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Craniomaxillofacial Trauma & Reconstruction is published by MDPI from Volume 18 Issue 1 (2025). Previous articles were published by another publisher in Open Access under a CC-BY (or CC-BY-NC-ND) licence, and they are hosted by MDPI on mdpi.com as a courtesy and upon agreement with Sage.
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Case Report

Injured Anterior Superior Alveolar Nerve Endoscopically Resected Within Maxillary Sinus

by
Amir H. Dorafshar
*,
A. Lee Dellon
,
Eric Lee Wan
,
Sashank Reddy
and
Victor W. Wong
Department of Plastic and Reconstructive Surgery, Johns Hopkins University School of Medicine, Baltimore, MD, USA
*
Author to whom correspondence should be addressed.
Craniomaxillofac. Trauma Reconstr. 2017, 10(3), 208-211; https://doi.org/10.1055/s-0036-1592088
Submission received: 2 February 2016 / Revised: 1 March 2016 / Accepted: 1 April 2016 / Published: 23 August 2016
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Abstract

:
Posttraumatic facial pain is due to an injured nerve, most often a branch of the trigeminal nerve. While surgical approaches to injuries of the supraorbital, supra-trochlear, infraorbital, and inferior alveolar nerves have been reported, an injury to the anterior superior alveolar nerve (ASAN) has not been reported. An algorithm is proposed for the diagnosis of injury to the ASAN versus the infraorbital nerve itself. A case is reported in which pain relief was achieved by dividing the ASAN within the maxillary sinus, leaving the proximal end exposed within the sinus at the level of the orbital floor.

Posttraumatic facial pain is most often due to an injured nerve, and usually this is a branch of the trigeminal nerve. Based on improving knowledge of the anatomical pathways [1,2,3,4], surgical approaches to the supraorbital/supratrochlear [5,6,7,8], infraorbital [6,9,10,11], and inferior alveolar nerves have been reported [12,13,14]. These surgeries have included neurolysis, neuroma resection, and nerve reconstruction. To our knowledge, an injury to the anterior superior alveolar nerve (ASAN) has not been reported, and indeed, the anatomic pathway of the ASAN has only recently been well described [15,16]. Here, we report an endoscopic transantral approach to ASAN neurectomy that is not a Le Fort I osteotomy. An algorithm for diagnosis is formulated based on nerve blocks and quantitative sensory testing to distinguish between an ASAN injury and an injury to the infraorbital nerve.

Case Report

A 52-year-old man presented with 15 years of intense burning pain in the gingiva overlying the left central and lateral maxillary incisors, teeth numbers 9 and 10 (Figure 1). He previously underwent an extensive array of procedures that all failed to relieve his pain. These included two posterior fossa microsurgical decompressions of the trigeminal nerve, “gamma knife” treatment, and a peripheral nerve stimulator placed alongside the infraorbital nerve for “atypical facial pain.” He also had root canal treatments to teeth numbers 9 and 10, and these teeth were subsequently extracted in an attempt to relieve the pain.
Deeper questioning elicited a history of a sport-related injury (high-school level football) with a football helmet striking the left cheek. CT imaging demonstrated an old injury to the left canalis sinuosis (Figure 2), the bony canal within the medial maxillary wall that houses the ASAN along its course from the infraorbital nerve to the anterior maxillary teeth. The sensation of the upper lip was normal. A local anesthetic block of the ASAN gave complete pain relief, confirming a diagnosis of neuroma of the ASAN.
At surgery, the ASAN was identified through a transantral approach. The portion of the ASAN in the horizontal position and entering the canalis sinuosis was translucent and without bands of Fontana, whereas the ASAN more proximally, just after leaving the infraorbital nerve, had a normal appearance (Figure 3). The bands of Fontana are an indicator of the pathophysiological condition of the nerve. The banding pattern frequently is not present during compression injuries to nerves [17,18,19]. It was elected to resect a portion of the damaged nerve, and leave the proximal end to regenerate into the maxillary sinus.

Operative Technique

The patient was placed in a supine position following nasoendotracheal intubation and prepped and draped in the standard sterile condition. Lidocaine 1% with 1:100,000 epinephrine solution was infiltrated into the left gingiva-buccal sulcus. A sublabial incision was performed. A subperiosteal dissection proceeded to identify the left infraorbital nerve. At the infraorbital nerve foramen, a branch of the infraorbital nerve, believed to be the ASAN, was visualized (Figure 3). The nerve was dissected distally into the maxillary bone to confirm the ASAN had been correctly identified (Figure 4). A maxillary antrostomy (Caldwell-Luc) was performed under the infraorbital nerve. While visualizing the infraorbital nerve using an endoscope, an osteotome was used to carefully release the infraorbital nerve from its bony foramen into the maxillary sinus. The ASAN could be seen directly branching from the infraorbital nerve. The nerve was divided at its take off from the infraorbital nerve and the proximal end was placed into the maxillary sinus. A distal segment of the nerve was sent for histopathological diagnosis, which confirmed resection of the ASAN. The incision was next closed in the standard fashion after replacing the maxillary bone pieces back into the maxillary antrostomy site as free bone grafts. The patient was observed overnight and sent home the following day without complication. Relief from the original pain was immediately achieved following resection of the ASAN. The patient, now 4 months out of surgery, no longer suffers from the original pain.

