Malignant Tonsil Tumor Surgery
- Author: Niels Kokot, MD; Chief Editor: Arlen D Meyers, MD, MBA
Background
Head
and neck squamous cell carcinoma (HNSCC) is the sixth most common malignancy
worldwide, with over 40,000 new cases per year in the US. Of all primary
HNSCCs, oropharyngeal carcinomas are the third most common, with the tonsil
being the most common site of malignancy within the oropharynx.
Historically,
the standard treatment of tonsil cancer has consisted of surgery with or
without adjuvant radiotherapy. Given the important role the oropharynx plays in
speech and swallowing, nonsurgical therapy with organ-preserving chemoradiation
has gained a role in the treatment of tonsil carcinoma in attempts to avoid the
morbidity of surgery. However, organ-preserving chemoradiation is not without
its own morbidity. Additionally, minimally invasive transoral surgical
techniques have become more widespread in the treatment of tonsillar carcinoma and
may decrease the morbidity associated with surgical therapy. As such, the
optimal treatment of tonsillar carcinoma is debated among head and neck
oncologists.
This
article will detail the frequency, etiology, and work-up of tonsillar squamous
cell carcinoma (SCC). It will then focus on the surgical treatment of tonsillar
SCC.
History Of The Procedure
Historically,
the mainstay of treatment for tonsillar SCC has consisted of open surgery, neck dissection, and tracheostomy, with or without adjuvant
radiotherapy. Typical open approaches include a lip-splitting mandibulotomy to
provide maximal access to the tonsillar fossa and to achieve wide margins and
control of critical neurovascular structures. Frequently, this approach
requires a reconstruction with either a regional rotational flap or a microvascular
free flap. Although this approach is effective, it is not without morbidity. In
an effort to decrease morbidity, surgeons have developed minimally invasive
transoral techniques to treat tonsillar SCC. With the increased use of
transoral techniques, surgical therapy remains a viable option in the treatment
of tonsillar SCC.
Problem
Tonsillar
SCC is a very treatable disease when diagnosed at an early stage. However,
advance stage disease continues to have a poor prognosis, with stage IV disease
carrying a 5-year survival approximately 50% or less. In addition to the poor
prognosis associated with advanced stage disease, treatment may be associated
with significant morbidity to the patient with respect to speech and
swallowing. Both radical surgery and radical chemoradiotherapy alike can lead
to significant impairment of swallowing, with reliance on a tracheostomy and
gastrostomy tube. This can have a negative impact on patient quality of life.
Epidemiology
Frequency
Malignancy
of the tonsils is an uncommon entity that accounts for little more than 0.5% of
new malignancies in the United States every year. More than 8,000 oropharyngeal
carcinomas are diagnosed in the United States each year. The Armed Forces
Institute of Pathology (AFIP) registry from 1945-1976 determined that more than
70% of malignancies in this region are squamous cell carcinoma. Squamous cell
carcinomas are about 3-4 times more common in men than in women, and they are
largely tumors that develop in the fifth decade of life or later.
Lymphomas
of the tonsil are the second most frequent malignancy in this area. Other more
uncommon malignancies include minor salivary gland tumors and metastatic
lesions.
Etiology
According
to the National Cancer Institute, accepted risk factors for squamous cell
carcinoma include smoking and ethanol abuse. More recently, however, some
indications show that viral etiology should also be considered. Although
Epstein-Barr virus (EBV) is a major consideration in nasopharyngeal carcinoma,
human papilloma virus (HPV) has been shown as more of a menace in this region.
Some
studies have identified indications of HPV presence in approximately 60% of
tonsillar carcinomas.
When
the tonsils are included in studies of the entire oropharyngeal region, the
risk factors include the following:
- A diet deficient in fruits and vegetables
- Consumption of the South American beverage mate
- Chewing of betel quid
- Infection with HPV
- Tobacco smoking
- Ethanol use
HPV
is a double-stranded DNA virus that infects basal cells of the epithelium and
can be found in up to 36% of squamous cell carcinomas of the oropharnyx.[1]
Although more than 100 strains have been isolated, HPV type 16
and 18 are most commonly associated with cancers. The viral genome codes for
the oncoproteins E6 and E7, which have increased activity in highly oncogenic
strains. The E6 oncoprotein causes degradation of the tumor suppressor p53,
preventing programmed cell death. The E7 oncoprotein results in loss of the
retinoblastoma (Rb) tumor suppressor. Loss of pRb leads to accumulation of p16,
which would normally inhibit cell cycle progression through cyclin D1 and
CDK4/CDK6 mediated events. However, E7 overrides this cell cycle checkpoint,
and cell progress from G1 into S phase. Because of this accumulation, p16 can
be used as a marker of HPV activity.
