Sentinel Lymph Node Centered Selective Neck Dissection Does Not Have Benefits Over Supraomohyoid Neck Dissection in Patients with cT1T2N0 Tongue Cancer

Young Ju Jin; J. Hun Hah

doi:10.3342/kjorl-hns.2018.00269

Abstract

Background and Objectives

This study aimed to evaluate the clinical efficacy of sentinel node centered selective neck dissection in patients with early stage tongue cancer (T1T2N0).

Subjects and Method

Lymphoscintigraphy was performed for 12 patients, subsequently followed by sentinel node centered selective neck dissection. The location of the sentinel node, pathological confirmation of node metastasis, and follow-up recurrence were analyzed.

Results

In total, 19 sentinel lymph nodes were identified. Of these, 18 were located in levels I to III, and one in level IV. After surgery, 3 patients (25%) were diagnosed with neck node metastasis: two experienced sentinel node metastasis and one experienced skipped metastasis. During follow-up, 3 of the 12 patients (25%) experienced recurrence.

Conclusion

The recurrence of lymph node could be covered with supraomohyoid neck dissection, which indicates that it has superiority over sentinel node centered selective neck dissection in preventing recurrence in T1T2N0 tongue cancer patients.

Key words: Lymphoscintigraphy ㆍ Neck dissection ㆍ Sentinel lymph node ㆍ Tongue cancer

Introduction

Patients with early stage tongue cancer (T1T2N0) experience satisfactory treatment outcomes, with reported 5-year survival rates ranging from 75% to 86% [1,2]. Cervical lymph node metastasis is the most significant prognostic factor in squamous cell cancer of the oral cavity. However, diagnostic modalities, such as computed tomography, magnetic resonance imaging, positron emission tomography, and ultrasonography, are not sufficiently sensitive to detect lymph nodes ＜2 mm thick [known as micrometastasis (0.2-2 mm)], and isolated tumor cells ＜0.2 mm [3]. Consequently, the rate of occult metastasis has been reported to be approximately 10% to 42% [1,4,5]. Generally, tumor thicknesses ＞4 mm, tumor size ＞2 cm, or the presence of vascular and perineural invasion, are associated with an increased risk for cervical lymph node metastasis.

Much debate surrounds neck surgery in cN0 tongue cancer patients including treatment versus observation, the extent of elective neck dissection (END), and the availability of sentinel lymph node biopsy (SLNB). Presently, END is considered to be a superior to observation, with better overall survival and disease-free survival rates, and a lower nodal recurrence rate with minimal complications [6-8]. However, END in N0 patients remains controversial due little evidence of different survival benefit, and complications such as scar formation, numbness in the neck, wound infection, chyle leakage, and shoulder syndromes from spinal accessory nerve damage [9,10]. Although consensus regarding the extent of END, especially considering levels IIb and IV, has yet to be reached, supraomohyoid neck dissection (SOND) remains preferred by surgeons [11-13]. The past decade, however, emerging evidence supporting the efficacy of SLNB has reported [14,15]. Benefits of SLNB include the avoidance of END-related morbidity, and decrease costs because END is performed in SLNB-positive patients only. However, the primary concern about SLNB is the possibility of false-negative diagnoses, multiple sentinel lymph nodes due to the variability of neck anatomy, ‘shine-through’ effect, and variable sensitivity depending on hospital facility and surgeon experience [16,17].

In this study, we evaluated the clinical efficacy of sentinel lymph node centered neck dissection (SCND) in patients with cT1T2N0 tongue cancer.

Subjects and Method

Twelve patients with a diagnosis of early tongue cancer (cT1T2N0) were recruited for this study from October 2012 to June 2015. All patients underwent preoperative lymphoscintigraphy in the morning of operation after the injection of 0.1 mL Tc-99m-antimony sulfur colloid into the intradermal space at a selected site surrounding the tumor (Fig. 1A) [18]. Subsequently, locations of the lymphoscintigraphy ‘hot spots’ were marked on the skin (Fig. 1B). All surgeries were performed by a single surgeon (J.H.H). At the beginning of the operation, the sentinel lymph nodes were identified using a hand-held gamma probe and marked again (Fig. 1C). After excision of the primary tongue lesion, the sentinel lymph nodes were dissected and sent for the frozen biopsy. SCND was performed instead of SOND to evaluate the utility of identifying sentinel lymph nodes. Primary tumors were excised using a clear margin 5 mm above the lateral mucosal area, and 10 mm above the medial and inferior muscle areas.

The medical records were reviewed retrospectively and the study protocol was approved by the Institutional Review Board of the authors’ institution (SNUH IRB No. H-1611-026-805). Demographic characteristics, pathology results, locations of sentinel node, and survival data were analyzed.

Results

Twelve patients (female=2, male=10; mean age=55.7 years, range=25 to 79 years) with cT1T2N0 tongue cancer underwent lymphoscintigraphy to identify sentinel lymph nodes. Tumor stages were as follows: T1, 83.3% (n=10); and T2, 16.6% (n=2). The depth of invasion was reported from final pathology results: ≤4 mm, 25% (n=3); ＞4 mm, ≤6 mm, 25% (n=3); and ＞6 mm, 50% (n=6). The depth of invasion in recurred patients was ＞6 mm (Table 1).

