The surgical plane for lingual tonsillectomy: an anatomic study


ORIGINAL RESEARCH ARTICLE Open Access

The surgical plane for lingual tonsillectomy:
an anatomic study
Eugene L. Son1*, Michael P. Underbrink1, Suimin Qiu2 and Vicente A. Resto1

Abstract

Background: The presence of a plane between the lingual tonsils and the underlying soft tissue has not been
confirmed. The objective of this study is to ascertain the presence and the characteristics about this plane for
surgical use.

Methods: Five cadaver heads were obtained for dissection of the lingual tonsils. Six permanent sections of previous
tongue base biopsies were reviewed. Robot assisted lingual tonsillectomy was performed using the dissection
technique from the cadaver dissection.

Results: In each of the 5 cadavers, an avascular plane was revealed deep to the lingual tonsils. Microscopic review
of the tongue base biopsies revealed a clear demarcation between the lingual tonsils and the underlying minor
salivary glands and muscle tissue. This area was relatively avascular. Using the technique described above, a lingual
tonsillectomy using TORS was performed with similar findings from the cadaver dissections.

Conclusions: A surgical plane for lingual tonsillectomy exists and may prove to have a role with lingual
tonsillectomy with TORS.

Keywords: Lingual tonsil, Surgical plane, Transoral robotic surgery, Lingual tonsillectomy

Background
The base of tongue had once been a difficult area for
surgery to perform on because of problems with expos-
ure. With new innovations in endoscope technology,
transoral laser microsurgery and transoral robotic sur-
gery (TORS) with the da Vinci Surgical System manufac-
tured by Intuitive Surgical, Inc., access to the tongue
base has been made more feasible. In the base of tongue,
the lingual tonsils are an important target for surgery.
There are two main indications for lingual tonsillectomy.
The first indication is lingual tonsil hypertrophy

(LTH), which can contribute to obstructive sleep apnea
(OSA) in pediatric and adult patients. LTH among other
functionally or fixed areas of obstruction in the upper
aerodigestive tract are targets for sleep surgery. In
pediatric patients, LTH can be primary or a secondary
following a tonsillectomy and adenoidectomy [1].
The second indication is for squamous cell carcinoma

of unknown primary (SCCUP) in the head and neck [2].

There has been an increase in the incidence of human
papilloma virus (HPV) related oropharyngeal squamous
cell carcinoma [3]. A large of number of SCCUP with
negative clinical and radiographical evidence of a pri-
mary tumor are most commonly found to have primar-
ies in the palatine and lingual tonsils. More recently,
performing palatine tonsillectomy and lingual tonsil-
lectomy has returned finding the primary tumor in
75–90 % allowing patients to receive a decreased amount
of radiation lessening side effects [3, 4].
Lingual tonsillectomy techniques include cold dissec-

tion, electrocautery, coblation, carbon dioxide (CO2)
laser and microdebrider [5–9]. Many of these methods
ablate or disrupt the microarchitecture of the lingual
tonsils. In SCCUP, carpet resection of the lingual tonsils
requires the desired tissue to be left intact for diagnosis
under a microscope by a pathologist. Lingual tonsillec-
tomy techniques have been described but no evidence of
a surgical plane of dissection is available. Some have de-
scribed the presence of a potential capsule and some
have stated there is none. Joseph et al. described a layer
of fibrous tissue that sometimes delineates this tissue

* Correspondence: eson85@gmail.com
1Department of Otolaryngology - Head and Neck Surgery, University of Texas
Medical Branch, 301 University Boulevard, Galveston, TX 77555, USA
Full list of author information is available at the end of the article

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Son et al. Journal of Otolaryngology - Head and Neck Surgery  (2016) 45:22 
DOI 10.1186/s40463-016-0137-3

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from the tongue but no definite capsule [10]. Multiple
authors in the early 20th century described a potential
plane as “a basement membrane analogous to the cap-
sule of the faucial tonsils” but not as delineated or devel-
oped as that tissue [11–14]. Dundar et al. describes the
lingual tonsil having no capsule [5]. Lin and Koltai in
their case series of coblation of lingual tonsillectomy in
26 pediatric patients describe no clear demarcation
between the lingual tonsils and the tongue muscula-
ture, although the change in tissue quantities becomes
readily apparent [1]. We believe that deep to the lin-
gual tonsils, a relatively avascular plane made up of
connective tissue exists. This potential surgical plane
may be utilized in lingual tonsillectomy for the afore-
mentioned indications.