Pathophysiology
Tonsillar
SCC may be confined to the tonsillar fossa, but extension to adjacent
structures is common. Carcinoma commonly spreads along the glossotonsillar
sulcus to involve the tongue base to a variable degree. In addition,
spread is frequently superior to involve the soft palate or nasopharynx. The
tonsillar fossa is bounded laterally by the superior constrictor muscle, which
may contain the spread of carcinoma.
However,
when the constrictor muscle is transgressed, the tumor gains access to the
parapharyngeal space. It may involve the pterygoid musculature or the mandible.
Superior extension in the parapharyngeal space can lead to skull base
involvement, and inferior extension can lead to involvement of the lateral
neck. Finally, extensive involvement within the parapharyngeal space may
involve the carotid artery.
Metastasis
to regional lymphatics is common. Neck metastases are present in approximately
65% of patients. In patients with a clinically negative neck, approximately 30%
of these patients will have occult neck disease. Most lymph node metastases are
to level II and to a lesser extent level III. Nodal metastases to level I or
level IV occur in approximately 10%, and skip lesions in both these locations
have been encountered.
Tonsillar
SCC may also metastasize to retropharyngeal lymph nodes. These nodes are not
the primary echelon nodes, but metastasis to this location may occur when the
lymphatics are disrupted in the case of node positive disease in the
jugulodigastric nodes or in the case of prior treatment with either surgery or
radiation. Distant metastasis from tonsillar SCC occurs in approximately 15-30%
of patients. The most common sites are lung, followed by liver, and then bone.[2]
Presentation
Patients
with tonsillar carcinomas may present with a neck mass. This is because
carcinomas arise deep within the aforementioned crypts. These are deep
epithelial invaginations of the surface epithelium.
A
squamous carcinoma may originate at 1 or more sites within the deep nests or branches
within the tonsil. In addition, the tonsil can enlarge considerably, bulging
into empty oral space before it causes alarm to the individual.
Finally,
the tonsils are lymphoid rich and contain abundant lymphatics that help the
neoplasm access and metastasize to neck nodes.
All
of these factors, and perhaps other unknown ones, explain why patients may
present with a neck mass.
One
of the unusual aspects of the neck node metastasis is the fact that a very
large number of these are cystic. This has led to many being erroneously called
branchial cleft carcinomas. In fact, the literature debates the existence of
such an entity as a branchial cleft carcinoma.[3]
Many pathologists feel that branchial cleft carcinoma is
actually either a metastasis or a direct extension from a tonsil squamous cell
carcinoma.
Regardless,
cystic neck lymph node with an occult primary tumor must prompt an investigation
of the tonsil. Occult primary squamous cell carcinomas that manifest as neck
lymphadenopathy are a common problem faced by otolaryngologists.
Although
the hypopharynx and the nasopharynx are often suspected as being the seed area,
the tonsil and the tongue base are also very likely (perhaps more likely) sites
and should also be promptly investigated.
In
addition to a neck mass presentation, usually in the jugulodigastric region,
other symptoms and signs may develop. These may be in conjunction with a neck
mass or may be the only presentation.
Sore
throat, ear pain, foreign body or mass sensation, and bleeding are all
possible. Trismus is an ominous sign because it probably indicates involvement
of the parapharyngeal space. Such tumors may be large enough to involve or
encase the carotid sheath. In addition, the tumor may extend to the skull or
mediastinum.
Even
if the neck mass is not evident on casual inspection, careful palpation may
reveal cervical lymphadenopathy.
If
the tumor has involved the tongue base, contralateral nodes may be involved.
Primary
tonsillar tumors may grow entirely beneath the surface. The clinician may
therefore see nothing suspicious or may see only a slight increase in the size
of the tonsil or the firmness of the area.
Alternatively,
an exophytic fungating mass with central ulceration and heaped-up edges may be
present. It may be deep red to white. Cutting into the lesion during biopsy may
demonstrate a gritty texture (a function of the degree of keratinization), a
firm resistance (a function of the degree of fibrosis), and cystification (a
function of necrosis). Obviously, these findings vary depending on the
specifics of the tumor according to the parameters parenthetically described.
The
constitutional signs and symptoms of weight loss and fatigue are not uncommon
with this neoplasm.
Indications
When
considering surgery for tonsillar SCC, one must consider several factors prior
to surgery, as follows:
- Is the primary tumor resectable?
- Is the neck disease resectable?
- Is there distant metastatic disease?
- What is the expected functional outcome following surgery?
- Are there comorbid patient conditions that will affect surgical outcomes?
- What is the patient’s preference for treatment?
Tumors
of the tonsil are considered unresectable when there is invasion of the lateral
pterygoid muscle, pterygoid plates, lateral nasopharyngeal wall, skull base, or
carotid artery encasement.
