Cancer of
the Oropharynx
The oropharynx includes the base of the tongue, tonsils,
soft palate, and
posterior pharyngeal wall. The oropharynx is extremely
rich in lymphatics.
Depending on the subsite involved, 15% to 75% of patients
present with
lymph node involvement. Oropharyngeal cancer that is
p16-positive (ie,
HPV-mediated) is a different disease than p16-negative
cancer. For
example, patients with HPV-associated H&N cancer tend
to be
younger13,16 and
have an improved response to treatment when compared
with patients with HPV-negative tumors.29-33,341 To take into account these
differences, separate staging criteria were published for
p16-negative and
p16-positive oropharyngeal cancer in the 8th edition of
the AJCC Cancer
Staging Manual.318 In
2018, the panel created separate algorithms for p16-
positive (HPV-mediated) oropharyngeal cancer. See the
section below on
Staging.
Workup and Staging
A multidisciplinary consultation is encouraged including
a registered
dietitian and a speech-language/swallowing therapist as
clinically indicated
(see Principles of Nutrition in this Discussion
and in the NCCN Guidelines
for Head and Neck Cancers). Accurate staging (see Table 3
for p16-
negative oropharyngeal cancer and Table 4 for
p16-positive
oropharyngeal cancer) depends on a complete H&N
examination and
appropriate imaging studies (see Workup in NCCN
Guidelines for Cancer
of the Oropharynx).318,342
Skipping examination under anesthesia (EUA) with
confirmation biopsy for
oropharyngeal cancer that presents as a metastatic lymph
node may introduce error based on lack of rigor and precision. There may be
situations in which the EUA is undesirable or could be
bypassed. These
include patients at high risk for general anesthesia and
those who undergo
a thorough examination including tongue base palpation.
Those who
require systemic therapy/RT will not have their treatment
plan affected,
regardless of surgical evaluation. These situations
remain the minority of
cases. Therefore, the panel recommends EUA with biopsy
confirmation for
patients presenting with a p16-positive cervical lymph
node prior to
treatment decision-making.
Tumor HPV testing through p16 immunohistochemistry (IHC)
is required
for cancers of the oropharynx, because prior HPV
infection is related to
the development of a significant proportion of
oropharyngeal cancers (see
the following section on HPV Testing).
HPV Testing
The attributable fraction for HPV in newly diagnosed
oropharyngeal cancer
is estimated at 60% to 70% in the United States and parts
of the European
Union.15,343-346 There
are currently no diagnostic tests with regulatory
approval. A few HPV testing options are available for use
in the clinical
setting. Expression of p16 as detected by IHC is a widely
available
surrogate biomarker that has very good agreement with HPV
status as
determined by HPV E6/E7 mRNA expression.347-350 Other tests include
HPV detection by polymerase chain reaction (PCR) and in
situ
hybridization (ISH).347,349 Sensitivity
of IHC staining for p16 and PCRbased
assay is high, though specificity is highest for ISH.349 Analyses of
HPV testing methods have shown that sensitivity and
specificity of p16
IHC range from 94% to 97% and 83% to 84%, respectively,
with sensitivity
and specificity of HPV16 ISH ranging from 85% to 88% and
88% to
95%.347,350
The reduced specificity
for p16 IHC may be due to the
presence of p16-positive tumors that do not have evidence
of HPV DNA,
while the reduced sensitivity for HPV16 ISH may be due to
the presence of other high-risk HPV
types in the tumor. Due to variations in sensitivity
and specificity values of testing options, multiple
methods may be used in
combination for HPV detection.13,349-352 Sufficient pathologic material for
HPV testing can be obtained by fine-needle aspiration
(FNA).13,353
Guidelines for HPV testing have also been published by
the College of
American Pathologists.354 HPV
testing may prompt questions about
prognosis (ie, a favorable or a less favorable forecast)
and sexual history
that the clinician should be prepared to address.
Staging
The algorithms in the NCCN Guidelines for Oropharyngeal
Cancer reflect
the new staging criteria published in the 8th edition of the AJCC Cancer
Staging Manual for p16-negative oropharyngeal cancer and
p16-positive
oropharyngeal cancer.318 In
the updated staging criteria for p16-negative
oropharyngeal cancer, separate pathologic criteria are
now presented for
involvement of regional lymph nodes, since extranodal
extension is difficult
to accurately capture through the imaging workup that is
routinely done for
clinical staging.355 The
treatment algorithm for p16-negative disease is
divided into three staging categories: 1) T1–2, N0–1; 2)
T3–4a, N0–1; and
3) any T, N2–3. Of note, the following categories are
treated as advanced
cancer: T4b, any N; unresectable nodal disease; unfit for
surgery; or M1
disease at initial presentation (see the NCCN Guidelines
for Very
Advanced Head and Neck Cancers).
A clinical staging system for p16-positive oropharyngeal
cancer was
developed using data from 1907 patients with
non-metastatic HPV-positive
oropharyngeal cancer from seven cancer centers in Europe
and the
United States.356 OS
did not significantly differ between T4a and T4b
disease (P = .41). Five-year OS rates did not
significantly differ in patients
with N1, N2a, or N2b disease, based on the AJCC 7th edition N
classification,357 so
the study investigators reasoned that these patients could be grouped into one
category (ie, at least one ipsilateral metastatic
node ≤6 cm).