Methods
This study was approved by the institutional review
board from the University of Texas Medical Branch. Five
fresh cadaveric heads were procured for the purpose of
this study. These cadavers were ages ranged from
86 years-old to 101 years-old including 2 females and 3
males.

Cadaver dissection
The tongue from 5 cadaver heads were removed. Five
complete dissections of the lingual tonsils were per-
formed with scissors and forceps. First, a midline inci-
sion is made from the foramen cecum to the vallecula.
An incision is also made immediately posterior to the
circumvallate papilla. The anterior medial edge of a
side of the lingual tonsils were grasped with forceps
and then, dissection with the Iris scissors was per-
formed in the lateral posterior direction until the lin-
gual tonsils were removed en bloc on each side.
Grossly, the muscle was identified as darker red in
color and striations present. The dissection is carried
to the border of the lateral pharyngeal wall and pos-
teriorly to the edge of the vallecula. Care was take to
remove the lymphoid tissue while keeping the underlying
muscle intact. Digital photography was performed during
the dissections.

Histological sectioning
Six archived permanent sections of base of tongue
biopsy specimens from the department of pathology
at University of Texas Medical Branch were reviewed.
Three cases with no malignancy detected and three cases
with dysplasia were chosen for recording of digital pho-
tography under magnification. These specimens were
from base of tongue biopsies from patients with SCCUP
and had been fixed in formalin, processed for paraffin em-
bedding and stained with hematoxylin and eosin. These

specimens were reviewed for histological characterization
of the lingual tonsils.

Robot-assisted lingual tonsillectomy
A 52 year old male with SCCUP in the left neck under-
went robot assisted lingual tonsillectomy as well as bilat-
eral palatine tonsillectomy. A Fehy-Kastenbauer mouth
gag was used for access to the tongue base. The da Vinci
Surgical System was brought into the surgical field with
visualization of the lingual tonsils. The 30-degree angled
endoscope was placed in the midline, and the two work-
ing robotic arms were placed in the appropriate position.
A Maryland dissector was used on the right arm and a
monopolar cautery hook was used on the left arm for
the left sided lingual tonsillectomy. The robot was then
used to assist taking the lingual tonsil tissue down to the
muscle layer, starting medially and dissecting laterally. A
midline incision is made from the foramen cecum to an-
terior to the median glossoepiglottic fold. An incision is
also made immediately posterior to the circumvallate pa-
pilla. The anterior medial edge of a side of the lingual
tonsils were grasped and dissection was performed in
the lateral posterior direction until the lingual tonsils
were removed as one specimen for each side. Care was
take to remove the lymphoid tissue keeping the under-
lying musculature intact. The specimens were then sent to
the pathology department for histological review.

Results and discussion
Cadaver dissection
In all five cadaver dissections, the plane between the lin-
gual tonsils and the underlying musculature was identi-
fied and used for excision of the lingual tonsils. There
was a plane of dissection easily separating the lingual
tonsils and the underlying tongue musculature. No
grossly visible vessels nor nerves were encountered dur-
ing the dissections (Fig. 1).