Metastases
to the neck are considered unresectable when the tumor circumferentially
involves the carotid artery, if the tumor invades the deep muscles of the neck,
vertebral column invasion, skull base invasion, Horner’s syndrome, phrenic
nerve palsy, or brachial plexus invasion.
Relevant Anatomy
The
anatomy of the tonsillar area is responsible for the fact that the vast
majority of malignant tumors in this region present in advanced stages. In
addition, the tonsils themselves have ill-defined boundaries that merge with
other anatomic landmarks. Often, tumors involve these areas by the time a
tonsillar primary tumor is palpable. A primary tonsillar malignancy that
involves the base of tongue or palate is not unusual.
The
anterior border of the tonsil is the anterior faucial pillar, which contains
the palatoglossal muscle and is covered by squamous mucosa. The posterior
border of the tonsil is the posterior faucial pillar, which contains the
glossopharyngeal muscle and is covered by squamous epithelium. Occasionally,
the ciliated columnar epithelium is also contained. Superiorly, these areas
merge into the soft palate. Inferiorly, the pillars merge at the base of the
tongue at the glossotonsillar fold. Large tumors of the tonsil often extend to
the tongue base along this fold. No truly medial margin exists because this is
an anatomic space at the junction of the oral cavity and pharynx. The lateral
border is the superior constrictor muscle, which lines the tonsillar bed.
Beyond the constrictor muscle is the parapharyngeal space.
When
performing open surgery for tonsillar carcinoma, the anatomy is well known to
head and neck surgeons. Furthermore, resection of the primary tumor usually
follows a neck dissection, such that the carotid artery is under direct vision
and can be protected. However, as minimally invasive transoral techniques
become more prominent, the anatomy of the tonsil is approached from
“inside-out,” in a manner that may be unfamiliar to many head and neck
surgeons.
Holsinger
et al described the transoral lateral oropharyngectomy.[3]
This technique describes resecting the tonsil from lateral to
medial, such that the transoral anatomy is approached differently than when
performing a standard tonsillectomy.
The
operation begins by making an incision through mucosa near the retromolar
trigone and through the superior constrictor muscle. This allows the
constrictor muscle to be reflected off the medial pterygoid muscle, and deeper
dissection in this plane will encounter the parapharyngeal space fat. This
collection of fat is traversed by the blood vessels supplying the tonsillar
fossa.
As
the dissection continues deeply, the styloglossus muscle, and then the
stylopharyngeus muscle will be encountered. Between these muscles runs the
glossopharyngeal nerve, which may be identified during a transoral resection.
The internal carotid artery runs deep to these muscles, and they can be used as
a landmark.
Contraindications
Contraindications
to surgery include:
- Medical conditions precluding a general anesthetic
- Patient declines surgical treatment
- Carotid artery encasement
- Paraspinous muscle invasion
- Vertebral column invasion
- Skull base invasion
- Lateral pterygoid muscle invasion
- Pterygoid plate invasion
- Distant metastatic disease
- Unresectable neck disease
Laboratory Studies
- Liver function tests: Knowledge of hepatic function is necessary because (1) the patient's dietary and ethanol histories frequently lead to poor function, (2) hepatically metabolized chemotherapeutic agents or other medications (eg, pain medication) may be used, and (3) liver metastases are always possible.
- Pulmonary function tests:
- Any head and neck surgery carries additional risks of perioperative and postoperative respiratory complications.
- Respiratory reserve is a necessary bit of knowledge before such surgery is performed.
- Renal function tests: When certain chemotherapeutic agents are considered, renal function tests are necessary to ascertain whether the patient can eliminate agents that are handled by the kidneys.
- Clotting and coagulation studies (including platelet count, typing, cross-matching)
- The head and neck is one of the richest areas of vascularity in the human body.
- Hemorrhage is one of the biggest problems in tonsillar surgery.
- Having transfusion material available is wise.
Imaging Studies
- CT scanning of the neck, with and without contrast, is necessary to evaluate for metastases and to assess the extent of the tumor. In addition, if extended upward to include the bony areas, bone invasion is part of the new knowledge base. This is essential in staging tonsillar tumors.
- MRI is also extremely useful for assessing tumor size and soft tissue invasion.
- CT scan of the chest is the single most sensitive imaging study used to reveal lung metastasis and, therefore, should be the modality of choice, at least in high-risk patients (stage 4 disease, T4 tumor, N2 or N3 nodal disease, tumors that arise from the oropharynx, larynx, hypopharynx, or supraglottis).[4]
Diagnostic Procedures
- Biopsy is the only tool for obtaining diagnostic tissue.
- Tonsillar malignancies may be lymphoma; therefore, the pathologist and team should be immediately ready to handle the tissue properly.
- Special fixatives must be prepared. Some tissue may be needed for fresh studies, which are time dependent and require immediate handling. Some tissue should be frozen in liquid nitrogen. Given the nature of frozen sections and the type of unexpected events in a pathologist's day, alerting the pathologist 24 hours in advance of a possible lymphoma biopsy is wise.
