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Prevention of Lingual Nerve Injury in Third Molar Surgery: Literature Review
Accepted Manuscript Prevention of lingual nerve injury in third molar surgery: literature review Roberto Pippi, MD, DDS, Associate Professor, Andrea Spota, MD, DDS, Researcher, Marcello Santoro, DDS, PhD student PII:
S0278-2391(16)31328-3
DOI:
10.1016/j.joms.2016.12.040
Reference:
YJOMS 57602
To appear in:
Journal of Oral and Maxillofacial Surgery
Received Date: 7 August 2016 Revised Date:
23 November 2016
Accepted Date: 24 December 2016
Please cite this article as: Pippi R, Spota A, Santoro M, Prevention of lingual nerve injury in third molar surgery: literature review, Journal of Oral and Maxillofacial Surgery (2017), doi: 10.1016/ j.joms.2016.12.040. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT REVISED TITLE PAGE Prevention of lingual nerve injury in third molar surgery: literature review Authors: Roberto Pippi, MD, DDS, Associate Professor, Department of Odontostomatological and Maxillo Facial Sciences, “Sapienza” University of Rome.
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Andrea Spota, MD, DDS, Researcher, Department of Odontostomatological and Maxillo Facial Sciences, “Sapienza” University of Rome.
Marcello Santoro, DDS, PhD student, Department of Odontostomatological and Maxillo Facial
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Sciences, “Sapienza” University of Rome.
Corresponding author:
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Marcello Santoro, DDS, PhD student, Department of Odontostomatological and Maxillo Facial
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Sciences, Via Caserta 6, 00161 Rome, +393334025038, [email protected].
ACCEPTED MANUSCRIPT Prevention of lingual nerve injury in third molar surgery: literature review Abstract Purpose. To identify any factors which may aid the surgeon in preventing or minimizing the risk of lingual nerve injury during third molar surgery.
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Methods. Electronic research was carried out on the correlation between lingual nerve damage and lower third molar surgery (topographic anatomy, surgical technique, and regional anesthesia) using PubMed, Scopus and Cochrane central databases. The research only included articles published in English up to February 2016.
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Results. Lingual nerve anatomy varied greatly: direct contact between the lingual nerve and the third molar alveolar wall was reported in a wide range of cases (0-62%) and the nerve was located at the same level or above the top of the ridge in 0-17.6% of cases. No detailed data was found on the actual incidence of lingual nerve injury resulting from local anesthesia by injection. Permanent lingual nerve damage did not show statistically significant differences between the simple buccal approach and the buccal approach + lingual flap retraction, although the latter was significantly associated with an increased risk of temporary damage. As far as permanent damage was concerned, no statistically significant differences were found between the lingual split technique and the buccal approach with or without lingual flap retraction. As opposed to tooth sectioning, ostectomy was strongly statistically associated with permanent lingual nerve damage.
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Conclusions. Results should be interpreted with extreme caution due to the considerable heterogeneity of the data as well as the considerable influence of several anatomical and surgical variables, all closely related, but which are difficult to analyze independently. It seems preferable to avoid lingual flap elevation, except in selected cases in which the presence of more than one unfavourable surgical variable predict a high risk of nerve injury. Tooth sectioning may reduce the extent of ostectomy or even, in some cases, prevent it, potentially acting as a protective factor in lingual nerve injury.
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Introduction Lingual nerve injury in oral-maxillofacial surgery is rather uncommon, but it is a highly disabling complication with a high risk of medico-legal consequences.1-4 Lower third molar extraction is one of the most common procedures in oral surgery and is undoubtedly the most frequent cause of lingual nerve damage. Several etiological factors, either anatomical or surgical, have been addressed; however, nerve damage is often unexpected by the surgeon.5-7 The effect of certain surgical procedures on lingual nerve injury is also still unclear. The wide use of surgical instruments for lingual nerve protection during lower third molar extraction is still debated. There are no studies in the literature which unequivocally prove that lingual flap retraction can cause more harm than benefit.8-14 The aim of the present study was to identify any factors which may help the surgeon prevent or minimize the risk of nerve injury in lower third molar surgery.
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Materials and methods Electronic research was performed using PubMed, Scopus and Cochrane central databases, including only articles published in English up to February 2016. The following keywords were used as search criteria: lingual nerve injury, lingual nerve and anatomy, lingual nerve and prevention, lingual nerve and third molar or wisdom tooth, lingual nerve and lingual flap, lingual nerve and lingual split, lingual nerve and mandibular block, lingual nerve and paraesthesia, and lingual nerve and anaesthetics. The research was carried out individually by all authors. The abstract of each article was viewed and the full text was downloaded if it was considered relevant to the following selection criteria of the study: for the anatomy section - articles which reported data about topographical relationships between the lingual nerve and the neighboring anatomical structures; for the section related to local anesthesia - articles which reported data on the incidence, mechanisms and preventive standards of nerve damage; for the surgical section - articles which reported clear and complete information regarding the technique used, the number of procedures, the number of extracted third molars and relative incidence of temporary and permanent nerve damage with at least 6 months of follow-up. Studies in which data of interest were indirectly obtainable by extrapolating them from other findings were also selected. Cross-checking was also carried out using the references of all collected articles and the missing studies that met the above-listed selection criteria were added. No exclusion criterion was adopted in relation to the study type. No attempt was made to identify unpublished material or to contact the authors of published studies to obtain more information or to go back to the missing data. Due to the limited number of studies, as well as the considerable differences in their study design, it was not possible to apply any statistical method to determine the risk of bias and the degree of inconsistency (heterogeneity). The statistical association between nerve damage and the surgical technique used was tested by the Pearson's chi-square test (Chi2). A first statistical analysis was performed with specific focus on the surgical technique (lingual flap, buccal approach, buccal approach + lingual flap retraction), by combining only data of "similar studies" for the analyzed primary variable, such as studies in which it was possible to identify differences between two adopted techniques in terms of nerve injury: temporary lingual nerve injury in the buccal approach + lingual flap retraction vs buccal approach alone, permanent lingual nerve injury in buccal approach + lingual flap retraction vs buccal approach alone, temporary 2
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lingual nerve injury in the lingual split technique vs buccal approach + lingual flap retraction, and permanent lingual nerve injury in lingual split technique vs buccal approach + lingual flap retraction. Subsequently, the results of all selected studies were resumed for the analyzed interest variable in a "mixed group" of studies in which it was possible to go back to the result of a single surgical technique (buccal approach, lingual split technique, buccal approach + lingual flap retraction) in terms of nerve injury in order to assess the possible discrepancy with the analysis conducted only among similar studies as well as to identify differences between surgical approaches which were not directly compared in the literature (temporary and permanent lingual nerve injuries in lingual split technique vs buccal approach). Since it was not possible to assess the heterogeneity of studies in the mixed group due to the incompleteness of their data in relation to interest variables, the Chi2 test was performed. In the present analysis studies in which it was not possible to clearly distinguish the number of cases related to each of the three analyzed surgical techniques were not considered. To evaluate the association between nerve damage and tooth sectioning or ostectomy, only articles which reported clear information on the number of cases in which these techniques were performed and the relative incidence of nerve damage were taken into account. All articles in which these data were missing or could not be deduced were excluded. Even in this case it was not possible to apply any statistical method to determine both the risk of bias and the degree of inconsistency (heterogeneity).
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Results Lingual nerve in the lower third molar region Out of the 228 articles analyzed, 9 were selected for this topic with a total number of 964 cases (Table 1).15-23 The average horizontal distance between the lingual nerve and the third molar lingual alveolar wall was about 3.05 mm (SE = 0.48; range: 0.57-9.3). The average vertical distance between the lingual nerve and the top of the alveolar ridge was 7.24 mm (SE = 0.95; range: 2.2816.8). Direct contact between the lingual nerve and the alveolar wall was reported in a wide range of cases (0-62%). The nerve was located at the same level or above the top of the ridge in 0-17.6% of cases. Lingual nerve minimum and maximum diameters in the third molar region were 1.86 and 3.45 mm, respectively. Lingual nerve injury and regional anesthesia No detailed data was identified for the actual incidence of lingual nerve injury resulting from local anesthesia by injection.24-39 Lingual nerve injury and surgical technique Out of the 1,028 analyzed articles, 28 were selected to evaluate the influence of surgical techniques on lingual nerve damage (Table 2).40-67 When combining the results of similar articles51,54,56,58,62,63,66,67 for the variable “temporary lingual nerve injury in the buccal approach + lingual flap retraction vs buccal approach”, for a total of 4,830 cases, buccal approach + lingual flap retraction were more significantly associated (p<0.01; RR:12.22; 1.71-15.07, CI 95%) to lingual nerve injury than to the buccal approach.
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The same result was obtained by combining data from the mixed group44-49,51,52,54-67 for the “temporary lingual nerve injury in the buccal approach + lingual flap retraction vs buccal approach” variable for a total of 27,785 cases (p<0.01; RR:2.38; 2.60-22.97, CI 95%). As far as “permanent lingual nerve injury” was concerned no statistically significant differences (p=0.0743, 0.74-6.62, CI 95%) were found between the two techniques in the group of similar articles,51,54,56,58,62,63,66,67 and the analysis of the mixed group44-49,51,52,54-67 of studies seems to further confirm this finding (p=0.9808; 1.08-26.26, CI 95%). As for the “temporary lingual nerve injury in the lingual split technique vs buccal approach + lingual flap retraction” variable, in the group of similar studies (1,83046,48 cases) the lingual split technique was more significantly associated (p<0.01; RR:2.7; 0.26-0.47 CI 95%) to lingual nerve injury than to the buccal approach + lingual flap retraction technique, whereas in 9,49440-43,46,4851,54,56,58,62,63,66,67 cases of the mixed group, the association was significantly lower (p<0.01; RR:0.67; 0.48-4.11, CI 95%). As for permanent damage, the group of similar studies46,48 for “lingual nerve damage in the lingual split technique vs the buccal approach + lingual flap retraction” variable showed no statistically significant difference between the two techniques (p=0.2259; 0.73-6.59, CI 95%), as opposed to the mixed study group40-43,46,48-51,54,56,58,62,63,66,67 which showed a higher risk of permanent damage for the lingual split technique (p=0.0116; RR: 0.23; 0.13-6.11, CI 95%). When comparing the lingual split technique vs the buccal approach, no similar study group was found and the mixed study group40-48,50-67 (32,471 cases) showed a significantly higher risk of temporary and permanent lingual nerve damage for the lingual split technique (p<0.01; RR: 1.58; 10.06-42.59, CI 95%), whereas a greater risk of permanent lingual nerve damage was observed in the buccal approach (p<0.01; RR: 0.22; 4.43-64.65, CI 95%). In only 4 articles58,62,66,68 (6,064 cases, Table 3), information regarding the number of cases in which tooth sectioning was or was not performed and the relative incidence of nerve damage were clearly set out or they could be indirectly identified. Tooth sectioning was not statistically associated with permanent lingual nerve damage (p=0.523; 0.52-4.95, CI 95%). In only 4 articles46,58,66,68 (7,021 cases, Table 4), information regarding the number of cases in which ostectomy was or was not performed and the relative incidence of nerve damage were clearly set out or they could be indirectly identified. Ostectomy was strongly statistically associated with permanent lingual nerve damage (p<0.01; RR=6,92; 0.90-9.36, CI 95%).