An analysis of 704 patients with resected p16-positive
oropharyngeal
squamous cell carcinoma from five cancer centers showed
that the Nclassification
system for oropharyngeal cancer that was described in the
7th
edition of the AJCC
Cancer Staging Manual357
was not significantly
associated with OS.358 However,
patients with 4 or fewer pathologically
confirmed metastatic nodes had a higher 5-year OS rate,
compared to
patients with five or more pathologically confirmed
metastatic nodes (89%
vs. 71%, respectively). The results from this analysis
were used to
construct a pathologic staging system for patients with
p16-positive
disease: 1) pT1–T2 and fewer than five metastatic nodes;
2) pT1–T2 and
more than four metastatic nodes, or pT3–T4 and fewer than
five
metastatic nodes; and 3) pT3–T4 and more than four
metastatic nodes.
The 5-year OS rates for these staging groups were 90%
(95% CI, 87%–
93%), 84% (95% CI, 77%–90%), and 48% (95% CI, 30%–66%),
respectively. Five-year DFS rates for the three staging
groups were 86%
(95% CI, 82%–90%), 72% (95% CI, 64%–79%), and 40% (95%
CI, 24%–
56%), respectively. The results from this analysis are
consistent with an
earlier study that showed that the presence of five or
more metastatic
nodes, but not N-classification, was associated with
disease recurrence
and survival in 220 patients with surgically resected
p16-positive
oropharyngeal cancer.359
The modifications to the NCCN Guidelines for p16
(HPV)-positive
oropharyngeal cancer accommodate the new staging system
for p16-
positive oropharyngeal cancer. However, the changes are
relatively
modest, since the staging system changes are based on
prognostic
models and are not based on prospective data from
clinical trials that
guide clinical decision-making. Based on differences in
features
associated with prognosis,356,358 the staging criteria for p16-positive oropharyngeal
cancer differs from staging for p16-negative oropharyngeal
cancer in the following ways:318
• T4b
disease has been removed from the staging criteria for
defining the primary tumor.
• Criteria
for defining nodal involvement (both clinical and pathologic)
have been simplified for p16-positive disease. Clinical N
staging for
p16-positive oropharyngeal cancer is based on lymph node
size
and laterality, while pathologic N staging is based on
number of
lymph nodes. Further, pN3 disease has been removed for
pathologic N.
The treatment algorithms for p16-positive disease have
been divided by
the panel into four staging categories:
1) cT1–2, cN0
2) cT1–2, cN1 (single node ≤3 cm)
3) cT1–2, cN1 (single node >3 cm, or 2 or more
ipsilateral nodes
≤6 cm); or cT1–2, cN2; or cT3, cN0–2
4) cT4 or cN3
The algorithms in the NCCN Guidelines for p16
(HPV)-positive
oropharyngeal cancer incorporate the staging criteria
presented in the
revised 8th Edition
of the AJCC Cancer Staging Manual318 based
on
clinical staging criteria. This is to acknowledge that
decision-making is
currently frequently based on data from trials that
included oropharyngeal
as well as other anatomic sites that were staged
utilizing AJCC 7th
edition
nodal staging criteria.357
Treatment
Consensus is increasing that HPV status should be used as
a stratification
factor or should be addressed in separate trials
(HPV-related vs. unrelated
disease) for which patients with oropharyngeal cancer are
eligible.360-362
Some clinicians have
suggested that less-intense treatment may be
adequate for HPV-positive oropharyngeal cancers (ie,
deintensification).48
However, the available data supporting this assertion are
limited by
retrospective analyses, single-institution phase 3
trials, variability in HPV
testing method used, and short follow-up periods.48,363-365 Deintensification
treatment protocols for HPV-associated locally advanced
oropharyngeal
cancer are being investigated in ongoing clinical trials
(eg, NCT01154920,
NCT01706939, NCT01855451, NCT01687413, NCT01898494,
NCT02215265). Strategies under active investigation
include reducing or
using response-stratified RT dose, using RT alone versus
chemoradiation,
using less invasive surgical procedures such as transoral
robotic surgery
(TORS), using sequential systemic therapy/RT, and using
immunotherapy
and targeted therapy agents such as cetuximab.365-367
Results from multiple phase II trials show that RT
deintensification is
associated with promising PFS rates in patients with
p16-positive
oropharyngeal cancer.368-372 Analyses
of quality-of-life outcomes from one
of these trials showed that RT deintensification was
associated with a
quicker and more robust return to baseline-level
functioning.373
In a subset
analysis from the EORTC 24971 study,374 p16 status was not significantly
associated with survival outcomes in this analysis, but
the investigators
pointed out that the planned analysis was powered to
detect a large
treatment by marker interaction.375
With some exceptions, which are noted in this section
below, the
treatment algorithms for p16-negative and p16-positive
oropharyngeal
cancer are identical. There is currently no evidence that
the new staging
criteria published in the 8th edition of the AJCC Cancer Staging Manual318
should drive clinical decision-making. The difference
between p16-positive
and p16-negative oropharyngeal cancer is mainly
prognostic. Panel
members urge that patients with HPV-related cancers be
enrolled in
clinical trials evaluating biological and
treatment-related questions.365,367,376Early-stage
(T1–2, N–1 for p16-negative disease; T1–2, N0 or single node
≤3 cm for p16-positive
disease) oropharyngeal cancers may be treated
with: 1) resection of the primary with neck dissection;
or 2) definitive
RT.87,90,377,378
Results from the
randomized phase II ORATOR trial, which
included 68 patients with early-stage oropharyngeal
cancer, showed that
quality-of-life outcomes were generally better for
patients treated with RT,
compared to patients who received TORS with neck
dissection.379
Tumors
at or approaching the midline (ie, tumors in the base of
the tongue,
posterior pharyngeal wall, soft palate, and tonsil
invading the tongue base)
are at risk of contralateral metastasis and warrant
bilateral treatment.