- Another very important consideration is the fact that squamous cell carcinomas commonly arise deep in the crypts. This necessitates the surgeon taking a deep biopsy so that the true neoplasm is not missed. Given the propensity for these lesions to bleed, this is a tricky procedure, and the surgeon should be ready for the unexpected.
- Panendoscopy
- Operative endoscopy allows the surgeon to assess the full extent of the tumor. This can be very helpful when choosing between open and endoscopic surgical approaches. It also allows for a biopsy if it cannot be performed in the office.
- Bronchoscopy and esophagoscopy are utilized to assess for second primary tumors that may be present at the time of diagnosis.
- HPV testing
- NCCN guidelines recommend HPV testing for prognostic factors.
- Quantitative reverse transcriptase PCR (QRT-PCR) allows calculation of relative amounts of mRNA present in the sample.
- Able to calculate copy number
- Susceptible to false positives
- Type-specific HPV DNA in situ hybridization
- HPV-16 is most commonly used to examine oropharyngeal carcinomas.
- It is both sensitive and specific.
- P16 can be tested as a biomarker for HPV E7 activity.
Histologic Findings
Squamous cell carcinoma
Most
palatine tonsil squamous cell carcinomas are moderately to poorly
differentiated.
The
following variants, although essentially squamous cell carcinomas, in this area
have been described with some frequency:
- Basosquamous carcinoma Nonkeratinizing carcinoma (transitional cell or sinonasal type)
- Undifferentiated or lymphoepithelioma type
Lymphomas
Lymphoma
type determination is crucial and can be achieved only with the help of special
studies obtained by the pathologist. The cell and tissue markers used to type
lymphomas are quite sensitive. These require fresh frozen tissue and unusual
fixatives, in addition to immunohistochemical stains.
All
of these studies help in the crucial determination of lymphoma type. Many
require fresh or frozen tissue for immunohistochemical studies.
Most
tonsillar carcinomas are diffuse non-Hodgkin large B-cell lymphomas.
Mucosa-associated
lymphoid tissue (MALT) low-grade B-cell lymphomas composed of small cells are
uncommon in the tonsil. This is surprising because the tonsil consists of a
very intimate intermingled arrangement of epithelium and lymphocytes, which, in
theory, would make an ideal environment for the development of MALT lymphomas.
In reality, they are so uncommon in this region that they are case reportable.
Minor salivary gland malignancies
Minor
salivary gland malignancies are the third most common lesion of the tonsil.
These lesions include mucoepidermoid carcinoma, adenoid cystic carcinoma,
acinic cell carcinoma, and adenocarcinoma.
Metastatic lesions to the tonsil
Although
the palatine tonsils are a rich source of lymphatics and lymphoid tissue,
metastases to the palatine tonsils are rare. Case reports have described an
extraordinarily wide spectrum of malignancies metastatic to this area. Breast,
various lung primaries, renal carcinomas, and pancreatic and colorectal
malignancies have been reported. Documented cases of Wilms tumor and
choriocarcinoma metastasizing to this distant site also exist.
Staging
Staging
of tonsil carcinoma is according to the 6th edition of the AJCC
Cancer Staging Manual. Clinical information is taken from all sources,
including physical examination and any available imaging studies.
AJCC
tumor staging of tonsil carcinoma is as follows:
- Tx: Primary tumor cannot be assessed
- T0: No evidence of primary tumor
- Tis: Carcinoma in situ
- T1: Tumor ≤ 2 cm in greatest dimension
- T2: Tumor >2 cm but < 4 cm in greatest dimension
- T3: Tumor >4 cm in greatest dimension
- T4a: Tumor invades the larynx, deep or extrinsic muscles of the tongue, medial pterygoid muscle, hard palate, or mandible
- T4b: Tumor invades the lateral pterygoid muscle, pterygoid plates, lateral nasopharynx, skull base, or encases carotid artery
AJCC
nodal categories (except thyroid and nasopharyngeal carcinoma):
- Nx: Regional lymph nodes that cannot be assessed
- N0: No regional node metastasis
- N1: Metastasis in a single ipsilateral lymph node, 3 cm or smaller
- N2: Metastasis in a single ipsilateral lymph node, larger than 3 cm but not larger than 6 cm in greatest dimension is found; multiple ipsilateral lymph nodes, none larger than 6 cm; bilateral or contralateral lymph nodes, none larger than 6 cm
- N2a: Metastasis in a single ipsilateral lymph node larger than 3 cm but not larger than 6 cm
- N2b: Metastasis in multiple ipsilateral lymph nodes, none larger than 6 cm
- N2c: Metastasis in bilateral or contralateral lymph nodes, none larger than 6 cm
- N3: Metastasis in a lymph node larger than 6 cm
Distant
metastasis:
- Mx: Distant metastasis cannot be assessed
- M0: No distant metastasis
- M1: Distant metastasis
The
combination of the primary tumor, nodal status, and presence or absence of
distant metastasis is used as a part of the overall staging of the patient’s
disease according to AJCC guidelines:
- Stage I: T1 N0 M0
- Stage II: T2 N0 M0
- Stage III: T3 N0 M0 T1 N1 M0 T2 N1 M0 T3 N1 M0
- Stage IVa: T4a N0 M0 T4a N1 M0 T1 N2 M0 T2 N2 M0 T3 N2 M0 T4a N2 M0
- Stage IVb: Any T N3 M0 T4b Any N M0
- Stage IVc: Any T Any N M1
Medical Therapy
Non-surgical
therapy of tonsil carcinoma consists of radiation therapy to the primary site
and neck for early stage T1-2N0 tumors. For advanced stage tumors T3-4N+,
non-surgical therapy consists of organ-preservation concurrent chemoradiation.