Fig. 1 Gross dissection of lingual tonsils is shown. Left image shows
the lingual tonsils before dissection and the right image shows the
lingual tonsils dissected and reflected posteriorly

Son et al. Journal of Otolaryngology - Head and Neck Surgery  (2016) 45:22 Page 2 of 5



Histological sectioning
In these biopsies of the lingual tonsils, there was a rela-
tively less vascular or avascular area between the lingual
tonsil and the underlying minor salivary glands and
muscle tissue in all cases (Figs. 2 and 3). Between the
lingual tonsil and the submucosal muscular tissue at the
base of the tongue a distinct space or line is demon-
strated in both benign (Fig. 2) and premalignant (Fig. 3)
cases. The space indicated by the drawn line is less vas-
cular or avascular, by which the squamous mucosa with
the lingual tonsil is distinct from the minor salivary
gland and the muscle. The minor salivary gland and
muscle is intimately admixed especially in the super-
ficial portion of the muscle. Presence of submucosal
edema (Fig. 2a) may exaggerate the space and pres-
ence of dysplasia associated with peritumoral lym-
phocytes infiltrate may obscure the space between
the lingual tonsil and the underlying muscle as
showed in Fig. 3c. However, in all conditions, dissection
between two layers are feasible based on histological
study.

Robot-assisted lingual tonsillectomy
The procedure was performed uneventfully. No grossly
visible vessels nor nerves were encountered during the
dissections (Fig. 4). The patient had a normal post-
operative course without any complications. Microscopic
examination of this specimen showed microscopic foci
of squamous cell carcinoma for which a random biopsy
of the base of tongue would have missed.
The palatine tonsils have a well-described plan separating

it from the surrounding oropharyngeal musculature. There

Fig. 2 Permanent sections of base of tongue biopsies with benign
pathology. Blue line demarcates surgical plane. Lingual tonsils (LT),
minor salivary gland tissue (MS), muscle (MU) are labeled. Presence
of submucosal edema exageratign plane in a compared to no
edema in b (hypervascular) and c

Fig. 3 Permanent sections of base of tongue biopsies with premalignant pathology. Blue line demarcates surgical plane. Lingual tonsils (LT), minor salivary
gland tissue (MS), muscle (MU) are labeled. Plane ispreserved in the presence of dysplasia in a and b (most defined plane). However, peritumoral
lymphocytes infiltrate obscure the space between the lingual tonsil and the underlying muscle in c

Son et al. Journal of Otolaryngology - Head and Neck Surgery  (2016) 45:22 Page 3 of 5



has been only speculation about the existence of a surgical
plane for the lingual tonsils, being only described anec-
dotally in the current literature. In our study, we show a
relatively avascular plane deep to the lingual tonsils in ca-
daver dissection, in histologic sections and in vivo.
In the five dissections performed, there was a space deep

to the tonsils that gave less resistance in the force of dissec-
tion. In Fig. 1, there a is an uneven layer deep to this plane
after dissection representing the minor salivary glands asso-
ciated with the muscle layer as seen in the histological
sections. In this plane, there were no grossly visible neuro-
vascular structures appreciated for all specimens. There
may be a feasible way for cold dissection of the tonsils using
direct visualization or with robot assistance with a potential
for decreased amount of cautery, minimal bleeding and
decreased post-operative morbidity. This plane may also be
utilized instead of ablative techniques such as in obstructive
sleep apnea in pediatric patients to prevent secondary
hypertrophy of the lingual tonsillar after tonsillectomy and
adenoidectomy for obstructive sleep apnea.
Decreased use of cautery for dissection and hemostasis

may provide better tissue diagnosis when lingual tonsil-
lectomy is performed for elucidation of a diagnosis of an
unknown head and neck primary tumor. In the case
described, the diagnosis was made using a carpet resec-
tion of the lingual tonsils using our technique. Random
biopsies of the base of tongue may miss a diagnosis
making the consequential treatment different.

Conclusions
The lingual tonsils have become more accessible in recent
times for surgical intervention for diagnostic and treat-
ment purposes. There is an avascular plane for dissection

deep to the lingual tonsils and superficial to the under-
lying minor salivary glands and lingual musculature. This
plane may be utilized in surgical resection in appropriate
patients to potentially decrease post-operative morbidity
and increase diagnostic yield. Further studies in human
subjects with this plane utilized will need to be performed
in the future.