Based on results from the phase III randomized GORTEC
trial155 and
retrospective analyses from the National Cancer Database
(NCDB),380,381
systemic therapy/RT is a treatment option for patients
with p16-negative
N1 disease. However, this is a category 2B option, since
the number of
patients with T1–T2, N1 disease enrolled in the GORTEC
trial is small,
and more data from prospective trials are needed. For
patients with p16-
positive disease, systemic therapy/RT is also a category
2B option for T1–
T2 disease
and the involvement of a single node ≤3 cm.
Research on the impact of adverse features such as
extranodal extension
and number of involved nodes on outcomes in patients with
p16-positive
disease who have undergone resection is rapidly evolving.
Currently, data
from only retrospective trials are available,45,359,360,382-385 and clinical trials
are being conducted to validate the revised AJCC staging318 for clinical
decision-making. Analyses from the RTOG 9501105 and EORTC 22931
trials104 showed
that extranodal extension is associated with poor
prognosis in patients with locally advanced H&N
cancer who have
undergone surgical resection.106 However, in a review of published data
from these RCTs, it was noted that these studies did not
investigate the
impact of HPV or p16 status.386 In response to this review, the
investigators from RTOG 9501 and EORTC 22931 pointed out
that the prevalence of HPV-positive/p16-positive tumors was likely to be low in
these trials.387 Other
limitations noted in this review included unplanned
subgroup analyses, the grouping of multiple H&N
subsites, inconsistent
quantitative reporting and lack of reporting on tumor and
lymph node
classification, treatment effect sizes, multivariable
analyses, and quality-oflife
outcomes. Therefore, the investigators who carried out
this review
argued that these trials lack the generalizability
necessary to rationalize
the use of adjuvant systemic therapy/RT in patients with
p16-positive
disease. Based on this controversy and a lack of
high-quality, prospective
clinical evidence, this recommendation is a category 2A
option for both
patients with p16-positive disease and p16-negative
disease. Adjuvant
systemic therapy/RT remains a category 1 recommendation
for patients
with other types of H&N cancer who have extranodal
extension. Since
patients with p16-positive oropharyngeal cancer have a
generally
favorable prognosis and may live longer, toxicity and
quality of life are
concerns for these patients.365,367 On the other hand, recent retrospective
analyses including 4,443 patients with HPV-positive
oropharyngeal cancer
from the NCDB showed that deintensification by using a
single primary
treatment modality such as definitive RT may be
associated with worse
treatment outcomes in the long-term.388 Omitting systemic therapy and
administering radiotherapy alone is a category 2B option
for patients with
p16-positive cT1–2, cN0–1 disease (single node ≤3 cm) who have
extranodal extension following surgery.
For patients with positive or close margins, re-resection
(if feasible), RT,
and systemic therapy/RT are treatment options.127 For patients with other
risk features, options include RT or systemic therapy/RT.
For patients with
p16-positive disease and other risk features such as pT3
or pT4 primary,
one positive node >3 cm or multiple positive nodes,
nodal disease in
levels IV or V, perineural invasion, vascular invasion,
or lymphatic
invasion, systemic therapy/RT is a category 2B option For
locally advanced resectable disease (T3–4a, N0–1, or N2–3 for p16-
negative disease; T1–2, cN1 [single node >3 cm, or 2
or more ipsilateral
nodes ≤6 cm] or N2, or T3, N0–3,
or T4 for p16-positive disease), three
treatment options are recommended (see the NCCN
Guidelines for
Cancer of the Oropharynx), in addition to enrollment in
clinical trials. The
three options are: 1) concurrent systemic therapy/RT;127,155 2) resection of
the primary and neck dissection (with appropriate
adjuvant therapy
[systemic therapy/RT or RT]); or 3) induction
chemotherapy (category 3)
(followed by RT or systemic therapy/RT).87,90,389 As with early-stage
disease, tumors at or approaching the midline should be
strongly
considered for bilateral treatment of the neck. An NCDB
analysis including
3,063 patients with cT1, N2 or cT2, N1–2 HPV-positive
oropharyngeal
cancer showed no statistically significant difference in
3-year OS between
patients who received upfront surgery and patients who
received definitive
systemic therapy/RT.390 However,
concurrent systemic therapy/RT is
preferred in patients with locoregionally advanced
HPV-positive disease
who have clinical evidence of fixed or matted nodes or
obvious extranodal
extension in patients, as surgery is not recommended for
these patients.
Panel recommendations regarding adjuvant therapy for
locally advanced
disease do not differ between p16-positive and
p16-negative
oropharyngeal cancer.
Concurrent systemic therapy/RT—with high-dose cisplatin
as the preferred
systemic agent—is recommended for treatment of
locoregionally
advanced p16-positive and p16-negative cancer of the
oropharynx (see
Principles of Systemic Therapy in the NCCN Guidelines for Head and
Neck Cancers). Patients with cN2–3 disease have a higher
likelihood of
needing triple-modality therapy because of poor-risk
factors present
pathologically after resection, which can be associated
with increased
toxicity. Beginning treatment with concurrent systemic
therapy/RT may
help decrease the need for triple modality therapy and
additional
treatment-induced morbidity. Therefore, definitive
concurrent systemic therapy/RT is preferred over upfront surgery for
p16-positive T4 or N3
oropharyngeal cancer.