Nineteen sentinel nodes were identified among the 12 patients using an intra-operative gamma probe (Fig. 1C). There were 18 sentinel nodes in levels I to III, and one sentinel node was identified in level IV (Table 2). In the final pathology report, 3 patients resulted with neck node metastasis. Two patients experienced sentinel node metastasis (left level III, right level III) and one patient experienced node metastasis from the other side (not the sentinel node, level Ia), which was diagnosed as skipped metastasis (Table 3). During follow-up, 3 of the 12 patients who underwent SCND experienced recurrence. Recurrence was detected in a median period of 8.5 months after operation. All recurrence nodes were found in levels I to III where could be treated with SOND (Table 4).

Discussion

Perilymphatic invasion and tumor thickness are widely accepted risk factors for neck node metastasis [19]. In the pathological analysis of 66 cN0 patients, Tsushima, et al. [18] reported that the probability of nodal metastasis is increased in patients with tumor thicknesses ≥6 mm (48%) compared with tumor thicknesses ＜6 mm (20%).

In our study, 50% (n=3) of patients experienced regional recurrence among those with a tumor thickness ＞6 mm (n=6). All regionally recurred patients had a tumor thickness ＞6 mm (n=3) (Table 1). Despite the limitation of the small number of patients, similar to other published reports, tumor thickness is considered as a risk factor for regional recurrence.

SOND and SCND can be selected for neck surgery in patients with early stage tongue cancer, N0 patients. SOND has been accepted as the standard neck operation because occult neck metastasis in cN0 necks is common in levels I to III, but not levels IV and V [20]. In our study, all recurrence nodes were found in levels I to III, supporting the superiority of SOND (Table 4). However, there are studies describing the superiority of SLNB for T1-2 N0 oral cavity cancer. An article by The American College of Surgeons Oncology Group reported that SLNB correctly identified lymph node metastasis in 100% of cases of T1 oral cancer (52 patients) and had a negative predictive value of 96% for T1T2N0 (100 patients) [17].

However, the sentinel node can be multiple and difficult to identify due to small size, and radiotherapy may lead to limitations in accurately localizing the node [16,17]. In one case, sentinel lymph node was identified opposite side to tongue cancer. However, the neck nodes ultimately recurred on the same side. Therefore, the uncertainty of lymphoscintigraphy results may lead to increased false-positive rates of sentinel lymph nodes.

To evaluate the clinical efficacy of SCND, we reviewed the three cases of recurrence (Table 4). In Case A, the sentinel node was found at the left level III; accordingly, SCND was performed over left level II to IV. However, recurrence was found in left level Ib 7.5 months later. If SOND was performed, the left level Ib lymph node would have been removed and recurrence could have been avoided. In Case B, the sentinel node was found in right level III, and the right level II to IV lymph nodes were removed. During follow-up, recurrence was found in right levels Ib and IIa, near the hyoid bone at 8.5 months. If we performed SOND, right level Ib and IIa would have been covered. In Case C, the sentinel nodes were identified in left levels Ib and II. However, recurrence was found in right level III. Considering the primary tumor site was on the right, SOND could have prevented the level III recurrence on the right side. These particular cases show that SOND is superior to SCND in preventing recurrence in T1T2N0 tongue cancer patients.

In conclusion, Despite the limitation of small sample size in the present study, our data strongly suggest two points. First, tumor thickness ＞6 mm increases the risk for regional recurrence. Second, SCND based on sentinel lymph node detection has poorer performance than SOND, which is currently the standard END for T1-2, N0 oral cavity cancer patients. SCND is not only more complicated than SOND, it is inferior in terms of oncological safety.

Fig. 1.

Right tongue cancer (cT1N0) patient. Lymphangiography was taken in the morning of operation (A). Locations of ‘hot spots’ were marked on the skin (B). At the operation field, the sentinel lymph nodes were identified again using a hand-held gamma probe and marked again (C).

Table 1.

Demographic characteristics of the patients (n=12)

Characteristics	cN0 (n=12)	pN1 (n=3)	Recurred patient (n=3)
Mean age (range), year	55.7 (25-79)	60 (37-79)	43 (25-67)
Sex
Male	10	3	3
Female	2	-	-
Site of tongue cancer
Right	6	2	2
Left	6	1	1
Tumor stage
T1	10	1	2
T2	2	2	1
Final pathology result, depth of invasion, mm
≤4	3	-	-
4＜, ≤6	3	1	-
＞6	6	2	3

Table 2.

The location of identified sentinel lymph node (patients, n=12)

SLN location	SLN number (n=19)
Level I	9
Level II	4
Level III	5
Level IV	1

SLN: sentinel lymph node

Table 3.

Comparison between preoperative SLN and pathologically proven metastasis site after SCND

Characteristics	SLN site before SCND	LN metastasis site after SCND (positive LN/ total dissected LN)
pN1 (n=3)
	Lt Ib, II	Ia (1/44)
	Lt III	Lt III (1/16)
	Rt III	Rt II, III (2/22)

SLN: sentinel lymph node, LN: lymph node, SCND: sentinel lymph node centered selective neck dissection, pN: pathologically proven lymphnode metastasis

Table 4.

Three cases of recurrence

Recurred patient	Case A	Case B	Case C
Tumor side, stage	Lt T1 N0	Rt T1 N0	Rt T2 N1
Disease free survival, month	7.5	8.5	18.5
Sentinel LN site	Lt III	Rt III	Lt Ib,II
SCND	Lt II, III, IV	Rt II, III, IV	Lt Ia, Ib, II, III
			Rt Ib, II, III
Recurred LN	Lt Ib	Rt Ib, IIa	Rt III
Adjuvant therapy	PORT	PORT	PORT → Chemotherapy

LN: lymph node, SCND: sentinel lymph node centered neck dissection, PORT: postoperative radiation therapy

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