Discussion

For a person to have symptoms due to isolated injury to the ASAN, other branches of the infraorbital nerve must be without symptoms. A history from the patient should include ipsilateral pain only in the labial gingiva about the central and lateral maxillary incisors. Gingival pain further lateral toward the bicuspids and molars must include branches of the medial and posterior superior alveolar nerve, while gingival pain involving the buccal gingiva must include branches of the greater palatine nerve. The most important diagnostic approach is to do a local anesthetic block of the nerves, the techniques for which are well described [20,21,22].
Documentation of infraorbital, nerve-innervated skin involvement with nerve injury can be done with quantitative sensory testing, and has also been well described [9,23,24,25]. Normal neurosensory testing of the upper lip, with a positive response to local anesthetic block of the ASAN, documents injury to the ASAN branch of the infraorbital nerve, and suggests the location of the nerve injury in the region found in the patient in the case reported here. Temporary pain relief was achieved through local blocks into the upper left gingival region of the central incision.
An algorithm for the management of facial pain due to an injury to the trigeminal nerve was suggested by Rosson et al. in 2010 [11]. That algorithm relies on first treating the patient with medical management, then consideration of which trigeminal nerve branch is involved by the history and anatomic location of the pain, then documentation of the involved branch by quantitative sensory testing, and finally confirming that role of that branch by local anesthetic nerve block. This is the approach used in the patient presented here, and which we suggest for future facial pain patients.

References

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Figure 1. Site of pain, in the gingiva of the left central and lateral incisor.
Figure 1. Site of pain, in the gingiva of the left central and lateral incisor.
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Figure 2. CT coronal image demonstrating normal canalis sinuosis (yellow arrow) on the right with damaged canalis sinuosis on the left.
Figure 2. CT coronal image demonstrating normal canalis sinuosis (yellow arrow) on the right with damaged canalis sinuosis on the left.
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Figure 3. Intraoperative views: (a) incision in the left upper lip sulcus, with first view of the anterior superior alveolar nerve (ASAN) exiting inferior to the infraorbital nerve following maxillary antrotomy. (b) Antrotomy view of the ASAN in its horizontal course, being held by a nerve hook. (c) Brilliant green dye marking the anatomic pathway of the ASAN from the antrum to the tooth origins.
Figure 3. Intraoperative views: (a) incision in the left upper lip sulcus, with first view of the anterior superior alveolar nerve (ASAN) exiting inferior to the infraorbital nerve following maxillary antrotomy. (b) Antrotomy view of the ASAN in its horizontal course, being held by a nerve hook. (c) Brilliant green dye marking the anatomic pathway of the ASAN from the antrum to the tooth origins.
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Figure 4. Schematic showing the surgical plan and anatomic course of anterior superior alveolar nerve in yellow.
Figure 4. Schematic showing the surgical plan and anatomic course of anterior superior alveolar nerve in yellow.
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MDPI and ACS Style

Dorafshar, A.H.; Dellon, A.L.; Wan, E.L.; Reddy, S.; Wong, V.W. Injured Anterior Superior Alveolar Nerve Endoscopically Resected Within Maxillary Sinus. Craniomaxillofac. Trauma Reconstr. 2017, 10, 208-211. https://doi.org/10.1055/s-0036-1592088

AMA Style

Dorafshar AH, Dellon AL, Wan EL, Reddy S, Wong VW. Injured Anterior Superior Alveolar Nerve Endoscopically Resected Within Maxillary Sinus. Craniomaxillofacial Trauma & Reconstruction. 2017; 10(3):208-211. https://doi.org/10.1055/s-0036-1592088

Chicago/Turabian Style

Dorafshar, Amir H., A. Lee Dellon, Eric Lee Wan, Sashank Reddy, and Victor W. Wong. 2017. "Injured Anterior Superior Alveolar Nerve Endoscopically Resected Within Maxillary Sinus" Craniomaxillofacial Trauma & Reconstruction 10, no. 3: 208-211. https://doi.org/10.1055/s-0036-1592088

APA Style

Dorafshar, A. H., Dellon, A. L., Wan, E. L., Reddy, S., & Wong, V. W. (2017). Injured Anterior Superior Alveolar Nerve Endoscopically Resected Within Maxillary Sinus. Craniomaxillofacial Trauma & Reconstruction, 10(3), 208-211. https://doi.org/10.1055/s-0036-1592088

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