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Discussion Lingual nerve in the lower third molar region Thorough knowledge of the lingual nerve anatomy and topography is crucial in order to avoid iatrogenic nerve damage or at least to reduce the risk of nerve injury. Actually, lingual nerve spatial localization ranges widely from individual to individual as well as in the same individual.15-23, 69-71 Although several studies15-23 have attempted to define topographical relationships between the lingual nerve and lower third molar in both the horizontal and vertical planes (Table 1), comparison among studies was quite difficult since the reference points used for measurements were different. In addition, most studies often neglected important parameters, and thus provided inaccurate information regarding race, age, gender, edentulism type and degree of bone atrophy of sample subjects. In addition, most investigations were based on studies performed on cadavers, for which relatively inaccurate information was often provided as far as time and method of preservation of anatomical preparations were concerned. Moreover, study sample dimensions were often too inadequate to obtain significant results. For example, discrepancies found in space measurements in the Mendes at al.22 and Bhenia et al.18 studies are not only related to the different landmarks used and the number of analyzed anatomical preparations, but to the storage time as well. Actually, although stored in the same way, Bhenia et al.18 refer to an extremely larger number of anatomical preparations analyzed within a maximum of about 24 hours of death, thus ensuring lower dimensional tissue alterations compared to the study of Mendes et al.22 in which the preparation times varied from 2 to 5 years. Kiesselbach and Chamberlain15 and Progel et al.16 results also came from rather small samples and might be susceptible to errors due to the possible lingual nerve dislocation from its actual position during fixation and preparation of anatomical specimens.18 Actually, although anatomical dissection is rather easy to perform, it is well known to differently alter the lingual nerve spatial position even more when not properly executed.69 Therefore, different methods have been proposed to evaluate lingual nerve running, such as MRI,17 ultrasounds,72 or radiographic imaging with radiopaque landmarks placed inside or alongside the lingual nerve.20,69,73 Although these indirect methods were intended to overcome possible spatial lingual nerve alterations due to the dissection, they were not able to accurately identify and measure anatomical relationships between the lingual nerve and neighboring structures.69 Other factors which make it even more difficult to interpret the results of different studies involve the high variability of lingual nerve position in relation both to the alveolar process morphology and to the existing space between the third molar and the ascending mandibular branch. Actually, the lingual nerve position may be influenced by both alveolar process prominence and a marked inclination of its lingual surface in the lower third molar region. A small distance between the lower third molar and the mandibular ascending branch may also justify a more cranial lingual nerve position.23,70 Although the influence of the degree of mandibular atrophy on lingual nerve topographical relationships has often been overlooked by most studies, some authors16,19 have suggested that the loss of both muscle tone and connective tissue tension, secondary to aging, may partially compensate the lingual nerve superficial position due to bone atrophy resulting from tooth loss through an easier nerve deepening within mouth floor, which possibly leaves nerve spatial relationships with mandibular alveolar ridge unchanged. 5
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In this regard, a recent study23 stressed the strong discrepancy in lingual nerve location in relation to edentulism type, alerting the possible greater lingual nerve proximity to the mandibular alveolar crest in edentulous subjects. A marked bone loss may therefore be an important risk factor for lingual nerve injury during routine oral surgery involving lingual access flap management in the posterior region of the mandible.19 Actually, almost all anatomical studies highlight the risk of the lingual nerve being close to the lingual surface of the alveolar process (0-62%) or to an even higher level than the mandibular bone crest (0-17.6%), almost directly laying on the retromolar region (Table 1).15-23 All these findings are considerably important in the prevention of lingual nerve damage during most routine oral surgeries. Therefore, in lower third molar extraction, the distal release incision should not be directed towards the lingual aspect of the ascending branch of the mandible, but instead should be inclined vestibularly 45° in respect to the lower third molar distal surface.12,14,19,52,74 Lingual nerve injury and regional anesthesia The lingual nerve is also susceptible to injury through common local anesthetic injection procedures although the true incidence of this event and the actual causative mechanisms are still being debated. Damage to the lingual nerve may be directly caused by the syringe needle24-26 during needle penetration as the nerve cannot be easily moved away during needle advancement since it is stabilized within the inter-pterygoid fascia when the mouth is fully open. Alternatively, the nerve can be directly damaged by the needle during its retraction from the tissues24,27 especially when common chamfered needles are used since their tips are easily susceptible to distortion and irregular curvatures, particularly as a result of bone contact or in the case of multiple injections which can break the perineurium and induce both endoneurium herniation and interruption of multiple nerve fibers or entire fascicles.27-29 However, since the lingual nerve average diameter is 1.86 mm and the diameter of the most commonly used needle in dental practice (25-gauge) is about 0.45 mm, it seems impossible that this type of trauma can be capable of breaking the nerve bundle, thus resulting in neurotmesis.24-27, 29,30 Furthermore, needle penetration can be responsible for direct trauma to the intraneural vessels with formation of an intraneural hematoma able to exert a certain degree of compression to the nerve fibers, leading to a focal block of nerve transmission without any interruption of both the axonal and perineural connective continuity. The return to normality may take several weeks as the progressive reduction of hematoma pressure allows nerve remyelination.24-27,29,30 It has also been suggested that local anesthetics are able to cause a localized chemical injury to the nerve if deposited in the intra-fascicular space or inside the nerve during needle retraction.24,26 Chemical trauma may be responsible for demyelination, axonal degeneration, inflammation and edema of the endoneural fibers.31 The more easily the ester or amide group hydrolysis occurs, the greater the amount of bioavailable alcohol group is; therefore, the stronger the anesthetic power is, the greater the possibility of nerve cell damage. In this regard, articaine and prilocaine have shown a greater cytotoxic power than lidocaine.24,26,29,32 High doses of these anesthetics are therefore not recommended due to easy production of neurotoxic metabolites. High concentrations of lidocaine also showed neuropathic effects after perineural or intrafascicular injections.24,26,29,32-34
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It is not possible to provide accurate information about the true incidence of lingual nerve injury during local anesthesia since it is often difficult to extrapolate it from that of the inferior alveolar nerve, and since it is often not clearly specified whether local anesthesia is followed by non-surgical procedures to exclude other possible causes of lingual nerve damage. Sambrook and Goss35 estimated a 1:27.415 risk of lingual nerve and inferior alveolar nerve damage during truncal mandibular anesthesia. Similarly, Pogrel and Thamby24 reported a nerve damage incidence which ranged from 1:160.571 to 1:26.762, claiming that during the professional life of each practitioner it is very likely to have at least one patient with nerve trauma due to local anesthesia. Harm and Durham25 reported approximately a 3.62% chance of lingual nerve trauma whenever mandibular nerve block anesthesia is performed while Krafft and Hickel36 found a 0.15% incidence of lingual nerve injury (18/12,104) during nerve block anesthesia not performed for surgery. Moreover, nerve damage due to local anesthesia more frequently affected the lingual nerve (more than 2/3 of cases) rather than the inferior alveolar nerve.24,34,37 Actually, although the diameter of the two nerves was found to be approximately the same at the injection site, the lingual nerve seems to be more exposed to needle trauma and also possesses less nerve fascicles compared to the inferior alveolar nerve.38 Pogrel al.38 showed that in approximately 33% of cases the lingual nerve is formed by only a single fascicle at the injection point, as opposed to 7-39 fascicles in the lower third molar area. This might explain why nerve alterations resulting from local anesthesia most frequently involve the entire lingual nerve distribution area.24,36,38 Furthermore, dysesthesia, which is the most disabling sensorial alteration, oddly occurs more frequently after nerve injury resulting from local anesthesia procedures (34%) rather than after surgical procedures (8%).24 Therefore, patients not only face an increased risk of being in greater discomfort, but they almost always are also poorly-informed about the possible risk of lingual nerve damage during local anesthesia compared to that related to surgery.24 Although sensory alteration recovery occurs within 8 weeks in 85-94% of cases,24,36 preventive measures for lingual nerve injury should be applied as soon as at the time of local anesthesia, a procedure which is often underestimated by dentists and surgeons. Due to the considerable variability of lingual nerve size and anatomical position, little can be done to predict and prevent its injury at this stage.39 However, it seems preferable to use a small-diameter needle while high concentrations of local anesthetics and multiple injections should be avoided.32,34,37,40 In particular, 4% prilocaine and 4% articaine appear to be associated to a 7.3 and 3.6 times greater probability, respectively, of causing paresthesia during inferior alveolar nerve block anesthesia than expected on the basis of the total local anesthetic use by U.S. dentists.72 Moreover, these substances, compared to other common local anesthetics, may more easily result in neuropathic pain although the true incidence of these phenomena still remains unclear.23,24,75 Lingual flap and nerve protection in third molar surgery Routine use of a surgical instrument for lingual nerve protection during lower third molar extraction is still debated. Actually, although the use of a lingual flap retractor can apparently provide greater operating safety, it is considered a possible etiologic factor of lingual nerve injury.13,14,46,49,51,52,54 However, there are no studies in the literature which unquestionably prove that lingual flap retraction may more easily lead to damage rather than benefit. In most studies, the different levels of experience of surgeons was not taken into account, the surgical technique was not standardized, and the information describing the surgical steps and variables (tooth eruption degree, inclusion 7