Many panel members did not agree that induction
chemotherapy should
be recommended for locally or regionally advanced cancer
of the
oropharynx. This disagreement is reflected by the
category 3
recommendations for oropharyngeal cancer (see The
Induction
Chemotherapy Controversy in this Discussion and the NCCN
Guidelines
for Cancer of the Oropharynx).155,374,391-398
The Induction
Chemotherapy Controversy
Defining the role of induction chemotherapy in the
management of locally
or regionally advanced H&N cancers has generated
considerable
discussion within the NCCN Panel. The algorithm for the
management of
advanced p16-positive and p16-negative oropharyngeal
cancer (see the
NCCN Guidelines for Cancer of the Oropharynx)
illustrates the lack of
consensus among NCCN Member Institutions despite the
extensive
discussion. Thus, induction chemotherapy has a category 3
recommendation (ie, major disagreement) for the
management of
locoregionally advanced p16-negative and p16-positive
oropharyngeal
cancer. However in other sites, category 2A and 2B
recommendations for
induction chemotherapy are common based on the update
from RTOG 91-
11 (see Cancer of the Glottic Larynx, Cancer of
the Supraglottic Larynx,
and Cancer of the Hypopharynx in the NCCN
Guidelines for Head and
Neck Cancers).399 For
selected patients with hypopharyngeal and
laryngeal cancers less than T4a in extent (for which
total laryngectomy is
indicated, if managed surgically), induction chemotherapy—used
as part
of a larynx preservation strategy—is listed as a category
2A designation.
Panel members feel that induction chemotherapy should
only be done in
centers with expertise in these regimens because of
challenges
associated with appropriate patient selection and
management of
treatment-related toxicities.391 Residual toxicity from induction chemotherapy
may also complicate the subsequent delivery of definitive
RT or systemic therapy/RT.
A summary of the data helps provide some perspective on
the NCCN
Panel’s recommendations. Most randomized trials of
induction
chemotherapy followed by RT and/or surgery compared to
locoregional
treatment alone, which were published in the 1980s and
1990s, did not
show an improvement in OS with the incorporation of
chemotherapy.396
However, a change in the pattern of failure with less
distant metastases
was noted in some studies.400 Also, a correlation was noted between
response to induction chemotherapy and subsequent durable
response to
radiation.400,401 Thus,
the concept developed that, in selected patients,
induction chemotherapy could facilitate organ preservation,
avoid morbid
surgery, and improve overall quality of life of the
patient even though OS
was not improved. Because total laryngectomy is among the
procedures
most feared by patients,402 larynx preservation was the focus of initial
studies.
Two randomized studies—the Veterans Affairs (VA)
Laryngeal Cancer
Study Group trial in advanced laryngeal cancer and the
EORTC trial
predominantly in advanced hypopharynx cancer—established
the role of
induction cisplatin/5-FU chemotherapy followed by
definitive RT in
responding patients as an alternative treatment to
primary total
laryngectomy and postoperative radiation, offering
potential larynx
preservation without compromise in survival (see Cancer
of the Larynx
and Cancer of the Hypopharynx in this Discussion).400,401 Yet even in this
setting, the role of induction chemotherapy decreased
with time.
Randomized trials and related meta-analyses indicated
that concurrent
systemic therapy/RT (with cisplatin being the
best-studied agent) offered
superior locoregional tumor control and survival compared
to radiation
alone,403-411 and
shorter duration of therapy compared to induction therapy
followed by radiation. Meta-analyses reported that
concurrent systemic therapy/RT was more efficacious than an induction
chemotherapy
strategy.396,398 In
the larynx preservation setting, Intergroup 91-11
compared radiation alone, concurrent cisplatin/radiation,
and induction
cisplatin/5-FU followed by radiation; all arms had
surgery for
relapsed/refractory disease. The concurrent
cisplatin/radiation arm had the
highest larynx preservation rate (see Cancer of the
Larynx in this
Discussion).412 A
long-term follow-up of 91-11 confirmed that concomitant
systemic therapy/RT improved the larynx preservation rate
and that
induction chemotherapy was not superior to RT alone.399 However, OS did
not differ among the treatment arms.
