Management of lymph node metastases from an unknown primary site to the head and neck (Review)
- Authors:
- Published online on: July 29, 2014 https://doi.org/10.3892/mco.2014.361
- Pages: 917-922
Abstract
1. Introduction
Cancer of unknown primary site (CUP) is a heterogenous group of malignancies presenting with distant metastases without an identified primary tumor at diagnosis (1). As a clinical entity defined by the exclusion of a primary tumor, the standardized diagnostic work-up includes meticulous medical history and clinical examination using modern diagnostic tools. The estimated incidence of CUP accounts for ~3–9% of all head and neck cancers, with squamous cell histology accounting for 53–77% of the cases (2–4). Over the last few years, there has been a decrease in the incidence of cervical CUP, due to a more accurate diagnosis of the primary tumor by means of a thorough fibre optic endoscopy of the pharynx and larynx, esophagogastroduodenoscopy, bronchoscopy and advanced imaging technology in the majority of patients (5).
Cervical CUP preferentially affects male patients, aged 55–60 years, with a history of alcohol and tobacco abuse; however, a proportion of CUP cases may include younger non-smokers presenting with human papillomavirus (HPV)-related oropharyngeal cancer. The discrepancies observed in certain series may result from the inclusion of patients with tumors of other histological types (such as undifferentiated carcinomas, lymphomas and melanoma) (5–7). The symptom that commonly prompts initial consultation is a mass in the neck, which accounted for 94% of the 352 patients in the series reported by Grau et al (5), with pain and weight loss reported in only 9 and 7%, respectively. In a series of 167 patients reported by Issing et al (4), the incidence of cervical swelling, pain and dysphagia was 100, 9 and 3.6%, respectively. Typically, the enlarged cervical lymph nodes are located at level II, with bilateral involvement reported in <10% of the cases (2,4,5). The clinical N classification in the majority of cases is N2, with a median nodal size of 3.5–5 cm (2,5,8) and the time interval between the appearance of cervical mass and diagnosis is 2–5 months (2,4).
The optimal therapeutic management of patients with CUP remains controversial, due to the absence of randomized studies comparing different treatment options. Therefore, treatment is mainly based on non-randomized evidence and institutional policy. Recommendations include surgery alone (9), limited field radiotherapy and extensive prophylactic irradiation of all the potential mucosal sites and both sides of the neck, with or without concomitant chemotherapy (10–12). However, the morbidity of these combined treatments may be high, decreasing the quality of life of relatively young patients. No randomized or prospective studies are currently available to specifically support these approaches and such a study may be difficult to undertake, as this disease is rare.
In this review, only patients with the squamous cell histotype are discussed, as patients with other histological types may undergo different treatment and have a different prognosis. The aim of the present review was to revise the diagnostic work-up of this entity, including molecular biology, and to better define the multidisciplinary approach of patients with cervical node metastases from CUP, including the extent of neck surgery, the volume and dose of radiation and the addition and type of systemic therapy.
2. Diagnostic work-up
The diagnostic approaches in patients with CUP are first aimed at establishing the histopathological type of the tumor and, second, at detecting the primary tumor site. These two objectives are interdependent, as histopathological diagnosis guides the search for the primary site and the diagnostic work-up determines the N and M classification of the disease. Therefore, the diagnostic manoeuvres include physical examination, fine-needle aspiration biopsy (FNAB), imaging studies, endoscopy and molecular biology studies.
Physical examination
A painless and unilateral cervical mass is the most common clinical presentation. The site of palpable cervical lymphadenopathy may be useful in suggesting the possible primary tumor site. In patients with a squamous cell histotype, the jugulodigastric and midjugular lymph nodes are most commonly involved, whereas metastatic adenocarcinoma is more frequently diagnosed in the low cervical or supraclavicular areas. In addition, based on the metastatic lymph node level, several possible sites of the primary tumors may be predicted (13) (Table I). The most commonly involved level of lymph node involvement is level II (30–50%), followed by levels I and III (10–20%) and levels IV and V (5–10%).
FNAB
FNAB is most commonly used as the first-step diagnostic procedure to establish malignancy. This is an efficient, minimally invasive and cost-effective diagnostic method, with a negligible risk of seeding tumor cells along the needle track (14). The diagnosis is usually established with routine histological staining, supplemented by immunohistochemical analysis. Provided this approach is conducted by an experienced histopathologist, it may achieve a diagnostic sensitivity of 83–97% and a specificity of 91–100% for metastatic lesions (14,15). Repeat FNAB, core or open biopsy may be required in cases of uncertain or non-diagnostic histology. However, the value of performing an open biopsy remains controversial, due to the high incidence of local recurrence. Martin and Morfit (16) described open biopsy as ‘ill-advised and needless surgery’. By contrast, no adverse effects regarding neck disease control or survival were reported in studies of open neck lymph node biopsy, provided that the biopsy was followed by definitive treatment in the form of radiotherapy or comprehensive neck dissection (17). In view of these data, it may not be imperative to perform an immediate neck dissection when an open biopsy frozen sections reveal metastatic cancer in the excised node. Of note, an open neck lymph node biopsy should not be performed prior to the completion of a thorough clinical, radiological and endoscopic search for the primary tumor.