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depth, patient age, type and drug for anesthesia, surgical flap, type of retractor, type of ostectomy and tooth section, etc.) was not provided in a clear and comprehensive way. In addition, most studies were small-sized and observational so they were subjected to the lower statistical power of this study type (Table 2).40-67 Lingual nerve protection undoubtedly requires a great deal of caution. Although different types of lingual retractors have been proposed, including those of Howarth, Ward, Meade, Hovell, Walters and Rowe, there is no scientific evidence supporting the superiority of one over other instruments, the choice of which seems strongly influenced by surgeon’s personal experience.8,11,13,14,50,76 However, a large and smooth rather than narrow and pointed active retractor surface has been suggested to be less traumatic on the lingual nerve during flap retraction.8 Some authors assert that the lingual flap detachment for retractor placement, although associated with a high possibility of temporary nerve damage, may reduce the incidence of permanent nerve injury through improved access to and better visibility of the surgical area, thus ensuring safer use of both manual and rotating instruments.8,12-14 On the contrary, the results of the present analysis seem to confirm the conclusions reached by Pichler al.7, that is, although lingual retraction may be associated with a higher incidence of temporary nerve damage, it neither protects nor harms the lingual nerve permanently. Actually, the present review does not show any statistically significant difference in permanent lingual nerve damage between simple buccal approach and the combined approach (buccal approach + lingual flap retraction; p=0.98), although the latter is significantly associated with an increased risk of temporary damage (p<0.01). However, the lingual split technique seems to be statistically associated with an increased risk of temporary (p<0.01) nerve damage compared to the buccal approach with or without lingual flap retraction (p<0.01), whereas no statistically significant difference was found between the lingual split technique and the buccal approach + lingual flap retraction in permanent lingual nerve damage. However, these results and more so those derived from the “mixed groups”, should be interpreted with extreme caution due to the considerable heterogeneity of data from which they arise as well as to the presence of many confounding factors. Avoiding lingual flap detachment as much as possible in order to reduce the incidence of lingual nerve damage is therefore highly recommended. Actually, lingual nerve protection through the lingual flap should be restricted to selected cases in which the presence of more unfavorable surgical variables predict a high risk of nerve injury.9,10,13,14,46,49,51,52,54,77 Tooth sectioning and ostectomy in lower third molar surgery Although tooth sectioning is one of the possible risk factors for lingual nerve injury during lower third molar surgery,9,54,78-80 the present review did not find any statistically significant differences between the incidence of lingual nerve damage in surgeries in which tooth sectioning was performed and that of surgeries in which it was not. However, the present results (Table 3) refer to an extremely limited sample (6,064 lower third molars) since most of the studies analyzed did not clearly specify the number of cases in which tooth sectioning was actually performed or they omitted information on nerve damage incidence in cases in which tooth sectioning was performed or not. Furthermore, it is almost always impossible to correlate cases in which tooth sectioning was performed and in which lingual nerve damage occurred with lower third molar position or number and type of sections. The lack of statistically significant differences can also be related to confounding factors such as the surgeon’s skills and experience and therefore variables related to the surgical technique (anesthesia, 8
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flap design, need for ostectomy and its characteristics, suturing etc.), lingual nerve and lower third molar local anatomical variability, possible local pathological processes such as inflammatory adhesions as a result of recurrent pericoronitis affecting one or more surgical steps. During tooth sectioning, the lingual nerve may be involved by the bur. In the case of lower third molar bone impaction, predisposing conditions are both pre-existing bone fenestrations and iatrogenic intra-operative perforation of the alveolar wall at the level the lingual nerve running. For this reason, it would be a good rule to perform a subtotal lower third molar section and then complete the separation of fragments by using an elevator or another hand instrument.52 However, tooth sectioning may reduce the extent of ostectomy, or even help avoid it altogether in some cases, thus making it a possible protective factor for lingual nerve injury.9,52,62 Actually, in the present study removal of periradicular bone tissue, especially at the lingual and/or disto-lingual sites, was found to be strongly correlated to lingual nerve damage (p<0.0, Table 4). However, this finding also arises from a rather limited number of cases (7,021) since in most studies clear and comprehensive information regarding the number of cases in which ostectomy was actually performed, and/or the incidence of nerve damage in cases in which it was performed or not, is missing. Several authors claim that ostectomy should be carried out only when a total view of the periradicular bone surface is possible. Therefore, ostectomy should not be blindly performed, especially at the lower third molar distal and disto-lingual sites.81-83 If preoperative planning indicates the need to remove lower third molar distal or disto-lingual bone, a limited retraction of the lingual tissue may be appropriate both to improve surgical field visibility and to allow lingual nerve protection during bur use.74 Suture There is no data on the true incidence of lingual nerve damage caused by suture at the lower third molar fresh extraction site. Only a few studies cite suture as a possible risk factor for lingual nerve injury through a direct trauma of the needle or through "throttling" during knot closure.12,14,74 It is therefore recommended to avoid inserting the needle too apically in relation to the incision line. Chossegros et al.12 considered safe-inserting the needle at about 3 mm from the gingival margin of the lingual flap. Anatomical considerations in preventing lingual nerve injuries in other oral surgical procedures Even during implant or periodontal surgery in the posterior lingual mandibular region, it is preferable to perform intra-sulcular incisions, avoiding vertical relaxation incisions, especially in the molar region, and full-thickness flaps, avoiding any tearing or damage that may indirectly injure the lingual nerve.69 Moreover, the possibility of a relatively shallow position of the lingual nerve, even anteriorly to the lower third molar, should be always considered especially in cases of marked alveolar ridge atrophy.19 A study on cadavers (30 analyzed nerves) by Chan et al.69 analyzed the topographic lingual nerve anatomy in relation to the teeth mesial to the lower third molar region. Actually, these authors identified the lingual nerve on the vertical plane at about 9.6 mm, on average, below the meanlingual portion of the second molar cemento-enamel junction, until reaching an average of about 13 mm at the first molar level, and 15 mm in the second premolar area, without reporting any statistically significant differences between the left and right side of the jaw. The same authors53 also found that the first molar region was that in which the lingual nerve most frequently curved in a medial direction towards the tongue (41.60-58.33% of cases; 24 analyzed nerves, 12 per side), followed by the second molar (16.67-33.33% of cases) and finally, by the second premolar regions 9
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(16.67-25% of cases). On the contrary, this finding was quite rare in the first premolar area (8.33%; 1/12 analyzed nerves, on the left side).69 Few studies, on the other hand, have assessed an intra-lingual distribution of the lingual nerve.84-86 Their results indicated that a wide median longitudinal portion of the dorsum of the tongue was poorly innervated by lingual nerve and that, therefore, its branches could be easily avoided such as during the excision of median pathological lesions or during the removal of tissue at the lateral margins of the tongue up to about 1 cm from the latter. Actually, lingual nerve terminal branches, which run on genioglossus muscle, can be excluded from iatrogenic injury if incisions involve the lateral margins of the tongue and tissues connected to the genioglossus muscle are carefully dissected.84-86 The anatomical relationship between the lingual nerve and the submandibular gland duct (Wharton duct) is also quite variable. Mendes et al.22 (24 analyzed nerves) reported that the glandular duct crossed the lingual nerve superiorly in 62.5% of cases, whereas it ran beneath the nerve in 37.5% of cases. Similarly, in a topographical study on atrophic mandibles, Holzle et al.19 reported 4/34 cases (11.7%) in which Wharton duct ran deeper than the lingual nerve. On the contrary, Erdogmus et al.21 asserted that the lingual nerve maintained the same spatial relationship beneath the submandibular duct in all 42 cases. Knowledge of such anatomical variables may therefore be fundamental in preventing lingual nerve injury through a careful blunt dissection of tissues during surgical procedures involving both the floor of the mouth and the tongue. Conclusion
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The present review does not show any statistically significant differences in permanent lingual nerve damage between simple the buccal approach and the buccal approach combined with lingual retraction in lower third molar surgery, although buccal approach + lingual flap retraction is significantly associated with an increased risk of temporary nerve damage. The lingual split technique is statistically associated with an increased risk of temporary nerve damage compared both to the buccal approach + lingual flap retraction and to the simple buccal approach, while it does not show any differences in permanent lingual nerve damage compared to buccal approach + lingual flap retraction. It seems therefore preferable to avoid lingual flap elevation, except in selected cases in which the presence of more unfavourable surgical variables predict a high risk of nerve injury. There seems to be no statistically significant difference between the incidence of lingual nerve damage in surgeries in which tooth sectioning was performed and those in which it was not. Tooth sectioning may reduce the extent of ostectomy or even, in some cases, avoid it altogether, thus potentially acting as a protective factor in lingual nerve injury. Actually, removal of peri-radicular bone tissue, especially at the lingual and/or disto-lingual sites, is strongly associated with lingual nerve damage. However, these results should be interpreted with extreme caution due to the considerable heterogeneity of the data as well as the substantial influence of several anatomical and surgical variables, all closely related to possible nerve damage, but which are difficult to analyze independently. Moreover, most studies are observational and include a very limited significant sample population compared to the rareness of lingual nerve damage, so long-term randomized large-scale prospective studies are necessary to identify risk factors for lingual nerve injury. 10
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1. Hillerup S, Stoltze K. Lingual nerve injury in third molar surgery I. Observations on recovery of sensation with spontaneous healing. Int J Oral Maxillofac Surg 2007; 36: 884889. 2. Fielding AF, Rachiele DP, Frazier G. Lingual nerve paresthesia following third molar surgery: a retrospective clinical study. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 1997; 84: 345-348. 3. Cheung LK, Leung YY, Chow LK, Wong MC, Chan EK, Fok YH. Incidence of neurosensory deficits and recovery after lower third molar surgery: a prospective clinical study of 4338 cases. Int J Oral Maxillofac Surg 2010; 39: 320-326. 4. Lydiatt DD. Litigation and the lingual nerve. J Oral Maxillofac Surg 2003; 61(2):197-200; discussion 200. 5. Robert RC, Bacchetti P, Pogrel MA. Frequency of trigeminal nerve injuries following third molar removal. J Oral Maxillofac Surg 2005; 63: 732-735. 6. Pogrel MA, Hung L. Etiology of lingual nerve injury in the third molar region: a cadaver and histologic study. J Oral Maxillofac Surg 2006; 64: 1790-1799. 7. Pichler JW, Beirne OR. Lingual flap retraction and prevention of lingual nerve damage associated with third molar surgery: a systematic review of the literature. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2001; 91(4): 395-401. 8. Greenwood M, Langton SG, Rood JP. A comparison of broad and narrow retractors for lingual nerve protection during lower third molar surgery. Br J Oral Maxillofac Surg 1994; 32: 114-117. 9. Valmaseda-Castellón E, Berini-Aytés L, Gay-Escoda C. Lingual nerve damage after third lower molar surgical extraction. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2000; 90: 567-573. 10. Céspedes-Sánchez JM, Ayuso-Montero R, Marí-Roig A, Arranz-Obispo C, López-López J. The importance of a good evaluation in order to prevent oral nerve injuries: a review. Acta Odontol Scand 2014; 72(3): 161-167. 11. Moss C, Wake M. Lingual access for third molar surgery: a 20-year retrospective audit. Br J Oral MaxillofacSurg 1999; 37: 255-258. 12. Chossegros C, Guyot L, Cheynet F, Belloni D, Blanc JL. Is lingual nerve protection necessary for lower third molar germectomy? A prospective study of 300 procedures. Int J Oral Maxillofac Surg 2002; 31: 620-624. 13. To EW, Chan FF. Lingual nerve retractor. Br J Oral Maxillofac Surg 1994: 32: 125-126. 14. Pogrel MA, Goldman KE. Lingual flap retraction for third molar removal. J Oral Maxillofac Surg 2004; 62(9): 1125-1130. 15. Kiesselbach JE, Chamberlain JG. Clinical and anatomic observations on the relationship of the lingual nerve to the mandibular third molar region. J Oral Maxillofac Surg 1984; 42: 565-567. 16. Pogrel MA, Renaut A, Schmidt B, Ammar A. The relationship of the lingual nerve to the mandibular third molar region: an anatomic study. J Oral Maxillofac Surg 1995; 53: 11781181. 17. Miloro M, Halkias LE, Slone HW, Chakeres DW. Assessment of the lingual nerve in the third molar region using magnetic resonance imaging. J Oral Maxillofac Surg 1997; 55: 134-137. 11