This article focuses on surgical treatment, and therefore these therapies will
not be discussed in detail.
Preoperative Details
When
evaluating a patient with tonsil carcinoma for surgery, one must determine the
optimal surgical approach. For most early stage tumors and select late-stage
tumors, a transoral approach may be appropriate. Transoral approaches include
using a standard mouth gag and headlight as performing a standard
tonsillectomy, transoral laser microsurgery (TLM), or a new technique transoral
robotic surgery (TORS).[5]
However,
for most advanced stage tumors, the standard open approaches are typically
appropriate. Open approaches may include a lip-splitting mandibulotomy or a lateral
pharyngotomy to achieve access to the tumor. Typically in these open
approaches, reconstruction with either a local, regional, or free tissue flap
is needed to close the surgical defect. When deciding upon an approach, the
surgeon must carefully assess the extent of the tumor, and when considering a
transoral approach, the surgeon must determine if transoral access is possible.
Factors
preventing transoral access include trismus, large teeth, small transverse
mandibular dimensions, mandibular tori, large tongue, poor atlanto-occipital
extension, and prior radiation that may obscure tissue planes or determination
of resection margin. Furthermore, if the tumor has significant lateral
extension, transoral resection may put the carotid artery at risk, making this
approach unsafe.
In
addition, if transoral resection may leave a positive margin (such as with
skull base extension), then an open approach should be chosen. Finally, the
experience of the surgeon must be considered. Transoral resection tonsil carcinoma
approaches the anatomy from “inside-out” in a way that may not be familiar to
many surgeons. This can make transoral surgery difficult and compromise the
resection margin.
When
the tumor has significant involvement of adjacent sites such as the soft
palate, tongue base, or nasopharynx, a transoral resection may not be
appropriate due to the need for reconstruction. When more than half the soft
palate or tongue base is resected, these patients may benefit from
reconstruction with a flap, and an open surgical approach may be more
appropriate. Most of these factors can be accurately assessed prior to taking
the patient to the operating room for definitive treatment. Physical
examination in the office or during operative endoscopy can accurately map out
the extent of the tumor. Careful examination of preoperative imaging can
determine the proximity of the carotid artery to the tumor.
Intraoperative Details
If
the patient is deemed a candidate for transoral resection, the surgeon must
then decide how to resect the tumor. Options include the using standard
mouthgags and a headlight, TLM, or TORS. Holsinger et al described their
approach to transoral lateral oropharyngectomy for removal of tonsil carcinomas
using standard mouthgags and a headlight.[3]
This approach involves incising the superior constrictor
muscle at the pterygomandibular raphe, and then reflecting the constrictor
muscle from lateral to medial. This approach takes the superior constrictor
muscle as the lateral margin of resection.
Transoral
laser microsurgery techniques have been described in detail by Steiner and
Ambrosch.[6] The standard approach is to gain
exposure via standard mouthgags or distending oropharyngoscopes. The operating
microscope and a CO2 laser is then used to remove the tumor piecemeal. Using
the enhanced visualization of the microscope and the differential cutting of
the laser through normal tissue versus tumor allows the surgeon to follow the
tumor and preserve the maximal amount of normal tissue. Because the tumor is
removed piecemeal, it is imperative that the surgeon communicate effectively
with the pathologist to ensure a true negative margin.[7]
Transoral
Robotic Surgery is new technique pioneered by Weinstein et al.[5]
TORS achieves exposure of the tumor using standard mouthgags.
