptomatic and no periodontal pocket was found. C, A dental radiograph was taken at the 1‐y follow‐up. Unusual views were not seen

The one‐year follow‐up demonstrated that the left mandibular second molar with dental bridge was asymptomatic with no pain, swelling, or tooth mobility, and a less than 3 mm probing depth (Figure 3B). The radiograph showed no pathological changes in the tooth and its surrounding tissues (Figure 3C).

DISCUSSION

Many previous in vitro and in vivo studies using CT, CBCT, micro CT, or operating microscopes have reported that the incidence of a mandibular second molar with a MM canal ranges from 0% to 12.8%.3, 5, 7, 8, 10, 11, 12, 16, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48 Asian ethnic groups showed a higher prevalence of the Vertucci type I configuration, whereas Caucasian groups demonstrated Vertucci root canal configuration variability.5 Nosrat et al9 found significant differences in the incidence of a MM canal between Caucasian and non‐Caucasian groups. Our PubMed literature search did not reveal any clinical case reports or original research articles showing a MM root canal in an Asian mandibular second molar.3, 5, 7, 11, 42 Hence, a MM canal in the mandibular second molar is a rare phenomenon in Asian populations such as Japanese, Korean, and Chinese. To the best of our knowledge, this case report is the first to demonstrate a mesial root canal in a Japanese mandibular second molar.

MM canals have been described as having a small orifice deep within the isthmus or a developmental groove between the two orifices of the MB and ML canals.52 Age is associated with the presence of MM canals and small accessory canals.8, 12 Peiris et al8 confirmed that canal development is completed at around 30‐40 years of age in molars. Azim et al51 correlated the occurrence of MM canals with age and concluded that younger patients, aged 30‐40 years, had a significantly higher incidence of a MM canal. Nosrat et al9 reported that the incidence of MM canals was 32.1% in patients <20 years old, 23.8% in patients 21‐40 years old, and 3.8% in patients older than 40. The significantly higher incidence of a MM canal in younger patients is explained by the calcification process of the pulp, which undergoes a reduction in size due to the continuous deposition of dentin with age. Thus, a MM canal in a 44‐year‐old patient is less likely than in a younger patient.

The recent technical studies suggest that the detection and the negotiation of MM canal were increased to 22%‐77.41%49, 50, 51, 52 by using specialized instruments under the operating microscope. Their management has been minimally invasive. Especially, troughing technique may enhance the chances of locating MM canal.51 And then, troughing preparation is safe and effective for the negotiation of MM canals.49, 50, 51 In brief, troughing technique requires minimal dentin removal between the MB and ML canals in a mesio‐apical direction away from the furcal danger zone. Troughing at that level requires clear visibility, specialized instruments of small size munce discovery burs, and caution to avoid strip perforation and its subsequent using ultrasound tips or long‐shank round burs under the operating microscope. Therefore, because of the thin dentine related to the distal aspect of the MM canal and the position of the orifice, the integrity of root structure at the coronal level might be jeopardized by deep troughing if large instruments are used. Hence, further apical extension of troughing preparation might jeopardize the dentin thickness around the danger zone and possibly lead to root perforations. Several authors have suggested that a troughing preparation with a depth ranging between 0.7 and 2.0 mm is adequate.49, 50, 51

In conclusion, the diagnosis and management of MM canal are important, and the management should have been minimally invasive. We successfully carried out root canal treatment on an Asian mandibular second molar with a rare MM canal using troughing preparation. In addition, CBCT images revealed the “confluent” morphology of the three root canals in the mesial root.16

CONFLICT OF INTEREST

None declared for all authors.

AUTHOR CONTRIBUTION

TN, KT, KW, SS, TI, HK, and HS: drafted the manuscript and contributed to treatment of the patient. All authors have read and approved the final manuscript.