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18. Behnia H, Kheradvar A, Shahrokhi M. An anatomic study of the lingual nerve in the third molar region. J Oral Maxillofac Surg 2000; 58: 649-651. 19. Hölzle FW, Wolff KD. Anatomic position of the lingual nerve in the mandibular third molar region with special consideration of an atrophied mandibular crest: an anatomical study. Int J Oral Maxillofac Surg 2001; 30(4): 333-338. 20. Karakas P, Uzel M, Koebke J. The relationship of the lingual nerve to the third molar region using radiographic imaging. Br Dent J 2007; 203: 29-31. 21. Erdogmus S, Govsa F, Celik S. Anatomic position of the lingual nerve in the mandibular third molar region as potential risk factors for nerve palsy. J Craniofac Surg 2008; 19(1): 264-270. 22. Mendes MB, de CarvalhoLeite Leal Nunes CM, de Almeida Lopes MC. Anatomical relationship of lingual nerve to the region of mandibular third molar. J Oral Maxillofac Res 2014; 4(4): e2. 23. Dias GJ, de Silva RK, Shah T, Sim E, Song N, Colombage S, Cornwall J. Multivariate assessment of site of lingual nerve. Br J Oral Maxillofac Surg. 2015; 53(4): 347-351. 24. Pogrel MA, Thamby S. Permanent nerve involvement resulting from inferior alveolar nerve blocks. J Am Dent Assoc 2000; 131(7): 901-907. 25. Harn SD, Durham TM. Incidence of lingual nerve trauma and postinjection complications in conventional mandibular block anesthesia. J Am Dent Assoc 1990; 121(4): 519-523. 26. Pogrel MA, Bryan J, Regezi J. Nerve damage associated with inferior alveolar dental blocks. J Am Dent Assoc 1995; 126(8): 1150-1155. 27. Stacy GC, Hajjar G. Barbed needle and inexplicable paresthesias and trimus after dental regional anaesthesia. Oral Surg Oral Med Oral Pathol 1994; 77(6): 585-588. 28. Crean SJ, Powis A. Neurological complications of local anaesthetics in dentistry. Dent Update 1999; 26(8): 344-349. 29. Haas DA, Lennon D. A 21 year retrospective study of reports of paresthesia following local anesthetic administration. J Can Dent Assoc 1995; 61(4): 319-320, 323-326, 329-330. 30. Hutchings ML. Nerve damage and nerve blocks. J Am Dent Assoc 1996; 127(1): 25. 31. Saray A, Apan A, Kisa U. Free radical-induced damage in experimental peripheral nerve injection injury. J Reconstr Microsurg 2003; 19(6): 401-406. 32. Moore PA, Haas DA. Paresthesias in dentistry. Dent Clin North Am. 2010; 54(4): 715-730. 33. Kirihara Y, Saito Y, Sakura S, Hashimoto K, Kishimoto T, Yasui Y. Comparative neurotoxicity of intrathecal and epidural lidocaine in rats. Anesthesiology 2003; 99(4): 961968. 34. Gaffen AS, Haas DA. Retrospective review of voluntary reports of nonsurgical paresthesia in dentistry. J Can Dent Assoc 2009; 75(8): 579. 35. Sambrook PJ, Goss AN. Severe adverse reactions to dental local anaesthetics: prolonged mandibular and lingual nerve anaesthesia. Aust Dent J 2011; 56(2): 154-159. 36. Krafft TC, Hickel R. Clinical investigation into the incidence of direct damage to the lingual nerve caused by local anaesthesia. J Craniomaxillofac Surg 1994; 22(5): 294-296. 37. Garisto GA, Gaffen AS, Lawrence HP, Tenenbaum HC, Haas DA. Occurrence of paresthesia after dental local anesthetic administration in the United States. J Am Dent Assoc 2010; 141(7): 836-844.
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38. Pogrel MA, Schmidt BL, Sambajon V, Jordan RC. Lingual nerve damage due to inferior alveolar nerve blocks: a possible explanation. J Am Dent Assoc 2003; 134(2): 195-199. 39. Morris CD, Rasmussen J, Throckmorton GS, Finn R. The anatomic basis of lingual nerve trauma associated with inferior alveolar block injections. J Oral Maxillofac Surg 2010; 68: 2833-2836. 40. Rud J. The split-bone technique for removal of impacted mandibular third molars. J Oral Surg. 1970; 28(6): 416-421. 41. Rood JP. Lingual split technique. Damage to inferior alveolar and lingual nerves during removal of impacted mandibular third molars. Br Dent J 1983; 154: 402-403. 42. Hochwald DA, Davis WH, Martinoff J. Modified distolingual splitting technique for removal of impacted mandibular third molars: incidence of postoperative sequelae. Oral Surg Oral Med Oral Pathol 1983; 56(1): 9-11. 43. Rud J. Reevaluation of the lingual split-bone technique for removal of impacted mandibular third molars. J Oral MaxillofacSurg 1984; 42: 114-117. 44. Goldberg MH, Nemarich AN, Marco WP. Complications after mandibular third molar surgery: a statistical analysis of 500 consecutive procedures in private practice. J Am Dent Assoc 1985; 111: 277-279. 45. Wofford DT, Miller RI. Prospective study of dysesthesia following odontectomy of impacted mandibular third molars. J Oral Maxillofac Surg 1987; 45: 15-19. 46. Mason DA. Lingual nerve damage following lower third molar surgery. Int J Oral Maxillofac Surg 1988; 17: 290-294. 47. Obiechina AE. Paraesthesia after mandibular third molar extractions in Nigerians. Odontostomatol Trop 1990; 13: 113-114. 48. Rood JP. Permanent damage to inferior alveolar and lingual nerves during the removal of impacted mandibular third molars. Comparison of two methods of bone removal. Br Dent J 1992; 172: 108-110. 49. Schultze-Mosgau S, Reich RH. Assessment of inferior alveolar and lingual nerve disturbances after dentoalveolar surgery, and of recovery of sensitivity. Int J Oral Maxillofac Surg 1993; 22: 214-217. 50. Walters H. Reducing lingual nerve damage in third molar surgery: A clinical audit of 1350 cases. Br Dent J 1995; 178: 140-144. 51. Robinson PP, Smith KG. Lingual nerve damage during lower third molar removal: a comparison of two surgical methods. Br Dent J 1996; 180: 456-461. 52. Appiah-Anane S, Appiah-Anane MG. Protection of the lingual nerve during operations on the mandibular third molar: a simple method. Br J Oral Maxillofac Surg 1997; 35: 170-172. 53. Moss CE, Wake MJ. Lingual access for third molar surgery: a 20-year retrospective audit. Br J Oral Maxillofac Surg 1999; 37(4): 255-258. 54. Gargallo-Albiol J, Buenechea-Imaz R, Gay-Escoda C. Lingual nerve protection during surgical removal of lower third molars. A prospective randomised study. Int J Oral Maxillofac Surg. 2000; 29(4): 268-271. 55. Benediktsdóttir IS, Wenzel A, Petersen JK, Hintze H. Mandibular third molar removal: risk indicators for extended operation time, postoperative pain, and complications. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2004; 97: 438-446. 56. Gomes AC, Vasconcelos BC, de Oliveira e Silva ED, da Silva LC. Lingual nerve damage after mandibular third molar surgery: a randomized clinical trial. J Oral Maxillofac Surg. 2005; 63(10): 1443-1446. 57. Jerjes W, Swinson B, Moles DR, El-Maaytah M, Banu B, Upile T, Kumar M, Al Khawalde M, Vourvachis M, Hadi H, Kumar S, Hopper C. Permanent sensory nerve impairment following third molar surgery: a prospective study. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2006; 102: e1-e7. 13
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58. Baqain ZH, Abukaraky A, Hassoneh Y, Sawair F. Lingual nerve morbidity and mandibular third molar surgery: a prospective study. Med Princ Pract 2010; 19: 28-32. 59. Jerjes W, Upile T, Shah P, Nhembe F, Gudka D, Kafas P, McCarthy E, Abbas S, Patel S, Hamdoon Z, Abiola J, Vourvachis M, Kalkani M, Al-Khawalde M, Leeson R, Banu B, Rob J, El-Maaytah M, Hopper C. Risk factors associated with injury to the inferior alveolar and lingual nerves following third molar surgery-revisited. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2010; 109(3): 335-345. 60. Janakiraman EN, Alexander M, Sanjay P. Prospective analysis of frequency and contributing factors of nerve injuries following third-molar surgery. J Craniofac Surg 2010; 21: 784-786. 61. Lata J, Tiwari AK. Incidence of lingual nerve paraesthesia following mandibular third molar surgery. Natl J Maxillofac Surg 2011; 2(2): 137-140. 62. CharanBabu HS, Reddy PB, Pattathan RK, Desai R, Shubha AB. Factors influencing lingual nerve paraesthesia following third molar surgery: a prospective clinical study. J Maxillofac Oral Surg 2013; 2(2): 168-172. 63. Smith WP. The relative risk of neurosensory deficit following removal of mandibular third molar teeth: the influence of radiography and surgical technique. Oral Surg Oral Med Oral Pathol Oral Radiol 2013; 115(1): 18-24. 64. Guerrouani A, Zeinoun T, Vervaet C, Legrand W. A four-year monocentric study of the complications of third molar extractions under general anesthesia: about 2112 patients. Int J Dent 2013; 2013: 763837. 65. Nguyen E, Grubor D, Chandu A. Risk factors for permanent injury of inferior alveolar and lingual nerves during third molar surgery. J Oral Maxillofac Surg 2014; 72(12): 2394-2401 66. Yadav S, Verma A, Sachdeva A. Assessment of lingual nerve injury using different surgical variables for mandibular third molar surgery: a clinical study. Int J Oral Maxillofac Surg 2014; 43(7): 889-893. 67. Shad S, Shah SM, Alamgir, Abbasi MM. Frequency of lingual nerve injury in mandibular third molar extraction: a comparison of two surgical techniques. J Ayub Med Coll Abbottabad 2015; 27(3): 580-583. 68. Cheung LK, Leung YY, Chow LK, Wong MC, Chan EK, Fok YH. Incidence of neurosensory deficits and recovery after lower third molar surgery: a prospective clinical study of 4338 cases. Int J Oral Maxillofac Surg 2010; 39: 320-326. 69. Chan HL, Leong DJ, Fu JH, Yeh CY, Tatarakis N, Wang HL. The significance of the lingual nerve during periodontal/implant surgery. J Periodontol 2010; 81(3): 372-377. 70. Kim SY, Hu KS, Chung IH, Lee EW, Kim HJ. Topographic anatomy of the lingual nerve and variations in communication pattern of the mandibular nerve branches. Surg Radiol Anat 2004; 26: 128-135. 71. Benninger B, Kloenne J, Horn JL. Clinical anatomy of the lingual nerve and identification with ultrasonography. Br J Oral Maxillofac Surg 2013; 51(6): 541-544. 72. Olsen J, Papadaki M, Troulis M, Kaban L, O’Neill M, Donoff B. Using ultrasound to visualize the lingual nerve. J Oral Maxillofac Surg 2007; 65: 2295-2300. 73. Trost O, Kazemi A, Cheynel N, Benkhadra M, Soichot P, Malka G, Trouilloud P. Spatial relationships between lingual nerve and mandibular ramus: original study method, clinical and educational applications. Surg Radiol Anat 2009; 31: 447-452. 74. Nizam SA, Ziccardi VB. Trigeminal nerve injuries: avoidance and management of iatrogenic injury. Oral Maxillofac Surg Clin North Am 2015; 27(3): 411-424. 75. Renton T, Yilmaz Z, Gaballah K. Evaluation of trigeminal nerve injuries in relation to third molar surgery in a prospective patient cohort. Recommendations for prevention. Int J Oral Maxillofac Surg 2012; 41(12): 1509-1518. 14
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76. Pippi R, Alvaro R. Piezosurgery for the lingual split technique in mandibular third molar removal: a suggestion. J Craniofac Surg 2013; 24(2): 531-533. 77. Ress RT. Permanent damage to inferior alveolar and lingual nerves. Br Dent J 1992; 73:123124. 78. Schwartz LJ. Lingual anesthesia following mandibular odontectomy. J Oral Surg 1973; 31: 918-920. 79. Renton T, McGurk M. Evaluation of factors predictive of lingual nerve injury in third molar surgery. Br J Oral Maxillofac Surg 2001; 39: 423-428. 80. Queral-Godoy E, Figueiredo R, Valmaseda-Castellón E, Berini-Aytés L, Gay-Escoda C. Frequency and evolution of lingual nerve lesions following lower third molar extraction. J Oral Maxillofac Surg 2006; 64(3): 402-407. 81. Blackburn CW, Bramley PA. Lingual nerve damage associated with the removal of lower third molars. Br Dent J 1989; 167:103-107. 82. Fielding AF, Rachiele DP, Frazier G. Lingual nerve paresthesia following third molar surgery: a retrospective clinical study. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 1997; 84(4): 345-348. 83. Bataineh AB. Sensory nerve impairment following mandibular third molar surgery. J Oral Maxillofac Surg 2001; 59: 1012-1017. 84. Zur KB, Mu L, Sanders I. Distribution pattern of the human lingual nerve. Clin Anat 2004; 17: 88-92. 85. Toure G, Bicchieray L, Selva J, Vacher C. The intra-lingual course of the nerves of the tongue. Surg Radiol Anat 2005: 27: 297-302. 86. Rusu MC, Nimigean V, Podoleanu L, Ivaşcu RV, Niculescu MC. Details of the intralingual topography and morphology of the lingual nerve. Int J Oral Maxillofac Surg 2008; 37(9): 835-839.