Imaging
Computed tomography (CT) or magnetic resonance imaging (MRI) of the neck may be performed in order to determine the extent of the disease. The aim of performing imaging studies in such patients is, first, the detection of the primary site in the head and neck region and, second, the staging evaluation of the lymph node status prior to any locoregional treatment. Imaging should be performed prior to any invasive procedure or treatment, in order to avoid diagnostic misinterpretation. If the lymph node is situated in levels IV or V, a chest/abdominal/pelvic CT is recommended. The extent and location of cervical disease and its association with neighboring structures, the presence of extracapsular extension and the status of the retropharyngeal and contralateral neck nodes should be investigated. In the search for a primary tumor in the head and neck, a CT scan may be either complemented or supplanted by MRI with gadolinium contrast, which exhibits superior soft tissue resolution, particularly for the evaluation of the nasopharynx or oropharynx. The potential of CT, MRI or both to detect a primary tumor ranges from 9.3 to 23% (3,18,19), rising to 60% when suspicious radiological findings direct subsequent endoscopic biopsies (20).
Over the last 2 decades, positron emission tomography (PET) has also been used in patients with CUP. A review of 16 studies using fludeoxyglucose (18F-FDG)-PET reported a diagnostic accuracy in detecting the primary tumor site of 24.5%, while sensitivity and specificity were 88 and 75%, respectively (21,22). A disadvantage of FDG-PET is its lack of anatomical information, which may impede precise localization of the FDG accumulation. Therefore, the application of combined FDG-PET/CT or MRI may be of greater value in the detection of the primary site. Several studies using FDG-PET/CT reported identification of the primary tumor in 48–73% of the cases and modification of treatment plans in almost 30% of the patients (23). Kwee and Kwee (24) published a meta-analysis of 11 studies, including 433 patients with CUP who underwent PET/CT; the overall primary tumor detection rate was 37%, with 84% sensitivity and 84% specificity. In 4 of those studies, only patients with CUP were enrolled and the primary tumor detection rate was 28–57%, whereas sensitivity and specificity were 70–100% and 73–100%, respectively. In 3 of the trials comparing the utility of PET/CT vs. PET, the authors reported that, although PET/CT identified more primary sites compared to PET, these differences were not statistically significant. Overall, PET/CT was reported to modify therapy in 20–60% of the cases.
Molecular studies
Better insight into the etiology and pathogenesis of head and neck tumors has led to the development of specific diagnostic tests and effective therapeutic strategies. Molecular studies have the potential to further improve diagnosis. Among head and neck cancers, the Epstein-Barr virus (EBV) genome has been identified only in nasopharyngeal carcinoma (25). As a result, the identification of the EBV genome in a metastatic cervical node may lead to the subsequent identification of an unsuspected primary site within the nasopharynx. In situ hybridization for EBV-encoded RNA or polymerase chain reaction for EBV genomic DNA may be performed on tissue obtained by FNAB and should be considered, particularly for young patients with poorly differentiated squamous cell carcinoma histology in a cervical lymph node (25). High-risk HPV has been advocated as a major etiological factor for a subset of head and neck squamous cell carcinomas. These carcinomas are considered to exhibit a special predilection for the oropharyngeal tonsils and are characterized by non-keratinizing basaloid morphology and a strong reactivity to p16 immunostaining. Identifying HPV DNA or RNA in the lymph nodes may thus provide a means for localizing the primary tumor site in the oropharynx (26). These molecular findings used in conjunction with histology, clinical history and radiological findings, may be used to distinguish the primary site of cervical lymph node metastases of CUP of the head and neck.
Endoscopy with biopsy
A definitive evaluation of the unknown primary site may be performed using endoscopy of the upper aerodigestive tract (UADT) with the patient under general anesthesia, assisted by careful palpation of accessible regions and directed biopsies of clinically or radiologically suspicious areas. Bronchoscopy is recommended when there is an abnormality of the lung on chest imaging (20). The likelihood of discovering a primary tumor by endoscopy correlates with the presence of suspicious findings on preliminary examination. When routine diagnostic work-up fails to identify the primary tumor, subsequent endoscopy may be successful in 29.2% of the cases, as reported by Cianchetti et al (20). Repeated endoscopy is required only when the suspicious site was not adequately biopsied during the first procedure.