Nonetheless, interest in the role of induction
chemotherapy endures for a
few reasons. Advances in surgery, RT, and concurrent
systemic
therapy/RT have yielded improvements in locoregional
control; thus, the
role of distant metastases as a source of treatment
failure has increased
and induction chemotherapy allows greater drug delivery
for this
purpose.413,414 Clinicians
have increasing concern regarding the long-term
morbidity of concurrent systemic therapy/RT, and thus
have increasing
interest in exploring alternative approaches that might
have a more
favorable side effect profile.415 Finally, a more effective triplet
chemotherapy regimen has been identified for induction
chemotherapy
compared to the standard cisplatin/5-FU used in induction
trials of the
1980s and 1990s, and in the related meta-analyses. Three
phase III trials
compared induction cisplatin plus infusional 5-FU with
(or without) the
addition of a taxane (docetaxel or paclitaxel) followed
by the same
locoregional treatment. Results showed significantly
improved outcomes
(response rates, DFS, or OS, depending on the trial) for
patients in the
three-drug induction group compared to those receiving
two drugs
(cisplatin plus 5-FU).374,394,395,397 A randomized phase III trial in the
larynx
preservation setting similarly showed superior larynx
preservation
outcome when induction docetaxel/cisplatin/5-FU (TPF) and
cisplatin/5-FU
were compared.416,417 A
meta-analysis including five RCTs (N = 1772) showed that the TPF
induction chemotherapy regimen was associated
with reduced risk of death (HR, 0.72; 95% CI, 0.63–0.83; P
< .001) and
greater reductions in progression (HR, 0.78; 95% CI, 0.69–0.87;
P < .001),
locoregional failure (HR, 0.79; 95% CI, 0.66–0.94; P =
.007), and distant
failure (HR, 0.63; 95% CI, 0.45–0.89; P = .009)
compared with cisplatin
plus 5-FU.418
Whether adding induction chemotherapy to concurrent
chemoradiation
results in a clear advantage in OS continues to be
unclear.393,419,420
Both
the DeCIDE and the PARADIGM trials did not convincingly
show a
survival advantage with the incorporation of induction
chemotherapy.419,420
In patients with stage III or IV squamous cell H&N
cancers, a randomized
phase II study compared induction TPF followed by
concurrent
cisplatin/5-FU with RT versus concurrent cisplatin/5-FU
with RT alone. A
higher radiologic complete response rate was reported
with the
incorporation of induction chemotherapy.421 Results from a larger follow-up
study suggest a survival advantage.422
Other induction chemotherapy regimens have been evaluated
in phase II
trials. The ECOG-ACRIN trial (E2303) showed promising
results in terms
of primary site response and survival for cetuximab,
paclitaxel, and
carboplatin as induction chemotherapy, followed by
systemic therapy/RT
with the same drug regimen in patients with stage III or
IV squamous cell
H&N cancers (N = 74),423 but the incremental benefit of
induction
chemotherapy requires further validation using randomized
design. Two
phase II studies have evaluated the feasibility of TPF
with cetuximab
followed by systemic therapy/RT or RT alone.424,425 The DeLOS-II trial
showed that TPF followed by RT, with cetuximab
administered throughout,
was feasible but not superior to TPF and subsequent RT
without
cetuximab.424 An
EORTC trial evaluating this induction regimen followed
by systemic therapy/RT was stopped prematurely due to
numerous
serious adverse events.425 There is currently a lack of consensus regarding the most
appropriate
regimen to be administered following induction
chemotherapy.426
Of note,
investigators in the DeCIDE trial used the combination of
docetaxel/hydroxyurea/5-FU with RT after induction
chemotherapy in this
setting.420 Panel
members agree that weekly cetuximab or carboplatin are
reasonable agents to use with concurrent radiation.419,427-429 Results of the
phase III GORTEC 2007-02 trial, in which 370 patients
with bulky nodal
disease (N2b, N2c, or N3) were randomized to receive
carboplatin/5-FU
with concurrent RT or TPF followed by cetuximab/RT,
showed no
significant differences between the study arms for
survival outcomes and
local control.430 There
was a trend towards a lower rate of distant
metastases in the TPF arm (HR, 0.54; 95% CI, 0.30–0.99; P
= .05).
Weekly cisplatin with RT following induction chemotherapy
is a category
2B option, based on extrapolation.419,428,429 However, because of toxicity
concerns, high-dose cisplatin (100 mg/m2 every 21 days × 3) is not
recommended after induction cisplatin-based chemotherapy.393,428 Thus,
this highlights concerns that any efficacy gains of
induction may be offset
by the use of better-tolerated—but potentially less
effective—concurrent
regimens or poorer patient compliance with the
radiation-based part of
treatment. Because of these uncertainties, enrollment of
patients in
appropriate clinical trials is particularly encouraged.
Outside of a clinical
trial, proceeding directly to concurrent systemic
therapy/RT—high-dose
cisplatin preferred—is considered the gold standard by
many NCCN Panel
Members in several settings (see Principles of
Systemic Therapy in the
NCCN Guidelines for Head and Neck Cancers).104-107,403,431 When
induction chemotherapy is used, data show that the
addition of a taxane to
cisplatin/5-FU, of which TPF is the most extensively
studied, is more
efficacious than cisplatin/5-FU.418,426 Therefore, when used as induction
chemotherapy for squamous cell H&N cancer, this
regimen is a category 1
preferred recommendation. Paclitaxel, cisplatin, and 5-FU
is also an option
for induction chemotherapy.394 Radiation Therapy
Fractionation
The recommended schedules are shown in the algorithm (see
Principles
of Radiation Therapy in the NCCN Guidelines for Cancer
of the
Oropharynx). IMRT is preferred, as it may be
useful for decreasing
toxicity.432,433 A
fractionation schedule of 69.96 Gy at 2.12 Gy/fraction daily
(Monday–Friday) for 6 to 7 weeks is recommended for
patients with highrisk
subclinical disease, consistent with the fractionation
schedule used for
these patients in RTOG 0615.120 Moderate acceleration of treatment is
acceptable in patients with early-stage oropharyngeal
cancer.127,434
Despite the evidence that RT dose deintensification may
improve longterm
function while preserving PFS in patients with
p16-positive
disease,368-370,373 more
studies are needed in this area.
Follow-up/Surveillance
Recommendations for surveillance are provided in the
algorithm (see
Follow-up Recommendations in the NCCN Guidelines for Head and
Neck
Cancers).
Cancer of the Hypopharynx
The hypopharynx extends from the superior border of the
hyoid bone to
the lower border of the cricoid cartilage and is
essentially a muscular, lined
tube extending from the oropharynx to the cervical
esophagus. For staging
purposes, the hypopharynx is divided into three areas: 1)
the pyriform
sinus (the most common site of cancer in the
hypopharynx); 2) the
posterior pharyngeal walls; and 3) the postcricoid area.
Workup and Staging
A multidisciplinary consultation is encouraged. Accurate
staging (see
Table 3) depends on a complete H&N examination
coupled with
appropriate studies (see Workup in the NCCN Guidelines
for Cancer of
the Hypopharynx).318 For
patients with cancer of the hypopharynx, the prognosis can be quite poor
despite aggressive combined modality
treatment.