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ACCEPTED MANUSCRIPT Table 1. Lingual nerve location in the lower third molar region N. of nerves
Horizontal distance (mm)
Vertical distance (mm)
Mandibular bone contact (%)
At the level of or above the mandibular crest (%)
Diameter (mm)
Kiesselbach and Chamberlaind, 198415
C
34
0.59±0.90
2.28±1.96
62
17.6
1.86
Pogrel et al., 199516
C
40
3.45±1.48
8.32±4.05
Miloro et al., 199717
MR
20
2.53±0.67
2.75±0.97
Bhenia et al., 200018
C
669
2.06±1.10
3.01±0.42
Holzle and Wolff, 200119
C
68
0.86±1.00
7.83±1.65
Karakas et al., 200720
C
21
4.19±1.99
9.56±5.28
Erdogmus et al., 200821
C
42
Mendes et al., 201322
C
24
Dias et al., 201523
C
46
0
15
3.45
25
10
2.54
23.27
14.05
-
57.4
SC
8.82
2.74
0
4.7
2.56±0.59
9.3±2.1
7.06±1.3
0
0
2.04±0.4
4.40±2.4
16.8±5.7
0
0
-
0.57±0.56
9.15±3.87
26
7
-
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C=cadaver; MR=magnetic resonance
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ACCEPTED MANUSCRIPT Table 2. Incidence of lingual nerve injury Surgical method
Anesthesia
Bone removal method
LTMs (number)
Temporary LN injury (%)
Permanent LN injury (%)
Rud, 197040
PS
LST
L
C, D
718
0.83
0.14
Rood, 198341
PS
LST
G
C, D
1,400
6.64
0
Hochwald et al., 198342
PS
LST
L&G
C
Rud, 198443
PS
LST
G
C
Goldberg et al., 198544
PS
BA
L&G
D
Wofford and Miller, 198745
PS
BA
L
D
Mason, 198846
PS
BA+LF
G
C, D
Obiechina, 199047
PS
BA
Rood, 199248
PS
BA+LF LST
PS
BA+LF
Walters, 199550
PS
Robinson and Smith, 199651
PS
L
G
C, D
Moss and Wake, 199953
RS
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Gargallo-Albiol et al., 200054
Benediktsdottir et al., 200455 Gomes et al., 200556
PS
0
609
3
0
500
0.6
0.2
576
0.71
0.17
747
8.3
0.4
293
19.8
1.02
367
0.27
0
406
3.2
2
384
12.8
0
791
1.9
0
LST
G
C
1,000
0.5
0
BA+LF
L&G
D
352
6.53
0.85
390
0.51
0.25
BA
L
D
504
0.2
0
LST
G
C
2,088
0.8
0
BA+LF
L
D
142
2.11
0
158
0.63
0
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PS
4.3
D
BA
Appiah-Anane and AppiahAnane199752
598
L
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Schultze-Mosgua and Reich, 199349
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LST
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Study type
SC
Authors, year
BA
PS
BA
L
D
388
0.5
0
RCT
BA
L&G
D
55
0
0
55
9.1
0
BA+LF Jerjes et al., 200657
PS
BA
L
NS
1,087
5.52
1
Baquain et al., 201058
PS
BA
L
D
299
0.3
0
110
9.1
0
3,236
0.62
1.1
BA+LF Jerjes et al., 201059
PS
BA
L
17
NS
ACCEPTED MANUSCRIPT Janakiraman et al., 201060
PS
BA
Lata201161
PS
BA
L
CharanBabu et al., 201362
PS
BA
L
119
4.2
1.7
D
90
5.5
1.1
D
92
1.1
0
8
37.5
0
1,455
0.14
0.07
134
1.5
0
7,659
6.5
0
Smith, 201363
PS
BA
L&G
D
BA+LF
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BA+LF
RS
BA
G
D
Nguyen et al., 201465
RS
BA
L&G
D
10,160
0.069
0.079
Yadav et al., 201466
PS
BA
L
D
576
1.7
0.2
624
9.1
0.5
190
2.1
0.52
190
8.95
0
BA+LF RCT
BA BA+LF
L
NS
M AN U
Shad et al., 201567
SC
Guerrouani et al., 201364
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C=chisel; D=drill; PS=prospective study; G=general; L=local; BA=buccal approach; LF=lingual flap; LN=lingual nerve; NS=not specified; RS=retrospective study; LST=lingual split technique; LTMs=lower third molars; RCT=randomized controlled trial
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Table 3. Lingual nerve injury by tooth sectioning Total cases (number)
Cases with TS (%)
LN injury with TS (%)
LN injury without TS (%)
Baquain et al., 201058
426
27.5
5.7
1.3
Cheung et al., 201068
4,338
62
0.57
0.91
100
13
7.7
3.4
1,200
57.7
0.4
CharanBabu et al., 201362 Yadav et al., 201466
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LN=lingual nerve; TS=tooth sectioning
RI PT
Authors, year
19
0.2
ACCEPTED MANUSCRIPT Table 4. Lingual nerve damage by ostectomy Total cases (number)
Cases with O (%)
LN injury with O (%)
LN injury without O (%)
Mason, 198846
1,040
66
20.9
3.4
Baquain et al., 201058
443
68.6
3.6
0
Cheung et al., 201068
4,338
20
0.91
0.64
Yadav et al., 201466
1,200
93.5
0.3
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LN=lingual nerve; O=ostectomy
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Authors, year
20
0
S0278-2391(16)31328-3
DOI:
10.1016/j.joms.2016.12.040
Reference:
YJOMS 57602
To appear in:
Journal of Oral and Maxillofacial Surgery
Received Date: 7 August 2016 Revised Date:
23 November 2016
Accepted Date: 24 December 2016
Please cite this article as: Pippi R, Spota A, Santoro M, Prevention of lingual nerve injury in third molar surgery: literature review, Journal of Oral and Maxillofacial Surgery (2017), doi: 10.1016/ j.joms.2016.12.040. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT REVISED TITLE PAGE Prevention of lingual nerve injury in third molar surgery: literature review Authors: Roberto Pippi, MD, DDS, Associate Professor, Department of Odontostomatological and Maxillo Facial Sciences, “Sapienza” University of Rome.
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Andrea Spota, MD, DDS, Researcher, Department of Odontostomatological and Maxillo Facial Sciences, “Sapienza” University of Rome.
Marcello Santoro, DDS, PhD student, Department of Odontostomatological and Maxillo Facial
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Sciences, “Sapienza” University of Rome.
Corresponding author:
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Marcello Santoro, DDS, PhD student, Department of Odontostomatological and Maxillo Facial
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Sciences, Via Caserta 6, 00161 Rome, +393334025038, [email protected].
ACCEPTED MANUSCRIPT Prevention of lingual nerve injury in third molar surgery: literature review Abstract Purpose. To identify any factors which may aid the surgeon in preventing or minimizing the risk of lingual nerve injury during third molar surgery.
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Methods. Electronic research was carried out on the correlation between lingual nerve damage and lower third molar surgery (topographic anatomy, surgical technique, and regional anesthesia) using PubMed, Scopus and Cochrane central databases. The research only included articles published in English up to February 2016.
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Results. Lingual nerve anatomy varied greatly: direct contact between the lingual nerve and the third molar alveolar wall was reported in a wide range of cases (0-62%) and the nerve was located at the same level or above the top of the ridge in 0-17.6% of cases. No detailed data was found on the actual incidence of lingual nerve injury resulting from local anesthesia by injection. Permanent lingual nerve damage did not show statistically significant differences between the simple buccal approach and the buccal approach + lingual flap retraction, although the latter was significantly associated with an increased risk of temporary damage. As far as permanent damage was concerned, no statistically significant differences were found between the lingual split technique and the buccal approach with or without lingual flap retraction. As opposed to tooth sectioning, ostectomy was strongly statistically associated with permanent lingual nerve damage.
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Conclusions. Results should be interpreted with extreme caution due to the considerable heterogeneity of the data as well as the considerable influence of several anatomical and surgical variables, all closely related, but which are difficult to analyze independently. It seems preferable to avoid lingual flap elevation, except in selected cases in which the presence of more than one unfavourable surgical variable predict a high risk of nerve injury. Tooth sectioning may reduce the extent of ostectomy or even, in some cases, prevent it, potentially acting as a protective factor in lingual nerve injury.
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Introduction Lingual nerve injury in oral-maxillofacial surgery is rather uncommon, but it is a highly disabling complication with a high risk of medico-legal consequences.1-4 Lower third molar extraction is one of the most common procedures in oral surgery and is undoubtedly the most frequent cause of lingual nerve damage. Several etiological factors, either anatomical or surgical, have been addressed; however, nerve damage is often unexpected by the surgeon.5-7 The effect of certain surgical procedures on lingual nerve injury is also still unclear. The wide use of surgical instruments for lingual nerve protection during lower third molar extraction is still debated. There are no studies in the literature which unequivocally prove that lingual flap retraction can cause more harm than benefit.8-14 The aim of the present study was to identify any factors which may help the surgeon prevent or minimize the risk of nerve injury in lower third molar surgery.