The tonsillar fossa and the base of the tongue are considered to be one of the most common sites of a hidden primary tumor in patients with CUP. Although the true incidence remains unknown, it is estimated to be 18–40%. The tonsils have also been incriminated as the site of occult primary tumors, particularly in patients bearing head and neck tumors associated with chronic HPV infection of the upper aerodigestive mucosa. It was previously suggested that directed random biopsies and unilateral or bilateral tonsillectomy should be included in the screening for detection of the occult primary tumor (27). In the absence of a visible or palpable lesion, Waltonen et al (28) reported that tonsillectomy may result in a significantly higher likelihood of detecting an occult tonsillar tumor compared to deep tonsil biopsy. The evidence supporting bilateral tonsillectomy is less convincing, although the detection rates of a primary tumor site in the contralateral tonsil were reported to be 10–23% (27–29).
According to data reported in the literature, in an optimal scenario, the diagnostic work-up should be conducted in 4 steps: i) Patient history, clinical examination with UADT assessment by multiple examiners and modern imaging using contrast-enhanced CT or MRI as the method of choice. The added value of FDG-PET/CT to the conventional work-up has yet to be determined. ii) Tissue diagnosis preferably obtained by a FNAB; when the FNAB is non-diagnostic, it should be repeated (image-guided). A core needle biopsy is recommended after multiple inconclusive FNABs followed by excisional biopsy of the enlarged node. Appropriate immunohistochemical examinations allow tissue characterization of the tumor in the vast majority of the patients. iii) Endoscopy under general anesthesia with ipsilateral tonsillectomy and directed biopsy. Optimal imaging information of the potential sites of the hidden primary tumor is crucial, as this guides mucosal sampling. Reversing the order of examinations increases the rate of false-positive findings on CT or PET. A second endoscopy is required only when a suspicious mucosal site is inadequately biopsied during the previous procedure. iv) Molecular studies. To obtain optimal information predicting the primary site, HPV and/or EBV immunostaining of the FNAB sample obtained from the enlarged cervical lymph node is required, particularly in cases where no suggestive findings are recorded on imaging and endoscopy and/or in patients without a history of smoking and alcohol abuse.
3. Treatment
The optimal therapeutic management of patients with cervical CUP remains controversial, due to the absence of randomized studies comparing different treatment options. The type of treatment may be individualized depending on patient age, tumor site, histology and extent of metastatic lymph node involvement. Generally, these patients should be treated with aggressive multimodal therapy, similar to patients with locally advanced head and neck cancer.
The majority of authors recommend surgical removal of the neck disease, followed by comprehensive postoperative radiotherapy (5,30–32). Surgery alone is not recommended, except for patients with pN1 or N2a neck disease in level I, with no extracapsular extension. The locoregional control rates were reported to be 80–90%, with a median nodal recurrence rate of ~34% and a 5-year overall survival rate of ≤65% (33). Treating a metastatic lymph node in the neck from CUP requires complying with 2 requirements: i) the surgical procedure must be oncologically sound and the damage inflicted to the anatomical structures of the neck should be kept to a minimum; and ii) open biopsy of a positive lymph node or isolated adenectomy are generally discouraged, unless there is strong cytological evidence of a lymphoma. However, if the cytology is compatible with squamous cell carcinoma, opening the capsule of an infiltrated lymph node or breaking the lymphatic drainage net may increase the risk of tumor dissemination. Thus, the minimum procedure considered for the surgical treatment of a metastatic lymph node in the neck is selective neck dissection of the affected lymphatic levels. The extent of the dissection is determined by the radiological and clinical findings and must involve the entire lymphatic chain where the metastatic lymph nodes are situated, avoiding an oversized surgical procedure. Radical neck dissection should only be considered in cases with radiological signs or intraoperative findings of extracapsular disease involving the jugular vein or the sternocleidomastoid muscle.
Neck dissection in a patient with an unknown primary site is the final step in the diagnostic effort aiming to locate the primary tumor, as well as the first therapeutic procedure. Therefore, neck dissection in a patient with an unknown primary site must be performed only after the exhaustion of all other available diagnostic methods. The cervical specimen will provide enough tumor tissue to perform full immunohistochemical studies that may eventually yield decisive data regarding the site of origin.