Abbreviations
CO2: carbon dioxide; HPV: human papilloma virus; LTH: lingual tonsil
hypertrophy; OSA: obstructive sleep apnea; SCCUP: squamous cell carcinoma
of unknown primary; TORS: transoral robotic surgery.

Competing interests
The authors declare that they have no competing interests.

Authors’ contributions
ES performed the dissection, drafted and edited manuscript. MU performed
the surgery and edited the manuscript. SQ prepared and interpreted the
histology. VA conceived the study and edited the manuscript. All authors
read and approved the final manuscript.

Acknowledgement
No other acknowledgments.

Author details
1Department of Otolaryngology - Head and Neck Surgery, University of Texas
Medical Branch, 301 University Boulevard, Galveston, TX 77555, USA.
2Department of Pathology, University of Texas Medical Branch, 301 University
Boulevard, Galveston, TX 77555, USA.

Received: 6 January 2016 Accepted: 30 March 2016

References
1. Lin AC, Koltai PJ. Persistent pediatric obstructive sleep apnea and lingual

tonsillectomy. Otolaryngol Head Neck Surg. 2009;141:81–5.
2. Mehta V et al. A new paradigm for the diagnosis and management of

unknown primary tumors of the head and neck: A role for transoral robotic
surgery. Laryngoscope. 2013;123:146–51.

Fig. 4 Intra-operative photography of lingual tonsillectomy during TORS. Lingual tonsil is grasped and reflected posteriorly

Son et al. Journal of Otolaryngology - Head and Neck Surgery  (2016) 45:22 Page 4 of 5



3. Forastiere AA et al. HPV-associated head and neck cancer: a virus-related
cancer epidemic. Lancet Oncol. 2010;11:781–9.

4. Nagel TH et al. Transoral laser microsurgery for the unknown primary: Role
for lingual tonsillectomy. Head Neck. 2014;36(7):942–6.

5. Dundar A et al. Lingual tonsil hypertrophy producing obstructive sleep
apnea. Laryngoscope. 1996;106:1167–9.

6. Abdel-Aziz M et al. Lingual tonsils hypertrophy; a cause of obstructive sleep
apnea in children adenotonsillectomy: Operative problems and
management. Int J Pediatr Otorhinolaryngol. 2011;75:1127–31.

7. Robinson S et al. Lingual tonsillectomy using bipolar radiofrequency plasma
excision. Otolaryngol Head Neck Surg. 2006;134:328–30.

8. Bower CM. Lingual tonsillectomy. Oper Tech Otolaryngol. 2005;16:238–41.
9. Kluszynski BA, Matt BH. Lingual tonsillectomy in a child with obstructive

sleep apnea: a novel technique. Laryngoscope. 2006;116:668–9.
10. Joseph M, Reardon E, Goodman M. Lingual tonsillectomy: A treatment for

inflammatory lesions of the lingual tonsil. Laryngoscope. 1984;94:179–84.
11. Cohen HB. The lingual tonsils: General considerations and its neglect.

Laryngoscope. 1917;27:691–700.
12. Waugh JM. Lingual quinsy. Trans Am Acad Ophthalmol Otolaryngol.

1923;89:726–31.
13. Hoover WB. The treatment of the lingual tonsil and lateral pharyngeal

bands of lymphoid tissue. Surg Clin North Am. 1934;14:1257–69.
14. Elfman LK. Lingual tonsils. Laryngoscope. 1949;59:1016–25.

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Son et al. Journal of Otolaryngology - Head and Neck Surgery  (2016) 45:22 Page 5 of 5


	Abstract
	Background
	Methods
	Results
	Conclusions

	Background
	Methods
	Cadaver dissection
	Histological sectioning
	Robot-assisted lingual tonsillectomy

	Results and discussion
	Cadaver dissection
	Histological sectioning
	Robot-assisted lingual tonsillectomy

	Conclusions
	Abbreviations
	Competing interests
	Authors’ contributions
	Acknowledgement
	Author details
	References