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Materials and methods Electronic research was performed using PubMed, Scopus and Cochrane central databases, including only articles published in English up to February 2016. The following keywords were used as search criteria: lingual nerve injury, lingual nerve and anatomy, lingual nerve and prevention, lingual nerve and third molar or wisdom tooth, lingual nerve and lingual flap, lingual nerve and lingual split, lingual nerve and mandibular block, lingual nerve and paraesthesia, and lingual nerve and anaesthetics. The research was carried out individually by all authors. The abstract of each article was viewed and the full text was downloaded if it was considered relevant to the following selection criteria of the study: for the anatomy section - articles which reported data about topographical relationships between the lingual nerve and the neighboring anatomical structures; for the section related to local anesthesia - articles which reported data on the incidence, mechanisms and preventive standards of nerve damage; for the surgical section - articles which reported clear and complete information regarding the technique used, the number of procedures, the number of extracted third molars and relative incidence of temporary and permanent nerve damage with at least 6 months of follow-up. Studies in which data of interest were indirectly obtainable by extrapolating them from other findings were also selected. Cross-checking was also carried out using the references of all collected articles and the missing studies that met the above-listed selection criteria were added. No exclusion criterion was adopted in relation to the study type. No attempt was made to identify unpublished material or to contact the authors of published studies to obtain more information or to go back to the missing data. Due to the limited number of studies, as well as the considerable differences in their study design, it was not possible to apply any statistical method to determine the risk of bias and the degree of inconsistency (heterogeneity). The statistical association between nerve damage and the surgical technique used was tested by the Pearson's chi-square test (Chi2). A first statistical analysis was performed with specific focus on the surgical technique (lingual flap, buccal approach, buccal approach + lingual flap retraction), by combining only data of "similar studies" for the analyzed primary variable, such as studies in which it was possible to identify differences between two adopted techniques in terms of nerve injury: temporary lingual nerve injury in the buccal approach + lingual flap retraction vs buccal approach alone, permanent lingual nerve injury in buccal approach + lingual flap retraction vs buccal approach alone, temporary 2
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lingual nerve injury in the lingual split technique vs buccal approach + lingual flap retraction, and permanent lingual nerve injury in lingual split technique vs buccal approach + lingual flap retraction. Subsequently, the results of all selected studies were resumed for the analyzed interest variable in a "mixed group" of studies in which it was possible to go back to the result of a single surgical technique (buccal approach, lingual split technique, buccal approach + lingual flap retraction) in terms of nerve injury in order to assess the possible discrepancy with the analysis conducted only among similar studies as well as to identify differences between surgical approaches which were not directly compared in the literature (temporary and permanent lingual nerve injuries in lingual split technique vs buccal approach). Since it was not possible to assess the heterogeneity of studies in the mixed group due to the incompleteness of their data in relation to interest variables, the Chi2 test was performed. In the present analysis studies in which it was not possible to clearly distinguish the number of cases related to each of the three analyzed surgical techniques were not considered. To evaluate the association between nerve damage and tooth sectioning or ostectomy, only articles which reported clear information on the number of cases in which these techniques were performed and the relative incidence of nerve damage were taken into account. All articles in which these data were missing or could not be deduced were excluded. Even in this case it was not possible to apply any statistical method to determine both the risk of bias and the degree of inconsistency (heterogeneity).
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Results Lingual nerve in the lower third molar region Out of the 228 articles analyzed, 9 were selected for this topic with a total number of 964 cases (Table 1).15-23 The average horizontal distance between the lingual nerve and the third molar lingual alveolar wall was about 3.05 mm (SE = 0.48; range: 0.57-9.3). The average vertical distance between the lingual nerve and the top of the alveolar ridge was 7.24 mm (SE = 0.95; range: 2.2816.8). Direct contact between the lingual nerve and the alveolar wall was reported in a wide range of cases (0-62%). The nerve was located at the same level or above the top of the ridge in 0-17.6% of cases. Lingual nerve minimum and maximum diameters in the third molar region were 1.86 and 3.45 mm, respectively. Lingual nerve injury and regional anesthesia No detailed data was identified for the actual incidence of lingual nerve injury resulting from local anesthesia by injection.24-39 Lingual nerve injury and surgical technique Out of the 1,028 analyzed articles, 28 were selected to evaluate the influence of surgical techniques on lingual nerve damage (Table 2).40-67 When combining the results of similar articles51,54,56,58,62,63,66,67 for the variable “temporary lingual nerve injury in the buccal approach + lingual flap retraction vs buccal approach”, for a total of 4,830 cases, buccal approach + lingual flap retraction were more significantly associated (p<0.01; RR:12.22; 1.71-15.07, CI 95%) to lingual nerve injury than to the buccal approach.
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The same result was obtained by combining data from the mixed group44-49,51,52,54-67 for the “temporary lingual nerve injury in the buccal approach + lingual flap retraction vs buccal approach” variable for a total of 27,785 cases (p<0.01; RR:2.38; 2.60-22.97, CI 95%). As far as “permanent lingual nerve injury” was concerned no statistically significant differences (p=0.0743, 0.74-6.62, CI 95%) were found between the two techniques in the group of similar articles,51,54,56,58,62,63,66,67 and the analysis of the mixed group44-49,51,52,54-67 of studies seems to further confirm this finding (p=0.9808; 1.08-26.26, CI 95%). As for the “temporary lingual nerve injury in the lingual split technique vs buccal approach + lingual flap retraction” variable, in the group of similar studies (1,83046,48 cases) the lingual split technique was more significantly associated (p<0.01; RR:2.7; 0.26-0.47 CI 95%) to lingual nerve injury than to the buccal approach + lingual flap retraction technique, whereas in 9,49440-43,46,4851,54,56,58,62,63,66,67 cases of the mixed group, the association was significantly lower (p<0.01; RR:0.67; 0.48-4.11, CI 95%). As for permanent damage, the group of similar studies46,48 for “lingual nerve damage in the lingual split technique vs the buccal approach + lingual flap retraction” variable showed no statistically significant difference between the two techniques (p=0.2259; 0.73-6.59, CI 95%), as opposed to the mixed study group40-43,46,48-51,54,56,58,62,63,66,67 which showed a higher risk of permanent damage for the lingual split technique (p=0.0116; RR: 0.23; 0.13-6.11, CI 95%). When comparing the lingual split technique vs the buccal approach, no similar study group was found and the mixed study group40-48,50-67 (32,471 cases) showed a significantly higher risk of temporary and permanent lingual nerve damage for the lingual split technique (p<0.01; RR: 1.58; 10.06-42.59, CI 95%), whereas a greater risk of permanent lingual nerve damage was observed in the buccal approach (p<0.01; RR: 0.22; 4.43-64.65, CI 95%). In only 4 articles58,62,66,68 (6,064 cases, Table 3), information regarding the number of cases in which tooth sectioning was or was not performed and the relative incidence of nerve damage were clearly set out or they could be indirectly identified. Tooth sectioning was not statistically associated with permanent lingual nerve damage (p=0.523; 0.52-4.95, CI 95%). In only 4 articles46,58,66,68 (7,021 cases, Table 4), information regarding the number of cases in which ostectomy was or was not performed and the relative incidence of nerve damage were clearly set out or they could be indirectly identified. Ostectomy was strongly statistically associated with permanent lingual nerve damage (p<0.01; RR=6,92; 0.90-9.36, CI 95%).
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Discussion Lingual nerve in the lower third molar region Thorough knowledge of the lingual nerve anatomy and topography is crucial in order to avoid iatrogenic nerve damage or at least to reduce the risk of nerve injury. Actually, lingual nerve spatial localization ranges widely from individual to individual as well as in the same individual.15-23, 69-71 Although several studies15-23 have attempted to define topographical relationships between the lingual nerve and lower third molar in both the horizontal and vertical planes (Table 1), comparison among studies was quite difficult since the reference points used for measurements were different. In addition, most studies often neglected important parameters, and thus provided inaccurate information regarding race, age, gender, edentulism type and degree of bone atrophy of sample subjects. In addition, most investigations were based on studies performed on cadavers, for which relatively inaccurate information was often provided as far as time and method of preservation of anatomical preparations were concerned. Moreover, study sample dimensions were often too inadequate to obtain significant results. For example, discrepancies found in space measurements in the Mendes at al.22 and Bhenia et al.18 studies are not only related to the different landmarks used and the number of analyzed anatomical preparations, but to the storage time as well. Actually, although stored in the same way, Bhenia et al.18 refer to an extremely larger number of anatomical preparations analyzed within a maximum of about 24 hours of death, thus ensuring lower dimensional tissue alterations compared to the study of Mendes et al.22 in which the preparation times varied from 2 to 5 years. Kiesselbach and Chamberlain15 and Progel et al.16 results also came from rather small samples and might be susceptible to errors due to the possible lingual nerve dislocation from its actual position during fixation and preparation of anatomical specimens.18 Actually, although anatomical dissection is rather easy to perform, it is well known to differently alter the lingual nerve spatial position even more when not properly executed.69 Therefore, different methods have been proposed to evaluate lingual nerve running, such as MRI,17 ultrasounds,72 or radiographic imaging with radiopaque landmarks placed inside or alongside the lingual nerve.20,69,73 Although these indirect methods were intended to overcome possible spatial lingual nerve alterations due to the dissection, they were not able to accurately identify and measure anatomical relationships between the lingual nerve and neighboring structures.69 Other factors which make it even more difficult to interpret the results of different studies involve the high variability of lingual nerve position in relation both to the alveolar process morphology and to the existing space between the third molar and the ascending mandibular branch. Actually, the lingual nerve position may be influenced by both alveolar process prominence and a marked inclination of its lingual surface in the lower third molar region. A small distance between the lower third molar and the mandibular ascending branch may also justify a more cranial lingual nerve position.23,70 Although the influence of the degree of mandibular atrophy on lingual nerve topographical relationships has often been overlooked by most studies, some authors16,19 have suggested that the loss of both muscle tone and connective tissue tension, secondary to aging, may partially compensate the lingual nerve superficial position due to bone atrophy resulting from tooth loss through an easier nerve deepening within mouth floor, which possibly leaves nerve spatial relationships with mandibular alveolar ridge unchanged. 5