Treatment
Patients with resectable disease are divided into two
groups based on the
indicated surgical options: 1) those with early-stage
cancer who are
amenable to larynx-preserving (conservation) surgery
(most T1, N0;
selected T2, N0); and 2) those with advanced resectable
cancer who
require pharyngectomy with total or partial laryngectomy
(T1–4a, any N).
The surgery and RT options for the former group (see the
NCCN
Guidelines for Cancer of the Hypopharynx)
represent a consensus among
the panel members.
Patients with T1–3, any N disease, for whom the indicated
surgical option
is partial or total laryngopharyngectomy, may be managed
with three
approaches (see the NCCN Guidelines for Cancer of the
Hypopharynx) in
addition to enrollment in clinical trials: 1) induction
chemotherapy followed
by additional treatment, depending on the response; 2)
surgery with neck
dissection, lymph node dissection, and postoperative
radiation or
chemoradiation as dictated by pathologic risk features;
or 3) concurrent
systemic therapy/RT. When using concurrent systemic
therapy/RT, the
preferred systemic agent is high-dose cisplatin (category
1) (see Principles
of Systemic Therapy in the NCCN Guidelines for Head and
Neck
Cancers). Given the functional loss resulting from this
surgery and the
overall poor prognosis, participation in clinical trials
is encouraged.
The recommendation of the induction
chemotherapy/definitive RT option is
based on an EORTC randomized trial.400 This trial enrolled 194 eligible
patients with stage II to IV resectable squamous cell
carcinoma of the
pyriform sinus (152 patients) and aryepiglottic fold (42
patients), excluding
patients with T1 or N2c disease. Patients were randomly
assigned either
to laryngopharyngectomy and postoperative RT, or to
systemic therapy with cisplatin and 5-FU
for a maximum of 3 cycles, followed by definitive
RT. In contrast to a similar approach used for laryngeal
cancer, a
complete response to induction chemotherapy was required
before
proceeding with definitive RT. The published results
showed equivalent
survival, with median survival duration and a 3-year
survival rate of 25
months and 43% (95% CI, 27%–59%), respectively, for the
surgery group
versus 44 months and 57% (95% CI, 42%–72%), respectively,
for the
induction chemotherapy group.400 A functioning larynx was preserved in
42% of patients who did not undergo surgery. Local or
regional failure
rates did not differ between the surgery-treated patients
and
chemotherapy-treated patients, although the chemotherapy
recipients did
show a significant reduction in distant metastases as a
site of first failure
(P = .041).
For induction chemotherapy as part of a larynx
preservation strategy,
inclusion of only patients with the specified TNM stages
is recommended.
Success on larynx preservation with an induction
chemotherapy strategy
is best established for patients who had a complete
response to induction
therapy at the primary site and stable or improved
disease in the neck. A
randomized trial showed that an alternating regimen of
cisplatin/5-FU with
RT yielded larynx preservation, progression-free
interval, and OS rates
equivalent to those obtained with induction platinum/5-FU
followed by
RT.435,436
However, a long-term
update from this trial showed that larynx
preservation rate was higher in patients who were
randomized to receive
the alternating regimen (32%), compared to patients who
received the
sequential regimen (25%).436 Given available randomized data
demonstrating the superiority of TPF compared with PF for
induction
chemoradiation, the triplet is now recommended as
induction for this
approach.416,417
As noted in the algorithm, surgery is recommended if a
partial response or
less occurs after induction chemotherapy (see the NCCN
Guidelines for
Cancer of the Hypopharynx). The nature of the operation will
depend on
the stage and extent of the tumor. Partial laryngeal
surgery may still be
considered, although most patients will require total
laryngectomy, and at
least a partial pharyngectomy. In this situation, or when
primary surgery is
the selected management path, postoperative systemic
therapy/RT is
recommended (category 1) for the adverse pathologic
features of
extranodal extension and/or positive or close mucosal
margin. For other
risk features, clinical judgment should be used when
deciding to use RT
alone or when considering adding systemic therapy to RT
(see the NCCN
Guidelines for Cancer of the Hypopharynx). Severe
late toxicity appears to
be associated with the amount of RT415 and treatment with radiosensitizing
systemic therapy.
Options for patients with T4a, any N disease include: 1)
total
laryngopharyngectomy plus neck dissection(s) followed by
adjuvant
systemic therapy/RT or RT; 2) enrollment in clinical
trials; 3) induction
chemotherapy (category 3); or 4) systemic therapy/RT
(category 3) (see
the NCCN Guidelines for Cancer of the Hypopharynx,
and Newly
Diagnosed Locoregionally Advanced
Disease under Very
Advanced Head
and Neck Cancers in the Discussion, below).
Radiation Therapy
Fractionation
Fractionation for RT is discussed in the algorithm (see Principles
of
Radiation Therapy in the NCCN Guidelines for Cancer
of the
Hypopharynx).
Follow-up/Surveillance
Recommendations for surveillance are provided in the
algorithm (see
Follow-up Recommendations in the NCCN Guidelines for Head and
Neck
Cancers).