The robotic endoscope and operating instruments are then inserted into the
mouth and used to resect the tumor in a modified fashion described by Holsinger
et al. Advantages of TORS include enhanced 3-D visualization and use of wristed
instruments and angled endoscopes that allow the surgeon to achieve access to
the tumor that are otherwise difficult with the standard transoral approach or
TLM.[6]
In
all cases of transoral resection, the surgeon must be able to control bleeding
from branches of the carotid arterial system. This is achieved either by
electrocautery or through the use of surgical hemoclips. Typically, the
surgical bed is left to heal by secondary intention. This makes protecting the
carotid artery critical, to prevent erosion of the vessel wall by exposure to
saliva.
In
cases in which an open approach is needed, exposure of the tumor may be through
a lip-splitting mandibulotomy, a lateral pharyngotomy, or a combination of
transoral exposure and lateral pharyngotomy. This leaves the patient with an
open communication between the neck and the pharynx, necessitating a
reconstruction with a soft tissue flap. Common options for reconstruction
include a pectoralis major myocutaneous flap, radial forearm fasciocutaneous
free flap, or anterolateral thigh fasciocutaneous or myocutaneous free flap.
Advantages of open approaches include direct access to the tumor while
providing maximal control of the great vessels. However, patients are subjected
to longer operative times, the need for reconstruction, and longer time for
recovery of swallowing.
Treatment
of tonsillar carcinoma requires management of the regional lymphatics.
Selective neck dissection to include levels I-IV is the standard operation. In
open approaches, neck dissection is performed with the resection of the primary
tumor. In transoral approaches, neck dissection can be performed concomitantly,
or it may be staged to avoid the risk of a salivary fistula. In addition, the
retropharyngeal nodes may be at risk. These can be removed at the time of
primary tumor resection.
Postoperative Details
Patients
undergoing surgery for tonsillar carcinoma must be monitored carefully in the
postoperative period. Issues that are critical to consider include airway
management, potential for bleeding, and diet. Airway management is dependent on
the approach used and the extent of resection. When a transoral approach is
utilized, patients may remain intubated following surgery, depending on the
extent of resection, the potential risk for bleeding, or the preference of the
surgeon. In most cases, patients undergoing transoral resection will not need a
tracheostomy, as swelling is generally less than in open resections.
In
the case of open resections, edema is usually significant, especially with flap
reconstruction, and most patients will require a tracheostomy. The tracheostomy
is temporary in most cases. Bleeding following resection of tonsillar carcinoma
can be significant and life-threatening. Most cases of transoral resection
allow the wound to heal by secondary intention. As a result, branches of the
external carotid artery that have been ligated during surgery are at risk for
bleeding. Bleeding can be brisk, and due to the proximity to the airway,
aspiration of blood can be a significant problem. Rich et al reported a 3.6%
bleeding rate in a large series of oropharyngeal carcinomas treated with TLM.[7]
Resumption
of an oral diet is also an important consideration following surgical treatment
of tonsillar carcinoma. Nearly all patients will have some level of dysphagia
that can interfere with resumption of a normal diet. Transoral resections
typically have less dysphagia, although many patients will require a temporary
feeding tube. Timing of feeding tube removal can be dictated by a clinical
examination, with or without a modified barium swallow. Long-term percutaneous
gastrostomy (PEG) tube requirement is rare with transoral resections. Weinstein
et al reported a 3.7% PEG tube rate in their initial study of TORS radical
tonsillectomy.[5] This is similar to the rate (4%)
reported by Moore et al in their study of transoral resection of tonsil
carcinomas.[8]
Adjuvant
treatment with radiation therapy or chemoradiation is frequently indicated
following surgery, and is dictated by the final pathology. Indications for
postoperative radiotherapy include perineural or lymphovascular invasion,
multiple positive nodes, close margins, and T4 disease. Indications for
postoperative chemoradiation include positive margins and extracapsular spread
in the lymph nodes.[9]
Follow-up
Routine
follow-up care of patients with tonsil cancer is important, particularly
because the risk of developing a second primary tumor is highest in this group.
Patients with head and neck cancers have a 20% overall risk of developing a
second primary tumor, while patients with tonsil cancer have as high as a 30%
risk.
Complications
Complications
of the various forms of current therapy include the following:
- Pain
- Xerostomia
- Infections
- Poor wound healing
- Dysphagia
- Fistula formation
- Trismus
- Velopharyngeal insufficiency
- Potential disfigurement
- Fatigue
The
family and patient should understand all of these in advance before committing
to any therapy.
Outcome and Prognosis
The
prognosis as determined by 5-year survival rate of treated squamous cell
carcinoma of the tonsillar region is as follows:
- Stage I - 80%
- Stage II - 70%
- Stage III - 40%
- Stage IV - 30%
The
survival from tonsillar carcinoma has historically been considered poor,
especially for late stage (III and IV) disease. However, more recent literature
has shown promising results with surgical therapy for tonsillar carcinoma, even
for advanced stage disease. Rich et al reported 2- and 5-year disease-specific
survival rates of 96% and 92% for stage III and IV oropharyngeal carcinoma
treated with transoral laser microsurgery (TLM) and adjuvant therapy.[7]
Likewise, Moore et al reported 94% disease-specific survival
in stage III and IV tonsillar carcinomas treated with transoral resection and
adjuvant therapy. The results of these studies indicate that select patients,
when treated appropriately, can have excellent survival outcomes despite
historically poor outcomes.