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In this regard, a recent study23 stressed the strong discrepancy in lingual nerve location in relation to edentulism type, alerting the possible greater lingual nerve proximity to the mandibular alveolar crest in edentulous subjects. A marked bone loss may therefore be an important risk factor for lingual nerve injury during routine oral surgery involving lingual access flap management in the posterior region of the mandible.19 Actually, almost all anatomical studies highlight the risk of the lingual nerve being close to the lingual surface of the alveolar process (0-62%) or to an even higher level than the mandibular bone crest (0-17.6%), almost directly laying on the retromolar region (Table 1).15-23 All these findings are considerably important in the prevention of lingual nerve damage during most routine oral surgeries. Therefore, in lower third molar extraction, the distal release incision should not be directed towards the lingual aspect of the ascending branch of the mandible, but instead should be inclined vestibularly 45° in respect to the lower third molar distal surface.12,14,19,52,74 Lingual nerve injury and regional anesthesia The lingual nerve is also susceptible to injury through common local anesthetic injection procedures although the true incidence of this event and the actual causative mechanisms are still being debated. Damage to the lingual nerve may be directly caused by the syringe needle24-26 during needle penetration as the nerve cannot be easily moved away during needle advancement since it is stabilized within the inter-pterygoid fascia when the mouth is fully open. Alternatively, the nerve can be directly damaged by the needle during its retraction from the tissues24,27 especially when common chamfered needles are used since their tips are easily susceptible to distortion and irregular curvatures, particularly as a result of bone contact or in the case of multiple injections which can break the perineurium and induce both endoneurium herniation and interruption of multiple nerve fibers or entire fascicles.27-29 However, since the lingual nerve average diameter is 1.86 mm and the diameter of the most commonly used needle in dental practice (25-gauge) is about 0.45 mm, it seems impossible that this type of trauma can be capable of breaking the nerve bundle, thus resulting in neurotmesis.24-27, 29,30 Furthermore, needle penetration can be responsible for direct trauma to the intraneural vessels with formation of an intraneural hematoma able to exert a certain degree of compression to the nerve fibers, leading to a focal block of nerve transmission without any interruption of both the axonal and perineural connective continuity. The return to normality may take several weeks as the progressive reduction of hematoma pressure allows nerve remyelination.24-27,29,30 It has also been suggested that local anesthetics are able to cause a localized chemical injury to the nerve if deposited in the intra-fascicular space or inside the nerve during needle retraction.24,26 Chemical trauma may be responsible for demyelination, axonal degeneration, inflammation and edema of the endoneural fibers.31 The more easily the ester or amide group hydrolysis occurs, the greater the amount of bioavailable alcohol group is; therefore, the stronger the anesthetic power is, the greater the possibility of nerve cell damage. In this regard, articaine and prilocaine have shown a greater cytotoxic power than lidocaine.24,26,29,32 High doses of these anesthetics are therefore not recommended due to easy production of neurotoxic metabolites. High concentrations of lidocaine also showed neuropathic effects after perineural or intrafascicular injections.24,26,29,32-34
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It is not possible to provide accurate information about the true incidence of lingual nerve injury during local anesthesia since it is often difficult to extrapolate it from that of the inferior alveolar nerve, and since it is often not clearly specified whether local anesthesia is followed by non-surgical procedures to exclude other possible causes of lingual nerve damage. Sambrook and Goss35 estimated a 1:27.415 risk of lingual nerve and inferior alveolar nerve damage during truncal mandibular anesthesia. Similarly, Pogrel and Thamby24 reported a nerve damage incidence which ranged from 1:160.571 to 1:26.762, claiming that during the professional life of each practitioner it is very likely to have at least one patient with nerve trauma due to local anesthesia. Harm and Durham25 reported approximately a 3.62% chance of lingual nerve trauma whenever mandibular nerve block anesthesia is performed while Krafft and Hickel36 found a 0.15% incidence of lingual nerve injury (18/12,104) during nerve block anesthesia not performed for surgery. Moreover, nerve damage due to local anesthesia more frequently affected the lingual nerve (more than 2/3 of cases) rather than the inferior alveolar nerve.24,34,37 Actually, although the diameter of the two nerves was found to be approximately the same at the injection site, the lingual nerve seems to be more exposed to needle trauma and also possesses less nerve fascicles compared to the inferior alveolar nerve.38 Pogrel al.38 showed that in approximately 33% of cases the lingual nerve is formed by only a single fascicle at the injection point, as opposed to 7-39 fascicles in the lower third molar area. This might explain why nerve alterations resulting from local anesthesia most frequently involve the entire lingual nerve distribution area.24,36,38 Furthermore, dysesthesia, which is the most disabling sensorial alteration, oddly occurs more frequently after nerve injury resulting from local anesthesia procedures (34%) rather than after surgical procedures (8%).24 Therefore, patients not only face an increased risk of being in greater discomfort, but they almost always are also poorly-informed about the possible risk of lingual nerve damage during local anesthesia compared to that related to surgery.24 Although sensory alteration recovery occurs within 8 weeks in 85-94% of cases,24,36 preventive measures for lingual nerve injury should be applied as soon as at the time of local anesthesia, a procedure which is often underestimated by dentists and surgeons. Due to the considerable variability of lingual nerve size and anatomical position, little can be done to predict and prevent its injury at this stage.39 However, it seems preferable to use a small-diameter needle while high concentrations of local anesthetics and multiple injections should be avoided.32,34,37,40 In particular, 4% prilocaine and 4% articaine appear to be associated to a 7.3 and 3.6 times greater probability, respectively, of causing paresthesia during inferior alveolar nerve block anesthesia than expected on the basis of the total local anesthetic use by U.S. dentists.72 Moreover, these substances, compared to other common local anesthetics, may more easily result in neuropathic pain although the true incidence of these phenomena still remains unclear.23,24,75 Lingual flap and nerve protection in third molar surgery Routine use of a surgical instrument for lingual nerve protection during lower third molar extraction is still debated. Actually, although the use of a lingual flap retractor can apparently provide greater operating safety, it is considered a possible etiologic factor of lingual nerve injury.13,14,46,49,51,52,54 However, there are no studies in the literature which unquestionably prove that lingual flap retraction may more easily lead to damage rather than benefit. In most studies, the different levels of experience of surgeons was not taken into account, the surgical technique was not standardized, and the information describing the surgical steps and variables (tooth eruption degree, inclusion 7
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depth, patient age, type and drug for anesthesia, surgical flap, type of retractor, type of ostectomy and tooth section, etc.) was not provided in a clear and comprehensive way. In addition, most studies were small-sized and observational so they were subjected to the lower statistical power of this study type (Table 2).40-67 Lingual nerve protection undoubtedly requires a great deal of caution. Although different types of lingual retractors have been proposed, including those of Howarth, Ward, Meade, Hovell, Walters and Rowe, there is no scientific evidence supporting the superiority of one over other instruments, the choice of which seems strongly influenced by surgeon’s personal experience.8,11,13,14,50,76 However, a large and smooth rather than narrow and pointed active retractor surface has been suggested to be less traumatic on the lingual nerve during flap retraction.8 Some authors assert that the lingual flap detachment for retractor placement, although associated with a high possibility of temporary nerve damage, may reduce the incidence of permanent nerve injury through improved access to and better visibility of the surgical area, thus ensuring safer use of both manual and rotating instruments.8,12-14 On the contrary, the results of the present analysis seem to confirm the conclusions reached by Pichler al.7, that is, although lingual retraction may be associated with a higher incidence of temporary nerve damage, it neither protects nor harms the lingual nerve permanently. Actually, the present review does not show any statistically significant difference in permanent lingual nerve damage between simple buccal approach and the combined approach (buccal approach + lingual flap retraction; p=0.98), although the latter is significantly associated with an increased risk of temporary damage (p<0.01). However, the lingual split technique seems to be statistically associated with an increased risk of temporary (p<0.01) nerve damage compared to the buccal approach with or without lingual flap retraction (p<0.01), whereas no statistically significant difference was found between the lingual split technique and the buccal approach + lingual flap retraction in permanent lingual nerve damage. However, these results and more so those derived from the “mixed groups”, should be interpreted with extreme caution due to the considerable heterogeneity of data from which they arise as well as to the presence of many confounding factors. Avoiding lingual flap detachment as much as possible in order to reduce the incidence of lingual nerve damage is therefore highly recommended. Actually, lingual nerve protection through the lingual flap should be restricted to selected cases in which the presence of more unfavorable surgical variables predict a high risk of nerve injury.9,10,13,14,46,49,51,52,54,77 Tooth sectioning and ostectomy in lower third molar surgery Although tooth sectioning is one of the possible risk factors for lingual nerve injury during lower third molar surgery,9,54,78-80 the present review did not find any statistically significant differences between the incidence of lingual nerve damage in surgeries in which tooth sectioning was performed and that of surgeries in which it was not. However, the present results (Table 3) refer to an extremely limited sample (6,064 lower third molars) since most of the studies analyzed did not clearly specify the number of cases in which tooth sectioning was actually performed or they omitted information on nerve damage incidence in cases in which tooth sectioning was performed or not. Furthermore, it is almost always impossible to correlate cases in which tooth sectioning was performed and in which lingual nerve damage occurred with lower third molar position or number and type of sections. The lack of statistically significant differences can also be related to confounding factors such as the surgeon’s skills and experience and therefore variables related to the surgical technique (anesthesia, 8
