1. Introduction
After the strap muscles, the recurrent laryngeal nerve (RLN) is the second most common structure invaded by primary or metastatic thyroid cancer [
1]. RLN paralysis (RLNP) can cause persistent breathy hoarseness, shortening of phonation, and aspiration, which adversely affects patient quality of life [
2,
3]. Therefore, in thyroid cancer patients with preoperatively functional vocal folds (VF), first, sharp tumor resection from the RLN should be considered to maintain good voice and VF mobility with oncological safety [
4,
5,
6,
7,
8]. When it is difficult to preserve the RLN during complete removal of the thyroid cancer, it is desirable to adopt the RLN reconstruction procedure simultaneously during thyroid surgeries [
9,
10,
11,
12,
13]. Restoration of the muscle bulk and tension due to nerve reinnervation leads to excellent vocal outcomes. Some methods for RLN reconstruction have been reported, including direct RLN anastomosis [
14,
15], graft interposition between the dissected edges of the RLN [
16], and ansa cervicalis nerve (ACN) to RLN anastomosis [
17,
18]. When RLN reconstruction is difficult, phonosurgeries, such as thyroplasty type I [
19,
20], arytenoid adduction (AA) [
21], VF injection augmentation [
22], or nerve muscle pedicle (NMP) transplantation [
23,
24,
25,
26,
27,
28], should be considered. NMP transplantation is a method to induce reinnervation of the laryngeal muscle with implantation of other muscle nerve branches to the laryngeal muscle directly.
However, there are few reports describing the optimal procedure for maintaining vocal function in patients with unilateral RLN involvement in thyroid cancer. In the present study, various parameters of vocal function were analyzed to establish the optimal management of thyroid cancer patients with unilateral RLN involvement.
2. Materials and Methods
During a 17-year period from 2000 through 2016, we managed 80 patients with unilateral RLN involvement by thyroid cancer at Kumamoto University Hospital, Kumamoto, Japan, which is the tertiary oncology referral center in the area. Written informed consent was obtained from all patients. This research was approved by the ethical committee for medical and health research involving human subjects at Kumamoto University Hospital (No. 2338). Of the 80 patients, 15 were men (19%) and 65 women (81%), and they were aged 35–79 years (median age, 58 years). Of the 80 patients, 11 with preoperatively functional VF underwent preservation of the RLN involved in thyroid cancer using sharp dissection (shaving group). Thirty-three patients underwent immediate RLN reconstruction after resection of the RLN during thyroid cancer surgery (reconstruction group). The reconstruction group was further divided into two subgroups based on their preoperative VF mobility. Patients with preoperatively functional VF who needed RLN resection and reconstruction were named the normal-reconstruction subgroup (
n = 12), and those with preoperatively paralyzed VF who underwent RLN resection and reconstruction were referred to as the paralyzed-reconstruction subgroup (
n = 21). For the RLN reconstruction procedure, we selected direct RLN anastomosis (direct anastomosis,
n = 4), graft interposition between the dissected edges of the RLN (nerve interposition,
n = 12), and ACN to RLN anastomosis (nerve transfer,
n = 17). The remaining 36 patients underwent phonosurgeries to persistent unilateral RLNP for some time after thyroid surgery (phonosurgery group). This group included patients who underwent thyroid surgery at other hospitals. The procedures adopted for the 36 patients included NMP implantation with AA (
n = 20), and AA with or without thyroplasty type I (
n = 16).
Table 1 summarizes the characteristics of all patients in this study.
Our treatment strategies were as follows. When preoperative VF mobility was normal, we first tried to preserve the RLN involved in thyroid cancer with sharp dissection, which we called the ‘shaving technique’, according to Japanese guidelines for the treatment of thyroid tumor. The tumor was carefully shaved from the RLN using a scalpel under magnification. In cases with signs of invasion into the nerve fiber, such as color alteration, or when the entire circumference of the nerve was surrounded by the tumor, the RLN was extirpated together with the tumor, and RLN reconstruction procedures were performed immediately if it was possible to use the distal stump of the resected RLN, as suggested by Japanese guidelines. If the tumor invaded the RLN at the peripheral portion, and it was difficult to secure adequate nerve length for the reconstruction procedure, we divided the inferior pharyngeal constrictor muscle along the lateral edge of the thyroid cartilage before resecting the nerve to identify it under the muscle [
29]. In cases where the tumor invaded more of the peripheral portion of the RLN, we dissected the inferior horn or lateral plane of the thyroid cartilage to identify the nerve located by the side of the thyroid cartilage (
Figure 1a,b). With regard to the RLN reconstruction procedure, we first attempted direct anastomosis if this was possible (direct anastomosis,
Figure 2a). When the length of the resected RLN was too long to perform direct anastomosis, free nerve graft implantation between the dissected edges (nerve interposition:
Figure 2b) or ACN to RLN anastomosis (nerve transfer:
Figure 2c) were performed. The nerve graft for interposition was usually acquired from the great auricular nerve or the ACN. When nerve transfer was performed, the ACN was identified at the surface of the internal jugular vein, and its branches to the sternohyoid (SH) muscles were dissected. The major branch, or usually the common branch to these branches, was transected, and the proximal edge was anastomosed to the distal stump of the RLN. In cases where the simultaneous reconstruction of the RLN was difficult because the proximal stumps of the RLN could not be utilized for nerve reconstruction due to extensive tumor infiltration, we considered phonosurgery to persistent unilateral RLNP later, while holding discussions with the patients. Similarly, in cases where excision of the RLN had been performed at other hospitals, we generally chose phonosurgery rather than nerve reconstruction procedures, because it may have been difficult to detect the resected peripheral edge of the RLN, and preservation of CAN was uncertain. For phonosurgery, we first performed NMP with AA under general anesthesia, as previously reported [
24] (
Figure 3). If it was difficult to use ACN branches for the NMP procedure or if the patients could not undergo general anesthesia for a general condition, we applied AA with or without thyroplasty type I (
Figure 4a,b). We performed the operation under local anesthesia to finely tune the procedures by hearing the patient’s voice. During these surgical procedures, we use a neuromonitoring system to identify nerves and confirm the function.