The
safety and feasibility of transoral robotic surgery (TORS) as a minimally invasive
treatment alternative for malignancies of the head and neck was established by
investigators at the University of Pennsylvania, University of
Alabama-Birmingham, and the Mayo Clinic. This resulted in TORS being approved
by the US Food and Drug Administration (FDA) in 2009 for transoral
otolaryngology surgical procedures in adults restricted to benign and malignant
tumors classified as T1 and T2. Advanced T-stage tumors were not approved since
these studies only had a small number of advanced-stage tumors. While these
initial studies reported their oncologic outcomes, the follow-up was short due
to the relative infancy of the procedure. However, the oncologic data for TORS
are beginning to mature and longer-term follow-up data are being reported.
The
University of Pennsylvania reported the results of 47 consecutive patients with
advanced-stage oropharyngeal squamous cell carcinoma (OPSCC) and a minimum of
18 months follow-up who were treated with primary TORS, staged neck dissection,
and adjuvant radiation or chemoradiation as indicated.[10]
Seventy-seven percent of patients had T1 and T2 tumors, while
51% of patients had N1 disease and 49% of patients had N2 disease.
Negative
margins were achieved in 98% of patients. Five patients avoided radiotherapy
altogether, while 13 patients received radiotherapy only, 2 received
chemotherapy only, and 27 received concurrent chemoradiation. Local control and
regional control were 98% and 96%, respectively. Actuarial 1- and 2-year
overall survival was 96% and 82%, respectively. Actuarial disease-specific
survival at 1 year and 2 years was 98% and 90%, respectively. Disease-free
survival was 96% at 1 year and 79% at 2 years. When compared with similar organ-preservation
chemoradiation trials, oncologic control was similar.[11,
12]
With
the changing landscape of OPSCC and more tumors caused by human papillomavirus
(HPV) infection, the same authors analyzed the oncologic outcomes of a cohort
of TORS patients with respect to HPV status.[13]
In 50 patients treated with TORS, staged neck dissection, and
adjuvant radiation or chemoradiation as indicated, 37 patients (74%) had
HPV-positive tumors and 13 patients (26%) had HPV-negative tumors. There was no
statistical difference between the 2 groups with respect to the margin status,
presence of cervical metastases, recurrence, or survival curves. Many
HPV-induced tumors are presenting with smaller tumors at the primary site but
with advanced-stage neck disease.
To
determine the rates of regional recurrence in their patients, the authors
examined 31 patients, all with negative-margin TORS who underwent selective
neck dissection and adjuvant therapy, and they found only one regional
recurrence. Examination of the pathological specimens in the neck showed that
33% and 43% of the clinical N0 and N1 patients, respectively, were
pathologically upstaged, while 4 of the 14 clinical N1 patients had negative
pathological necks. Pathological staging of the necks allowed the authors to
selectively administer adjuvant therapy and to deintensify therapy in some
cases.[14]
The
University of Alabama-Birmingham (UAB) and the Mayo Clinic pooled their data to
report their 2-year survival analysis in a cohort of 89 patients with carcinoma
of the oral cavity, oropharynx, and supraglottic larynx.[15]
Seventy-nine percent of patients were stage T1 and T2, and
negative margins were achieved in all patients. Seventy-six percent of patients
underwent staged or concomitant neck dissection. Of the patients who underwent
TORS as primary treatment, 63% received adjuvant radiation therapy and 48% had
chemotherapy either before or after surgical treatment. Two-year
recurrence-free survival in patients who underwent TORS as primary treatment
was 89.3%.
Genden
et al reported 18-month survival data in 30 patients with head and neck
squamous cell carcinoma, the majority of who had OPSCC.[16]
All patients underwent TORS, concomitant neck dissection, and
adjuvant therapy as indicated. Because all patients were pathologically staged,
adjuvant therapy was deintensified in 4 patients, while it was escalated in 5
patients. Eighteen-month locoregional control, distant control, disease-free
survival, and overall survival rates were 91%, 93%, 78%, and 90%, respectively.
Comparison with a matched group of patients undergoing primary chemoradiation
showed no statistically significant survival differences.
In
addition to excellent oncologic outcomes, patients treated with TORS have shown
excellent functional outcomes with longer follow-up. The University of
Pennsylvania reported a 2.4% (one patient) gastrostomy tube dependency rate at
a minimum of 1-year follow-up, while the rate of feeding tube dependency in the
combined UAB and Mayo Clinic, as well as the Mt. Sinai study, was 0%.[10,
15] In addition to gastrostomy tube dependency rate,
quality-of-life data are now available in patients undergoing TORS.