Cancer of the Nasopharynx
NPC is an uncommon cancer, accounting for 0.7% of all
cancers
diagnosed worldwide in 2018.437 However, there are areas of the world
with endemic disease; global incidence rates are highest
in Southeast
Asia (especially southern China), Micronesia/Polynesia,
Eastern Asia, and
North Africa.438 Rates
are two to three times higher in men than in
women.439 Among
H&N cancers, NPC has one of the highest propensities
to metastasize to distant sites, affecting up to
one-third of patients in the
highest-risk subgroups.440 On the other hand, with modern radiotherapy
techniques, locoregional recurrences are uncommon,
occurring in fewer
than 10% among all but the most locally advanced
patients.441The NCCN
Guidelines for the evaluation and management of NPC
provide
recommendations aimed at addressing the risks for local,
regional, and
distant disease.
Workup and Staging
The workup of nasopharyngeal cancer includes a complete
H&N
examination and other studies (see the NCCN Guidelines
for Cancer of
the Nasopharynx). These studies are important to
determine the full extent
of tumor in order to assign stage appropriately and to
design radiation
ports that will encompass all the disease with
appropriate doses.
Multidisciplinary consultation is encouraged. The 2017
AJCC staging
classification (8th edition)
is used as the basis for treatment
recommendations (see Table 2).318
Epstein-Barr virus (EBV) DNA testing may also be
considered (see
Epstein-Barr Virus, below). HPV infection has been
associated with World
Health Organization type I NPC in case reports and very
small case
series, but the limited data regarding the impact on
chemoradiation
outcomes are conflicting.442-444 Therefore, routine testing for HPV in NPC
is not recommended by the NCCN Panel Epstein-Barr Virus
Infection with EBV is an etiologic factor in the
development of NPC.445,446
Workup for NPC may include EBV testing of both the tumor
itself and the
blood, particularly in the presence of nonkeratinizing
and undifferentiated
histology.447-449 Testing
methods for detection of EBV in tumor include ISH
for EBV-encoded RNA (EBER)450 and IHC staining for LMP1.451 ISH for
EBER tends to be a more sensitive testing method for
carcinomas, relative
to LMP1 IHC staining.452 Real-time
PCR may be used to evaluate EBV
DNA load in serum or plasma. Sensitivity and specificity
values range from
53% to 96%, and 88% to 100%, respectively.453 Testing for plasma EBV
DNA has been used in select centers as a means of residual
disease
monitoring. It should be noted as an important caveat
that no standardized
testing procedure has been established worldwide, and
there is little
consensus on sample preparation or assay specifications.454 For patients
with locoregionally confined NPC, studies have shown that
high initial
levels of plasma EBV DNA, or persistently elevated levels
near or at the
end of RT, are associated with a significantly poorer
outcome following RT
or chemoradiation.455-460 A
meta-analysis including 13 studies showed that
plasma EBV DNA levels assessed pre-treatment were
independent
prognostic factors for mortality (HR, 2.81; 95% CI, 2.44–3.24;
P < .001)
and distant metastasis (HR, 3.89; 95% CI, 3.39–4.47; P
< .001), though
these studies were significantly heterogeneous (P =
.03).461 Plasma EBV
DNA has also been studied as an indicator of disease
response to
chemotherapy or chemoradiation prior to additional
treatment462,463
and in
the setting of distant metastases.464 Most of these studies have been
based on real-time PCR assays amplifying the BamHI-W fragment.
Treatment
Patients with T1, N0, M0 nasopharyngeal tumors should be
treated with
definitive RT alone, including elective RT to the neck.
Advanced radiation
techniques are needed for the appropriate treatment of
NPC and to
minimize the long-term side effects that are common in
survivors. IMRT is preferred due to its ability to encompass all areas of
cancer spread, which
can be located in close proximity to the brainstem,
cochleae, and optic
nerves; proton therapy is considered if the normal tissue
constraints
cannot be met by IMRT. Population-based studies have
indicated that
high-volume radiation centers have better outcomes when
treating this
disease.465,466
Locoregionally
Advanced Disease
The Intergroup trial 0099, which randomly assigned
patients to EBRT with
concurrent cisplatin plus adjuvant chemotherapy with
cisplatin and 5-
fluorouracil (PF) for three cycles versus EBRT alone,
closed early when an
interim analysis disclosed a highly significant survival
advantage favoring
the combined chemotherapy and radiation group.431 The addition of
chemotherapy also decreased local, regional, and distant
recurrence
rates. Subsequent phase III randomized trials in Asia
confirmed that
concurrent chemoradiation without adjuvant PF increased
survival when
compared with RT alone.467-470 In one of these trials, 5-year OS was 70%
for the chemoradiation group versus 59% for the RT group.467 A
randomized study conducted in Singapore, which was
modeled after the
Intergroup 0099 treatment regimen, confirmed the benefit
of adding
concurrent platinum to RT with adjuvant PF, using a
multiday infusion of
platinum instead of a single bolus high-dose approach.469 However, one of
the largest phase III randomized trials ever conducted in
NPC comparing
concurrent cisplatin/RT with (or without) adjuvant PF
showed that adjuvant
chemotherapy did not significantly improve survival
following
chemoradiation (HR, 0.74; 95% CI, 0.49–1.10; P =
.13).471
An individual patient data meta-analysis by Blanchard et
al,472 which
included 19 trials and 4806 patients with non-metastatic
NPC, showed that
both adjuvant chemotherapy following chemoradiation and
chemoradiation
without adjuvant chemotherapy were associated with better
OS (HR, 0.65;
95% CI, 0.56–0.76 and HR, 0.80; 95% CI, 0.70–0.93,
respectively) and
PFS (HR, 0.62; 95% CI, 0.53–0.72 and HR, 0.81; 95% CI,
0.71–0.92,
respectively). However, differences between the included
studies
assessing chemoradiation with and without adjuvant
chemotherapy (eg,
different length of follow-up, fewer patients with stage
II disease in trials
assessing adjuvant chemotherapy) limited the ability to
make a firm
conclusion regarding the efficacy of one treatment modality
over the other.