In this study, we assessed vocal function using aerodynamic, acoustic, and perceptual analyses. The patients were asked to undergo vocal function tests preoperatively and at three different postoperative periods: 1, 6, and 12 months after surgery.
2.1. Aerodynamic Analysis
For aerodynamic analyses, patients were instructed to produce sustained phonation of the vowel /a/ for as long as possible at a comfortable pitch and loudness. The maximum phonation time (MPT) was measured twice for each patient using a stopwatch, and the greater value was recorded. The mean airflow rate (MFR) was measured using a phonatory function analyzer (PS-77E; Nagashima, Tokyo, Japan). Patients were instructed to produce the vowel /a/ at a comfortable pitch and loudness while keeping a mouthpiece around the lips and wearing a nose clip.
2.2. Acoustic Analysis
Acoustic analysis was conducted using the Multi-Dimensional Voice Program Model 5105 (version 3.1.7; Kay Elemetrics, Lincoln Park, NJ, USA). The vowel segment was cut from the complete voice sample, and 0.5–1 s from a stable portion of the vowel was trimmed and analyzed. The acoustic parameters included jitter (normal, <1.04%), shimmer (normal, <3.81%), and noise-to-harmonics ratio (NHR; normal, >7.2 dB). The NHR was converted into harmonics-to-noise (HNR) using the equation HNR = 10 × log
10 (1/NHR) [
31].
2.3. Perceptual Analysis
For perceptual analysis, patient voices were recorded in a sound-treated room using a digital recorder (Model PMD 670; Marantz, Sagamihara, Japan) connected to a microphone (Model WM-421; Panasonic, Yokohama, Japan). The microphone was held 20 cm away from the mouth during the recordings. Recording samples included name, date, and standard text in Japanese, and sustained phonation of the vowel /a/ at a comfortable pitch and loudness. The voice was digitized at 45 kHz through an antialiasing filter and stored in a pulse modulation format. The speech segments of the recordings were used for auditory perceptual analysis. All speech samples were anonymized before assessment according to the Grade overall-Roughness-Breathiness-Asthenia-Strain voice scale (GRBAS) [
32] to prevent any possible bias. Three different listeners assessed the randomly arranged recordings (one laryngologist and two speech pathologists). The mean values of grade (G) and breathiness (B) scores assigned by the three judges using a four-point scale (0 = normal, 1 = slight disturbance, 2 = moderate disturbance, 3 = severe disturbance) were calculated, because unilateral RLNP causes breathy hoarseness.
2.4. Statistical Analysis
In this study, we compared vocal outcomes between the evaluation periods in the same group and among different groups. First, the time-dependent vocal function was analyzed in each group. Among the reconstruction group, the difference in vocal function between the normal-reconstruction subgroup (n = 12) and the paralyzed-reconstruction subgroup (n = 21) was evaluated. Additionally, in the paralyzed reconstruction subgroup, we compared vocal function between the different reconstruction methods (nerve transfer (n = 13) vs. nerve interposition (n = 8)) and the patient age (under 65 years old (n = 11) vs. over 65 years (n = 10)). Patients who underwent direct anastomosis of the resected RLN were excluded from the analysis due to preoperative normal VF mobility. The vocal function in the normal-reconstruction subgroup (n = 12) was compared with that in the shaving group (n = 11), and the paralyzed-reconstruction group (n = 21) was compared with that of the phonosurgery group (n = 36). All measurements are shown as the mean ± standard deviation. The Mann–Whitney U-test was used for statistical analysis (StatView 5.0 for, SAS Institute, Cary, NC, USA). For all parameters, statistical significance was set at p < 0.05.