Leonhardt
et al found that in 38 patients with OPSCC undergoing TORS, staged neck
dissection, and adjuvant therapy, declines in the eating and diet domains on
the Performance Status Scale that were seen at 6 months returned to baseline at
12 months.[17] Declines in the speech domain remained
significantly decreased at 6 and 12 months. Patients receiving adjuvant
chemoradiation had significantly lower diet domain scores at 6 and 12 months
compared with those who underwent surgery only.
Hurtuketal
et al used the Head and Neck Cancer Inventory to show that speech, aesthetics,
attitude, and overall quality of life remained in the high domain at 12 months,
while the eating domain dropped to the intermediate level at 12 months in 18 of
64 patients who underwent TORS and adjuvant therapy for head and neck squamous
cell carcinoma at all sites.[18]
Genden
et al compared TORS patients with a similar cohort of patients treated with
primary chemoradiation and found that all TORS patients returned to baseline in
the eating, speech, and diet domains on the Performance Status Scale for Head
and Neck, as well as the Functional Oral Intake Score. In contrast, patients
treated with chemoradiation had a lower-than-baseline diet score and lower
Functional Oral Intake Score.[16]
Since
its inception, TORS has proven to be a safe and efficacious, minimally invasive
means of achieving an en bloc resection of head and neck malignancies.
Functional outcomes have been excellent, and as the data mature, the oncologic
outcomes appear to be equivalent to those with achieved with standard open
surgery or organ-preservation chemoradiation protocols. By surgically staging
patients with TORS and neck dissection, adjuvant therapy can be tailored to the
individual patient and can be deintensified in some cases of low-risk disease.
TORS offers the potential to maximize oncologic control while maximizing
functional outcomes. This approach is in stark contrast to chemoradiation
protocols in which all patients receive identical therapy. More studies are
necessary to validate long-term outcomes.
It
is becoming apparent that survival for tonsil cancer correlates with HPV
status. There has been recent evidence from both the surgical and nonsurgical
literature that patients with HPV-positive tumors have improved survival. Several
retrospective case series have shown that patients with HPV-positive
oropharyngeal tumors have a better prognosis than patients with HPV-negative
tumors.[19] Similar findings were reported in a
prospective analysis of data from a small clinical trial.[20]
More
recently, Ang et al analyzed the HPV status in a large number of patients
randomized to receive either standard fractionated chemoradiation or
accelerated fractionation chemoradiation for stage III-IV OPSCC.[21]
Patients with HPV-positive tumors had improved 3-year overall
survival (82.4% vs 57.1%, P < .001) and 58% risk-of-death reduction
compared with patients with HPV-negative tumors.
Furthermore,
these authors found that patients could be risk stratified according to HPV
status and smoking history. Low-risk patients had HPV-positive tumors and less
than 10 pack years smoking history or had HPV-positive tumors, more than 10
pack years smoking history, but had N0-N2a neck disease. Intermediate-risk
patients had HPV-positive tumors with more than 10 pack years smoking history
and advanced neck disease or they had HPV-negative tumors with less than 10
pack years smoking history and T2-T3 tumors. The high-risk group had
HPV-negative tumors with less than 10 pack years smoking history and T4 tumors
or they had HPV-negative tumors and more than 10 pack years smoking history.
Three-year overall survival in the low-, intermediate-, and high-risk groups
was 93%, 70.8%, and 46.2%, respectively.
In
the surgical literature, HPV tumor status is proving to affect prognosis as
well. Rich et al reported improved overall survival (HR = 0.04) and
disease-specific survival (HR = 0.10) in patients with p16-positive tumors
compared with p16-negative tumors.[7]
While p16 serves as a biomarker for HPV positivity, the
authors did not, however, find that HPV positivity affected survival. This may
be related to discrepancies between the different detection techniques.
Results
of the above studies, and others, indicate that HPV-positive tumors have
improved outcomes compared with HPV-negative tumors. Knowledge of the HPV
status of the tumor is important for prognosis and risk stratification of
patients and should be included in the pathologic analysis of tumor specimens.
Future and Controversies
The
largest controversy regarding the treatment of tonsillar carcinoma surrounds
whether this cancer should be treated primarily with surgery or with
organ-preservation chemoradiation. Each treatment is not without its own risks,
and the decision regarding treatment should be made in conjunction with the
recommendations of the multidisciplinary team and the preferences of the
patient.
Recent
surgical literature has been extremely promising in the treatment of tonsillar
carcinoma. Minimally invasive techniques such as transoral robotic surgery and
transoral laser microsurgery offer patients an excellent option for treatment
both from a functional and an oncologic standpoint.
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