Radiation alone has been extensively used, with acceptable results (5,12). A potential advantage of radiation compared to surgery in this setting is that potential primary sites in the head and neck may be included in the radiation field. Neck dissection following irradiation may be required for nodal residual disease (34). A nodal excision may be sufficient when radical, comprehensive irradiation to the neck and mucosal sites is planned (30). The most frequently used therapeutic approach consists of surgical removal of the neck disease, followed by postoperative radiotherapy to the neck, or to the neck and the involved mucosa. The indications for postoperative radiotherapy in patients with CUP include excisional or incisional biopsy of the neck prior to definitive treatment, extracapsular extension of the tumor and multiple positive lymph nodes. However, primary radiotherapy may be administered to patients with initial stage N2b or N3 disease as a sole treatment, or followed by neck dissection after 4–6 weeks. Patients with large nodes fixed to the adjacent structures and patients with a low performance status and comorbidities may also be treated by primary irradiation.
Although the value of irradiation of the potential primary sites has not been confirmed by randomized studies, several authors reported that mucosal irradiation reduces the emergence of primary tumors and regional recurrence, without however affecting overall survival (33,35,36). A higher 5-year overall survival rate was reported for patients treated with extensive radiotherapy including the neck nodes and pharyngeal mucosa, compared to those treated by more limited volumes (57.6 vs. 24%; P<0.01). According to the level of the neck affected, the dose commonly administered with standard fractionation (dose per fraction of 1.8–2 Gy) is 65–70 Gy to the involved nodal stations and 50 Gy for the uninvolved neck and mucosal sites. In case of clinically suspicious mucosal sites, a dose of 60–64 Gy is recommended. The predominant manifestations of acute radiation toxicity include dysphagia and mucositis, particularly in patients treated with combined radiochemotherapy compared to those treated with radiotherapy alone. Xerostomia is the most common late complication of radiotherapy. Other late adverse effects include persisting edema of the larynx or skin, soft tissue fibrosis, necrosis and osteoradionecrosis (33,35–37). Huang et al (38) reported severe (grade 3–4) acute mucositis in 34%, insertion of a nasogastric feeding tube in 54% and severe late xerostomia or neck fibrosis in 7% of the patients. Combined with postoperative complications and post-chemotherapy toxicity, antineoplastic treatment may significantly affect the quality of life, particularly in long-term surviving patients, underlining the significance of advanced radiotherapy techniques, such as 3D conformal and intensity-modulated radiation therapy, regardless of any anticipated benefit on tumor control.
Concurrent chemoradiotherapy in patients with locally advanced squamous cell carcinoma of the head and neck significantly improves response rate and overall survival (39–44). In addition, the combination of platinum-based chemotherapy with cetuximab exhibited increased efficacy as first-line treatment of patients with recurrent or metastatic head and neck cancer (43). The abovementioned results were obtained from large, well-conducted randomized studies published over the last few years. However, there are currently no available randomized reports on the efficacy of chemoradiotherapy in patients with CUP. To the best of our knowledge, only 4 retrospective studies, including ~100 patients treated with various cytotoxic agents, have been conducted to date. Chemotherapy was administered prior to, during or after radiotherapy and the results were compared to historical controls (43–46).
4. Conclusion
Over the past several decades, the substantial improvements in diagnostics have allowed more accurate determination of the extent of the disease in the neck and the systemic spread to distant organs and the identification of the hidden primary tumor in more than half of the patients with CUP presenting as a neck mass. In cases with no primary tumor on initial examinations, the site of the index primary may be predicted with a high level of probability.
There remains the question of whether CUP is different from tumors of known primary site. If we accept the concept of a specific natural history and biology of unknown primary tumors, further research on the biology of CUP should focus on determining whether this group of tumors share unique genetic, chromosomal and/or phenotypic anomalies. It is hypothesized that novel molecular techniques, such as DNA and gene expression profiling as well as proteomics, play a significant role in this research (47,48).
The optimal extension of radiotherapy volumes remains an open issue. A randomized trial proposed by the European Organization for Research on Treatment of Cancer Radiotherapy Group and the Radiation Therapy Oncology Group, designed to investigate whether the disease-free survival achieved by ipsilateral neck irradiation is equivalent to that achieved by a more extensive irradiation field including mucosal and bilateral neck nodes, was prematurely terminated due to insufficient accrual. The answer to this question may lead to major management decisions for the majority of patients with cervical CUP.
The use of immunohistochemical markers may predict response to treatment, similar to other types of head and neck cancer (48,49). However, the focus of investigation is the natural history of CUP. Insights into the molecular biology of CUP are required in order to identify the cell signalling pathways responsible for primary tumor dormancy and early metastatic spread, leading to the optimal diagnostic and therapeutic management of these patients.
Acknowledgements
This study was supported by the Natural Science and Doctor Program Fund of Guangdong Province (grant no. S2012040006622) and the International Cooperative Program Fund of Guangdong Province (grant no. 2012B050600015).
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