4. Discussion
During the management of RLN involvement in thyroid cancer, proper methods must be selected depending on the situation. The vocal outcomes after the shaving technique in this study showed excellent results, that is, aerodynamic parameters were in the normal range and acoustic and perceptual parameters reached near-normal levels. The advantages of the shaving technique include not only good vocal function, but also a high frequency of preservation of VF mobility with excellent oncological safety [
4,
5,
6,
7,
8]. The restoration of VF mobility after the shaving technique has been reported to range between 60–92% [
4,
6,
7,
8]. Similarly, in our study, VF mobility was preserved in 10 (91%) of 11 patients. However, once the RLN had been resected, even after the administration of the immediate RLN reconstruction method, VF mobility was never recovered. This is because a certain degree of misalignment between the adductor and abductor nerve fibers may have occurred.
When the shaving technique is difficult due to severe tumor invasion to the RLN, an immediate RLN reconstruction procedure should be performed simultaneously. In this study, compared with the shaving group, there were no significant differences in any of the parameters in the reconstruction group. RLN reconstruction surgery induces nerve reinnervation of the laryngeal muscles, resulting in the prevention of progressive loss of muscle tone and bulk. Additionally, the position of the paralyzed VF was improved due to laryngeal muscle reinnervation. Iwaki et al. [
33] evaluated pre-and postoperative VF positions in patients who underwent immediate RLN reconstruction surgery for unilateral RLNP caused by thyroid cancer. The paralyzed VF was fixed in the paramedian position preoperatively. On the other hand, in many patients who had their RLN previously resected, the VF was fixed in the abducted position. The RLN damaged by thyroid cancer may not be completely denervated and can still stimulate the laryngeal muscles. Because the ratio of adductor to abductor motor axons of the RLN is 4:1 [
34], a partially paralyzed VF may be adducted and fixed in the paramedian position. After laryngeal reinnervation procedures, because reinnervation of the laryngeal muscle is achieved, the position of the VFs shift to the median or paramedian position even after RLN resection [
35,
36]. In this study, most parameters were improved significantly at 6 months postoperatively compared with the preoperative data. This means that reinnervation of the laryngeal muscle will be achieved 6 months after the operation.
Concerning the difference in RLN reconstruction methods, a previous animal study indicated that direct RLN anastomosis showed the best performance both histologically and physiologically [
37]. In a clinical study, Miyauchi et al. [
38] and Yoshioka et al. [
39] reported that the vocal outcome of immediate RLN reconstruction after thyroid cancer surgery was not reflected by surgical methods. They compared vocal outcomes between direct anastomosis, nerve interposition, nerve transfer, and vagus to RLN anastomosis using MPT or phonation efficiency index (MPT/vital capacity). In this study, there were significant differences in some parameters at 1 month after surgery between nerve interposition and nerve transfer. However, significant differences in these parameters also existed preoperatively and they disappeared at 6 months or later. It is too early to induce nerve reinnervation of the laryngeal muscles at 1 month after surgery with the RLN reconstruction procedure; the differences would be influenced by the patient backgrounds between the two groups. Additionally, the vocal outcomes after the immediate RLN reconstruction procedure were not affected by patient age or preoperative RLNP in this study. These results are similar to those shown in previous reports [
38,
39]. Therefore, surgeons should select the easiest and most appropriate methods for RLN reconstruction.
If it is impossible to carry out the RLN reconstruction method simultaneously during thyroid cancer surgery, we have to perform phonosurgery later as a secondary procedure. In this study, all evaluated parameters in the phonosurgery group were improved significantly immediately after surgery. In the comparison between immediate RLN reconstruction and phonosurgeries, several parameters were significantly better in the phonosurgery group than in the reconstruction group at 1 month. This phenomenon could be attributed to the effects of VF adduction by AA and/or thyroplasty type I. On the other hand, at 6 and 12 months after surgery, some parameters in the reconstruction group were significantly better than those in the phonosurgery group. Improved muscle tension and VF position due to laryngeal muscle reinnervation led to these results. Regarding AA and thyroplasty type I, vocal function was improved by shifting the paralyzed VF medially (
Figure 4). Therefore, we cannot prevent muscle atrophy and flaccidity with time by these surgeries, and the long-term vocal outcome is inconsistent. Although there are some reports on the effectiveness of RLN reconstruction procedures in patients who have previously undergone thyroid cancer surgery with RLN resection [
40], the peripheral stump of the RLN may be buried in the cicatricial tissue and be difficult to reach for reconstruction. NMP transplantation is a method of inducing laryngeal muscle reinnervation with implantation of a nerve-muscle pedicle directly into the laryngeal muscle (
Figure 3). We usually adopt NMP for RLNP caused by the previous thyroid cancer surgery. In our previous study on various causes of unilateral persistent RLNP, the effectiveness of NMP methods was improved gradually over long periods, and some parameters of NMP with AA were better than those of AA with or without thyroplasty type I at 24 months after surgery [
26].
The limitations of this study were the small number of patients and the inconsistency of patient ages and sexes. Some parameters of vocal function are easily influenced by age and sex [
41,
42]. Therefore, further studies including sufficient number of patients who are age- and sex-matched are necessary.