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flap design, need for ostectomy and its characteristics, suturing etc.), lingual nerve and lower third molar local anatomical variability, possible local pathological processes such as inflammatory adhesions as a result of recurrent pericoronitis affecting one or more surgical steps. During tooth sectioning, the lingual nerve may be involved by the bur. In the case of lower third molar bone impaction, predisposing conditions are both pre-existing bone fenestrations and iatrogenic intra-operative perforation of the alveolar wall at the level the lingual nerve running. For this reason, it would be a good rule to perform a subtotal lower third molar section and then complete the separation of fragments by using an elevator or another hand instrument.52 However, tooth sectioning may reduce the extent of ostectomy, or even help avoid it altogether in some cases, thus making it a possible protective factor for lingual nerve injury.9,52,62 Actually, in the present study removal of periradicular bone tissue, especially at the lingual and/or disto-lingual sites, was found to be strongly correlated to lingual nerve damage (p<0.0, Table 4). However, this finding also arises from a rather limited number of cases (7,021) since in most studies clear and comprehensive information regarding the number of cases in which ostectomy was actually performed, and/or the incidence of nerve damage in cases in which it was performed or not, is missing. Several authors claim that ostectomy should be carried out only when a total view of the periradicular bone surface is possible. Therefore, ostectomy should not be blindly performed, especially at the lower third molar distal and disto-lingual sites.81-83 If preoperative planning indicates the need to remove lower third molar distal or disto-lingual bone, a limited retraction of the lingual tissue may be appropriate both to improve surgical field visibility and to allow lingual nerve protection during bur use.74 Suture There is no data on the true incidence of lingual nerve damage caused by suture at the lower third molar fresh extraction site. Only a few studies cite suture as a possible risk factor for lingual nerve injury through a direct trauma of the needle or through "throttling" during knot closure.12,14,74 It is therefore recommended to avoid inserting the needle too apically in relation to the incision line. Chossegros et al.12 considered safe-inserting the needle at about 3 mm from the gingival margin of the lingual flap. Anatomical considerations in preventing lingual nerve injuries in other oral surgical procedures Even during implant or periodontal surgery in the posterior lingual mandibular region, it is preferable to perform intra-sulcular incisions, avoiding vertical relaxation incisions, especially in the molar region, and full-thickness flaps, avoiding any tearing or damage that may indirectly injure the lingual nerve.69 Moreover, the possibility of a relatively shallow position of the lingual nerve, even anteriorly to the lower third molar, should be always considered especially in cases of marked alveolar ridge atrophy.19 A study on cadavers (30 analyzed nerves) by Chan et al.69 analyzed the topographic lingual nerve anatomy in relation to the teeth mesial to the lower third molar region. Actually, these authors identified the lingual nerve on the vertical plane at about 9.6 mm, on average, below the meanlingual portion of the second molar cemento-enamel junction, until reaching an average of about 13 mm at the first molar level, and 15 mm in the second premolar area, without reporting any statistically significant differences between the left and right side of the jaw. The same authors53 also found that the first molar region was that in which the lingual nerve most frequently curved in a medial direction towards the tongue (41.60-58.33% of cases; 24 analyzed nerves, 12 per side), followed by the second molar (16.67-33.33% of cases) and finally, by the second premolar regions 9
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(16.67-25% of cases). On the contrary, this finding was quite rare in the first premolar area (8.33%; 1/12 analyzed nerves, on the left side).69 Few studies, on the other hand, have assessed an intra-lingual distribution of the lingual nerve.84-86 Their results indicated that a wide median longitudinal portion of the dorsum of the tongue was poorly innervated by lingual nerve and that, therefore, its branches could be easily avoided such as during the excision of median pathological lesions or during the removal of tissue at the lateral margins of the tongue up to about 1 cm from the latter. Actually, lingual nerve terminal branches, which run on genioglossus muscle, can be excluded from iatrogenic injury if incisions involve the lateral margins of the tongue and tissues connected to the genioglossus muscle are carefully dissected.84-86 The anatomical relationship between the lingual nerve and the submandibular gland duct (Wharton duct) is also quite variable. Mendes et al.22 (24 analyzed nerves) reported that the glandular duct crossed the lingual nerve superiorly in 62.5% of cases, whereas it ran beneath the nerve in 37.5% of cases. Similarly, in a topographical study on atrophic mandibles, Holzle et al.19 reported 4/34 cases (11.7%) in which Wharton duct ran deeper than the lingual nerve. On the contrary, Erdogmus et al.21 asserted that the lingual nerve maintained the same spatial relationship beneath the submandibular duct in all 42 cases. Knowledge of such anatomical variables may therefore be fundamental in preventing lingual nerve injury through a careful blunt dissection of tissues during surgical procedures involving both the floor of the mouth and the tongue. Conclusion
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The present review does not show any statistically significant differences in permanent lingual nerve damage between simple the buccal approach and the buccal approach combined with lingual retraction in lower third molar surgery, although buccal approach + lingual flap retraction is significantly associated with an increased risk of temporary nerve damage. The lingual split technique is statistically associated with an increased risk of temporary nerve damage compared both to the buccal approach + lingual flap retraction and to the simple buccal approach, while it does not show any differences in permanent lingual nerve damage compared to buccal approach + lingual flap retraction. It seems therefore preferable to avoid lingual flap elevation, except in selected cases in which the presence of more unfavourable surgical variables predict a high risk of nerve injury. There seems to be no statistically significant difference between the incidence of lingual nerve damage in surgeries in which tooth sectioning was performed and those in which it was not. Tooth sectioning may reduce the extent of ostectomy or even, in some cases, avoid it altogether, thus potentially acting as a protective factor in lingual nerve injury. Actually, removal of peri-radicular bone tissue, especially at the lingual and/or disto-lingual sites, is strongly associated with lingual nerve damage. However, these results should be interpreted with extreme caution due to the considerable heterogeneity of the data as well as the substantial influence of several anatomical and surgical variables, all closely related to possible nerve damage, but which are difficult to analyze independently. Moreover, most studies are observational and include a very limited significant sample population compared to the rareness of lingual nerve damage, so long-term randomized large-scale prospective studies are necessary to identify risk factors for lingual nerve injury. 10
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76. Pippi R, Alvaro R. Piezosurgery for the lingual split technique in mandibular third molar removal: a suggestion. J Craniofac Surg 2013; 24(2): 531-533. 77. Ress RT. Permanent damage to inferior alveolar and lingual nerves. Br Dent J 1992; 73:123124. 78. Schwartz LJ. Lingual anesthesia following mandibular odontectomy. J Oral Surg 1973; 31: 918-920. 79. Renton T, McGurk M. Evaluation of factors predictive of lingual nerve injury in third molar surgery. Br J Oral Maxillofac Surg 2001; 39: 423-428. 80. Queral-Godoy E, Figueiredo R, Valmaseda-Castellón E, Berini-Aytés L, Gay-Escoda C. Frequency and evolution of lingual nerve lesions following lower third molar extraction. J Oral Maxillofac Surg 2006; 64(3): 402-407. 81. Blackburn CW, Bramley PA. Lingual nerve damage associated with the removal of lower third molars. Br Dent J 1989; 167:103-107. 82. Fielding AF, Rachiele DP, Frazier G. Lingual nerve paresthesia following third molar surgery: a retrospective clinical study. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 1997; 84(4): 345-348. 83. Bataineh AB. Sensory nerve impairment following mandibular third molar surgery. J Oral Maxillofac Surg 2001; 59: 1012-1017. 84. Zur KB, Mu L, Sanders I. Distribution pattern of the human lingual nerve. Clin Anat 2004; 17: 88-92. 85. Toure G, Bicchieray L, Selva J, Vacher C. The intra-lingual course of the nerves of the tongue. Surg Radiol Anat 2005: 27: 297-302. 86. Rusu MC, Nimigean V, Podoleanu L, Ivaşcu RV, Niculescu MC. Details of the intralingual topography and morphology of the lingual nerve. Int J Oral Maxillofac Surg 2008; 37(9): 835-839.
15
ACCEPTED MANUSCRIPT Table 1. Lingual nerve location in the lower third molar region N. of nerves
Horizontal distance (mm)
Vertical distance (mm)
Mandibular bone contact (%)
At the level of or above the mandibular crest (%)
Diameter (mm)
Kiesselbach and Chamberlaind, 198415
C
34
0.59±0.90
2.28±1.96
62
17.6
1.86
Pogrel et al., 199516
C
40
3.45±1.48
8.32±4.05
Miloro et al., 199717
MR
20
2.53±0.67
2.75±0.97
Bhenia et al., 200018
C
669
2.06±1.10
3.01±0.42
Holzle and Wolff, 200119
C
68
0.86±1.00
7.83±1.65
Karakas et al., 200720
C
21
4.19±1.99
9.56±5.28
Erdogmus et al., 200821
C
42
Mendes et al., 201322
C
24
Dias et al., 201523
C
46
0
15
3.45
25
10
2.54
23.27
14.05
-
57.4
SC
8.82
2.74
0
4.7
2.56±0.59
9.3±2.1
7.06±1.3
0
0
2.04±0.4
4.40±2.4
16.8±5.7
0
0
-
0.57±0.56
9.15±3.87
26
7
-
AC C
EP
TE D
C=cadaver; MR=magnetic resonance
RI PT
Study type
M AN U
Authors, year
16
ACCEPTED MANUSCRIPT Table 2. Incidence of lingual nerve injury Surgical method
Anesthesia
Bone removal method
LTMs (number)
Temporary LN injury (%)
Permanent LN injury (%)
Rud, 197040
PS
LST
L
C, D
718
0.83
0.14
Rood, 198341
PS
LST
G
C, D
1,400
6.64
0
Hochwald et al., 198342
PS
LST
L&G
C
Rud, 198443
PS
LST
G
C
Goldberg et al., 198544
PS
BA
L&G
D
Wofford and Miller, 198745
PS
BA
L
D
Mason, 198846
PS
BA+LF
G
C, D
Obiechina, 199047
PS
BA
Rood, 199248
PS
BA+LF LST
PS
BA+LF
Walters, 199550
PS
Robinson and Smith, 199651
PS
L
G
C, D
Moss and Wake, 199953
RS
AC C
Gargallo-Albiol et al., 200054
Benediktsdottir et al., 200455 Gomes et al., 200556
PS
0
609
3
0
500
0.6
0.2
576
0.71
0.17
747
8.3
0.4
293
19.8
1.02
367
0.27
0
406
3.2
2
384
12.8
0
791
1.9
0
LST
G
C
1,000
0.5
0
BA+LF
L&G
D
352
6.53
0.85
390
0.51
0.25
BA
L
D
504
0.2
0
LST
G
C
2,088
0.8
0
BA+LF
L
D
142
2.11
0
158
0.63
0
EP
PS
4.3
D
BA
Appiah-Anane and AppiahAnane199752
598
L
TE D
Schultze-Mosgua and Reich, 199349
M AN U
LST
RI PT
Study type
SC
Authors, year
BA
PS
BA
L
D
388
0.5
0
RCT
BA
L&G
D
55
0
0
55
9.1
0
BA+LF Jerjes et al., 200657
PS
BA
L
NS
1,087
5.52
1
Baquain et al., 201058
PS
BA
L
D
299
0.3
0
110
9.1
0
3,236
0.62
1.1
BA+LF Jerjes et al., 201059
PS
BA
L
17
NS
ACCEPTED MANUSCRIPT Janakiraman et al., 201060
PS
BA
Lata201161
PS
BA
L
CharanBabu et al., 201362
PS
BA
L
119
4.2
1.7
D
90
5.5
1.1
D
92
1.1
0
8
37.5
0
1,455
0.14
0.07
134
1.5
0
7,659
6.5
0
Smith, 201363
PS
BA
L&G
D
BA+LF
RI PT
BA+LF
RS
BA
G
D
Nguyen et al., 201465
RS
BA
L&G
D
10,160
0.069
0.079
Yadav et al., 201466
PS
BA
L
D
576
1.7
0.2
624
9.1
0.5
190
2.1
0.52
190
8.95
0
BA+LF RCT
BA BA+LF
L
NS
M AN U
Shad et al., 201567
SC
Guerrouani et al., 201364
AC C
EP
TE D
C=chisel; D=drill; PS=prospective study; G=general; L=local; BA=buccal approach; LF=lingual flap; LN=lingual nerve; NS=not specified; RS=retrospective study; LST=lingual split technique; LTMs=lower third molars; RCT=randomized controlled trial
18
ACCEPTED MANUSCRIPT
Table 3. Lingual nerve injury by tooth sectioning Total cases (number)
Cases with TS (%)
LN injury with TS (%)
LN injury without TS (%)
Baquain et al., 201058
426
27.5
5.7
1.3
Cheung et al., 201068
4,338
62
0.57
0.91
100
13
7.7
3.4
1,200
57.7
0.4
CharanBabu et al., 201362 Yadav et al., 201466
AC C
EP
TE D
M AN U
SC
LN=lingual nerve; TS=tooth sectioning
RI PT
Authors, year
19
0.2
ACCEPTED MANUSCRIPT Table 4. Lingual nerve damage by ostectomy Total cases (number)
Cases with O (%)
LN injury with O (%)
LN injury without O (%)
Mason, 198846
1,040
66
20.9
3.4
Baquain et al., 201058
443
68.6
3.6
0
Cheung et al., 201068
4,338
20
0.91
0.64
Yadav et al., 201466
1,200
93.5
0.3
AC C
EP
TE D
M AN U
SC
LN=lingual nerve; O=ostectomy
RI PT
Authors, year
20
0