A network meta-analysis based on this individual patient
data
meta-analysis472 (including
20 trials and 5,144 patients) showed that the
addition of adjuvant chemotherapy to chemoradiation was
associated with
better PFS (HR, 0.81; 95% CI, 0.66–0.98), compared to
chemoradiation
only.473 The
authors argued that more chemotherapy, in addition to
concurrent chemoradiation, could reduce recurrence rates.
The
NRG-HN001 trial (NCT02135042) is currently in progress to
further
investigate the role of adjuvant chemotherapy following
chemoradiation in
patients with locoregionally advanced NPC. This phase
II/III study aims to
investigate whether delivery of adjuvant chemotherapy can
be
individualized based on EBV DNA plasma levels after
chemoradiation.
Results from three systematic reviews suggest that
induction
chemotherapy prior to systemic therapy/RT in patients
with locally
advanced NPC may potentially impact tumor control,
compared to
systemic therapy/RT without additional chemotherapy.473-475 However,
these reviews had inconsistent results when evaluating
the impact on
survival. Two reviews showed that induction chemotherapy
prior to
systemic therapy/RT had superior OS and PFS rates, compared
to
systemic therapy/RT alone,474,475 while another review showed that
induction chemotherapy prior to systemic therapy/RT did
not have better
survival outcomes than systemic therapy/RT alone or
systemic therapy/RT
followed by adjuvant chemotherapy.473 Expert groups (eg, ESMO, NCI)
differ in their clinical practice guidelines regarding
use of induction
chemotherapy for these patients,476 and the NCCN expert panel could not
reach uniform consensus in this regard. Clinical trials
are continuing to investigate the role
of induction chemotherapy prior to systemic
therapy/RT for patients with locoregionally advanced NPC,
and two
recently published randomized phase III trials from China
show a survival
benefit for induction chemotherapy followed by concurrent
systemic
therapy/RT, compared to concurrent systemic therapy/RT
alone.477,478
Currently available evidence shows trends favoring the
addition of
chemotherapy to concurrent systemic therapy/RT in
patients with
locoregionally advanced NPC;473-475 however, it remains unclear whether
to administer chemotherapy to these patients before or
after systemic
therapy/RT.
For patients with locoregionally advanced NPC (T1, N1–3;
T2–T4, any N),
enrollment in a clinical trial is preferred. The panel
recommends
concurrent systemic therapy/RT (cisplatin) with either
induction or adjuvant
chemotherapy for locoregionally advanced NPC. Concurrent
systemic
therapy/RT (cisplatin) alone is a category 2B
recommendation. Concurrent
cisplatin with radiation is recommended for all patients
who do not have a
contraindication to the drug, because the vast majority
of randomized trials
support the use of cisplatin in this setting.431,467 If using adjuvant
chemotherapy, the standard remains PF. The substitution
of carboplatin
for cisplatin in induction, concurrent, and adjuvant
regimens, while studied
to some extent, should be limited to cisplatin-ineligible
patients.429,479,480
Induction chemotherapy (followed by systemic therapy/RT)
is also a
recommended option for patients with NPC with either T1,
N1–3 or T2–T4,
any N lesions. Gemcitabine/cisplatin is a category 1
preferred option,478
and modified TPF is also a category 1 option, but only
for EBV-associated
disease, as panel members observed that the dosing
schedule used in the
study by Sun et al481 (docetaxel
60 mg/m2 every 3 weeks, cisplatin 60
mg/m2
every 3 weeks, and 5-FU
600 mg/m2
as a continuous 120-hour
infusion on days 1–5, 22–26, and 43–47) may not be
effective for non–
EBV-associated disease in patients in the United States.
Besides TPF,
several other induction/sequential chemotherapy regimens
are lower-level
recommendations included in the algorithm for NPC.395,429,467,477,482
Radiation Therapy
Fractionation
Radiation dose-fractionation schedules may vary slightly
depending on
institutional preference (see Principles of Radiation
Therapy in the NCCN
Guidelines for Cancer of the Nasopharynx).
Radiation doses of 66 to 70.2
Gy given in standard fractions of 1.8 to 2.0 Gy/fraction
are recommended
for control of the gross primary tumor and involved lymph
nodes; an
alternative schedule consists of 2.12 Gy/fraction daily
(Monday–Friday) for
33 to 35 fractions to all areas of gross disease to a
total dose of
approximately 70 Gy.120 Low-
to intermediate-risk subclinical disease, such
as in the low neck, is often treated with 44 to 50 Gy at
2.0 Gy/fraction or
can be treated simultaneously with the main plan for the
gross disease to
54 to 63 Gy at 1.6 to 1.8 Gy/fraction. For areas
considered to be at
intermediate risk, slightly higher doses such as 59.4 to
63 Gy in 1.8 to 2.0
Gy/fraction can be given to different regions of the
skull base and neck.
The total doses and fractionation should be prescribed in
relationship to
each other and the overall schedule as part of an
integrated plan to
address the varying areas at risk.
Follow-up/Surveillance
Recommendations for surveillance are provided in the
algorithm (see
Follow-up Recommendations in the NCCN Guidelines for Head and
Neck
Cancers). Since the deep areas of the skull base are
inaccessible to
clinical examination, periodic cross-sectional imaging
may be necessary.
The clinical benefit of blood EBV DNA monitoring is
currently uncertain
(see Epstein-Barr Virus, above), but it may be
considered in centers with
experience
(category 2B).
